MCT8316AT [TI]
MCT8316A High Speed Sensorless Trapezoidal Control Integrated FET BLDC Driver;型号: | MCT8316AT |
厂家: | TEXAS INSTRUMENTS |
描述: | MCT8316A High Speed Sensorless Trapezoidal Control Integrated FET BLDC Driver |
文件: | 总179页 (文件大小:5489K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
MCT8316A
SLLSFH8A – AUGUST 2021 – REVISED DECEMBER 2021
MCT8316A High Speed Sensorless Trapezoidal Control Integrated FET BLDC Driver
1 Features
3 Description
•
Three-phase BLDC motor driver with integrated
sensorless motor control algorithm
– Code-free high speed Trapezoidal Control
– Supports upto 3 kHz (electrical frequency)
– Very fast startup time (<50 ms)
– Fast Deceleration (<150 ms)
– Supports 120° or 150° modulation to improve
acoustic performance
– Windmilling support through forward
resynchronization and reverse drive
– Analog, PWM, freq. or I2C based speed input
– Active Demagnetization to reduce power losses
– Configurable motor startup and stop options
– Optional closed loop speed control
– Anti-voltage surge protections prevents
overvoltage
– Variable monitoring through DACOUT
4.5- to 35-V operating voltage (40-V abs max)
High output current capability: 8-A peak
Low MOSFET on-state resistance
– 95-mΩ RDS(ON) (HS + LS) at TA = 25°C
Low power sleep mode
– 3-µA (maximum) at VVM = 24-V, TA = 25°C
Speed loop accuracy: 3% with internal clock and
1% with external clock reference
The MCT8316A provides
a
single-chip, code-
free sensorless trapezoidal solution for customers
requiring high speed operation (up to 3kHz electrical)
or very fast startup time (<50ms) for 12- to 24-V
brushless-DC motors up to 8-A peak current. The
MCT8316A integrates three 1/2-H bridges with 40-V
absolute maximum capability and a very low RDS(ON)
of 95 mΩ (high-side + low-side). Power management
features of an adjustable buck regulator and LDO
generate the 3.3-V or 5.0-V voltage rails for the device
and can be used to power external circuits.
Sensorless trapezoidal control is highly configurable
through register settings (MCT8316AV) or hardware
pins (MCT8316AT) ranging from motor start-up
behavior to closed loop operation. Register settings
for MCT8316AV can be set in non-volatile EEPROM,
which allows the device to operate stand-alone once
it has been configured. The device receives a speed
command through a PWM input, analog voltage,
variable frequency square wave or I2C command.
There are a large number of protection features
integrated into the MCT8316A, intended to protect the
device, motor, and system against fault events.
•
•
•
•
•
•
Device Information(1)
PART NUMBER
MCT8316A1V
PACKAGE
VQFN (40)
VQFN (40)
BODY SIZE (NOM)
7.00 mm × 5.00 mm
7.00 mm × 5.00 mm
Flexible device configuration options
– MCT8316AV: I2C interface (EEPROM)
– MCT8316AT: Hardware pin based configuration
Supports up to 100-kHz PWM frequency for low
inductance motor support
MCT8316A1T
•
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
•
•
•
•
•
•
Does not require external current sense resistor
Built-in 3.3-V ±5%, 20-mA LDO regulator
Built-in 3.3-V/5-V, 170-mA buck regulator
Dedicated DRVOFF pin to disable (Hi-Z) outputs
Spread spectrum and slew rate for EMI mitigation
Suite of Integrated protection features
Documentation for reference:
•
•
•
Refer E2E FAQ for clarification.
Refer MCT8316A tuning guide
Refer to the MCT8316A EVM GUI
LDO out
3.3-V, up to 20-mA
– Supply undervoltage lockout (UVLO)
– Motor lock detection (5 different types)
– Overcurrent protection (OCP)
– Thermal warning and shutdown (OTW/TSD)
– Fault condition indication pin (nFAULT)
– Optional fault diagnostics over I2C interface
4.5 to 35-V (40-V abs max)
Buck out
3.3 or 5.0-V, up to 170-mA
SPEED
PWM, analog, frequency or
commanded over I2C
MCT8316A
A
B
C
DIRECTION
BRAKE
Sensorless
Trap
A
FG
Speed feecback
EEPROM
/HW
nFAULT
I2C/HW
Op onal during opera on;
I2C speed, diagnos cs, or
on-the- y con gura on
Buck/LDO Regulator
2 Applications
8-A peak output current,
typically 12 to 24-V
•
•
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Brushless-DC (BLDC) Motor Modules
Robotic Vacuum Suction Motors
Motor Cycle Fuel Pumps
Appliance Fans and Pumps
Automotive Fan and Blowers
Medical CPAP Blowers
Integrated Current Sensing
DACOUTx
Op onal real- me variable
monitoring, 12-bit DAC
Simplified Schematic
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
MCT8316A
www.ti.com
SLLSFH8A – AUGUST 2021 – REVISED DECEMBER 2021
Table of Contents
1 Features............................................................................1
2 Applications.....................................................................1
3 Description.......................................................................1
4 Revision History.............................................................. 2
5 Device Comparison Table...............................................3
6 Pin Configuration and Functions...................................7
7 Specifications.................................................................. 9
7.1 Absolute Maximum Ratings........................................ 9
7.2 ESD Ratings............................................................... 9
7.3 Recommended Operating Conditions.........................9
7.4 Thermal Information..................................................10
7.5 Electrical Characteristics...........................................10
7.6 Characteristics of the SDA and SCL bus for
Standard and Fast mode.............................................16
7.7 Typical Characteristics..............................................18
8 Detailed Description......................................................19
8.1 Overview...................................................................19
8.2 Functional Block Diagram.........................................20
8.3 Feature Description...................................................22
8.4 Device Functional Modes..........................................82
8.5 External Interface......................................................82
8.6 EEPROM access and I2C interface.......................... 84
8.7 EEPROM (Non-Volatile) Register Map..................... 90
8.8 RAM (Volatile) Register Map...................................147
9 Application and Implementation................................156
9.1 Application Information........................................... 156
9.2 Typical Applications................................................ 156
10 Power Supply Recommendations............................165
10.1 Bulk Capacitance..................................................165
11 Layout.........................................................................166
11.1 Layout Guidelines................................................. 166
11.2 Layout Example.................................................... 167
11.3 Thermal Considerations........................................168
12 Device and Documentation Support........................169
12.1 Support Resources............................................... 169
12.2 Trademarks...........................................................169
12.3 Electrostatic Discharge Caution............................169
12.4 Glossary................................................................169
13 Mechanical, Packaging, and Orderable
Information.................................................................. 169
13.1 Tape and Reel Information....................................169
4 Revision History
Changes from Revision * (August 2021) to Revision A (December 2021)
Page
•
Updated device status to Production Data......................................................................................................... 1
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SLLSFH8A – AUGUST 2021 – REVISED DECEMBER 2021
5 Device Comparison Table
DEVICE
PACKAGES
40-pin VQFN (7x5 mm)
INTERFACE
BUCK REGULATOR
MCT8316AV
MCT8316AT
I2C
Yes
Hardware
Table 5-1. MCT8316AV (I2C variant) vs MCT8316AT (Hardware variant) configuration comparison
Parameter
MCT8316AV (I2C variant)
MCT8316AT (Hardware variant)
Initial Speed Detect (ISD) Parameters
ISD Enable
ISD_EN (2 settings)
Enable
Brake Enable
BRAKE_EN (2 settings)
HIZ_EN (2 settings)
Disable
Hi-Z Enable
Disable
Reverse Drive Enable
Resynchronization Enable
Stationary Brake Enable
Stationary Detect Threshold
Brake Mode
RVS_DR_EN (2 settings)
RESYNC_EN (2 settings)
STAT_BRK_EN (2 settings)
STAT_DETECT_THR (8 settings)
BRK_MODE(2 settings)
BRK_CONFIG (2 settings)
BRK_CURR_THR (8 settings)
BRK_TIME (16 settings)
HIZ_TIME (16 settings)
Enable
Enable
Enable
25-mV
Low side
Brake Configuration
Brake Current Threshold
Brake Time
N/A since BRAKE_EN is set to Disable
Hi-Z Time
N/A since HIZ_EN is set to Disable
RMP_1, RMP_2 pins (12 settings)
Stationary Brake Time
Motor Start-up Parameters
Start-up Method
STARTUP_BRK_TIME (8 settings)
MTR_STARTUP (4 settings)
ALIGN_RAMP_RATE (16 settings)
ALIGN_TIME (16 settings)
RMP_1 pin (2 settings)
RMP_1, RMP_2 pins (4 settings)
RMP_1, RMP_2 pins (16 settings)
20%
Align Ramp Rate
Align Time
Align Duty
ALIGN_DUTY (8 settings)
Align Current Threshold
IPD Clock Frequency
IPD Current Threshold
IPD Release Mode
ALIGN_CURR_THR (16 settings)
IPD_CLK_FREQ (8 settings)
IPD_CURR_THR (16 settings)
IPD_RLS_MODE (2 settings)
IPD_ADV_ANGLE (4 settings)
IPD_REPEAT (4 settings)
ILIMIT_1, ILIMIT_2 pins (7 settings)
CONFIG_1 pin (4 settings)
ILIMIT_1, ILIMIT_2 pins (7 settings)
Tristate
IPD Advance Angle
30o
IPD Repeat Times
RMP_1, RMP_2 pins (2 settings)
RMP_1, RMP_2 pins (18 settings)
First Cycle Frequency
Open Loop Parameters
Open Loop Current Limit Configuration
Open Loop Duty Cycle
Open Loop Current Limit
Open Loop Acceleration A1
Open Loop Acceleration A2
Open to Closed Loop Handoff Threshold
Auto Handoff
SLOW_FIRST_CYC_FREQ (16 settings)
OL_ILIMIT_CONFIG (2 settings)
OL_DUTY (8 settings)
Open loop current limit defined by OL_ILIMIT
RMP_1, RMP_2 pins (4 settings)
ILIMIT_1, ILIMIT_2 pins (7 settings)
RMP_1, RMP_2 pins (16 settings)
Same value as OL_ACC_A1
OL_ILIMIT (16 settings)
OL_ACC_A1 (32 settings)
OL_ACC_A2 (32 settings)
OPN_CL_HANDOFF_THR (32 settings)
AUTO_HANDOFF (2 settings)
FIRST_CYCLE_FREQ_SEL (2 settings)
MIN_DUTY (16 settings)
RMP_1, RMP_2 pins (2 settings)
RMP_1, RMP_2 pins (2 settings)
Defined by SLOW_FIRST_CYC_FREQ
CONFIG_3 pin (4 settings)
First Cycle Frequency Select
Minimum Duty
Closed Loop Parameters
Commutation Type
COMM_CONTROL (2 options)
CL_ACC (32 settings)
120o commutation
Closed Loop Acceleration Rate
Closed Loop Deceleration Rate
RMP_1, RMP_2 pins (16 settings)
Same value as CL_ACC
CL_DEC (32 settings)
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Table 5-1. MCT8316AV (I2C variant) vs MCT8316AT (Hardware variant) configuration comparison
(continued)
Parameter
MCT8316AV (I2C variant)
PWM_FREQ_OUT (32 settings)
PWM_MODUL (3 settings)
PWM_MODE (2 settings)
LD_ANGLE_POLARITY
MCT8316AT (Hardware variant)
CONFIG_1 pin (8 settings)
Mixed modulation
PWM Switching Frequency
PWM Modulation
PWM Mode
Single-ended mode
Lead Angle Polarity
Lead Angle
Positive
LD_ANGLE( 256 settings)
DYN_DEGAUSS_EN (2 settings)
LDANGLE pin (16 settings)
RMP_1, RMP_2 pins (2 settings)
LDANGLE pin (16 settings)
Dynamic Degauss Enable
BEMF Threshold
BEMF_THRESHOLD1 and
BEMF_THRESHOLD2 (64 settings)
Fast Start-up Enable
INTEG_ZC_METHOD (2 settings)
CLOSED_LOOP_MODE (4 settings)
MAX_SPEED (65536 settings)
RMP_1, RMP_2 pin (2 settings)
Disable
Speed/ Power Loop Enable
Maximum Speed
N/A since CLOSED_LOOP_MODE is set to
Disable
Speed/ Power Loop Max. Duty Cycle
Speed/ Power Loop Min. Duty Cycle
Speed/ Power Loop Kp
SPD_POWER_V_MAX (8 settings)
SPD_POWER_V_MIN (8 settings)
SPD_POWER_KP (1024 settings)
SPD_POWER_KI (4096 settings)
CONST_POWER_MODE (4 settings)
MAX_POWER (1024 settings)
Speed/ Power Loop Ki
Power Regulation Mode
Maximum Power
Constant Power Limit Hysteresis
Fast Deceleration Enable
Fast Deceleration Current Limit
Fast Deceleration Speed Delta
Fast Deceleration Duty Threshold
Fast Deceleration Duty Window
Dynamic Brake Current Limit Enable
Dynamic Brake Current Low Limit
FG Signal Configuration Parameters
FG Output Mode Select
CONST_POWER_LIMIT_HYST (4 settings)
FAST_DECEL_EN (2 settings)
Disable
FAST_DECEL_CURR_LIM (16 settings)
FAST_BRK_DELTA (8 settings)
N/A since FAST_DECEL_EN is set to Disable
FAST_DEC_DUTY_THR (8 settings)
FAST_DEC_DUTY_WIN (8 settings)
DYNAMIC_BRK_CURR (2 settings)
DYN_BRK_CURR_LOW_LIM (16 settings)
FG_SEL (3 settings)
Output FG in open and closed loop
Divide by 1 (2-pole motor)
FG division factor
FG_DIV (16 settings)
FG Configuration
FG_CONFIG (2 settings)
FG_BEMF_THR (8 settings)
FG active as long as motor is driven
FG BEMF Threshold
N/A since FG_CONFIG is set to FG active as
long as motor is driven
Motor Stop Configuration Parameters
Motor Stop Method
MTR_STOP (5 settings)
Recirculation mode
1000-ms
Motor Brake Time
MTR_STOP_BRK_TIME (16 settings)
ACT_SPIN_BRK_THR (8 settings)
Active Spin-down Brake Duty Cycle
Threshold
N/A since MTR_STOP set to recirculation
mode
Brake Duty Threshold
BRAKE_DUTY_THRESHOLD (8 settings)
AVS_EN (2 settings)
Immediate
Enable
AVS Enable
Fault Protection Parameters
Cycle-by-Cycle(CBC) Current Limit
CBC Current Limit Mode
CBC_ILIMIT (16 settings)
ILIMIT_2 pin (7 settings)
CBC_ILIMIT_MODE (9 settings)
Auto recovery next PWM cycle; nFault active;
driver is in recirculation state
Lock Current Limit Mode
Lock Current Limit
LOCK_ILIMIT_MODE (9 settings)
LOCK_ILIMIT (16 settings)
Disable
N/A since LOCK_ILIMIT_MODE is set to
Disable
Lock Current Deglitch Time
LOCK_ILIMIT_DEG (16 settings)
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Table 5-1. MCT8316AV (I2C variant) vs MCT8316AT (Hardware variant) configuration comparison
(continued)
Parameter
MCT8316AV (I2C variant)
MCT8316AT (Hardware variant)
CBC Limit Retry PWM Cycles
CBC_RETRY_PWM_CYC (4 settings)
N/A since CBC_ILIMIT_MODE is set to Auto
recovery next PWM cycle
Motor Lock Mode
MTR_LCK_MODE (9 settings)
Automatic recovery after tCLK_RETRY;
driver is tristated
Lock Retry Time
LCK_RETRY (8 settings)
5s
Abnormal Speed Enable
LOCK1_EN (2 settings)
Enable
Loss of Sync Enable
LOCK2_EN (2 settings)
Enable
No Motor Enable
LOCK3_EN (2 settings)
Enable
Abnormal Speed Threshold
Number of Times Sync Lost
No Motor Threshold
LOCK_ABN_SPEED (8 settings)
LOSS_SYNC_TIMES (8 settings)
NO_MTR_THR (8 settings)
MAX_VM_MOTOR (8 settings)
MAX_VM_MODE (2 settings)
MIN_VM_MOTOR (8 settings)
MIN_VM_MODE (2 settings)
AUTO_RETRY_TIMES (8 settings)
CONFIG_3 pin (4 settings)
Trigger after losing sync 5 times
25-mV
Overvoltage Threshold
No Limit
Overvoltage Mode
N/A since MAX_VM_MOTOR set to No Limit
Undervoltage Threshold
No Limit
Undervoltage Mode
N/A since MIN_VM_MOTOR set to No Limit
No Limit
Automatic Retry Attempts
150o Commutation Parameters
150o Two Phase Step 0 Duty
150o Two Phase Step 1 Duty
150o Two Phase Step 2 Duty
150o Two Phase Step 3 Duty
150o Two Phase Step 4 Duty
150o Two Phase Step 5 Duty
150o Two Phase Step 6 Duty
150o Two Phase Step 7 Duty
150o Three Phase Step 0 Duty
150o Three Phase Step 1 Duty
150o Three Phase Step 2 Duty
150o Three Phase Step 3 Duty
150o Three Phase Step 4 Duty
150o Three Phase Step 5 Duty
150o Three Phase Step 6 Duty
150o Three Phase Step 7 Duty
Miscellaneous Algorithm Parameters
Open to Closed Loop Handoff Cycles
Blanking Time
TWOPH_STEP0 (8 settings)
TWOPH_STEP1 (8 settings)
TWOPH_STEP2 (8 settings)
TWOPH_STEP3 (8 settings)
TWOPH_STEP4 (8 settings)
TWOPH_STEP5 (8 settings)
TWOPH_STEP6 (8 settings)
TWOPH_STEP7 (8 settings)
THREEPH_STEP0 (8 settings)
THREEPH_STEP1 (8 settings)
THREEPH_STEP2 (8 settings)
THREEPH_STEP3 (8 settings)
THREEPH_STEP4 (8 settings)
THREEPH_STEP5 (8 settings)
THREEPH_STEP6 (8 settings)
THREEPH_STEP7 (8 settings)
N/A since COMM_CONTROL set to 120o
commutation
OL_HANDOFF_CYC (4 settings)
TBLANK (16 settings)
RMP_1, RMP_2 pins (2 settings)
CONFIG_1 pin (5 settings)
Lead Angle for 150o commutation
LEAD_ANGLE_150DEG_ADV (4 settings)
N/A since COMM_CONTROL is set to 120o
commutation
Gate Driver Parameters
Slew Rate
SLEW_RATE (4 settings)
OVP_SEL (2 settings)
OVP_EN (2 settings)
SLEW_RATE pin(4 settings)
Overvoltage Level
Overvoltage Enable
32-V
Enable
Overtemperature Warning Reporting Enable OTW_REP (2 settings)
Disable
OCP Retry Time
OCP Level
OCP_RETRY (2 settings)
OCP_LVL (2 settings)
500-ms
CONFIG_2 pin (2 settings)
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Table 5-1. MCT8316AV (I2C variant) vs MCT8316AT (Hardware variant) configuration comparison
(continued)
Parameter
MCT8316AV (I2C variant)
OCP_MODE (4 settings)
BEMF_THR (2 settings)
EN_AAR (2 settings)
MCT8316AT (Hardware variant)
OCP Mode
CONFIG_2 pin (2 settings)
BEMF Comparator Threshold
Active Asynchronous Rectification Enable
Active Synchronous Rectification Enable
Current Sense Amplifier Gain
Delay Compensation Enable
Delay Target
CONFIG_2 pin (2 settings)
Same as EN_AAR
ILIMIT pin(4 settings)
CONFIG_2 pin (2 settings)
0-µs
EN_ASR (2 settings)
CSA_GAIN (4 settings)
DELAY_COMP_EN (2 settings)
TARGET_DELAY (16 settings)
BUCK_SR (2 settings)
Buck Slew Rate
1000-V/µs
Buck Power Sequencing Disable
BUCK_PS_DIS (2 settings)
Disabled if BUCK_SEL set to 3.3V; else
enabled
Buck Current Limit
BUCK_CL (2 settings)
BUCK_SEL (4 settings)
BUCK_DIS (2 settings)
600-mA
Buck Voltage Selection
Buck Disable
SLEW_RATE pin (2 settings)
Enable
Pin and Device Configuration Parameters
Register address of variable to be monitored DACOUT1_VAR_ADDR (12-bit)
on DACOUT1 pin
N/A
N/A
Register address of variable to be monitored DACOUT2_VAR_ADDR (12-bit)
on DACOUT1 pin
Brake Configuration
Direction Configuration
Speed Input Mode
BRAKE_INPUT (3 settings)
DIR_INPUT (3 settings)
BRAKE pin input
DIR pin input
SPD_CTRL_MODE (4 settings)
DAC_SOX_CONFIG (4 settings)
DAC_XTAL_CONFIG (2 settings)
SSM_CONFIG (2 settings)
DEV_MODE (2 settings)
Speed input in analog mode
SOx Pin
N/A
Pin 36 and 37 Configuration
Spread Spectrum Modulation
Device Mode
N/A
Enable
Standby
Speed PWM Input Range
Clock Source
SPD_PWM_RANGE_SELECT (2 settings)
CLK_SEL (3 settings)
325-Hz to 95-kHz
Internal oscillator
External Clock Mode Enable
External Clock Configuration
EXT_CLK_EN (2 settings)
N/A since CLK_SEL set to Internal Oscillator
N/A since CLK_SEL set to Internal Oscillator
EXT_CLK_CONFIG (8 settings)
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6 Pin Configuration and Functions
DVDD
DGND
1
2
32
31
30
29
LDANGLE
RMP_2
DVDD
DGND
1
2
32
31
30
29
EXT_WD
SCL
RMP_1
FG
FB_BK
3
SDA
FG
FB_BK
3
4
GND_BK
SW_BK
CPL
4
GND_BK
SW_BK
CPL
28 SPEED/WAKE
5
28 SPEED/WAKE
5
27
26
25
24
23
22
21
AVDD
AGND
6
MCT8316AT
(Thermal Pad)
27
26
25
24
23
22
21
AVDD
AGND
6
MCT8316AV
(Thermal Pad)
CPH
7
CPH
7
CP
NC
8
CP
NC
8
9
VM
VM
NC
9
VM
VM
NC
NC
10
11
12
NC
10
11
12
VM
NC
VM
NC
PGND
DRVOFF
PGND
DRVOFF
Figure 6-2. MCT8316AT 40-Pin VQFN With Exposed
Thermal Pad Top View
Figure 6-1. MCT8316AV 40-Pin VQFN With Exposed
Thermal Pad Top View
Table 6-1. Pin Functions
PIN
40-pin Package
TYPE(1)
DESCRIPTION
MCT8316A MCT8316A
NAME
V
T
AGND
26
26
GND
Device analog ground. Refer Layout Guidelines for connections recommendation.
3.3-V internal regulator output. Connect a X5R or X7R, 1-µF, 6.3-V ceramic
capacitor between the AVDD1 and AGND pins. This regulator can source up to
20 mA externally.
AVDD
27
35
27
35
PWR O
High → brake the motor
Low → normal operation
BRAKE
I
Connect to PGND via 10-kΩ resistor, if not used
CONFIG_1
CONFIG_2
CONFIG_3
-
-
-
33
37
38
I
I
I
Connect resistor to GND for parameter configuration.
Connect resistor to GND for parameter configuration.
Connect resistor to GND for parameter configuration.
Charge pump output. Connect a X5R or X7R, 1-µF, 16-V ceramic capacitor between
the CP and VM pins.
CP
8
8
PWR
CPH
CPL
7
6
7
6
PWR
PWR
Charge pump switching node. Connect a X5R or X7R, 47-nF, ceramic capacitor
between the CPH and CPL pins. TI recommends a capacitor voltage rating at least
twice the normal operating voltage of the device.
Multipurpose pin:
DAC output when configured as DACOUT2
CSA output configured as SOX
DACOUT2/
SOX
36
-
O
DACOUT1
DACOUT2
DGND
37
38
2
-
-
O
O
DAC output DACOUT1
DAC output DACOUT2
2
GND
Device digital ground. Refer Layout Guidelines for connections recommendation.
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Table 6-1. Pin Functions (continued)
PIN
40-pin Package
TYPE(1)
DESCRIPTION
MCT8316A MCT8316A
NAME
V
T
Direction of motor spinning;
When low, phase driving sequence is OUT A → OUT B → OUT C
When high, phase driving sequence is OUT A → OUT C → OUT B
DIR
34
34
I
Connect to PGND via 10-kΩ resistor, if not used
DRVOFF
DVDD
21
1
21
1
I
Coast (Hi-Z) all six MOSFETs.
1.5-V internal regulator output. Connect a X5R or X7R, 1-µF, 6.3-V ceramic
capacitor between the DVDD and DGND pins.
PWR
EXT_CLK
EXT_WD
33
32
-
-
I
I
External clock reference input in external clock reference mode.
External watchdog input.
Feedback for buck regulator. Connect to buck regulator output after the inductor/
resistor.
FB_BK
FG
3
3
PWR I/O
O
Motor speed indicator output. Open-drain output requires an external pull-up resistor
to 1.8 to 5-V.
29
29
GND_BK
ILIMIT
4
-
4
GND
Buck regulator ground. Refer Layout Guidelines for connections recommendation.
Connect resistor to GND for parameter configuration.
39
32
I
I
LDANGLE
-
Connect resistor to GND for parameter configuration.
22, 23, 24, 22, 23, 24,
NC
-
No connection, open
25, 39
25
Fault indicator. Pulled logic-low with fault condition; Open-drain output requires an
external pull-up resistor to 1.8V to 5.0V.
nFAULT
40
40
O
OUTA
OUTB
OUTC
PGND
RMP_1
RMP_2
SCL
13, 14
13, 14
PWR O
Half bridge output A
16, 17
16, 17
PWR O
Half bridge output B
19, 20
19, 20
PWR O
Half bridge output C
12, 15, 18
12, 15, 18
GND
Device power ground. Refer Layout Guidelines for connections recommendation.
Connect resistor to GND for parameter configuration.
Connect resistor to GND for parameter configuration.
I2C clock input
-
30
31
-
I
I
-
31
30
I
SDA
-
I/O
I2C data line
SLEW_RAT
E
-
36
I
Connect resistor to GND for parameter configuration.
SPEED/
WAKE
Device speed input; supports analog, frequency or PWM speed input. The speed pin
input can be configured through SPD_CTRL_MODE.
28
5
28
5
I
SW_BK
PWR
Buck switch node. Connect this pin to an inductor or resistor.
Device and motor power supply. Connect to motor supply voltage; bypass to GND
with a 0.1-µF capacitor plus one bulk capacitor. TI recommends a capacitor voltage
rating at least twice the normal operating voltage of the device.
VM
9, 10, 11
9, 10, 11
PWR I
GND
Thermal
pad
Must be connected to ground
(1) I = input, O = output, GND = groung pin, PWR = power, NC = no connect
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7 Specifications
7.1 Absolute Maximum Ratings
over operating ambient temperature range (unless otherwise noted)(1)
MIN
MAX UNIT
Power supply pin voltage (VM)
–0.3
40
4
V
V/µs
V
Power supply voltage ramp (VM)
Voltage difference between ground pins (GND_BK,DGND, PGND, AGND)
Charge pump voltage (CPH, CP)
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–1
0.3
VVM + 6
VVM +0.3
5.75
VVM +0.3
4
V
Charge pump negative switching pin voltage (CPL)
Switching regulator pin voltage (FB_BK)
Switching node pin voltage (SW_BK)
V
V
V
Analog regulators pin voltage (AVDD)
V
Analog regulators pin voltage (DVDD)
1.7
V
Logic pin input voltage (BRAKE, DRVOFF, DIR, EXT_CLK, EXT_WD, SCL, SDA, SPEED)
Open drain pin output voltage (nFAULT, FG)
Output pin voltage (OUTA, OUTB, OUTC)
Ambient temperature, TA
6
V
6
V
VVM + 1
125
V
–40
–40
–65
°C
°C
°C
Junction temperature, TJ
150
Storage tempertaure, Tstg
150
(1) Operation outside the Absolute Maximum Ratings may cause permanent device damage. Absolute Maximum Ratings do not imply
functional operation of the device at these or any other conditions beyond those listed under Recommended Operating Conditions.
If used outside the Recommended Operating Conditions but within the Absolute Maximum Ratings, the device may not be fully
functional, and this may affect device reliability, functionality, performance, and shorten the device lifetime
7.2 ESD Ratings
VALUE
±2000
±750
UNIT
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001(1)
Charged device model (CDM), per JEDEC specification JS-002(2)
Electrostatic
discharge
V(ESD)
V
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
7.3 Recommended Operating Conditions
over operating ambient temperature range (unless otherwise noted)
MIN
NOM
MAX UNIT
VVM
Power supply voltage
VVM
4.5
24
35
8
V
A
(1)
IOUT
Peak output winding current
OUTA, OUTB, OUTC
BRAKE, DRVOFF, DIR, EXT_CLK,
EXT_WD, SPEED, SDA, SCL
VIN_LOGIC
Logic input voltage
–0.1
–0.1
5.5
V
VOD
IOD
TA
Open drain pullup voltage
nFAULT, FG
nFAULT, FG
5.5
5
V
Open drain output current capability
Operating ambient temperature
Operating Junction temperature
mA
°C
°C
–40
–40
125
150
TJ
(1) Power dissipation and thermal limits must be observed
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UNIT
SLLSFH8A – AUGUST 2021 – REVISED DECEMBER 2021
7.4 Thermal Information
MCT8316A
RGF (VQFN)
40 Pins
25.7
THERMAL METRIC(1)
RθJA
Junction-to-ambient thermal resistance
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
RθJC(top)
RθJB
Junction-to-case (top) thermal resistance
Junction-to-board thermal resistance
15.2
7.3
ΨJT
Junction-to-top characterization parameter
Junction-to-board characterization parameter
Junction-to-case (bottom) thermal resistance
0.2
ΨJB
7.2
RθJC(bot)
2.0
(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report.
7.5 Electrical Characteristics
at TJ = –40°C to +150°C, VVM = 4.5 to 35 V (unless otherwise noted). Typical limits apply for TA = 25°C, VVM = 24 V
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
POWER SUPPLIES
VVM > 6 V, VSPEED = 0, TA = 25 °C
VSPEED = 0, TA = 125 °C
3
5
7
µA
µA
IVMQ
VM sleep mode current
3.5
VVM > 6 V, VSPEED > VEN_SB, DRVOFF =
High, TA = 25 °C, LBK = 47 uH, CBK = 22
µF
8
15
mA
VVM > 6 V, VSPEED > VEN_SB, DRVOFF =
High, RBK = 22 Ω, CBK = 22 µF
25
8
28
15
28
mA
mA
mA
IVMS
VM standby mode current
VVM > 6 V, VSPEED > VEN_SB, DRVOFF =
High, LBK = 47 uH, CBK = 22 µF
VVM > 6 V, VSPEED > VEN_SB, DRVOFF =
High, RBK = 22 Ω, CBK = 22 µF
25
VVM > 6 V, VSPEED > VEX_SL
,
PWM_FREQ_OUT = 10000b (25 kHz),
TJ = 25 °C, LBK = 47 uH, CBK = 22 µF,
No Motor Connected
11
27
11
18
30
17
30
mA
mA
mA
mA
VVM > 6 V, VSPEED > VEX_SL
,
PWM_FREQ_OUT = 10000b (25 kHz),
TJ = 25 °C, RBK = 22 Ω, CBK = 22 µF, No
Motor Connected
IVM
VM operating mode current
VVM > 6 V, VSPEED > VEX_SL
,
PWM_FREQ_OUT = 10000b (25 kHz),
LBK = 47 uH, CBK = 22 µF, No Motor
Connected
VVM > 6 V, VSPEED > VEX_SL
,
PWM_FREQ_OUT = 10000b (25 kHz),
RBK = 22 Ω, CBK = 22 µF, No Motor
Connected
28
VAVDD
IAVDD
VDVDD
VVCP
fCP
Analog regulator voltage
0 mA ≤ IAVDD ≤ 30 mA
3.125
3.3
3.465
20
V
mA
V
External analog regulator load
Digital regulator voltage
1.4
4.0
1.55
4.7
1.65
5.5
Charge pump regulator voltage
Charge pump switching frequency
VCP with respect to VM
V
400
kHz
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at TJ = –40°C to +150°C, VVM = 4.5 to 35 V (unless otherwise noted). Typical limits apply for TA = 25°C, VVM = 24 V
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
BUCK REGULATOR
VVM > 6 V, 0 mA ≤ IBK ≤ 170 mA,
BUCK_SEL = 00b
3.1
4.6
3.7
5.2
3.3
5.0
4.0
5.7
3.5
5.4
4.3
6.2
V
V
V
V
VVM > 6 V, 0 mA ≤ IBK ≤ 170 mA,
BUCK_SEL = 01b
Buck regulator average voltage
(LBK = 47 µH, CBK = 22 µF)
VVM > 6 V, 0 mA ≤ IBK ≤ 170 mA,
BUCK_SEL = 10b
VBK
VVM > 6.7 V, 0 mA ≤ IBK ≤ 170 mA,
BUCK_SEL = 11b
VVM < 6.0 V (BUCK_SEL = 00b, 01b,
10b) or VVM < 6.0 V (BUCK_SEL = 11b),
0 mA ≤ IBK ≤ 170 mA
VVM–
IBK*(RLBK
V
+2) (1)
VVM > 6 V, 0 mA ≤ IBK ≤ 20 mA,
BUCK_SEL = 00b
3.1
4.6
3.7
5.2
3.3
5.0
4.0
5.7
3.5
5.4
4.3
6.2
V
V
V
V
VVM > 6 V, 0 mA ≤ IBK ≤ 20 mA,
BUCK_SEL = 01b
Buck regulator average voltage
(LBK = 22 µH, CBK = 22 µF)
VVM > 6 V, 0 mA ≤ IBK ≤ 20 mA,
BUCK_SEL = 10b
VBK
VVM > 6.7 V, 0 mA ≤ IBK ≤ 20 mA,
BUCK_SEL = 11b
VVM < 6.0 V (BUCK_SEL = 00b, 01b,
10b) or VVM < 6.0 V (BUCK_SEL = 11b),
0 mA ≤ IBK ≤ 20 mA
VVM–
IBK*(RLBK
V
+2)(1)
VVM > 6 V, 0 mA ≤ IBK ≤ 10 mA,
BUCK_SEL = 00b
3.1
4.6
3.7
5.2
3.3
5.0
4.0
5.7
3.5
5.4
4.3
6.2
V
V
V
V
VVM > 6 V, 0 mA ≤ IBK ≤ 10 mA,
BUCK_SEL = 01b
Buck regulator average voltage
(RBK = 22 Ω, CBK = 22 µF)
VVM > 6 V, 0 mA ≤ IBK ≤ 10 mA,
BUCK_SEL = 10b
VBK
VVM > 6.7 V, 0 mA ≤ IBK ≤ 10 mA,
BUCK_SEL = 11b
VVM < 6.0 V (BUCK_SEL = 00b, 01b,
10b) or VVM < 6.0 V (BUCK_SEL = 11b),
0 mA ≤ IBK ≤ 10 mA
VVM–
IBK*(RBK
+2)
V
VVM > 6 V, 0 mA ≤ IBK ≤ 170 mA, Buck
regulator with inductor, LBK = 47 uH, CBK
= 22 µF
–100
–100
–100
100
100
mV
mV
mV
VVM > 6 V, 0 mA ≤ IBK ≤ 20 mA, Buck
regulator with inductor, LBK = 22 uH, CBK
= 22 µF
VBK_RIP
Buck regulator ripple voltage
VVM > 6 V, 0 mA ≤ IBK ≤ 10 mA, Buck
regulator with resistor; RBK = 22 Ω, CBK
= 22 µF
100
170
LBK = 47 uH, CBK = 22 µF,
BUCK_PS_DIS = 1b
mA
mA
mA
mA
mA
mA
LBK = 47 uH, CBK = 22 µF,
BUCK_PS_DIS = 0b
170 –
IAVDD
LBK = 22 uH, CBK = 22 µF,
BUCK_PS_DIS = 1b
20
IBK
External buck regulator load
LBK = 22 uH, CBK = 22 µF,
BUCK_PS_DIS = 0b
20 –
IAVDD
RBK = 22 Ω, CBK = 22 µF,
BUCK_PS_DIS = 1b
10
RBK = 22 Ω, CBK = 22 µF,
BUCK_PS_DIS = 0b
10 –
IAVDD
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at TJ = –40°C to +150°C, VVM = 4.5 to 35 V (unless otherwise noted). Typical limits apply for TA = 25°C, VVM = 24 V
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
Regulation Mode
20
535
535
2.95
2.7
kHz
kHz
V
fSW_BK
Buck regulator switching frequency
Linear Mode
20
VBK rising, BUCK_SEL = 00b
VBK falling, BUCK_SEL = 00b
VBK rising, BUCK_SEL = 01b
VBK falling, BUCK_SEL = 01b
VBK rising, BUCK_SEL = 10b
VBK falling, BUCK_SEL = 10b
VBK rising, BUCK_SEL = 11b
VBK falling, BUCK_SEL = 11b
2.7
2.5
4.3
4.1
2.7
2.5
4.3
4.1
2.8
2.6
4.4
4.2
2.8
2.6
4.4
4.2
V
4.55
4.35
2.95
2.7
V
V
Buck regulator undervoltage lockout
VBK_UV
V
V
4.55
4.35
V
V
Buck regulator undervoltage lockout
hysteresis
VBK_UV_HYS
Rising to falling threshold
90
200
400
mV
BUCK_CL = 0b
BUCK_CL = 1b
360
80
600
150
910
250
mA
mA
Buck regulator Current limit threshold
IBK_CL
Buck regulator Overcurrent protection
trip point
IBK_OCP
2
3
1
4
A
tBK_RETRY
Overcurrent protection retry time
0.7
1.3
ms
DRIVER OUTPUTS
VVM > 6 V, IOUT = 1 A, TA = 25°C
VVM < 6 V, IOUT = 1 A, TA = 25°C
VVM > 6 V, IOUT = 1 A, TJ = 150 °C
VVM < 6 V, IOUT = 1 A, TJ = 150 °C
VVM = 24 V, SLEW_RATE = 00b
VVM = 24 V, SLEW_RATE = 01b
VVM = 24 V, SLEW_RATE = 10b
VVM = 24 V, SLEW_RATE = 11b
VVM = 24 V, SLEW_RATE = 00b
VVM = 24 V, SLEW_RATE = 01b
VVM = 24 V, SLEW_RATE = 10b
VVM = 24 V, SLEW_RATE = 11b
VVM = 24 V, SR = 25 V/µs
95
105
140
145
25
125
130
185
190
45
mΩ
mΩ
mΩ
mΩ
V/us
V/us
V/us
V/us
V/us
V/us
V/us
V/us
ns
Total MOSFET on resistance (High-side
+ Low-side)
RDS(ON)
13
30
50
80
Phase pin slew rate switching low to high
(Rising from 20 % to 80 %)
SR
80
125
200
25
185
280
45
130
14
30
50
80
Phase pin slew rate switching high to low
(Falling from 80 % to 20 %
SR
80
125
200
1800
1100
650
500
185
280
3400
1550
1000
750
110
VVM = 24 V, SR = 50 V/µs
ns
Output dead time (high to low / low to
high)
tDEAD
VVM = 24 V, SR = 125 V/µs
ns
VVM = 24 V, SR = 200 V/µs
ns
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SLLSFH8A – AUGUST 2021 – REVISED DECEMBER 2021
at TJ = –40°C to +150°C, VVM = 4.5 to 35 V (unless otherwise noted). Typical limits apply for TA = 25°C, VVM = 24 V
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
SPEED INPUT - PWM MODE
ƒPWM
PWM input frequency
PWM input resolution
0.01
11
12
11
13
12
11
10
8
95
13
14
12
14
13
12
11
10
kHz
bits
bits
bits
bits
bits
bits
bits
bits
fPWM = 0.01 to 0.35 kHz
12
13
fPWM = 0.35 to 2 kHz
fPWM = 2 to 3.5 kHz
fPWM = 3.5 to 7 kHz
fPWM = 7 to 14 kHz
fPWM = 14 to 29.2 kHz
fPWM = 29.3 to 60 kHz
fPWM = 60 to 95 kHz
11.5
13.5
12.5
11.5
10.5
9
ResPWM
SPEED INPUT - ANALOG MODE
VANA_FS
Analog full-speed voltage
Analog voltage resolution
2.95
3
3
3.05
V
VANA_RES
732
μV
SPEED INPUT - FREQUENCY MODE
ƒPWM_FREQ PWM input frequency range
SLEEP MODE
Duty cycle = 50%
32767
40
Hz
SPD_CTRL_MODE = 00b (analog
mode)
VEN_SL
VEX_SL
Analog voltage to enter sleep mode
Analog voltage to exit sleep mode
mV
V
SPD_CTRL_MODE = 00b (analog
mode)
2.2
0.5
SPD_CTRL_MODE = 00b (analog
mode)
VSPEED > VEX_SL
Time needed to detect wake up signal on
SPEED pin
tDET_ANA
1
3
1.5
5
μs
VSPEED > VEX_SL to DVDD voltage
available, SPD_CTRL_MODE = 01b
(PWM mode)
tWAKE
Wakeup time from sleep mode
ms
SPD_CTRL_MODE = 00b (analog
mode)
VSPEED > VEN_SL, ISD detection disabled
tEX_SL_DR_A Time taken to drive motor after exiting
20
1.5
5
ms
μs
from sleep mode
NA
Time needed to detect wake up signal on SPD_CTRL_MODE = 01b (PWM mode)
tDET_PWM
0.5
1
3
SPEED pin
VSPEED > VDIG_IH
VSPEED > VDIG_IH to DVDD voltage
available and release nFault,
SPD_CTRL_MODE = 01b (PWM mode)
tWAKE_PWM Wakeup time from sleep mode
ms
ms
ms
tEX_SL_DR_P Time taken to drive motor after wakeup SPD_CTRL_MODE = 01b (PWM mode)
20
2
from sleep state
VSPEED > VDIG_IH, ISD detection disabled
WM
SPD_CTRL_MODE = 00b (analog
tDET_SL_ANA Time needed to detect sleep command mode)
VSPEED < VEN_SL
0.5
1
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED < VDIG_IL, SLEEP_TIME = 00b
0.035
0.14
14
0.05
0.2
20
0.065
0.26
26
ms
ms
ms
ms
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED < VDIG_IL, SLEEP_TIME = 01b
tDET_SL_PWM Time needed to detect sleep command
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED < VDIG_IL, SLEEP_TIME = 10b
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED < VDIG_IL, SLEEP_TIME = 11b
140
200
260
SPD_CTRL_MODE = 11b (Frequency
Time needed to detect sleep command mode)
VSPEED < VDIG_IL
tDET_SL_FRE
4000
1
ms
ms
Q
Time needed to stop driving motor after VSPEED < VEN_SL (analog
detecting sleep command mode) or VSPEED < VDIG_IL (PWM mode)
tEN_SL
2
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SLLSFH8A – AUGUST 2021 – REVISED DECEMBER 2021
at TJ = –40°C to +150°C, VVM = 4.5 to 35 V (unless otherwise noted). Typical limits apply for TA = 25°C, VVM = 24 V
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
STANDBY MODE
VEN_SB
VEX_SB
SPD_CTRL_MODE = 00b (analog
mode)
Analog voltage to enter standby mode
Analog voltage to exit standby mode
40
mV
mV
SPD_CTRL_MODE = 00b (analog
mode)
170
SPD_CTRL_MODE = 00b (analog
mode)
VSPEED > VEN_SB, ISD detection disabled
tEX_SB_DR_A Time taken to drive motor after exiting
6
6
2
ms
ms
ms
standby mode
NA
tEX_SB_DR_P Time taken to drive motor after exiting
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED > VDIG_IH, ISD detection disabled
standby mode
WM
SPD_CTRL_MODE = 00b (analog
mode)
tDET_SB_ANA Time needed to detect standby mode
0.5
1
VSPEED < VEN_SB
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED < VDIG_IL, SLEEP_TIME = 00b
0.035
0.14
14
0.05
0.2
20
0.065
0.26
26
ms
ms
ms
ms
ms
ms
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED < VDIG_IL, SLEEP_TIME = 01b
Time needed to detect standby
tEN_SB_PWM
command
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED < VDIG_IL, SLEEP_TIME = 10b
SPD_CTRL_MODE = 01b (PWM mode)
VSPEED < VDIG_IL, SLEEP_TIME = 11b
140
200
4000
1
260
SPD_CTRL_MODE = 11b (Frequency
mode), VSPEED < VDIG_IL
tEN_SB_FREQ Time needed to detect standby mode
SPD_CTRL_MODE = 10b (I2C
mode), SPEED_CMD = 0
tEN_SB_DIG
Time needed to detect standby mode
2
2
VSPEED < VEN_SL (analog
mode) or VSPEED < VDIG_IL (PWM mode)
or SPEED_CMD = 0 (I2C mode)
Time needed to stop driving motor after
detecting standby command
tEN_SB
1
ms
LOGIC-LEVEL INPUTS (BRAKE, DIR, EXT_CLK, EXT_WD, SCL, SDA, SPEED)
0.25*AV
DD
VIL
VIH
Input logic low voltage
Input logic high voltage
AVDD = 3 to 3.6 V
AVDD = 3 to 3.6 V
V
V
0.65*AV
DD
VHYS
IIL
Input hysteresis
50
-0.15
-0.3
0.6
500
800
0.15
0
mV
µA
Input logic low current
Input logic high current
AVDD = 3 to 3.6 V
AVDD = 3 to 3.6 V
SPEED pin To GND
To GND
IIH
µA
RPD_SPEED Input pulldown resistance
RPD Input pulldown resistance
OPEN-DRAIN OUTPUTS (nFAULT, FG)
1
1.4
110
MΩ
kΩ
90
100
VOL
Output logic low voltage
IOD =-5 mA
VOD = 3.3 V
0.4
0.5
V
IOZ
Output logic high current
0
µA
I2C Serial Interface
0.3*AVD
D
VI2C_L
LOW-level input voltage
-0.5
V
V
V
0.7*AVD
D
VI2C_H
HIGH-level input voltage
Hysterisis
5.5
0.05*AV
DD
VI2C_HYS
VI2C_OL
II2C_OL
II2C_IL
Ci
LOW-level output voltage
LOW-level output current
open-drain at 2mA sink current
VI2C_OL = 0.6V
0
0.4
6
V
mA
µA
pF
Input current on SDA and SCL
Capacitance for SDA and SCL
-10(2)
10(2)
10
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SLLSFH8A – AUGUST 2021 – REVISED DECEMBER 2021
at TJ = –40°C to +150°C, VVM = 4.5 to 35 V (unless otherwise noted). Typical limits apply for TA = 25°C, VVM = 24 V
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
Standard Mode
250(3)
250(3)
ns
ns
Output fall time from VI2C_H(min) to
VI2C_L(max)
tof
Fast Mode
Fast Mode
Pulse width of spikes that must be
suppressed by the input filter
tSP
0
50(4)
ns
OSCILLATOR
EXT_CLK_CONFIG = 000b
EXT_CLK_CONFIG = 001b
EXT_CLK_CONFIG = 010b
EXT_CLK_CONFIG = 011b
EXT_CLK_CONFIG = 100b
EXT_CLK_CONFIG = 101b
EXT_CLK_CONFIG = 110b
EXT_CLK_CONFIG = 111b
8
16
kHz
kHz
kHz
kHz
kHz
kHz
kHz
kHz
32
64
fOSCREF
External clock reference
128
256
512
1024
EEPROM
EEProg
Programing voltage
Retention
1.35
1.5
1.65
V
TA = 25 ℃
100
Years
Years
Cycles
Cycles
EERET
EEEND
TJ = -40 to 150 ℃
TJ = -40 to 150 ℃
TJ = -40 to 85 ℃
10
1000
Endurance
20000
PROTECTION CIRCUITS
VUVLO Supply undervoltage lockout (UVLO)
VM rising
VM falling
4.3
4.1
140
3
4.4
4.2
200
5
4.5
4.3
350
7
V
V
VUVLO_HYS Supply undervoltage lockout hysteresis Rising to falling threshold
mV
µs
tUVLO
Supply undervoltage deglitch time
Supply rising, OVP_EN = 1, OVP_SEL =
0
32.5
31.8
20
34
33
22
21
35
34.3
23
V
V
V
V
Supply falling, OVP_EN = 1, OVP_SEL
= 0
VOVP
Supply overvoltage protection (OVP)
Supply rising, OVP_EN = 1, OVP_SEL =
1
Supply falling, OVP_EN = 1, OVP_SEL
= 1
19
22
Rising to falling threshold, OVP_SEL = 1
Rising to falling threshold, OVP_SEL = 0
0.9
0.7
2.5
2.25
2.2
65
1
0.8
5
1.1
0.9
7
V
V
VOVP_HYS
tOVP
Supply overvoltage protection (OVP)
Supply overvoltage deglitch time
µs
V
Supply rising
2.5
2.4
100
2.85
2.65
2.75
2.6
150
3
Charge pump undervoltage lockout
(above VM)
VCPUV
Supply falling
V
VCPUV_HYS Charge pump UVLO hysteresis
Rising to falling threshold
Supply rising
mV
V
2.7
2.5
VAVDD_UV
Analog regulator undervoltage lockout
Supply falling
2.8
V
VAVDD_
Analog regulator undervoltage lockout
hysteresis
Rising to falling threshold
180
200
240
mV
UV_HYS
OCP_LVL = 0b
OCP_LVL = 1b
10
15
16
24
20
28
A
A
IOCP
Overcurrent protection trip point
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at TJ = –40°C to +150°C, VVM = 4.5 to 35 V (unless otherwise noted). Typical limits apply for TA = 25°C, VVM = 24 V
PARAMETER
TEST CONDITIONS
MIN
0.1
0.2
0.6
1
TYP
0.3
0.6
1.25
1.6
5
MAX UNIT
OCP_DEG = 00b
0.7
1.2
1.8
2.5
6
µs
µs
µs
µs
ms
ms
°C
°C
°C
°C
°C
°C
OCP_DEG = 01b
tOCP
Overcurrent protection deglitch time
OCP_DEG = 10b
OCP_DEG = 11b
OCP_RETRY = 0
OCP_RETRY = 1
Die temperature (TJ)
Die temperature (TJ)
Die temperature (TJ)
Die temperature (TJ)
Die temperature (TJ)
Die temperature (TJ)
4
tRETRY
Overcurrent protection retry time
425
160
25
500
170
30
575
180
35
TOTW
Thermal warning temperature
Thermal warning hysteresis
TOTW_HYS
TTSD
TTSD_HYS
TTSD
Thermal shutdown temperature
Thermal shutdown hysteresis
Thermal shutdown temperature (FET)
Thermal shutdown hysteresis (FET)
175
25
185
30
195
35
170
20
180
25
190
30
TTSD_HYS
(1) RLBK is resistance of inductor LBK
(2) If AVDD is switched off, I/O pins must not obstruct the SDA and SCL lines.
(3) The maximum tf for the SDA and SCL bus lines (300 ns) is longer than the specified maximum tof for the output stages (250 ns). This
allows series protection resistors (Rs) to be connected between the SDA/SCL pins and the SDA/SCL bus lines without exceeding the
maximum specified tf.
(4) Input filters on the SDA and SCL inputs suppress noise spikes of less than 50 ns
7.6 Characteristics of the SDA and SCL bus for Standard and Fast mode
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
Standard-mode
fSCL
SCL clock frequency
0
4
100
kHz
µs
After this period, the first clock pulse is
generated
tHD_STA
Hold time (repeated) START condition
tLOW
tHIGH
LOW period of the SCL clock
HIGH period of the SCL clock
4.7
4
µs
µs
Set-up time for a repeated START
condition
tSU_STA
4.7
µs
(4)
tHD_DAT
tSU_DAT
tr
Data hold time (2)
I2C bus devices
0 (3)
250
µs
ns
ns
Data set-up time
Rise time for both SDA and SCL signals
1000
300
Fall time of both SDA and SCL signals (3)
tf
ns
µs
µs
(6) (7) (8)
tSU_STO
tBUF
Set-up time for STOP condition
4
Bus free time between STOP and START
condition
4.7
Cb
Capacitive load for each bus line (9)
Data valid time (10)
400
3.45 (4)
3.45 (4)
pF
µs
µs
tVD_DAT
tVD_ACK
Data valid acknowledge time (11)
For each connected device (including
hysteresis)
0.1*AVD
D
VnL
Vnh
Noise margin at the LOW level
Noise margin at the HIGHlevel
V
V
For each connected device (including
hysteresis)
0.2*AVD
D
Fast-mode
fSCL
SCL clock frequency
Hold time (repeated) START condition
0
400
KHz
µs
After this period, the first clock pulse is
generated
tHD_STA
0.6
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over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
1.3
NOM
MAX
UNIT
µs
tLOW
tHIGH
LOW period of the SCL clock
HIGH period of the SCL clock
0.6
µs
Set-up time for a repeated START
condition
tSU_STA
0.6
µs
(4)
tHD_DAT
tSU_DAT
tr
Data hold time (2)
0 (3)
100 (5)
20
µs
ns
ns
Data set-up time
Rise time for both SDA and SCL signals
300
300
20 x
(AVDD/
5.5V)
Fall time of both SDA and SCL signals (3)
tf
ns
(6) (7) (8)
tSU_STO
tBUF
Set-up time for STOP condition
0.6
1.3
µs
µs
Bus free time between STOP and START
condition
Cb
Capacitive load for each bus line (9)
Data valid time (10)
400
0.9 (4)
0.9 (4)
pF
µs
µs
tVD_DAT
tVD_ACK
Data valid acknowledge time (11)
For each connected device (including
hysteresis)
0.1*AVD
D
VnL
Vnh
Noise margin at the LOW level
Noise margin at the HIGHlevel
V
V
For each connected device (including
hysteresis)
0.2*AVD
D
(1) All values referred to VIH(min) (0.3VDD) and VIL(max) levels (see Table 9).
(2) tHD_DAT is the data hold time that is measured from the falling edge of SCL, applies to data in transmission and the acknowledge.
(3) A device must internally provice a hold time of at least 300 ns for the SDA signal (with respect to the VIH(min) of the SCL signal) to
bridge the undefined region of the falling edge of SCL.
(4) The maximum tHD_DAT could be 3.45 us and .9 us for Standard-mode and Fast-mode, but must be less than the maximum of tVD_DAT or
tVD_ACK by a transistion time. This maximum must only be met if the device does not stretch the LOW period (tLOW) of the SCL signal. If
the clock stretched the SCL, the data must be valid by the set-up time before it releases the clock.
(5) A Fast-mode I2C-bus device can be used in a Standard-mode I2C-bus system, but the requirement tSU_DAT 250 ns must then be met.
This will automatically be the case if the device does not stretch the LOW period of the SCL signal. If such a device does stretch the
LOW period if the SCL signal, it must output the next data bit to the SDA line tr(max) + tSU_DAT = 1000 + 250 = 1250 ns (according to the
Standard-mode I2C-bus specification) before the SCL line is released. Also the acknowledge timing must meet this set-up time.
(6) If mixed with Hs-mode devices, faster fall times according to Table 10 are allowed.
(7) The maximum tf for the SDA and SCL bus lines is specified at 300 ns. The maximum fall time for the SDA output stage tf is specified
at 250 ns. This allows series protection resistors to be connected in between the SDA and the SCL pins and the SDA/SCL bus lines
without exceeding the maximum specified tf.
(8) In Fast-mode Plus, fall time is specified the same for both output stage and bus timing. If series resistors are used, designers should
allow for this when considering bus timing.
(9) The maximum bus capacitance allowable may vary from the value depending on the actual operating voltage and frequency of the
application.
(10) tVD_DAT = time for data signal from SCL LOW to SDA output (HIGH or LOW, depending on which one is worse).
(11) tVD_ACK = time for Acknowledgement signal from SCL LOW to SDA output (HIGH or LOW, dependging on which one is worse).
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7.7 Typical Characteristics
30
28.5
27
25.5
24
160
150
140
130
120
110
100
90
22.5
Buck with Inductor (25C)
21
19.5
18
16.5
15
Buck with Inductor (150C)
Buck with Resistor (25C)
Buck with Resistor (150C)
13.5
12
80
70
10.5
9
60
-40 -20
10 12.5 15 17.5 20 22.5 25 27.5 30 32.5 35
Supply Voltage (V)
0
20
40
60
80 100 120 140
Junction Temperature (C)
Figure 7-1. Supply current over supply voltage
Figure 7-2. RDS(ON) (high and low side combined)
for MOSFETs over temperature
100
5.75
5.5
TJ = -40 C
97.5
TJ = 25 C
TJ = -150 C
5.25
5
95
92.5
90
4.75
BUCK_SEL = 00b
BUCK_SEL = 01b
BUCK_SEL = 10b
BUCK_SEL = 11b
4.5
87.5
85
4.25
4
82.5
80
3.75
3.5
3.25
3
77.5
75
0
0.02 0.04 0.06 0.08 0.1 0.12 0.14 0.16 0.18 0.2
Buck Output Load Current (A)
4
8
12
16
20
24
28
32
36
Supply Voltage (V)
Figure 7-4. Buck regulator output voltage over load
current
Figure 7-3. Buck regulator efficiency over supply
voltage
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8 Detailed Description
8.1 Overview
The MCT8316A provides a single-chip, code-free sensorless trapezoidal solution for customers requiring high
speed operation (up to 3 kHz electrical speed) or very fast startup time (< 50ms) for 12- to 24-V brushless-DC
motors requiring up to 8-A peak phase currents.
The MCT8316A integrates three 1/2-H bridges with 40-V absolute maximum capability and a very low RDS(ON)
of 95-mΩ (high-side + low-side) to enable high power drive capability. Current is sensed using an integrated
current sensing circuit which eliminates the need for external sense resistors. Power management features of an
adjustable buck regulator and LDO generate the necessary voltage rails for the device and can be used to power
external circuits.
Sensorless trapezoidal control is highly configurable through register settings (MCT8316AV) or hardware pins
(MCT8316AT) ranging from motor start-up behavior to closed loop operation. Register settings can be stored in
non-volatile EEPROM, which allows the device to operate stand-alone once it has been configured. MCT8316A
allows for a high level of monitoring; any variable in the algorithm can be displayed and observed as an analog
output via two 12-bit DACs. This feature provides an effective method to tune speed loops as well as motor
acceleration. The device receives a speed command through a PWM input, analog voltage, frequency input or
I2C command.
In-built protection features include power-supply undervoltage lockout (UVLO), charge-pump undervoltage
lockout (CPUV), overcurrent protection (OCP), AVDD undervoltage lockout (AVDD_UV), buck regulator UVLO,
motor lock detection and overtemperature warning and shutdown (OTW and TSD). Fault events are indicated by
the nFAULT pin with detailed fault information available in the registers.
The MCT8316A device is available in a 0.5-mm pin pitch, VQFN surface-mount package. The VQFN package
size is 7 mm × 5 mm with a height of 1 mm.
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8.2 Functional Block Diagram
CAVDD 1µF
CFLY 47nF
VM
LBK
AVDD
Out
Buck
Out
- or -
RBK
SW_BK
AVDD AGND
CPL
CPH
CP
CCP
1µF
CBK
VM
VM
VM
GND_BK
Buck/LDO
Regulator
AVDD LDO
Regulator
Charge Pump
Input VM or
Buck/LDO
FB_BK
DVDD
CVM1
+
CVM2
0.1µF
>10µF
DVDD
LDO
Regulator
Protection
VCP
CDVDD
1µF
DRVOFF
VM
DGND
EEPROM
OUTA
OUTA
SPEED/WAKE
BRAKE
PWM, Freq or
Analog Input
Sensorless Trap
Engine
VGLS
Integrated
current
sensing
AVDD
DIR
PGND
IO Interafce
ISENA
PGND
VM
Protection
PGND
A
Protection
VCP
DRVOFF
FG
nFAULT
AVDD
OUTB
OUTB
VGLS
Speed/power loop
Fast accel & decel
120° & 150° capable
SCL
Integrated
current
sensing
AVDD
I2C
SDA
PGND
ISENB
PGND
VM
Protection
PGND
Optional external
clock reference
EXT_WD
EXT_CLK
Protection
VCP
DRVOFF
Built-in 60-MHz
Oscillator
12-bit
DAC
12-bit
ADC
OUTC
OUTC
Op onal external
clock reference
DACOUT1
VGLS
Integrated
current
sensing
DACOUT2
Variable
monitoring on
DACOUT1 &
DACOUT2 pins,
SOX output
VM
ISENA
ISENB
ISENC
OUTA
OUTB
OUTC
PGND
DACOUT2/SOX
PGND
ISENC
PGND
Protection
Figure 8-1. MCT8316AV Functional Block Diagram
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CAVDD 1µF
CFLY 47nF
VM
LBK
AVDD
Out
Buck
Out
- or -
RBK
SW_BK
AVDD AGND
CPL
CPH
CP
CCP
1µF
CBK
VM
VM
VM
GND_BK
Buck/LDO
Regulator
AVDD LDO
Regulator
Charge Pump
Input VM or
Buck/LDO
FB_BK
DVDD
CVM1
+
CVM2
0.1µF
>10µF
DVDD
LDO
Regulator
Protection
VCP
CDVDD
1µF
DRVOFF
VM
DGND
EEPROM
OUTA
OUTA
SPEED/WAKE
BRAKE
PWM, Freq or
Analog Input
Sensorless Trap
Engine
VGLS
Integrated
current
sensing
DIR
PGND
ISENA
RMP_1
PGND
VM
Protection
PGND
Protection
VCP
DRVOFF
RMP_2
LDANGLE
ILIMIT
OUTB
OUTB
IO Interafce
VGLS
Integrated
current
sensing
SLEW_RATE
CONFIG_1
CONFIG_2
Fast accel
PGND
ISENB
120° commutation
PGND
VM
Protection
PGND
AVDD
Protection
VCP
DRVOFF
12-bit
ADC
CONFIG_3
FG
OUTC
OUTC
VGLS
Integrated
current
sensing
nFAULT
VM
ISENA
ISENB
ISENC
OUTA
OUTB
OUTC
PGND
PGND
ISENC
PGND
Protection
Figure 8-2. MCT8316AT Functional Block Diagram
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8.3 Feature Description
8.3.1 Output Stage
The MCT8316A consists of an integrated 95-mΩ (combined high-side and low-side FETs' on-state resistance)
NMOS FETs connected in a three-phase bridge configuration. A doubler charge pump provides the proper
gate-bias voltage to the high-side NMOS FETs across a wide operating-voltage range in addition to providing
100% duty-cycle support. An internal linear regulator provides the gate-bias voltage for the low-side MOSFETs.
8.3.2 Device Interface Modes
The MCT8316A family of devices supports two different interface versions, I2C (MCT8316AV) and hardware
(MCT8316AT) to provide end application design suited for either flexibility or simplicity. The two interface
versions share the same 40-pin VQFN package with significant overlap in power and certain I/O pins (like
FG, nFAULT, DIR, BRAKE, SPEED/WAKE) positions - this compatibility lets application designers evaluate with
one interface version and potentially switch to another with minimal modifications to their design. The I2C version
(MCT8316AV) allows controlling the motor operation and system through BRAKE, DIR, DRVOFF, EXT_CLK,
EXT_WD and SPEED/WAKE . MCT8316AV also provides different signals for monitoring algorithm variables,
speed, fault and phase current feedback through DACOUT1, DACOUT2, FG, nFAULT and SOX. The hardware
version (MCT8316AT) allows controlling the motor operation and system through BRAKE, DIR, SPEED/WAKE,
DRVOFF and allows configuring system/algorithm parameters through CONFIG_1, CONFIG_2, CONFIG_3,
LDANGLE, ILIMIT, RMP_1, RMP_2, SLEW_RATE. MCT8316AT also provides different signals for monitoring
speed and fault feedback through FG and nFAULT.
8.3.2.1 Interface - Control and Monitoring
Motor Control Signals
•
When BRAKE pin is driven 'High', MCT8316A enters brake state. Low-side braking (see Low-Side
Braking) is implemented during this brake state. MCT8316A decreases output speed to value defined by
BRAKE_DUTY_THRESHOLD before entering brake state. As long as BRAKE is driven 'High', MCT8316A
stays in brake state. Brake pin input can be overwritten by configuring BRAKE_INPUT over the I2C interface.
The DIR pin decides the direction of motor spin; when driven 'High', the sequence is OUT A → OUT C →
OUT B, and when driven 'Low' the sequence is OUT A → OUT B → OUT C. DIR pin input can be overwritten
by configuring DIR_INPUT over the I2C interface.
When DRVOFF pin is driven 'High', MCT8316A stops driving the motor by turning OFF all MOSFETs (coast
state). When DRVOFF is driven 'Low', MCT8316A returns to normal state of operation, as if it was restarting
the motor (see DRVOFF Functionality). DRVOFF does not cause the device to go to sleep or standby mode;
the digital core is still active. Entry and exit from sleep or standby condition is controlled by SPEED pin.
SPEED/WAKE pin is used to control motor speed and wake up MCT8316A from sleep mode. SPEED pin can
be configured to accept PWM, frequency or analog input signals. It is used to enter and exit from sleep and
standby mode (see Table 8-19).
•
•
•
External Oscillator and Watchdog Signals (Optional)
•
EXT_CLK pin may be used to provide an external clock reference (see External Clock Source (Available for
MCT8316AV) ).
•
EXT_WD pin may be used to provide an external watchdog signal (see External Watchdog (Available only in
MCT836AV) ).
Output Signals
•
DACOUT1 outputs internal variable defined by address in register DACOUT1_VAR_ADDR, the output of
DACOUT1 is refreshed every PWM cycle (see DAC outputs).
•
DACOUT2 outputs internal variable defined by address in register DACOUT2_VAR_ADDR, the output of
DACOUT2 is refreshed every PWM cycle (see DAC outputs).
•
•
•
FG pin provides pulses which are proportional to motor speed (see FG Configuration).
nFAULT pin provides fault status in device or motor operation.
SOX pin provides the output of one of the current sense amplifiers.
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8.3.2.2 I2C Interface
The MCT8316AV supports an I2C serial communication interface that allows an external controller to send and
receive data. This I2C interface lets the external controller configure the EEPROM and read detailed fault and
motor state information. The I2C bus is a two-wire interface using the SCL and SDA pins which are described as
follows:
•
•
The SCL pin is the clock signal input.
The SDA pin is the data input and output.
8.3.2.3 Hardware Interface - Pin Configuration
MCT8316AT allows configuration of motor control algorithm and driver parameters through the pull-down
resistors connected to the device configuration pins, RMP_1, RMP_2, LDANGLE, CONFIG_1, ILIMIT,
SLEW_RATE, CONFIG_2 and CONFIG_3. This allows quick and easy configuration of the MCT8316 motor
control and gate driver parameters without the need for EEPROM programming through I2C interface. The
parameters that can be configured by each device configuration pin are detailed inTable 8-1 .
Table 8-1. Pin configurable parameters
Pin
Configurable Parameters
RMP_1, RMP_2
Start-up method, open loop acceleration rate, closed loop
acceleration rate, first cycle frequency, align time, dynamic degauss
enable, fast start-up enable, stationary brake time, auto handoff
enable, handoff threshold, open loop duty, align ramp rate
LDANGLE
CONFIG_1
Lead angle or BEMF threshold
PWM switching frequency, ZC detection blanking time, IPD clock
frequency
ILIMIT, SLEW_RATE
CBC limit, open loop, align and IPD current limit, buck output voltage
selection, phase output voltage slew rate
CONFIG_2
CONFIG_3
OCP level, OCP mode, AAR enable, delay compensation enable
Abnormal speed, minimum duty
RMP_1 and RMP_2 pins are used to set the start-up method (Double Align or IPD), open loop acceleration
rate A1 (OL_ACC_A1 in Hz/s), closed loop acceleration rate (CL_ACC in V/s), startup brake time
(STARTUP_BRK_TIME in ms), first cycle frequency (SLOW_FIRST_CYCLE_FREQ in Hz) and align time
(ALIGN_TIME in ms, if Double Align is selected).
RMP_1 is used to set the start-up method and the inertia profile of the motor-load system. Inertia profiles
range from ultra-high inertia (like ceiling fans) to ultra-high acceleration (like fuel pumps) with some example
applications for each type of inertia profile given in Table 8-2. Once the inertia profile is chosen using
RMP_1 pin, RMP_2 pin is used to set parameters like CL_ACC, OL_ACC_A1, STARTUP_BRK_TIME,
SLOW_FIRST_CYC_FREQ, ALIGN_TIME (if applicable).
Based on the inertia profile and CL_ACC chosen, other parameters including IPD repeat times (IPD_REPEAT),
dynamic degauss enable (DYN_DEGAUSS_EN), auto handoff enable (AUTO_HANDOFF), handoff threshold
(OPN_CL_HANDOFF_THR), OL duty (OL_DUTY), align ramp rate (ALIGN_RAMP_RATE) and fast start-up
enable (INTEG_ZC_METHOD) are auto-selected as per Tables through 12-11. Note that Open loop acceleration
rate A2 (OL_ACC_A2 in Hz/s2) is set to the same value as that of OL_ACC_A1.
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Table 8-2. Resistor values for configuring parameters on RMP_1 pin
Level
Resistor value,
RMP_1
MTR_STARTUP
RMP_2
ALIGN_RAMP_R CL_ACC (V/s)
ATE (V/s)
OL_DUTY (%)
configuration
classification
based on motor-
load inertia or
acceleration rate
0
1
2
3
4
Tied to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
Double Align
Ultra-high inertia
Very high inertia
High inertia
10
1, 2
15
20
25
5, 10
100
500
15, 20
25, 50
75, 100
Low acceleration
Medium
acceleration
5
6
30kΩ, ±5%
39kΩ, ±5%
High acceleration
150, 200
250, 500
Very high
1000
40
acceleration
7
51kΩ, ±5%
Ultra-high
1000, 32767
acceleration
8
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
IPD
Ultra-high inertia
Very high inertia
High inertia
10
1, 2
15
20
25
9
5, 10
10
11
12
100
500
15, 20
25, 50
75, 100
Low acceleration
Medium
acceleration
13
14
200kΩ, ±5%
240kΩ, ±5%
High acceleration
150, 200
250, 500
Very high
1000
40
acceleration
15
300kΩ, ±5%
Ultra-high
1000, 32767
acceleration
Table 8-3. Parameter values on RMP_2 pin for ultra-high inertia applications
Level
Resistor value, ALIGN_TIME
DYN_DEGAUS SLOW_FIRST_ STARTUP_BR CL_ACC (V/s) OL_ACC_A1
RMP_2
(ms)
S_EN
CYC_FREQ
(Hz)
K_TIME (ms)
(Hz/s)
0
Tied to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
10000
6000
10000
6000
4000
2000
4000
2000
6000
4000
6000
4000
2000
1000
2000
1000
N
N
N
N
N
N
N
N
N
N
N
N
N
N
N
N
0.01
5000
1
0.005
1
2
0.025
0.05
3
4
2000
1000
500
5
6
0.075
0.025
0.05
7
8
2
0.025
9
10
11
12
13
14
15
0.075
0.1
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For all resistor values in Table 8-3, AUTO_HANDOFF is enabled (1b), OPN_CL_HANDOFF_THR is 600Hz,
INTEG_ZC_METHOD is disabled (0b), IPD_REPEAT is 3.
Table 8-4. Parameter values on RMP_2 pin for very high inertia applications
Level
Resistor value, ALIGN_TIME
DYN_DEGAUS SLOW_FIRST_ STARTUP_BR CL_ACC (V/s) OL_ACC_A1
RMP_2
(ms)
S_EN
CYC_FREQ
(Hz)
K_TIME (ms)
(Hz/s)
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
6000
4000
6000
4000
2000
1000
2000
1000
4000
2000
4000
2000
1000
750
N
N
N
N
N
N
N
N
N
N
N
N
N
N
N
N
0.05
0.075
0.1
1000
5
0.05
1
2
3
4
500
500
250
5
6
0.25
0.25
0.5
7
8
10
0.5
9
10
11
12
13
14
15
0.5
1000
750
0.75
For all resistor values in Table 8-4, AUTO_HANDOFF is enabled (1b), OPN_CL_HANDOFF_THR is 600Hz,
INTEG_ZC_METHOD is disabled (0b), IPD_REPEAT is 3.
Table 8-5. Parameter values on RMP_2 pin for high inertia applications
Level
Resistor value, ALIGN_TIME
DYN_DEGAUS SLOW_FIRST_ STARTUP_BR CL_ACC (V/s) OL_ACC_A1
RMP_2
(ms)
S_EN
CYC_FREQ
(Hz)
K_TIME (ms)
(Hz/s)
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
4000
2000
4000
2000
1000
750
N
N
N
N
N
N
N
N
N
N
N
N
N
N
N
N
0.25
0.5
0.5
0.75
0.5
0.75
1
500
15
1
1
2
3
4
250
250
100
5
6
1000
750
7
8
2000
1000
2000
1000
750
20
2.5
9
10
11
12
13
14
15
500
750
2
500
For all resistor values in Table 8-5, AUTO_HANDOFF is enabled (1b), OPN_CL_HANDOFF_THR is 600Hz,
INTEG_ZC_METHOD is disabled (0b), IPD_REPEAT is 3.
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Table 8-6. Parameter values on RMP_2 pin for low acceleration applications
Level
Resistor value, ALIGN_TIME
DYN_DEGAUS SLOW_FIRST_ STARTUP_BR CL_ACC (V/s) OL_ACC_A1
RMP_2
(ms)
S_EN
CYC_FREQ
(Hz)
K_TIME (ms)
(Hz/s)
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
2000
1000
2000
1000
750
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
0.5
0.75
1
250
25
5
1
2
3
4
100
100
75
5
500
6
750
2
7
500
8
1000
750
0.5
0.75
1
50
10
9
10
11
12
13
14
15
1000
750
500
300
500
2
300
For all resistor values in Table 8-6, AUTO_HANDOFF is enabled (1b), OPN_CL_HANDOFF_THR is 600Hz,
INTEG_ZC_METHOD is disabled (0b), IPD_REPEAT is 3.
Table 8-7. Parameter values on RMP_2 pin for medium acceleration applications
Level
Resistor value, ALIGN_TIME
DYN_DEGAUS SLOW_FIRST_ STARTUP_BR CL_ACC (V/s) OL_ACC_A1
RMP_2
(ms)
S_EN
CYC_FREQ
(Hz)
K_TIME (ms)
(Hz/s)
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
750
500
750
500
300
200
300
200
500
300
500
300
200
100
200
100
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
0.5
0.75
1
100
75
25
1
2
3
4
75
75
50
5
6
2
7
8
0.5
0.75
1
100
50
9
10
11
12
13
14
15
2
For all resistor values in Table 8-7, AUTO_HANDOFF is enabled (1b), OPN_CL_HANDOFF_THR is 600Hz,
INTEG_ZC_METHOD is disabled (0b), IPD_REPEAT is 3.
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Table 8-8. Parameter values on RMP_2 pin for high acceleration applications
Resistor value, ALIGN_TIME
DYN_DEGAUS SLOW_FIRST_ STARTUP_BR CL_ACC (V/s) OL_ACC_A1
RMP_2
(ms)
S_EN
CYC_FREQ
(Hz)
K_TIME (ms)
(Hz/s)
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
500
300
500
300
200
100
200
100
300
200
300
200
100
75
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
N
Y
0.5
0.75
1
75
150
100
1
2
3
4
50
50
25
5
6
2
7
8
1
200
150
9
10
11
12
13
14
15
2
2
100
75
3
For all resistor values in Table 8-8, AUTO_HANDOFF is enabled (1b), OPN_CL_HANDOFF_THR is 600Hz,
INTEG_ZC_METHOD is disabled (0b), IPD_REPEAT is 3.
Table 8-9. Parameter values on RMP_2 pin for very high acceleration applications
Level
Resistor value, ALIGN_TIME
DYN_DEGAUS SLOW_FIRST_ STARTUP_BR CL_ACC (V/s) OL_ACC_A1
RMP_2
(ms)
S_EN
CYC_FREQ
(Hz)
K_TIME (ms)
(Hz/s)
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
200
100
200
100
75
N
Y
N
Y
N
Y
N
Y
Y
Y
Y
Y
Y
Y
Y
Y
1
50
250
200
1
2
2
3
4
3
25
25
10
5
50
6
75
5
7
50
8
100
75
5
500
500
9
10
11
12
13
14
15
100
75
10
10
15
50
25
50
25
For resistor values from (0-51)kΩ in Table 8-9, AUTO_HANDOFF is enabled (1b), OPN_CL_HANDOFF_THR is
600Hz, INTEG_ZC_METHOD is disabled (0b), IPD_REPEAT is 3.
For resistor values from (62-300)kΩ in Table 8-9, AUTO_HANDOFF is disabled (0b), OPN_CL_HANDOFF_THR
is 20Hz, INTEG_ZC_METHOD is enabled (1b), IPD_REPEAT is 1.
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Table 8-10. Parameter values on RMP_2 pin for ultra-high acceleration applications
Level
Resistor ALIGN_TIME (ms)
DYN_DEGAUSS_EN SLOW_FIRST_CYC_FREQ (Hz)
STARTU CL_ACC OL_ACC
value,
RMP_2
P_BRK_ (V/s)
TIME
_A1
(Hz/s)
(ms)
0
Tie to
GND
50
25
50
25
10
5
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
15
25
25
50
25
50
75
100
10
1000
1000
1
4.7kΩ,
±5%
2
10kΩ,
±5%
3
15kΩ,
±5%
4
22kΩ,
±5%
5
5
30kΩ,
±5%
6
39kΩ,
±5%
10
5
7
51kΩ,
±5%
8
62kΩ,
±5%
25
10
25
10
5
5
32767
2000
9
75kΩ,
±5%
10
11
12
13
14
15
91kΩ,
±5%
110kΩ,
±5%
150kΩ,
±5%
2
200kΩ,
±5%
2
240kΩ,
±5%
5
300kΩ,
±5%
2
For all resistor values in Table 8-10, AUTO_HANDOFF is disabled (0b), OPN_CL_HANDOFF_THR is 20Hz,
INTEG_ZC_METHOD is enabled (1b), IPD_REPEAT is 1.
For example, consider the use-case of MTR_STARTUP
–
Double Align, CL_ACC
–
75V/s,
STARTUP_BRK_TIME – 75ms, SLOW_FIRST_CYC_FREQ – 1Hz, ALIGN_TIME – 200ms. Here, RMP_1 pin
needs a pull-down resistor of 22kΩ to set start-up method to double align and select medium acceleration
inertia profile (corresponding to CL_ACC of 75V/s). RMP_2 pin needs a pull-down resistor of 30kΩ to select
the required CL_ACC, STARTUP_BRK_TIME, SLOW_FIRST_CYC_FREQ and ALIGN_TIME. Note that the
DYN_DEGAUSS_EN is set to enabled (1b) with this RMP_2 resistor value. If DYN_DEGAUSS_EN needs to be
disabled (0b), RMP_2 pull-down resistor can be set to 22kΩ, but this will increase the STARTUP_BRK_TIME to
300ms instead. Depending on the parameter that can be set to adjacent values, an optimal resistor setting can
be picked from the appropriate table for a given inertia profile.
LDANGLE pin is used to set the lead angle (LD_ANGLE in degrees) as per Table 8-11, if INTEG_ZC_METHOD
is set to 0b. If INTEG_ZC_METHOD is set to 1b, LDANGLE is pin is used to configure the BEMF threshold
(BEMF_THRESHOLD1 and BEMF_THRESHOLD2) for integration based ZC method for fast start-up as per
Table 8-11.
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Table 8-11. Resistor values for configuring parameters on LDANGLE pin
Resistor value, LDANGLE
LD_ANGLE (deg.)
BEMF_THRESHOLD1 and
BEMF_THRESHOLD2
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
0
200
1
2
300
2
4
400
3
6
500
4
8
600
5
10
12
14
16
18
20
22
24
26
28
30
700
6
800
7
1000
1200
1400
1600
1800
2100
2400
2700
3000
8
9
10
11
12
13
14
15
CONFIG_1 pin is used to set the PWM switching frequency (PWM_FREQ_OUT in kHz), ZC detection blanking
time (TBLANK in µs) and IPD clock frequency (IPD_CLK_FREQ in Hz) as per Table 8-12.
Table 8-12. Resistor values for configuring parameters on CONFIG_1 pin
Level
Resistor value,
CONFIG_1
TBLANK (μs)
PWM_FREQ_OUT (kHz) IPD_CLK_FREQ (Hz)
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
10
8
10
20
25
40
50
60
75
100
500
1
2
10
8
3
4
8
1000
2000
5000
5
6
6
8
7
6
8
6
9
4
10
11
12
13
14
15
6
4
4
2
4
2
ILIMIT and SLEW_RATE pins are used to set the cycle-by-cycle (CBC) current limit (ILIMIT in A), CSA_GAIN (in
V/A), Open Loop (OL_ILIMIT in A), align (ALIGN_CURR_THR in A) and IPD current limit (IPD_CURR_THR in A)
as per Table 8-13 and Table 8-14 . For a given resistor (configuration) value for ILIMIT pin, there are two different
values of OL_ILIMIT(ALIGN_CURR_THR and IPD_CURR_THR) that can be chosen(Limit_0 or Limit_1). After
choosing between Limit_0 and Limit_1, SLEW_RATE pin pull-down resistor value is selected based on the buck
output voltage level (BUCK_SEL, either 3.3V or 5V) and phase output slew rate(SLEW_RATE in V/µs) as per
Table 8-14.
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Table 8-13. Resistor values for configuring parameters on ILIMIT pin
Level
Resistor value,
ILIMIT
ILIMIT (A)
CSA_GAIN (V/A)
Open loop, align
current, IPD current ALIGN_CURR_THR,
OL_ILIMIT,
selection
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
IPD_CURR_THR (A)
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
0.5
1
1.2
0.25
0.42
0.5
1
1
0.6
2
1.33
2.67
3.33
4
0.6
0.5
0.83
1
3
0.3
2
4
0.3
1.33
2.67
2
5
0.15
0.15
0.15
0.15
0.15
0.15
0.15
0.15
0.15
0.15
0.15
3.33
2
6
4.67
4.67
5.33
6
2.67
3.33
4
7
8
2.67
4
9
2
2.67
3.33
4
10
11
12
13
14
15
6
6
4.67
5.33
2.67
3.33
4
7.33
7.33
7.33
8
4.67
5.33
6
4
6
Table 8-14. Resistor values for configuring parameters on SLEW_RATE pin
Level
Resistor value,
SLEW_RATE
BUCK_SEL
SLEW_RATE (V/μs)
Open loop, align current,
IPD current selection
0
1
2
3
4
5
6
7
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
3.3V
25
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
50
125
200
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Table 8-14. Resistor values for configuring parameters on SLEW_RATE pin (continued)
Resistor value,
SLEW_RATE
BUCK_SEL
SLEW_RATE (V/μs)
Open loop, align current,
IPD current selection
8
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
5V
25
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
Limit_0
Limit_1
9
10
11
12
13
14
15
50
125
200
For example, consider the use-case of ILIMIT – 4.67A, OL_ILIMIT – 3.33A, BUCK_SEL – 3.3V, SLEW_RATE
– 125V/µs. From Table 8-13, ILIMIT pin needs a pull-down resistor of 51kΩ, whereas OL_ILIMIT selection is
Limit_0. So, SLEW_RATE pin needs a pull-down resistor of 22kΩ, from Table 8-14.
Similarly, consider the use-case of ILIMIT – 7.33A, OL_ILIMIT – 4.67A, BUCK_SEL – 5V, SLEW_RATE –
25V/µs. Here, ILIMIT pin needs a pull-down resistor of 200kΩ, whereas OL_ILIMIT selection is Limit_1 from
Table 8-13. So, SLEW_RATE pin needs a pull-down resistor of 75kΩ from Table 8-14.
CONFIG_2 pin is used to set the OCP level (OCP_LVL as either 10 or 15A) and mode (OCP_MODE as
either latched or retry after 500ms), Active Asynchronous Rectification (AAR) enable (EN_AAR) and delay
compensation enable (DELAY_COMP_EN) as per Table 8-15.
Table 8-15. Resistor values for configuring parameters on CONFIG_2 pin
Level
Resistor value,
CONFIG_2
OCP_LVL (A)
DELAY_COMP_EN
EN_AAR
OCP_MODE
0
Tie to GND
4.7kΩ, ±5%
10kΩ, ±5%
15kΩ, ±5%
22kΩ, ±5%
30kΩ, ±5%
39kΩ, ±5%
51kΩ, ±5%
62kΩ, ±5%
75kΩ, ±5%
91kΩ, ±5%
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
10
15
10
15
10
15
10
15
10
15
10
15
10
15
10
15
Disable
Disable
Latched
1
2
Enable
Disable
Enable
Disable
Enable
Disable
Enable
3
4
Enable
Disable
Enable
5
6
7
8
Retry after 500ms
9
10
11
12
13
14
15
CONFIG_3 is used to set the abnormal speed threshold (LOCK_ABN_SPEED in Hz) and minimum duty cycle
(MIN_DUTY in %) as per Table 8-16.
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Table 8-16. Resistor values for configuring parameters on CONFIG_3 pin
Level
0
Resistor value, CONFIG_3
MIN_DUTY (%)
ABN_SPEED (Hz)
Tie to GND
2.5
5
1000
1
4.7kΩ, ±5%
10kΩ, ±5%
2
7.5
10
2.5
5
3
15kΩ, ±5%
4
22kΩ, ±5%
2000
3000
4000
5
30kΩ, ±5%
6
39kΩ, ±5%
7.5
10
2.5
5
7
51kΩ, ±5%
8
62kΩ, ±5%
9
75kΩ, ±5%
10
11
12
13
14
15
91kΩ, ±5%
7.5
10
2.5
5
110kΩ, ±5%
150kΩ, ±5%
200kΩ, ±5%
240kΩ, ±5%
300kΩ, ±5%
7.5
10
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8.3.3 Step-Down Mixed-Mode Buck Regulator
The MCT8316A has an integrated mixed-mode buck regulator in conjunction with AVDD to supply regulated
3.3 V or 5 V power for an external controller or system voltage rail. Additionally, the buck output can also be
configured to 4 V or 5.7 V for supporting the extra headroom for external LDO for generating a 3.3 V or 5 V
supplies. The output voltage of the buck is set by BUCK_SEL.
The buck regulator has a low quiescent current of ~1-2 mA during light loads to prolong battery life. The device
improves performance during line and load transients by implementing a pulse-frequency current-mode control
scheme which requires less output capacitance and simplifies frequency compensation design.
Table 8-17. Recommended settings for Buck Regulator
Buck Mode
Buck output voltage Max output
Max output current Buck current limit
AVDD power
sequencing
current from AVDD from Buck (IBK_MAX
)
(IAVDD_MAX
)
Inductor - 47 μH
Inductor - 47 μH
Inductor - 22 μH
Inductor - 22 μH
Resistor - 22 Ω
Resistor - 22 Ω
3.3 V or 4 V
5 V or 5.7 V
5 V or 5.7 V
3.3 V or 4 V
5 V or 5.7 V
3.3 V or 4 V
20 mA
170 mA - IAVDD
170 mA - IAVDD
20 mA - IAVDD
20 mA - IAVDD
10 mA - IAVDD
10 mA - IAVDD
600 mA (BUCK_CL = Not supported
0b)
(BUCK_PS_DIS = 1b)
20 mA
20 mA
20 mA
20 mA
20 mA
600 mA (BUCK_CL = Supported
0b)
(BUCK_PS_DIS = 0b)
150 mA (BUCK_CL = Not supported
1b)
(BUCK_PS_DIS = 1b)
150 mA (BUCK_CL = Supported
1b)
(BUCK_PS_DIS = 0b)
150 mA (BUCK_CL = Not supported
1b)
(BUCK_PS_DIS = 1b)
150 mA (BUCK_CL = Supported
1b)
(BUCK_PS_DIS = 0b)
8.3.3.1 Buck in Inductor Mode
The buck regulator in MCT8316A is primarily designed to support low inductance of 47-µH and 22-µH. A 47-µH
inductor allows the buck regulator to operate up to 170-mA load current support, whereas applications requiring
current up to 20-mA can use a 22-µH inductor which saves component size.
Figure 8-3 shows the connection of buck regulator in inductor mode.
VM
SW_BK
Ext. Load
VBK
Control
LBK
CBK
GND_BK
FB_BK
Figure 8-3. Buck (Inductor Mode)
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8.3.3.2 Buck in Resistor mode
If the external load requirement is less than 10-mA, the inductor can be replaced with a resistor. In resistor mode
the power is dissipated across the external resistor and the efficiency is lower than buck in inductor mode.
Figure 8-4 shows the connection of buck in resistor mode.
VM
SW_BK
Ext. Load
VBK
Control
RBK
CBK
GND_BK
FB_BK
Figure 8-4. Buck (Resistor Mode)
8.3.3.3 Buck Regulator with External LDO
The buck regulator also supports the voltage requirement to supply an external LDO to generate standard 3.3-V
or 5-V output rail with higher accuracies. The buck output voltage should be configured to 4-V or 5.7-V to provide
extra headroom to support the external LDO for generating 3.3-V or 5-V rail as shown in Figure 8-5. This allows
for a lower-voltage LDO design to save cost and better thermal management due to low drop-out voltage.
VM
VLDO
(3.3V / 5V)
VBK
SW_BK
(4V / 5.7V)
VIN
VLDO
Ext. Load
CLDO
Control
LBK
3.3V / 5V
LDO
CBK
GND_BK
FB_BK
GND
External LDO
GND
Figure 8-5. Buck Regulator with External LDO
8.3.3.4 AVDD Power Sequencing from Buck Regulator
The AVDD LDO has an option of using the power supply from mixed mode buck regulator to reduce the
device power dissipation. The power sequencing mode allows on-the-fly changeover of AVDD LDO input from
DC mains (VM) to buck output (VBK) as shown in Figure 8-6. This sequencing can be configured through the
BUCK_PS_DIS bit . Power sequencing is supported only when buck output voltage is set to 5-V or 5.7-V.
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VM
SW_BK
LBK
Ext. Load
VBK
Control
CBK
GND_BK
FB_BK
BUCK_PS_DIS
VBK
VM
AVDD LDO
REF
+
–
AVDD
AGND
External Load
CAVDD
Figure 8-6. AVDD Power Sequencing from Mixed Mode Buck Regulator
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8.3.3.5 Mixed Mode Buck Operation and Control
The buck regulator implements a pulse frequency modulation (PFM) architecture with peak current mode control.
The output voltage of the buck regulator is compared with the internal reference voltage (VBK_REF) which is
internally generated depending on the buck-output voltage setting (BUCK_SEL) which constitutes an outer
voltage control loop. Depending on the comparator output going high (VBK < VBK_REF) or low (VBK > VBK_REF),
the high-side power FET of the buck turns on and off respectively. An independent current control loop monitors
the current in high-side power FET (IBK) and turns off the high-side FET when the current becomes higher than
the buck current limit (IBK_CL). This implements a current limit control for the buck regulator. Figure 8-7 shows the
architecture of the buck and various control/protection loops.
SW_BK
IBK
Ext. Load
VBK
VM
LBK
PWM Control
and Driver
CBK
GND_BK
IBK
+
Current Limit
OC Protection
UV Protection
_
IBK_CL
IBK
+
_
IBK_OCP
FB_BK
VBK
+
_
VBK_UVLO
VBK
+
_
Voltage Control
VBK_REF
Buck
Reference
Voltage
BUCK_SEL
Buck Control
Generator
Figure 8-7. Buck Operation and Control Loops
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8.3.3.6 Buck Undervoltage Protection
If at any time the voltage on the FB_BK pin (buck regulator output) falls lower than the VBK_UVLO threshold,
both the high-side and low-side MOSFETs of the buck regulator are disabled . MCT8316A goes into reset state
whenever buck UV event occurs, since the internal circuitry in MCT8316A is powered from the buck regulator
output.
8.3.3.7 Buck Overcurrent Protection
The buck overcurrent event is sensed by monitoring the current flowing through high-side MOSFET of the buck
regulator. If the current through the high-side MOSFET exceeds the IBK_OCP threshold for a time longer than the
deglitch time (tOCP_DEG), a buck OCP event is recognized. MCT8316A goes into reset state whenever buck OCP
event occurs, since the internal circuitry in MCT8316A is powered from the buck regulator output.
8.3.4 AVDD Linear Voltage Regulator
A 3.3-V, linear regulator is integrated into the MCT8316A family of devicesand is available for use by external
circuitry. The AVDD LDO regulator is used for powering up the internal circuitry of the device and additionally,
this regulator can also provide the supply voltage for a low-power MCU or other circuitry supporting low current
(up to 20-mA). The output of the AVDD regulator should be bypassed near the AVDD pin with a X5R or X7R,
1-µF, 6.3-V ceramic capacitor routed directly back to the adjacent AGND ground pin.
The AVDD nominal, no-load output voltage is 3.3-V.
FB_BK
BUCK_PS_DIS
VBK
VM
REF
+
–
AVDD
AGND
External Load
CAVDD
Figure 8-8. AVDD Linear Regulator Block Diagram
Use Equation 1 to calculate the power dissipated in the device by the AVDD linear regulator with VM as supply
(BUCK_PS_DIS = 1b)
2 = (88/ F 8#8&&) × +#8&&
(1)
For example, at a VVM of 24-V, drawing 20-mA out of AVDD results in a power dissipation as shown in Equation
2.
P = 24 V - 3.3 V ì 20 mA = 414 mW
(2)
Use Equation 3 to calculate the power dissipated in the device by the AVDD linear regulator with buck output as
supply (BUCK_PS_DIS = 0b)
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P =
V
− V
× I
(3)
FB_BK
AVDD AVDD
8.3.5 Charge Pump
Since the output stages use N-channel FETs, the device requires a gate-drive voltage higher than the VM power
supply to turn-on the high-side FETs. The MCT8316A integrates a charge-pump circuit that generates a voltage
above the VM supply for this purpose.
The charge pump requires two external capacitors(CCP, CFLY) for operation. See the block diagram and pin
descriptions for details on these capacitors (value, connection, and so forth).
VM
VM
CCP
CP
CPH
VM
Charge
Pump
Control
CFLY
CPL
Figure 8-9. Charge Pump
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8.3.6 Slew Rate Control
An adjustable gate-drive current control for the MOSFETs in the output stage is provided to achieve configurable
slew rate for EMI mitigation. The MOSFET VDS slew rate is a critical factor for optimizing radiated emissions,
total energy and duration of diode recovery spikes and switching voltage transients related to parasitic elements
of the PCB. This slew rate is predominantly determined by the control of the internal MOSFET gate current as
shown in Figure 8-10.
VM
VCP (Internal)
Slew Rate
Control
OUTx
VCP (Internal)
Slew Rate
Control
GND
Figure 8-10. Slew Rate Circuit Implementation
The slew rate of each half-bridge can be adjusted through SLEW_RATE settings. Slew rate can be configured as
25-V/µs, 50-V/µs, 125-V/µs or 200-V/µs. The slew rate is calculated by the rise-time and fall-time of the voltage
on OUTx pin as shown in Figure 8-11.
VOUTx
VM
VM
80%
80%
20%
20%
0
Time
tfall
trise
Figure 8-11. Slew Rate Timings
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8.3.7 Cross Conduction (Dead Time)
The device is fully protected against any cross conduction of the MOSFETs. The high-side and low-side
MOSFETs are carefully controlled to avoid any shoot-through events by inserting a dead time (tdead). This is
implemented by sensing the gate-source voltage (VGS) of the high-side and low-side MOSFETs and ensuring
that the VGS of high-side MOSFET has reached below turn-off levels before switching on the low-side MOSFET
of same half-bridge as shown in Figure 8-12 and Figure 8-13 and vice versa.
VM
Gate
Control
+
VGS
VGS_HS
VGS_LS
–
OUTx
tDEAD
Gate
Control
+
GND
VGS
–
Figure 8-12. Cross Conduction Protection
OUTx HS
OUTx
Gate
(VGS_HS)
10%
tDEAD
OUTx
Gate
(VHS_LS)
10%
OUTx LS
Time
Figure 8-13. Dead Time
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8.3.8 SPEED Control
The MCT8316A offers four methods of directly controlling the speed of the motor. The speed control method is
configured by SPD_CTRL_MODE. The speed command can be controlled in one of the following four ways.
•
•
•
•
PWM input on SPEED pin by varying duty cycle of input signal
Frequency input on SPEED pin by varying frequency of input signal
Analog input on SPEED pin by varying amplitude of input signal
Over I2C by configuring SPEED_CTRL
The speed can also be indirectly controlled by varying the supply voltage (VM).
TARGET DUTY
Optional
Freq based
Freq
Duty
AVS, CL_ACC
PWM
PWM Duty
ADC
SPEED Pin
Transfer
Function
Speed Loop/
Constant
DUTY
CMD
SPEED
REF
Power mode
Analog
DUTY
OUT
FETs
PWM
I2C
Figure 8-14. Multiplexing the Speed Command
The signal path from SPEED pin input (or I2C based speed input) to output duty cycle (DUTY OUT) applied to
FETs is shown in Figure 8-14.
SPEED REF / TARGET DUTY
MAX_SPEED / 100%
MIN_DUTY x MAX_SPEED /
MIN_DUTY
DUTY CMD
0
100%
ZERO_
DUTY_
THR
MIN_DUTY
Figure 8-15. Speed Input Transfer Function
Figure 8-15 shows the relationship between DUTY CMD and SPEED REF / TARGET DUTY.
When speed loop is enabled, DUTY CMD sets the SPEED REF in Hz. MAX_SPEED sets the SPEED REF at
DUTY CMD of 100%. MIN_DUTY sets the minimum SPEED REF (MIN_DUTY x MAX_SPEED). SPEED REF
stays clamped at (MIN_DUTY x MAX_SPEED) for ZERO_DUTY_THR < DUTY CMD < MIN_DUTY.
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When speed loop is disabled, DUTY CMD sets the TARGET DUTY in % - TARGET DUTY is 100% when DUTY
CMD is 100% and TARGET DUTY is equal to MIN_DUTY when DUTY CMD is set to MIN_DUTY. TARGET
DUTY stays clamped at MIN DUTY for ZERO_DUTY_THR < DUTY CMD < MIN_DUTY.
ZERO_DUTY_THR sets the DUTY CMD below which SPEED REF/ TARGET DUTY (speed loop enabled/
disabled) is set to zero and motor is in stopped state. AVS, CL_ACC configure the transient characteristics of
DUTY OUT; the steady state value of DUTY OUT is directly configured in % through TARGET DUTY (when
speed loop is disabled) or through SPEED REF (when speed loop is enabled).
8.3.8.1 Analog-Mode Speed Control
Analog input based speed control can be configured by setting SPD_CTRL_MODE to 00b. In this mode, the duty
command (DUTY CMD) varies with the analog voltage input on the SPEED pin(VSPEED). When 0 < VSPEED
<
VEN_SB, DUTY CMD is set to zero and the motor is stopped. When VEN_SB < VSPEED < VANA_FS, DUTY CMD
varies linearly with VSPEED as shown in Figure 8-16 . When VSPEED > VANA_FS, DUTY CMD is clamped to 100%.
DUTY CMD
100%
Analog Speed Input
VEN_SB
VANA_FS
0
Figure 8-16. Analog-Mode Speed Control
8.3.8.2 PWM-Mode Speed Control
PWM based speed control can be configured by setting SPD_CTRL_MODE to 01b. In this mode, the PWM
duty cycle applied to the SPEED pin can be varied from 0 to 100% and duty command (DUTY CMD) varies
linearly with the applied PWM duty cycle. DUTY CMD is set to zero and the motor is stopped when the
PWM signal at SPEED pin stays < VDIG_IL for longer than tEN_SB_PWM. The frequency of the PWM input signal
applied to the SPEED pin is defined as fPWM and the range for this frequency can be configured through
SPD_PWM_RANGE_SELECT.
Note
fPWM is the frequency of the PWM signal the device can accept at SPEED pin to control motor speed.
It does not correspond to the PWM output frequency that is applied to the motor phases. The PWM
output frequency can be configured through PWM_FREQ_OUT (see Section 8.3.15).
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DUTY CMD
100%
PWM Duty Input
100%
Figure 8-17. PWM-Mode Speed Control
8.3.8.3 I2C based Speed Control
I2C based serial interface can be used for speed control by setting SPD_CTRL_MODE to 10b. In this mode,
the duty command can be written directly into SPEED_CTRL and the SPEED pin can be independently used
to control the sleep entry and exit. If SPEED pin input is < VEN_SL for a time longer than SLEEP_TIME,
MCT831A enters sleep state irrespective of the I2C duty command in SPEED_CTRL. When SPEED pin >
VEX_SL, MCT8316A exits sleep state and speed is controlled through SPEED_CTRL. If SPEED_CTRL is set to 0
and SPEED pin > VEX_SL, MCT8316A is in standby state.
8.3.8.4 Frequency-Mode Speed Control
Frequency based speed control is configured by setting SPD_CTRL_MODE to 11b. In this mode, duty command
varies linearly as a function of the frequency of the square wave input at SPEED pin as given in Equation
4. Input frequency greater than INPUT_MAX_FREQUENCY clamps the duty command to 100%. The duty
command is set to zero and the motor is stopped when the frequency signal at SPEED pin stays < VDIG_IL for
longer than tEN_SB_FREQ
.
Duty command = Frequency at SPEED pin / INPUT_MAX_FREQUENCY * 100
(4)
8.3.9 Starting the Motor Under Different Initial Conditions
The motor can be in one of three states when MCT8316A begins the start-up process. The motor may be
stationary, spinning in the forward direction, or spinning in the reverse direction. The MCT8316A includes a
number of features to allow for reliable motor start-up under all of these conditions. Figure 8-18 shows the motor
start-up flow for each of the three initial motor states.
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Brake
Align
Double Align
IPD
Sta onary
Slow rst cycle
Spinning in forward
direc on
Closed Loop
Coast (Hi-Z)
Brake
Spinning in reverse
direc on
Reverse Drive
Figure 8-18. Starting the motor under different initial conditions
Note
"Forward" means "spinning in the same direction as the commanded direction", and "Reverse" means
"spinning in the opposite direction as the commanded direction".
8.3.9.1 Case 1 – Motor is Stationary
If the motor is stationary, the commutation must be initialized to be in phase with the position of the motor. The
MCT8316A provides various options to initialize the commutation logic to the motor position and reliably start the
motor.
•
•
•
The align and double align techniques force the motor into alignment by applying a voltage across a
particular motor phase to force the motor to rotate in alignment with this phase.
Initial position detect (IPD) determines the position of the motor based on the deterministic inductance
variation, which is often present in BLDC motors.
The slow first cycle method starts the motor by applying a low frequency cycle to align the rotor position to
the applied commutation by the end of one electrical rotation.
MCT8316A also provides a configurable brake option to ensure the motor is stationary before initiating one of
the above start-up methods. Device enters open loop acceleration after going through the configured start-up
method.
8.3.9.2 Case 2 – Motor is Spinning in the Forward Direction
If the motor is spinning forward (same direction as the commanded direction) with sufficient speed (BEMF),
the MCT8316A resynchronizes with the spinning motor and continues commutation by going directly to closed
loop operation. By resynchronizing to the spinning motor, the user achieves the fastest possible start-up time
for this initial condition. This resynchronization feature can be enabled or disabled through RESYNC_EN. If
resynchronization is disabled, the MCT8316A can be configured to wait for the motor to coast to a stop and/or
apply a brake. After the motor has stopped spinning, the motor start-up sequence proceeds as in Case 1,
considering the motor is stationary.
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8.3.9.3 Case 3 – Motor is Spinning in the Reverse Direction
If the motor is spinning in the reverse direction (the opposite direction as the commanded direction), the
MCT8316A provides several methods to change the direction and drive the motor to the target speed reference
in the commanded direction.
The reverse drive method allows the motor to be driven so that it decelerates through zero speed. The motor
achieves the shortest possible spin-up time when spinning in the reverse direction.
If reverse drive is not enabled, then the MCT8316A can be configured to wait for the motor to coast to a stop
and/or apply a brake. After the motor has stopped spinning, the motor start-up sequence proceeds as in Case 1,
considering the motor is stationary.
Note
Take care when using the reverse drive or brake feature to ensure that the current is limited to an
acceptable level and that the supply voltage does not surge as a result of energy being returned to the
power supply.
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8.3.10 Motor Start Sequence (MSS)
Figure 8-19 shows the motor-start sequence implemented in the MCT8316A device.
Power On
DIR Change
N
ISD_EN
Y
Is motor
Y
sta onary
N
Reverse
Forward
N
Direc on of
Spin
N
RVS_DR_EN
Y
RESYNC_EN
Y
HIZ_EN
N
BEMF >
RESYNC_MIN_THRES
HOLD
N
Y
Brake_Rou ne
BRK_CONFIG
Speed > Open to
Closed Loop Hando
Hi-Z
N
Y
STAT_BRK_EN
BRK_CURR
BRK_TIME
Brake
N
Time >
HIZ_TIME
Y
Y
Brake
Y
N
Brake
N
Reverse Closed
Loop Decelera on
N
BRAKE_EN
Reverse
Open Loop
Decelera on
Time >
STARTUP_
BRK_TIME
N
N
Y
Current <
BRK_CURR_THR
Time >
BRK_TIME
Brake_Rou ne
Y
Y
Y
Direc on Reversal :
Zero Speed Crossover
Brake_Rou ne_End
Motor Start-up
Open loop
Closed Loop
Figure 8-19. Motor Starting-Up Flow
Power-On State
This is the initial state of the Motor Start Sequence (MSS). The MSS starts
in this state on initial power-up or whenever the MCT8316A device comes
out of standby or sleep mode.
DIR Change Judgement
ISD_EN Judgement
In MCT8316A, if direction change command is detected at start of MSS, the
motor direction detected in ISD is assumed to be opposite to commanded
direction and reverse drive is performed if RVS_DR_EN is set to 1b.
After power-on, the MCT8316A MSS enters the ISD_EN judgement where
it checks to see if the initial speed detect (ISD) function is enabled
(ISD_EN = 1b). If ISD is disabled, the MSS proceeds directly to the
BRAKE_EN judgement. If ISD is enabled, MSS advances to the ISD (Is
Motor Stationary) state.
ISD State
The MSS determines the initial condition (speed, direction of spin) of
the motor (see Initial Speed Detect (ISD)). If motor is deemed to be
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stationary (motor BEMF < STAT_DETECT_THR), the MSS proceeds to
STAT_BRK_EN judgement. If the motor is not stationary, MSS proceeds to
verify the direction of spin.
STAT_BRK_EN Judgement
Stationary Brake Routine
Direction of Spin Judgement
The MSS checks if the stationary brake function is enabled (STAT_BRK_EN
=1b). If the stationary brake function is enabled, the MSS advances to the
stationary brake routine. If the stationary brake function is disabled, the MSS
advances to motor start-up state (see Section 8.3.10.4).
The stationary brake routine can be used to ensure the motor is completely
stationary before attempting to start the motor. The stationary brake is
applied by turning on all three low-side driver MOSFETs for a time
configured by STARTUP_BRK_TIME.
The MSS determines whether the motor is spinning in the forward or
the reverse direction. If the motor is spinning in the forward direction,
the MCT8316A proceeds to the RESYNC_EN judgement. If the motor is
spinning in the reverse direction, the MSS proceeds to the RVS_DR_EN
judgement.
RESYNC_EN Judgement
If RESYNC_EN is set to 1b, MCT8316A proceeds to BEMF >
RESYNC_MIN_THRESHOLD judgement. If RESYNC_EN is set to 0b, MSS
proceeds to HIZ_EN judgement.
BEMF >
RESYNC_MIN_THRESHOLD
Judgement
If motor speed is such that BEMF > RESYNC_MIN_THRESHOLD,
MCT8316A uses the speed and position information from the ISD state
to transition to the closed loop state (see Motor Resynchronization )
directly. If BEMF < RESYNC_MIN_THRESHOLD, MCT8316A proceeds to
STAT_BRK_EN judgement.
RVS_DR_EN Judgement
The MSS checks to see if the reverse drive function is enabled
(RVS_DR_EN = 1). If it is enabled, the MSS transitions to check speed
of the motor in reverse direction. If the reverse drive function is not enabled,
the MSS advances to the HIZ_EN judgement.
Speed > Open to Closed Loop The MSS checks to see if the reverse speed is high enough for MCT8316A
Handoff Judgement
to decelerate in closed loop. Till the speed (in reverse direction) is high
enough, MSS stays in reverse closed loop deceleration. If speed is too low,
then the MSS transitions to reverse open loop deceleration.
Reverse Closed Loop, Open
Loop Deceleration and Zero
Speed Crossover
The MCT8316A resynchronizes in the reverse direction, decelerates the
motor in closed loop till motor speed falls below the handoff threshold.
(see Reverse Drive). When motor speed in reverse direction is too low,
the MCT8316A switches to open-loop, decelerates the motor in open-loop,
crosses zero speed, and accelerates in the forward direction in open-loop
before entering closed loop operation after motor speed is sufficiently high.
HIZ_EN Judgement
The MSS checks to determine whether the coast (Hi-Z) function is enabled
(HIZ_EN =1). If the coast function is enabled, the MSS advances to the
coast routine. If the coast function is disabled, the MSS advances to the
BRAKE_EN judgement.
Coast (Hi-Z) Routine
The device coasts the motor by turning OFF all six MOSFETs for a certain
time configured by HIZ_TIME.
BRAKE_EN Judgement
The MSS checks to determine whether the brake function is enabled
(BRAKE_EN =1). If the brake function is enabled, the MSS advances to
the brake routine. If the brake function is disabled, the MSS advances to the
motor start-up state (see Section 8.3.10.4).
Brake Routine
MCT8316A implements either a time based brake (duration configured by
BRK_TIME) or a current based brake (brake applied till phase currents <
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BRK_CURR_THR) based on BRK_CONFIG. Brake is applied either using
high-side or low-side MOSFETs based on BRK_MODE configuration.
Closed Loop State
In this state, the MCT8316A drives the motor with trapezoidal control.
8.3.10.1 Initial Speed Detect (ISD)
The ISD function is used to identify the initial condition of the motor and is enabled by setting ISD_EN to 1b. The
initial speed, position and direction is determined by sampling the phase voltage through the internal ADC. ISD
can be disabled by setting ISD_EN to 0b. If the function is disabled (ISD_EN set to 0b), the MCT8316A does not
perform the initial speed detect function and proceeds to check if the brake routine (BRAKE_EN) is enabled.
8.3.10.2 Motor Resynchronization
The motor resynchronization function works when the ISD and resynchronization functions are both enabled and
the device determines that the initial state of the motor is spinning in the forward direction (same direction as
the commanded direction). The speed and position information measured during ISD are used to initialize the
drive state of the MCT8316A, which can transition directly into closed loop state without needing to stop the
motor. In the MCT8316A, motor resynchronization can be enabled/disabled through RESYNC_EN bit. If motor
resynchronization is disabled, the device proceeds to check if the motor coast (Hi-Z) routine is enabled.
8.3.10.3 Reverse Drive
The MCT8316A uses the reverse drive function to change the direction of the motor rotation when ISD_EN
and RVS_DR_EN are both set to 1b and the ISD determines the motor spin direction to be opposite to
that of the commanded direction. Reverse drive includes synchronizing with the motor speed in the reverse
direction, reverse decelerating the motor through zero speed, changing direction, and accelerating in open
loop in forward (or commanded) direction until the device transitions into closed loop in forward direction
(see Figure 8-20). MCT8316A uses the same parameter values for open to closed loop handoff threshold
(OPN_CL_HANDOFF_THR), open loop acceleration rates (OL_ACC_A1, OL_ACC_A2) and open loop current
limit (OL_ILIMIT) in the reverse direction as in the forward direction..
Speed
Close loop
Handoff to close loop
Open loop
Time
Handoff to open loop
Open Loop
Reverse Deceleration
Figure 8-20. Reverse Drive Function
8.3.10.4 Motor Start-up
There are different options available for motor start-up from a stationary position and these options can be
configured by MTR_STARTUP. In align and double align mode, the motor is aligned to a known position by
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injecting a DC current. In IPD mode, the rotor position is estimated by applying 6 different high-frequency pulses.
In slow first cycle mode, the motor is started by applying a low frequency cycle.
8.3.10.4.1 Align
Align is enabled by configuring MTR_STARTUP to 00b. The MCT8316A aligns the motor by injecting a DC
current using a particular phase pattern (phase-C high-side FET and phase-B low-side FET are ON) - current
flowing into phase-B and flowing out from phase-C for a certain time configured by ALIGN_TIME.
The duty cycle during align is defined by ALIGN_DUTY. In MCT8316A, current limit during align is
configured through OL_ILIMIT_CONFIG and is determined by ILIMIT or OL_ILIMIT based on configuration of
OL_ILIMIT_CONFIG.
A fast change in the phase current during align may result in a sudden change in the driving torque and this
could result in acoustic noise. To avoid this, the MCT8316A ramps up duty cycle from 0 to until it reaches
ALIGN_DUTY at a configurable rate set by ALIGN_RAMP_RATE. At the end of align routine, the motor will be
aligned at the known position.
8.3.10.4.2 Double Align
Double align is enabled by configuring MTR_STARTUP to 01b. Single align is not reliable when the initial
position of the rotor is 180o out of phase with the applied phase pattern. In this case, it is possible to have
start-up failures using single align. In order to improve the reliabilty of align based start-up, the MCT8316A
provides the option of double align start-up. In double align start-up, MCT8316A uses a phase pattern for the
second align that is 60o out of phase with the first align phase pattern in the commanded direction. In double
align, relevant parameters like align time, current limit, ramp rate are the same as in the case of single align -
two different phase patterns are applied in succession with the same parameters to ensure that the motor will be
aligned to a known position irrespective of initial rotor position.
8.3.10.4.3 Initial Position Detection (IPD)
Initial Position Detection (IPD) can be enabled by configuring MTR_STARTUP to 10b. In IPD, inductive sense
method is used to determine the initial position of the motor using the spatial variation in the motor inductance.
Align or double align may result in the motor spinning in the reverse direction before starting open loop
acceleration. IPD can be used in such applications where reverse rotation of the motor is unacceptable. IPD
does not wait for the motor to align with the commutation and therefore can allow for a faster motor start-up
sequence. IPD works well when the inductance of the motor varies as a function of position. IPD works by
pulsing current in to the motor and hence can generate acoustics which must be taken into account when
determining the best start-up method for a particular application.
8.3.10.4.3.1 IPD Operation
IPD operates by sequentially applying six different phase patterns according to the following sequence:
BC-> CB-> AB-> BA-> CA-> AC (see Figure 8-21). When the current reaches the threshold configured by
IPD_CURR_THR, the MCT8316A stops driving the particular phase pattern and measures the time taken to
reach the current threshold from when the particular phase pattern was applied. Thus, the time taken to reach
IPD_CURR_THR is measured for all six phase patterns - this time varies as a function of the inductance in
the motor windings. The state with the shortest time represents the state with the minimum inductance. The
minimum inductance is because of the alignment of the north pole of the motor with this particular driving state.
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IPD_CLK
Clock
C
Drive
B C
C B
A B
B A
C A
A C
IPD_CURR_THR
Current
Search the Minimum Time
Minimum
Time
Smallest
Inductance
Saturation Position of
the Magnetic Field
Permanent
Magnet Position
Figure 8-21. IPD Function
8.3.10.4.3.2 IPD Release Mode
Two modes are available for configuring the way the MCT8316A stops driving the motor when the current
threshold is reached. The recirculate (or brake) mode is selected if IPD_RLS_MODE = 0b. In this configuration,
the low-side (LSC) MOSFET remains ON to allow the current to recirculate between the MOSFET (LSC) and
body diode (LSA) (see Figure 8-22). Hi-Z mode is selected if IPD_RLS_MODE = 1b. In Hi-Z mode, both the
high-side (HSA) and low-side (LSC) MOSFETs are turned OFF and the current recirculates through the body
diodes back to the power supply (see Figure 8-23).
In the Hi-Z mode, the phase current has a faster settle-down time, but that can result in a voltage increase on
VM. The user must manage this with an appropriate selection of either a clamp circuit or by providing sufficient
capacitance between VM and GND to absorb the energy. If the voltage surge cannot be contained or if it is
unacceptable for the application, recirculate mode must be used. When using the recirculate mode, select the
IPD_CLK_FREQ appropriately to give the current in the motor windings enough time to decay to to 0-A before
the next IPD phase pattern is applied.
HSB
HSC
LSC
HSA
VM
LSA
HSB
LSB
HSC
LSC
HSA
VM
LSA
M
M
LSB
Driving
Brake (Recirculate)
Figure 8-22. IPD Release Mode 0
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HSB
HSC
LSC
HSA
VM
LSA
HSB
HSC
LSC
HSA
VM
LSA
M
M
LSB
LSB
Driving
Hi-Z (Tri-State)
Figure 8-23. IPD Release Mode 1
8.3.10.4.3.3 IPD Advance Angle
After the initial position is detected, the MCT8316A begins driving the motor in open loop at an angle specified
by IPD_ADV_ANGLE.
Advancing the drive angle anywhere from 0° to 180° results in positive torque. Advancing the drive angle by
90° results in maximum initial torque. Applying maximum initial torque could result in uneven acceleration to the
rotor. Select the IPD_ADV_ANGLE to allow for smooth acceleration in the application (see Figure 8-24).
Motor spinning direction
C
B
A
B
A
B
A
A
B
C
C
C
C
30 advance
90 advance
120 advance
60 advance
Figure 8-24. IPD Advance Angle
8.3.10.4.4 Slow First Cycle Startup
Slow First Cycle start-up is enabled by configuring MTR_STARTUP to 11b. In slow first cycle start-up, the
MCT8316A starts motor commutation at a frequency defined by SLOW_FIRST_CYCLE_FREQ. The frequency
configured is used only for first cycle, and then the motor commutation follows acceleration profile configured by
open loop acceleration coefficients A1 and A2. The slow first cycle frequency has to be configured to be slow
enough to allow motor to synchronize with the commutation sequence. This mode is useful when fast startup is
desired as it significantly reduces the align time.
8.3.10.4.5 Open loop
Upon completing the motor position initialization with either align, double align, IPD or slow first cycle, the
MCT8316A begins to accelerate the motor in open loop. During open loop, fixed duty cycle is applied and the
cycle by cycle current limit functionality is used to regulate the current.
In MCT8316A, open loop current limit threshold is selected through OL_ILIMIT_CONFIG and is set either by
ILIMIT or OL_ILIMIT based on the configuration of OL_ILIMIT_CONFIG. Open loop duty cycle is configured
through OL_DUTY. While the motor is in open loop, speed (and commutation instants) is determined by
Equation 5. In MCT8316A, open loop acceleration coefficients, A1 and A2 are configured through OL_ACC_A1
and OL_ACC_A2 respectively. The function of the open-loop operation is to drive the motor to a speed at which
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the motor generates sufficient BEMF to allow the BEMF zero-crossing based commutation control to accurately
drive the motor.
Speed (t) = A1 * t + 0.5 * A2 * t2
(5)
8.3.10.4.6 Transition from Open to Closed Loop
MCT8316A has an internal mechanism to determine the motor speed for transition from open loop commutation
to BEMF zero crossing based closed loop commutation. This feature of automatically deciding the open to
closed handoff speed can be enabled by configuring AUTO_HANDOFF to 1b. If AUTO_HANDOFF is set to 0b,
the open to closed loop handoff speed needs to be configured by OPN_CL_HANDOFF_THR. The closed loop in
this section does not refer to closed speed loop - it refers to the commutation control changing from open loop
(equation based) to closed loop (BEMF zero crossing based).
8.3.11 Closed Loop Operation
In closed loop operation, the MCT8316A drives the motor using trapezoidal commutation. The commutation
instant is determined by the BEMF zero crossing on the phase which is not driven (Hi-Z). The duty cycle of the
applied motor voltage is determined by DUTY OUT (see SPEED Control).
8.3.11.1 120o Commutation
In 120o commutation, each phase is driven for 120o and is Hi-Z for 60o within each half electrical cycle as
shown in Figure 8-25. In 120o commutation there are six different commutation states. 120o commutation can
be configured by setting COMM_CONTROL to 00b. MCT8316A supports different modulation modes with 120o
commutation which can be configured through PWM_MODUL.
©
©
©
©
©
©
©
ZC
ZC
ZC
ZC
ZC
ZC
ZC
Commuta on point
©
ZC Back-EMF zero crossings
Phase
PHASE CURRENT
PHASE VOLTAGE
A
Phase
B
Phase
C
Figure 8-25. 120o commutation
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8.3.11.1.1 High-Side Modulation
High-side modulation can be configured by setting PWM_MODUL to 00b. In high-side modulation, for a given
commutation state, one of the high-side FETs is switching with the commanded duty cycle DUTY_OUT, while the
low-side FET is ON with 100% duty cycle (see Figure 8-26).
ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
Phase
Voltage A
Phase
Voltage B
Phase
Voltage C
Figure 8-26. 120o commutation in High Side Modulation Mode
8.3.11.1.2 Low-Side Modulation
Low-side modulation can be configured by setting PWM_MODUL to 01b. In low-side modulation, for a given
commutation state, one of the low-side FETs is switching with the commanded duty cycle DUTY_OUT, while the
high-side FET is ON with 100% duty cycle (see Figure 8-27).
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ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
Phase
Voltage A
Phase
Voltage B
Phase
Voltage C
Figure 8-27. 120 o commutation in Low Side Modulation Mode
8.3.11.1.3 Mixed Modulation
Mixed modulation can be configured by setting PWM_MODUL to 10b. In mixed modulation, MCT8316A
dynamically switches between high and low-side modulation (see Figure 8-28). The switching losses are
distributed evenly amongst the high and low-side MOSFETs in mixed modulation mode.
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ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
ZC
Phase
Voltage A
Phase
Voltage B
Phase
Voltage C
Figure 8-28. 120o commutation in Mixed Modulation Mode
8.3.11.2 Variable Commutation (Available only in MCT8316AV)
Variable commutation can be configured by setting COMM_CONTROL to 01b. 120o commutation may result in
acoustic noise due to the long Hi-Z period causing some torque ripple in the motor. In order to reduce this torque
ripple and acoustic noise, the MCT8316A uses variable commutation to reduce the phase current ripple at
commutation by extending 120o driving time and gradually decreasing duty cycle prior to entering Hi-Z state. In
this mode, the phase is Hi-Z between 30o and 60o and this window size is dynamically adjusted based on speed.
A smaller window size will typically give better acoustic performance. Figure 8-29 shows 150o commutation with
30o window size.
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©
©
©
©
©
©
©
ZC
ZC
ZC
ZC
ZC
ZC
ZC
Commuta on point
©
ZC Back-EMF zero crossings
Phase
A
PHASE CURRENT
PHASE VOLTAGE
15 deg
30 deg
Phase
B
15 deg
Phase
C
Figure 8-29. 150o commutation
Note
Different modulation modes are supported only with 120o commutation; variable commutation uses
mixed modulation mode only.
8.3.11.3 Lead Angle Control
To achieve the best efficiency, it is often desirable to control the drive state of the motor so that the motor
phase current is aligned with the motor BEMF voltage. MCT8316A provides the option to advance or delay the
phase voltage from the commutation point by adjusting the lead angle. The lead angle can be adjusted to obtain
optimal efficiency. This can be accomplished by operating the motor at constant speed and load conditions and
adjusting the lead angle (LD_ANGLE) until the minimum current is achieved. The MCT8316A has the capability
to apply both positive and negative lead angle (by configuring LD_ANGLE_POLARITY) as shown in Figure 8-30
Lead angle can be calculated by {LD_ANGLE x 0.12}o; for example, if the LD_ANGLE is 0x1E and
LD_ANGLE_POLARITY is 1b, then a lead angle of +3.6o(advance) is applied. If LD_ANGLE_POLARITY is
0b, then a lead angle of -3.6o(delay) is applied.
Note
For 120o commutation, the negative lead angle is limited to -20o; any lead angle lower than that will be
clamped to -20o.
For variable commutation, negative lead angle is not supported and positive lead angle is limited
to +15o. Anything configured higher than +15o or lower than 00 will be clamped to 15o and 0o
respectively.
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(a)
Phase
Voltage
Phase
BEMF
}
POS
(b)
Phase
Voltage
Phase
BEMF
}
NEG
Figure 8-30. Positive and Negative Lead Angle Definition
8.3.11.4 Closed loop accelerate
To prevent sudden changes in the torque applied to the motor which could result in acoustic noise, the
MCT8316A device provides the option of limiting the maximum rate at which the speed command can change.
The closed loop acceleration rate parameter sets the maximum rate at which the speed command changes
(shown in Figure 8-31). In the MCT8316A, closed loop acceleration rate is configured through CL_ACC.
y%
Speed command
input
x%
y%
Speed command
after closed loop
accelerate buffer
x%
Closed loop
accelerate settings
Figure 8-31. Closed loop accelerate
8.3.12 Speed Loop (Available only in MCT8316AV)
MCT8316A has a speed loop option which can be used to maintain constant speed under varying operating
conditions. Speed loop is enabled by setting CLOSED_LOOP_MODE to 01b. Kp and Ki coefficients are
configured through SPD_POWER_KP and SPD_POWER_KI. The output of speed loop (SPEED_PI_OUT) is
used to generate the DUTY OUT (see Figure 8-14). The PI controller output upper (VMAX) and lower bound
(VMIN) saturation limits are configured through SPD_POWER_V_MAX and SPD_POWER_V_MIN respectively.
When output of the speed loop saturates, the integrator is disabled to prevent integral wind-up. The speed loop
PI controller is as in Figure 8-32.
SPEED_REF is derived from duty command input and maximum motor speed (MAX_SPEED) configured by
user (see Equation 6). In speed loop mode, minimum SPEED_REF is set by MIN_DUTY * MAX_SPEED.
SPEED_REF = DUTY CMD * MAX_SPEED
(6)
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MAX_SPEED
VMAX
SPEED_REF
SPEED_PI_OUT
OUT
Kp
Ki
+
DUTY CMD
+
-
+
VMIN
SPEED_MEAS
+
+
Z-1
Switch Close
If VMIN<OUT <VMAX
Figure 8-32. Speed Loop
8.3.13 Input Power Regulation (Available only in MCT8316AV)
MCT8316A provides an option of regulating the (input) power instead of motor speed - this input power
regulation can be done in two modes, namely, closed loop power control and power limit control. Input power
regulation (instead of motor speed) mode is selected by setting CLOSED_LOOP_MODE to 10b. This should be
accompanied by setting CONST_POWER_MODE to 01b for closed loop power control or to 10b for power limit
control. In either of the power regulation modes, the maximum power that MCT8316A can draw from the DC
input supply is set by MAX_POWER - the power reference (POWER_REF in Figure 8-33) varies as function of
the duty command input (DUTY CMD) and MAX_POWER as given by Equation 7. The hysteresis band for the
power reference is set by CONST_POWER_LIMIT_HYST. In both the power regulation modes, the minimum
power reference is set by MIN_DUTY x MAX_POWER.
POWER_REF = DUTY CMD x MAX_POWER
(7)
In both the power regulation modes, MCT8316A uses the same PI controller parameters as in the speed loop
mode. Kp and Ki coefficients are configured through SPD_POWER_KP and SPD_POWER_KI. The PI controller
output upper (VMAX) and lower bound (VMIN) saturation limits are configured through SPD_POWER_V_MAX
and SPD_POWER_V_MIN respectively. The key difference between closed loop power control and power limit
control is in the when the PI controller decides the DUTY OUT (see Figure 8-14) applied to FETs. In closed
loop power control, DUTY OUT is always equal to POWER_PI_OUT from the PI controller output in Figure 8-33.
However, in power limit control, the PI controller decides the DUTY OUT only if POWER_MEAS > POWER_REF
+ CONST_POWER_LIMIT_HYST. If POWER_MEAS < POWER_REF + CONST_POWER_LIMIT_HYST, the PI
controller is not used and DUTY OUT is equal to DUTY CMD. Essentially, in closed loop power control, input
power is always actively regulated to POWER_REF whereas, in power limit control, input power is only limited
to POWER_REF and not actively regulated to POWER_REF. When output of the power PI loop saturates, the
integrator is disabled to prevent integral wind-up.
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MAX_POWER
VMAX
POWER_REF
POWER_PI_OUT
OUT
Kp
Ki
+
DUTY CMD
+
-
+
VMIN
POWER_MEAS
+
+
ESTIMATED
INPUT DC
CURRENT
Z-1
MEASURED INPUT
DC VOLTAGE
Switch Close
If VMIN<OUT <VMAX
Figure 8-33. Power Regulation
8.3.14 Anti-Voltage Surge (AVS)
When a motor is driven, energy is transferred from the power supply into the motor. Some of this energy
is stored in the form of inductive and mechanical energy. If the speed command suddenly drops such that
the BEMF voltage generated by the motor is greater than the voltage that is applied to the motor, then the
mechanical energy of the motor is returned to the power supply and the VM voltage surges. The AVS feature
works to prevent this voltage surge on VM and can be enabled by setting AVS_EN to 1b. AVS can be disabled by
setting AVS_EN to 0b. When AVS is disabled, the deceleration rate is configured through CL_DEC_CONFIG
8.3.15 Output PWM Switching Frequency
MCT8316A provides the option to configure the output PWM switching frequency of the MOSFETs through
PWM_FREQ_OUT. PWM_FREQ_OUT has range of 5-100 kHz. In order to select optimal output PWM switching
frequency, user has to make tradeoff between the current ripple and the switching losses. Generally, motors
having lower L/R ratio require higher PWM switching frequency to reduce current ripple.
8.3.16 Fast Start-up (< 50 ms)
MCT8316A has the capability to accelerate a motor from 0 to 100% speed within 50ms. This will only work
on low inertia motors which are capable of this level of acceleration. In order to achieve fast start-up, the
commutation instant detection needs to be configured to hybrid mode by setting INTEG_ZC_METHOD to 1b. In
the hybrid mode, the commutation instant is determined by using back-EMF integration at low-medium speeds
and by using built-in comparators (BEMF zero crossing) at higher speeds. MCT8316A automatically transitions
between back-EMF integration and comparator based commutation depending on the motor speed as shown
in Figure 8-34. The duty cycles for commutation method transition at lower speeds are directly configured by
INTEG_DUTY_THR_LOW and INTEG_DUTY_THR_HIGH and at higher speeds are indirectly configured by
INTEG_CYC_THR_LOW and INTEG_CYC_THR_HIGH. These duty cycles should be configured to provide a
sufficient hysteresis band to avoid repeated commutation method transitions near threshold duty cycles. The
BEMF threshold values used to determine the commutation instant in the back-EMF integration method are
configured by BEMF_THRESHOLD1 and BEMF_THRESHOLD2.
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Commutation method
Integration based
ZC based
Duty cycle
INTEG_DUTY INTEG_DUTY
_THR_LOW _THR_HIGH
Duty 1 Duty 2
Duty 1- Duty cycle at which motor speed is such that number
of BEMF samples per 30o is > INTEG_CYCL_THR_HIGH
Duty 2 - Duty cycle at which motor speed is such that number
of BEMF samples per 30o is < INTEG_CYCL_THR_LOW
Figure 8-34. Commutation Method Transition
8.3.16.1 BEMF Threshold
Figure 8-35 shows the three-phase voltages during 120o trapezoidal operation. It is seen that one of the phases
will always be floating within a 60o commuation interval and MCT8316A integrates this floating phase voltage
(which denotes the motor back-EMF) in the back-EMF integration method to detect the next commutation
instant. The floating phase voltage can either be increasing or decreasing and the algorithm starts the integration
after the zero cross detection in order to eliminate integration errors due to variable degauss time. The
floating phase voltage is periodically sampled (after zero cross) and added (discrete form of integration).
BEMF threshold (BEMF_THRESHOLD1 and BEMF_THRESHOLD2) value is set such that the integral value
of the floating phase voltage crosses the BEMF_THRESHOLD1 or BEMF_THRESHOLD2 value at (or very
near) to the commutation instant. BEMF_THRESHOLD1 is the threshold for rising floating phase voltage and
BEMF_THRESHOLD2 is the threshold for falling floating phase voltage. If BEMF_THRESHOLD2 is set to 0,
then BEMF_THRESHOLD1 is used as the threshold for both rising and falling floating phase voltage.
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Vpeak
Vpeak
2
Tc
Vpeak
Vpeak
2
Vpeak
Vpeak
2
0o
60o
300o
180o
240o
360o
120o
Electrical Angle, θ (degree)
Figure 8-35. Back-EMF integration using floating phase voltage
In Figure 8-35 , Vpeak is the peak-peak value of the back-EMF , Vpeak/2 denotes the zero cross of the
back-EMF and Tc is the commutation interval or time period of the 60o window. The highlighted triangle in each
60o window is the integral value of back-EMF used by the algorithm to determine the commutation instant. This
integral value, which can be approximated as the area of the highlighted triangle, is given by Equation 8.
(½)* (Vpeak/2) * Tc/2
(8)
See for an example application on setting the BEMF threshold.
8.3.16.2 Dynamic Degauss
In MCT8316A, the degauss time can be dynamically computed after the commutation for a precise detection of
the zero crossing instant. This is done by enabling the dynamic degauss feature (DYN_DEGAUSS_EN is set
to 1b). This feature allows the motor control algorithm to capture the zero crossing instant after the outgoing
(floating) phase voltage is completely settled; that is, when the outgoing phase current has decayed to zero
and the outgoing (floating) phase voltage is not clamped (to either VM or PGND) and represents the true
back-EMF. This accurate measurement of zero cross instant allows fast acceleration of the motors (< 50ms)
using MCT8316A.
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VM
*
*
VM
2
*
*
PGND
Degauss time(shown by double-sided arrow) after commutation during which the outgoing(floating) phase
voltage is clamped to VM(by negative outgoing phase current) during increasing back-EMF; sampling of
back-EMF(denoted by *) should start after degauss time is over for accurate zero cross instant detection
VM
VM
2
*
*
*
*
PGND
Degauss time(shown by double-sided arrow) after commutation during which the outgoing(floating) phase
voltage is clamped to PGND(by positive outgoing phase current) during decreasing back-EMF; sampling of
back-EMF(denoted by *) should start after degauss time is over for accurate zero cross instant detection
Figure 8-36. Degauss Time
8.3.17 Fast Deceleration
MCT8316A has the capability to decelerate a motor quickly (100% to 10% speed reduction within tens of ms)
without pumping energy back into the input DC supply using the fast deceleration feature in conjunction with
the AVS feature. The fast deceleration feature can be enabled by setting FAST_DECEL_EN to 1b; AVS_EN
should be set to 1b to prevent energy pump-back into the input DC supply. This combination enables a linear
braking effect resulting in a fast and smooth speed reduction without energy pump-back into the DC input supply.
This feature combination can also be used during reverse drive (see Reverse Drive) or motor stop (see Active
Spin-Down) to reduce the motor speed quickly without energy pump-back into the DC input supply.
The deceleration time can be controlled by appropriately configuring the current limit during deceleration,
FAST_DECEL_CURR_LIM. A higher current limit results in a lower deceleration time and vice-versa. A
higher than necessary current limit setting may result in motor stall faults, at low target speeds, due to
excessive braking torque. This can also lead to higher losses in MCT8316A, especially in repeated acceleration-
deceleration cycles. Therefore, the FAST_DECEL_CURR_LIM should be chosen appropriately, so as to
decelerate within the required time without resulting in stall faults or overheating.
FAST_BRK_DELTA is used to configure the target speed hysteresis band to exit the fast deceleration mode and
re-enter motoring mode when motor reaches the target speed. For example, if FAST_BRK_DELTA is set to 1%,
the fast deceleration is deemed complete when motor speed reaches within 1% of target speed. Setting a higher
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value for FAST_BRK_DELTA may eliminate motor stall faults, especially when high FAST_DECEL_CURR_LIM
values are used. Setting a higher value for FAST_BRK_DETLA will also result in higher speed error between
target speed and motor speed at the end of deceleration mode - motor will eventually reach the target speed
once motoring mode is resumed. FAST_DECEL_CURR_LIM and FAST_BRK_DELTA should be configured in
tandem to optimize between lower deceleration time and reliable (no stall faults) deceleration profile.
FAST_DEC_DUTY_THR configures the speed below which fast deceleration will be implemented. For example,
if FAST_DEC_DUTY_THR is set to 70%, any deceleration from speeds above 70% will not use fast
deceleration until the speed goes below 70%. FAST_DEC_DUTY_WIN is used to set the minimum deceleration
window (initial speed - target speed) below which fast deceleration will not be implemented. For example, if
FAST_DEC_DUTY_WIN is set to 15% and 50%->40% deceleration command is received, fast deceleration
is not used to reduce the speed from 50% to 40% since the deceleration window (10%) is smaller than
FAST_DEC_DUTY_WIN.
MCT8316A provides a dynamic current limit option during fast deceleration to improve the stability of fast
deceleration when braking to very low speeds; using this feature the current limit during fast deceleration can
be reduced as the motor speed decreases. This feature can be enabled by setting DYNAMIC_BRK_CURR
to 1b. The current limit at the start of fast deceleration (at FAST_DEC_DUTY_THR) is configured by
FAST_DECEL_CURR_LIM and the current limit at zero speed is configured by DYN_BRK_CURR_LOW_LIM;
the current limit during fast deceleration varies linearly with speed between these two operating points when
dynamic current limit is enabled. If dynamic current limit is disabled, current limit during fast deceleration stays
constant and is configured by FAST_DECEL_CURR_LIM.
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8.3.18 Active Demagnetization
MCT8316A has smart rectification features (active demagnetization) which decreases power losses in the device
by reducing diode conduction losses. When this feature is enabled, the device automatically turns ON the
corresponding MOSFET whenever it detects diode conduction. This feature can be enabled by configuring
EN_ASR.
Note
EN_ASR needs to be set to 1b to enable active demagnetization.
The MCT8316A device includes a high-side (AD_HS) and low-side (AD_LS) comparator which detects the
negative flow of current in the device on each half-bridge. The AD_HS comparator compares the sense-FET
output with the supply voltage (VM) threshold, whereas the AD_LS compatator compares with the ground
(0-V) threshold. Depending upon the flow of current from OUTx to VM or PGND to OUTx, the AD_HS or
the AD_LS comparator trips. These comparator outputs provide a reference point for the operation of active
demagnetization feature.
VM
AD_HS
Comparator
+
-
Sense
FET
(To Digital)
(To Digital)
OUTX
VM
+
-
Sense
FET
AD_LS
Comparator
0V (GND)
PGND
VREF
I/V Converter
SOX
GAIN
Figure 8-37. Active Demagnetization Operation
8.3.18.1 Active Demagnetization in action
Figure 8-38 shows the operation of active demagnetization during the BLDC motor commutation. As shown in
Figure 8-38 (a), the current is flowing from HA to LC in one commutation state. During the commutation change
over as shown in Figure 8-38 (b), the HB FET is turned ON (and HA FET is turned OFF), and the commutation
current (due to motor inductance) in OUTA flows through the body diode of LA. This results in a higher diode
loss depending on the commutation current. This commutation loss is reduced by turning on the LA FET for the
commutation time as shown in Figure 8-38 (c).
Similarly, the active demagnetization operation of a high-side FET is realized in Figure 8-38 (d), (e) and (f).
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VM
VM
HB
HC
HA
HB
HC
HA
OUTA
LB
OUTA
OUTB
OUTB
OUTC
OUTC
OUTC
OUTC
OUTC
OUTC
LA
LC
LA
LB
LC
(a) Current flowing from HA to LC
VM
(d) Current flowing from HC to LA
VM
Decay Current
Decay Current
HB
HC
HB
OUTA
LB
HC
HA
HA
OUTA
OUTB
OUTB
LA
LB
LC
LA
LC
(e) Decay current with AD disabled
VM
(b) Decay current with AD disabled
VM
Decay Current
Decay Current
HB
HC
HB
OUTA
LB
HC
HA
HA
OUTA
OUTB
OUTB
LA
LB
LC
LA
LC
(c) Decay current with AD enabled
(f) Decay current with AD enabled
Figure 8-38. Active Demagnetization in BLDC Motor Commutation
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Figure 8-39 (a) shows the BLDC motor phase current waveforms with Active Demagnetization with trapezoidal
commutation. This figure shows the operation of various switches in a single commutation cycle.
Figure 8-39 (b) shows the zoomed waveform of commutation cycle.
Current Limit
Phase ”A‘
Current
LA
HA
HA, LB
HB, LC
HB, LA
HC, LA
HC, LB
HA, LC
(a) Commutation current of Phase —A“
tmargin
tdead
HA Conducts
LA Body Diode
Conducts
HA Body Diode
Conducts
Phase ”A‘
Current
LA Conducts
tdead
HC, LA
HC, LB
HA, LC
HB, LC
(b) Zoomed waveform of Active Demagnetization
Figure 8-39. Current Waveforms with Active Demagnetization
8.3.19 Motor Stop Options
The MCT8316A provides different options for stopping the motor which can be configured by MTR_STOP.
8.3.19.1 Coast (Hi-Z) Mode
Coast (Hi-Z) mode is configured by setting MTR_STOP to 000b. When motor stop command is received, the
MCT8316A will transition into a high impedance (Hi-Z) state by turning off all MOSFETs. When the MCT8316A
transitions from driving the motor into a Hi-Z state, the inductive current in the motor windings continues to flow
and the energy returns to the power supply through the body diodes in the MOSFET output stage (see example
Figure 8-40).
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HSC
LSC
HSA
LSA
HSB
HSC
LSC
HSA
LSA
HSB
LSB
VM
M
VM
M
LSB
Driving State
High-Impedance State
Figure 8-40. Coast (Hi-Z) Mode
In this example, current is applied to the motor through the high-side phase-A MOSFET (HSA) and returned
through the low-side phase-C MOSFET (LSC). When motor stop command is received all 6 MOSFETs transition
to Hi-Z state and the inductive energy returns to supply through body diodes of MOSFETs LSA and HSC.
8.3.19.2 Recirculation Mode
Recirculation mode is configured by setting MTR_STOP to 001b. In order to prevent the inductive energy from
returning to DC input supply during motor stop, the MCT8316A allows current to circulate within the MOSFETs
by selectively turning OFF some of the active (ON) MOSFETs for a certain time (auto calculated recirculation
time to allow the inductive current to decay to zero) before transitioning into Hi-Z by turning OFF the remaining
MOSFETs.
If high-side modulation was active, prior to motor stop command, then the high-side MOSFET is turned OFF
on receiving motor stop command and the current recirculation takes place through low-side MOSFET (see
example Figure 8-41). Once the recirculation time lapses, the low-side MOSFET also turns OFF and all
MOSFETs are in Hi-Z state.
HSB
HSC
LSC
HSA
LSA
HSB
LSB
HSC
LSC
HSA
LSA
VM
M
VM
M
LSB
Low-Side Recirculaꢀon Mode
Driving State
Figure 8-41. Low-Side Recirculation
If low-side modulation was active, prior to motor stop command, then the low-side MOSFET is turned OFF
on receiving motor stop command and the current recirculation takes place through high-side MOSFET (see
example Figure 8-42). Once the recirculation time lapses, the high-side MOSFET also turns OFF and all
MOSFETs are in Hi-Z state
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HSB
HSC
HSA
LSA
HSB
LSB
HSC
LSC
HSA
LSA
VM
M
VM
M
LSB
LSC
High-Side Recircula on Mode
Driving State
Figure 8-42. High-Side Recirculation
8.3.19.3 Low-Side Braking
Low-side braking mode is configured by setting MTR_STOP to 010b. When a motor stop command is received,
the output speed is reduced to a value defined by ACT_SPIN_BRK_THR prior to turning all low-side MOSFETs
ON (see example Figure 8-43) for a time configured by MTR_STOP_BRK_TIME. If the motor speed is below
ACT_SPIN_BRK_THR prior to receiving stop command, then the MCT8316A transitions directly into the brake
state. After applying the brake for MTR_STOP_BRK_TIME, the MCT8316A transitions into the Hi-Z state by
turning OFF all MOSFETs.
HSC
LSC
HSA
LSA
HSB
HSC
LSC
HSA
LSA
HSB
LSB
VM
M
VM
M
LSB
Low-Side Braking
Driving State
Figure 8-43. Low-Side Braking
The MCT8316A can also enter low-side braking through BRAKE pin input. When BRAKE pin is pulled to
HIGH state, the output speed is reduced to a value defined by BRAKE_DUTY_THRESHOLD prior to turning all
low-side MOSFETs ON. In this case, MCT8316A stays in low-side brake state till BRAKE pin changes to LOW
state.
8.3.19.4 High-Side Braking
High-side braking mode is configured by setting MTR_STOP to 011b. When a motor stop command is received,
the output speed is reduced to a value defined by ACT_SPIN_BRK_THR prior to turning all high-side MOSFETs
ON (see example Figure 8-44) for a time configured by MTR_STOP_BRK_TIME. If the motor speed is below
ACT_SPIN_BRK_THR prior to receiving stop command, then the MCT8316A transitions directly into the brake
state. After applying the brake for MTR_STOP_BRK_TIME, the MCT8316A transitions into Hi-Z state by turning
OFF all MOSFETs.
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HSC
LSC
HSC
HSA
LSA
HSB
HSA
LSA
HSB
LSB
VM
M
VM
M
LSB
LSC
High-Side Braking
Driving State
Figure 8-44. High-Side Braking
8.3.19.5 Active Spin-Down
Active spin down mode is configured by setting MTR_STOP to 100b. When motor stop command is received,
MCT8316A reduces duty cycle to ACT_SPIN_BRK_THR and then transitions to Hi-Z state by turning all
MOSFETs OFF. The advantage of this mode is that by reducing duty cycle, the motor is decelerated to a
lower speed thereby reducing the phase currents before entering Hi-Z. Now, when motor transitions into Hi-Z
state, the energy transfer to power supply is reduced. The threshold ACT_SPIN_BRK_THR needs to configured
high enough for MCT8316A to not lose synchronization with the motor.
8.3.20 FG Configuration
The MCT8316A provides information about the motor speed through the Frequency Generate (FG) pin. In
MCT8316A, the FG pin output is configured through FG_CONFIG. When FG_CONFIG is configured to 1b, the
FG output is active as long as the MCT8316A is driving the motor. When FG_CONFIG is configured to 0b, the
MCT8316A provides an FG output until the motor back-EMF falls below FG_BEMF_THR.
8.3.20.1 FG Output Frequency
The FG output frequency can be configured by FG_DIV_FACTOR. In MCT8316, FG toggles once every
commutation cycle if FG_DIV_FACTOR is set to 0000b. Many applications require the FG output to provide
a pulse for every mechanical rotation of the motor. Different FG_DIV_FACTOR configurations can accomplish
this for 2-pole up to 30-pole motors.
Figure 8-45 shows the FG output when MCT8316A has been configured to provide FG pulses once every
commutation cycle (electrical cycle/3), once every electrical cycle (2 poles), once every two electrical cycle (4
poles), once every three electrical cycles (6 poles), once every four electrical cycles (8 poles), and so on.
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Phase A
Voltage
FG_DIV_FACTOR = 0000b
(Commuta on cycle)
FG_DIV_FACTOR = 0001b
(Elec cycle)
FG_DIV_FACTOR = 0010b
(Elec cycle*2)
FG_DIV_FACTOR = 0011b
(Elec cycle*3)
FG_DIV_FACTOR = 0100b
(Elec cycle*4)
Figure 8-45. FG Frequency Divider
8.3.20.2 FG Open-Loop and Lock Behavior
During closed loop operation, the driving speed (FG output frequency) and the actual motor speed are
synchronized. During open-loop operation, however, FG may not reflect the actual motor speed. During motor-
lock condition, the FG output is driven high.
The MCT8316A provides three options for controlling the FG output during open loop, as shown in Figure 8-46.
The selection of these options is configured through FG_SEL.
If FG_SEL is set to,
•
•
•
00b: When in open loop, the FG output is based on the driving frequency.
01b: When in open loop, the FG output will be driven high.
10b: The FG output will reflect the driving frequency during open loop operation in the first motor start-up
cycle after power-on, sleep/standby; FG will be held high during open loop operation in subsequent start-up
cycles.
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Open Loop
Close Loop
Phase A
Voltage
FG_SEL = 00
FG_SEL = 01
Close Loop
Open Loop
Open Loop
Close Loop
Phase A
Voltage
FG_SEL
= 10
Startup after power on or wake up from
sleep or standby mode
Rest of startups
Figure 8-46. FG Behavior During Open Loop
8.3.21 Protections
The MCT8316A is protected from a host of fault events including motor lock, VM undervoltage, AVDD
undervoltage, buck undervoltage, charge pump undervoltage, overtemperature and overcurrent events. Table
8-18 summarizes the response, recovery modes, power stage status, reporting mechanism for different faults.
Table 8-18. Fault Action and Response
FAULT
CONDITION
CONFIGURATION
REPORT
H-BRIDGE
LOGIC
RECOVERY
VM undervoltage
(NPOR)
Automatic:
VVM > VUVLO
VVM < VUVLO
—
—
Hi-Z
Disabled
AVDD undervoltage
(NPOR)
Automatic:
VAVDD > VAVDD_UV
VAVDD < VAVDD_UV
—
—
—
—
Hi-Z
Hi-Z
Disabled
Disabled
Buck undervoltage
(BUCK_UV)
Automatic:
VFB_BK > VBK_UV
VFB_BK < VBK_UV
nFAULT and
GATE_DRIVER_FA
ULT_STATUS
register
Charge pump
undervoltage
(VCP_UV)
Automatic:
VVCP > VCPUV
VCP < VCPUV
—
Hi-Z
Active
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Table 8-18. Fault Action and Response (continued)
FAULT
CONDITION
CONFIGURATION
REPORT
H-BRIDGE
LOGIC
RECOVERY
OVP_EN = 0b
None
Active
Active
No action (OVP Disabled)
OverVoltage
Protection
(OVP)
nFAULT and
GATE_DRIVER_FA
ULT_STATUS
register
VVM > VOVP
Automatic:
VVM < VOVP
OVP_EN = 1b
OCP_MODE = 00b
OCP_MODE = 01b
Hi-Z
Hi-Z
Hi-Z
Active
Active
Active
nFAULT and
GATE_DRIVER_FA
ULT_STATUS
register
Latched:
CLR_FLT
nFAULT and
GATE_DRIVER_FA
ULT_STATUS
register
Overcurrent
Protection
(OCP)
Retry:
tRETRY
IPHASE > IOCP
GATE_DRIVER_FA
ULT_STATUS
register
OCP_MODE = 10b
OCP_MODE = 11b
—
Active
Active
Hi-Z
Active
Active
No action
No action
None
Buck Overcurrent
Protection
Retry:
tRETRY
IBK > IBK_OCP
—
Disabled
(BUCK_OCP)
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
0000b
Latched:
CLR_FLT
Hi-Z
Active
Active
Active
Active
Active
Active
Active
Active
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
0001b
Latched:
CLR_FLT
Recirculation
High side brake
Low side brake
Hi-Z
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
0010b
Latched:
CLR_FLT
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
0011b
Latched:
CLR_FLT
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
0100b
Retry:
tLCK_RETRY
Motor lock: Abnormal
Speed; No Motor Lock;
Loss of Sync
Motor Lock
(MTR_LCK )
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
0101b
Retry:
tLCK_RETRY
Recirculation
High side brake
Low side brake
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
0110b
Retry:
tLCK_RETRY
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
0111b
Retry:
tLCK_RETRY
CONTROLLER_FA
ULT_STATUS
register
MTR_LCK_MODE =
1000b
Active
Active
Active
Active
No action
No action
MTR_LCK_MODE =
1xx1b
None
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Table 8-18. Fault Action and Response (continued)
FAULT
CONDITION
CONFIGURATION
REPORT
H-BRIDGE
LOGIC
RECOVERY
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
CBC_ILIMIT_MODE =
0000b
Automatic:
Next PWM cycle
Recirculation
Active
CBC_ILIMIT_MODE =
0001b
Automatic:
Next PWM cycle
None
Recirculation
Recirculation
Recirculation
Recirculation
Active
Active
Active
Active
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
CBC_ILIMIT_MODE =
0010b
Automatic:
VSOX < ILIMIT
CBC_ILIMIT_MODE =
0011b
Automatic:
VSOX < ILIMIT
Cycle by Cycle
Current Limit
(CBC_ILIMIT)
None
VSOX > CBC_ILIMIT
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
CBC_ILIMIT_MODE =
0100b
Automatic:
PWM cycle > CBC_RETRY_PWM_CYC
CBC_ILIMIT_MODE =
0101b
Automatic:
PWM cycle > CBC_RETRY_PWM_CYC
None
Recirculation
Active
Active
Active
Active
CONTROLLER_FA
ULT_STATUS
register
CBC_ILIMIT_MODE=
0110b
No action
No action
CBC_ILIMIT_MODE =
0111b, 1xxxb
None
Active
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE =
0000b
Latched:
CLR_FLT
Hi-Z
Active
Active
Active
Active
Active
Active
Active
Active
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE =
0001b
Latched:
CLR_FLT
Recirculation
High-side brake
Low-side brake
Hi-Z
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE =
0010b
Latched:
CLR_FLT
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE =
0011b
Latched:
CLR_FLT
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE =
0100b
Retry:
tLCK_RETRY
Lock-Detection
Current Limit
VSOX > LOCK_ILIMIT
(LOCK_ILIMIT)
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE =
0101b
Retry:
tLCK_RETRY
Recirculation
High-side brake
Low-side brake
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE =
0110b
Retry:
tLCK_RETRY
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE =
0111b
Retry:
tLCK_RETRY
CONTROLLER_FA
ULT_STATUS
register
LOCK_ILIMIT_MODE=
1000b
Active
Active
Active
Active
No action
No action
LOCK_ILIMIT_MODE =
1xx1b
None
IPD Timeout Fault
(IPD_T1_FAULT
and
IPD TIME > 500ms
(approx), during IPD
current ramp up or ramp
down
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
Latched:
CLR_FLT
—
Hi-Z
Active
IPD_T2_FAULT)
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
IP Frequency Fault
(IPD_FREQ_FAULT current decay in previous
IPD pulse before the
Latched:
CLR_FLT
—
Hi-Z
Active
Active
Active
)
IPD
OTW_REP = 0b
OTW_REP = 1b
None
Active
Active
No action
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
Thermal warning
(OTW)
Automatic:
TJ < TOTW – TOTW_HYS
CLR_FLT
TJ > TOTW
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Table 8-18. Fault Action and Response (continued)
FAULT
CONDITION
CONFIGURATION
REPORT
H-BRIDGE
LOGIC
RECOVERY
nFAULT and
CONTROLLER_FA
ULT_STATUS
register
Automatic:
TJ < TTSD – TTSD_HYS
CLR_FLT
Thermal shutdown
(TSD)
TJ > TTSD
—
Hi-Z
Active
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8.3.21.1 VM Supply Undervoltage Lockout
If at any time the input supply voltage on the VM pin falls lower than the VUVLO threshold (VM UVLO falling
threshold), all the integrated FETs, driver charge-pump and digital logic are disabled as shown in Figure 8-47.
MCT8316A goes into reset state whenever VM UVLO event occurs.
VUVLO (max) rising
VUVLO (min) rising
VUVLO (max) falling
VUVLO (min) falling
VVM
DEVICE ON
DEVICE OFF
DEVICE ON
Time
Figure 8-47. VM Supply Undervoltage Lockout
8.3.21.2 AVDD Undervoltage Lockout (AVDD_UV)
If at any time the voltage on the AVDD pin falls lower than the VAVDD_UV threshold, all the integrated FETs, driver
charge-pump and digital logic controller are disabled. Since internal circuitry in MCT8316A is powered through
the AVDD regulator, MCT8316A goes into reset state whenever AVDD UV event occurs.
8.3.21.3 BUCK Undervoltage Lockout (BUCK_UV)
If at any time the input supply voltage on the FB_BK pin falls lower than the VBK_UVLO threshold, both the
high-side and low-side MOSFETs of the buck regulator are disabled . Since internal circuitry in MCT8316A is
powered through the buck regulator,MCT8316A goes into reset state whenever buck UV event occurs.
8.3.21.4 VCP Charge Pump Undervoltage Lockout (CPUV)
If at any time the voltage on the VCP pin (charge pump) falls lower than the VCPUV threshold, all the integrated
FETs are disabled and the nFAULT pin is driven low. The DRIVER_FAULT and VCP_UV bits are set to 1b in
the status registers. Normal operation resumes (driver operation and the nFAULT pin is released) when the VCP
undervoltage condition clears. The VCP_UV bit stays set until cleared through the CLR_FLT bit.
8.3.21.5 Overvoltage Protection (OVP)
If at any time input supply voltage on the VM pins rises higher lower than the VOVP threshold voltage, all the
integrated FETs are disabled and the nFAULT pin is driven low. The DRIVER_FAULT and OVP bits are set to
1b in the status registers. Normal operation resumes (driver operation and the nFAULT pin is released) when the
OVP condition clears. The OVP bit stays set until cleared through the CLR_FLT bit. Setting the OVP_EN to 1b
enables this protection feature.
The OVP threshold can be set to 20-V or 32-V based on the OVP_SEL bit.
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VVM
VOVP (max) rising
VOVP (min) rising
VOVP (max) falling
VOVP (min) falling
DEVICE ON
DEVICE OFF
DEVICE ON
nFAULT
Time
Figure 8-48. Over Voltage Protection
8.3.21.6 Overcurrent Protection (OCP)
MOSFET overcurrent event is sensed by monitoring the current flowing through FETs. If the current across a
FET exceeds the IOCP threshold for longer than the tOCP deglitch time, an OCP event is recognized and action
is taken according to the OCP_MODE bit. The IOCP threshold is set through the OCP_LVL, the tOCP_DEG is set
through the OCP_DEG and the OCP_MODE bit can operate in four different modes: OCP latched shutdown,
OCP automatic retry, OCP report only and OCP disabled.
8.3.21.6.1 OCP Latched Shutdown (OCP_MODE = 00b)
When an OCP event happens in this mode, all MOSFETs are disabled and the nFAULT pin is driven low. The
DRIVER_FAULT, OCP and corresponding FET's OCP bits are set to 1b in the status registers. Normal operation
resumes (driver operation and the nFAULT pin is released) when the OCP condition clears and a clear fault
command is issued through the CLR_FLT bit.
Peak Current due
to deglitch time
IOCP
IOUTx
tOCP
nFAULT Released
nFAULT Pulled High
Fault Condition
nFAULT
Clear Fault
Time
Figure 8-49. Overcurrent Protection - Latched Shutdown Mode
8.3.21.6.2 OCP Automatic Retry (OCP_MODE = 01b)
When an OCP event happens in this mode, all the FETs are disabled and the nFAULT pin is driven low.
The DRIVER_FAULT, OCP and corresponding FET's OCP bits are set to 1b in the fault status registers.
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Normal operation resumes automatically (gate driver operation and the nFAULT pin is released) after the tRETRY
(OCP_RETRY) time elapses.The DRIVER_FAULT, OCP and corresponding FET's OCP bits are set to 1b until
cleared through the CLR_FLT bit.
Peak Current due
to deglitch time
IOCP
IOUTx
tRETRY
tOCP
nFAULT Released
nFAULT Pulled High
Fault Condition
nFAULT
Time
Figure 8-50. Overcurrent Protection - Automatic Retry Mode
8.3.21.6.3 OCP Report Only (OCP_MODE = 10b)
No protective action is taken when an OCP event happens in this mode. The overcurrent event is reported
by setting the DRIVER_FAULT, OCP, and corresponding FET's OCP bits to 1b in the fault status registers.
The device continues to operate as usual. The external controller manages the overcurrent condition by acting
appropriately. The reporting clears when the OCP condition clears and a clear fault command is issued through
the CLR_FLT bit.
8.3.21.6.4 OCP Disabled (OCP_MODE = 11b)
No action is taken when an OCP event happens in this mode.
8.3.21.7 Buck Overcurrent Protection
The buck overcurrent event is sensed by monitoring the current flowing through high-side MOSFET of the buck
regulator. If the current through the high-side MOSFET exceeds the IBK_OCP threshold for a time longer than the
deglitch time (tOCP_DEG), a buck OCP event is recognized. MCT8316A goes into reset state whenever buck OCP
event occurs, since the internal circuitry in MCT8316A is powered from the buck regulator output.
8.3.21.8 Cycle-by-Cycle (CBC) Current Limit (CBC_ILIMIT)
Cycle-by-cycle (CBC) current limit provides a means of controlling the amount of current delivered to the
motor. This is useful when the system must limit the amount of current pulled from the power supply during
motor operation. The CBC current limit limits the current applied to the motor from exceeding the configured
threshold. CBC current limit functionality is achieved by connecting the output of current sense amplifier VSOX to
a hardware comparator. If the voltage at output of current sense amplifier exceeds the CBC_ILIMIT threshold,
a CBC_ILIMIT event is recognized and action is taken according to CBC_ILIMIT_MODE. Total delay in reaction
to this event is dependent on the current sense amplifier gain and the comparator delay. CBC current limit in
closed loop is set through CBC_ILIMIT while configuration of OL_ILIMIT_CONFIG sets the CBC current limit in
open loop operation. Different modes can be configured through CBC_ILIMIT_MODE: CBC_ILIMIT automatic
recovery next PWM cycle, CBC_ILIMIT automatic recovery threshold based, CBC_ILIMIT automatic recovery
number of PWM cycles based, CBC_ILIMIT report only, CBC_ILIMIT disabled.
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8.3.21.8.1 CBC_ILIMIT Automatic Recovery next PWM Cycle (CBC_ILIMIT_MODE = 000xb)
When a CBC_ILIMIT event happens in this mode, MCT8316A stops driving the FETs using recirculation mode
to prevent the inductive energy from entering the DC input supply. The CBC_ILIMIT bit is set to 1b in the fault
status registers. Normal operation resumes at the start of next PWM cycle and CBC_ILIMIT bit is reset to 0b.
The status of CONTROLLER_FAULT bit and nFAULT pin will be determined by CBC_ILIMIT_MODE. When
CBC_ILIMIT_MODE is 0000b, CONTROLLER_FAULT bit is set to 1b and nFAULT pin driven low until next PWM
cycle. When CBC_ILIMIT_MODE is 0001b, CONTROLLER_FAULT bit is not set to 1b and nFAULT is not driven
low.
8.3.21.8.2 CBC_ILIMIT Automatic Recovery Threshold Based (CBC_ILIMIT_MODE = 001xb)
When a CBC_ILIMIT event happens in this mode, MCT8316A stops driving the FETs using recirculation mode
to prevent the inductive energy from entering the DC input supply. The CBC_ILIMIT bit is set to 1b in the status
registers. Normal operation resumes after VSOX falls below CBC_ILIMIT threshold and CBC_ILIMIT bit is set to
0b. The status of CONTROLLER_FAULT bit and nFAULT pin will be determined by CBC_ILIMIT_MODE. When
CBC_ILIMIT_MODE is 0010b, CONTROLLER_FAULT bit is set to 1b and nFAULT pin driven low until VSOX falls
below CBC_ILIMIT threshold. When CBC_ILIMIT_MODE is 0011b, CONTROLLER_FAULT bit is not set to 1b
and nFAULT is not driven low.
8.3.21.8.3 CBC_ILIMIT Automatic Recovery after 'n' PWM Cycles (CBC_ILIMIT_MODE = 010xb)
When a CBC_ILIMIT event happens in this mode, MCT8316A stops driving the FETs using recirculation
mode to prevent the inductive energy from entering the DC input supply. The CBC_ILIMIT bit is set to 1b
in the fault status registers. Normal operation resumes after (CBC_RETRY_PWM_CYC +1) PWM cycles and
CBC_ILIMIT bit is set to 0b. The status of CONTROLLER_FAULT bit and nFAULT pin will be determined by
CBC_ILIMIT_MODE. When CBC_ILIMIT_MODE is 0100b, CONTROLLER_FAULT bit is set to1b and nFAULT
pin driven low until (CBC_RETRY_PWM_CYC +1) PWM cycles lapse. When CBC_ILIMIT_MODE is 0101b,
CONTROLLER_FAULT bit is not set to 1b and nFAULT is not driven low.
8.3.21.8.4 CBC_ILIMIT Report Only (CBC_ILIMIT_MODE = 0110b)
No protective action is taken when a CBC_ILIMIT event happens in this mode. The CBC current limit event is
reported by setting the CONTROLLER_FAULT and CBC_ILIMIT bits to 1b in the fault status registers. The gate
drivers continue to operate. The external controller manages the overcurrent condition by acting appropriately.
The reporting clears when the CBC_ILIMIT condition clears and a clear fault command is issued through the
CLR_FLT bit.
8.3.21.8.5 CBC_ILIMIT Disabled (CBC_ILIMIT_MODE = 0111b or 1xxxb)
No action is taken when a CBC_ILIMIT event happens in this mode.
8.3.21.9 Lock Detection Current Limit (LOCK_ILIMIT)
The lock detection current limit function provides a configurable threshold for limiting the current to prevent
damage to the system. The MCT8316A continuously monitors the output of the current sense amplifier (CSA)
through the ADC. If at any time, the voltage on the output of CSA exceeds LOCK_ILIMIT for a time longer
than tLCK_ILIMIT, a LOCK_ILIMIT event is recognized and action is taken according to LOCK_ILIMIT_MODE. The
threshold is set through LOCK_ILIMIT, the tLCK_ILIMIT is set through LOCK_ILIMIT_DEG. LOCK_ILIMIT_MODE
can be set to four different modes: LOCK_ILIMIT latched shutdown, LOCK_ILIMIT automatic retry, LOCK_ILIMIT
report only and LOCK_ILIMIT disabled.
8.3.21.9.1 LOCK_ILIMIT Latched Shutdown (LOCK_ILIMIT_MODE = 00xxb)
When a LOCK_ILIMIT event happens in this mode, the status of MOSFETs will be configured by
LOCK_ILIMIT_MODE and nFAULT is driven low. Status of MOSFETs during LOCK_ILIMIT:
•
•
LOCK_ILIMIT_MODE = 0000b: All MOSFETs are turned OFF.
LOCK_ILIMIT_MODE = 0001b: MOSFET which was switching is turned OFF while the one which was
conducting stays ON till inductive energy is completely recirculated.
•
•
LOCK_ILIMIT_MODE = 0010b: All high-side MOSFETs are turned ON.
LOCK_ILIMIT_MODE = 0011b: All low-side MOSFETs are turned ON.
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The CONTROLLER_FAULT and LOCK_ILIMIT bits are set to 1b in the fault status registers. Normal operation
resumes (gate driver operation and the nFAULT pin is released) when the LOCK_ILIMIT condition clears and a
clear fault command is issued through the CLR_FLT bit.
8.3.21.9.2 LOCK_ILIMIT Automatic Recovery (LOCK_ILIMIT_MODE = 01xxb)
When a LOCK_ILIMIT event happens in this mode, the status of MOSFETs will be configured by
LOCK_ILIMIT_MODE and nFAULT is driven low. Status of MOSFETs during LOCK_ILIMIT:
•
•
LOCK_ILIMIT_MODE = 0100b: All MOSFETs are turned OFF.
LOCK_ILIMIT_MODE = 0101b: MOSFET which was switching is turned OFF while the one which was
conducting stays ON till inductive energy is completely recirculated.
LOCK_ILIMIT_MODE = 0110b: All high-side MOSFETs are turned ON
LOCK_ILIMIT_MODE = 0111b: All low-side MOSFETs are turned ON
•
•
The CONTROLLER_FAULT and LOCK_ILIMIT bits are set to 1b in the fault status registers. Normal operation
resumes automatically (gate driver operation and the nFAULT pin is released) after the tLCK_RETRY (configured
by LCK_RETRY) time lapses. The CONTROLLER_FAULT and LOCK_ILIMIT bits are reset to 0b after the
tLCK_RETRY period expires.
8.3.21.9.3 LOCK_ILIMIT Report Only (LOCK_ILIMIT_MODE = 1000b)
No protective action is taken when a LOCK_ILIMIT event happens in this mode. The lock detection current limit
event is reported by setting the CONTROLLER_FAULT and LOCK_ILIMIT bits to 1b in the fault status registers.
The gate drivers continue to operate. The external controller manages this condition by acting appropriately.
The reporting clears when the LOCK_ILIMIT condition clears and a clear fault command is issued through the
CLR_FLT bit.
8.3.21.9.4 LOCK_ILIMIT Disabled (LOCK_ILIMIT_MODE = 1xx1b)
No action is taken when a LOCK_ILIMIT event happens in this mode.
8.3.21.10 Thermal Warning (OTW)
If the die temperature exceeds the thermal warning limit (TOTW), the OT and OTW bits in the status register are
set to 1b. The reporting of OTW on the nFAULT pin can be enabled by setting OTW_REP to 1b. The device
performs no additional action and continues to function. In this case, the nFAULT pin is released when the die
temperature decreases below the hysteresis point of the thermal warning limit (TOTW - TOTW_HYS). The OTW bit
remains set until cleared through the CLR_FLT bit and the die temperature is lower than thermal warning limit.
(TOTW).
Note
Over-temperature warning (OTW) is not reported on nFAULT pin by default.
8.3.21.11 Thermal Shutdown (TSD)
If the die temperature exceeds the thermal shutdown limit (TTSD), all the FETs are disabled, the charge pump
is shut down, and the nFAULT pin is driven low. In addition, the DRIVER_FAULT, OT and TSD bit in the status
register are set to 1b. Normal operation resumes (driver operation and the nFAULT pin is released) when the
die temperature decreases below the hysteresis point of the thermal shutdown limit (TTSD - TTSD_HYS). The TSD
bit stays latched high indicating that a thermal event occurred until a clear fault command is issued through the
CLR_FLT bit. This protection feature cannot be disabled.
8.3.21.12 Motor Lock (MTR_LCK)
The MCT8316A continuously checks for different motor lock conditions (see Motor Lock Detection) during motor
operation. When one of the enabled lock condition happens, a MTR_LCK event is recognized and action is
taken according to the MTR_LCK_MODE.
In MCT8316AT, all motor lock condition detections are enabled and motor lock mode is configured to automatic
retry after 5 seconds.
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In MCT8316AV, all locks can be enabled or disabled individually and retry times can be configured through
LCK_RETRY . MTR_LCK_MODE bit can operate in four different modes: MTR_LCK latched shutdown,
MTR_LCK automatic retry, MTR_LCK report only and MTR_LCK disabled.
8.3.21.12.1 MTR_LCK Latched Shutdown (MTR_LCK_MODE = 00xxb)
When a MTR_LCK event happens in this mode, the status of MOSFETs will be configured by MTR_LCK_MODE
and nFAULT is driven low. Status of MOSFETs during MTR_LCK:
•
•
MTR_LCK_MODE = 0000b: All MOSFETs are turned OFF.
MTR_LCK_MODE = 0001b: MOSFET which was switching is turned OFF while the one which was
conducting stays ON till inductive energy is completely recirculated.
MTR_LCK_MODE = 0010b: All high-side MOSFETs are turned ON.
MTR_LCK_MODE = 0011b: All low-side MOSFETs are turned ON.
•
•
The CONTROLLER_FAULT, MTR_LCK and respective motor lock condition bits are set to 1b in the fault status
registers. Normal operation resumes (gate driver operation and the nFAULT pin is released) when the MTR_LCK
condition clears and a clear fault command is issued through the CLR_FLT bit.
8.3.21.12.2 MTR_LCK Automatic Recovery (MTR_LCK_MODE= 01xxb)
When a MTR_LCK event happens in this mode, the status of MOSFETs will be configured by MTR_LCK_MODE
and nFAULT is driven low. Status of MOSFETs during MTR_LCK:
•
•
MTR_LCK_MODE = 0100b: All MOSFETs are turned OFF.
MTR_LCK_MODE = 0101b: MOSFET which was switching is turned OFF while the one which was
conducting stays ON till inductive energy is completely recirculated.
MTR_LCK_MODE = 0110b: All high-side MOSFETs are turned ON.
MTR_LCK_MODE = 0111b: All low-side MOSFETs are turned ON.
•
•
The CONTROLLER_FAULT, MTR_LCK and respective motor lock condition bits are set to 1b in the fault status
registers. Normal operation resumes automatically (gate driver operation and the nFAULT pin is released) after
the tLCK_RETRY (configured by LCK_RETRY) time lapses. The CONTROLLER_FAULT, MTR_LCK and respective
motor lock condition bits are reset to 0b after the tLCK_RETRY period expires.
8.3.21.12.3 MTR_LCK Report Only (MTR_LCK_MODE = 1000b)
No protective action is taken when a MTR_LCK event happens in this mode. The motor lock event is reported
by setting the CONTROLLER_FAULT, MTR_LCK and respective motor lock condition bits to 1b in the fault
status registers. The gate drivers continue to operate. The external controller manages this condition by acting
appropriately. The reporting clears when the MTR_LCK condition clears and a clear fault command is issued
through the CLR_FLT bit.
8.3.21.12.4 MTR_LCK Disabled (MTR_LCK_MODE = 1xx1b)
No action is taken when a MTR_LCK event happens in this mode.
8.3.21.13 Motor Lock Detection
The MCT8316A provides different lock detect mechanisms to determine if the motor is in a locked state. Multiple
detection mechanisms work together to ensure the lock condition is detected quickly and reliably. In addition to
detecting if there is a locked motor condition, the MCT8316A can also identify and take action if there is no motor
connected to the system. Each of the lock detect mechanisms and the no-motor detection can be disabled by
their respective register bits (LOCK1/2/3_EN).
8.3.21.13.1 Lock 1: Abnormal Speed (ABN_SPEED)
MCT8316A monitors the speed continuously and at any time the speed exceeds LOCK_ABN_SPEED, an
ABN_SPEED lock event is recognized and action is taken according to the MTR_LCK_MODE.
threshold is set through the LOCK_ABN_SPEED register. ABN_SPEED lock can be enabled/disabled by
LOCK1_EN.
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8.3.21.13.2 Lock 2: Loss of Sync (LOSS_OF_SYNC)
The motor is commutated by detecting the zero crossing on the phase which is in Hi-Z state. If the motor is
locked, the back-EMF will disappear and MCT8316A will be not able to detect the zero crossing. If MCT8316A
is not able to detect zero crossing for LOSS_SYNC_TIMES number of times, LOSS_OF_SYNC event is
recognized and action is taken according to the MTR_LCK_MODE. LOSS_OF_SYNC lock can be enabled/
disabled by LOCK2_EN.
8.3.21.13.3 Lock3: No-Motor Fault (NO_MTR)
The MCT8316A continuously monitors the relevant phase current (low-side phase in the present phase pattern);
if the relevant phase current stays below NO_MTR_THR for a time longer than NO_MTR_DEG_TIME, a
NO_MTR event is recognized. The response to the NO_MTR event is configured through MTR_LCK_MODE .
NO_MTR lock can be enabled/disabled by LOCK3_EN.
8.3.21.14 IPD Faults
The MCT8316A uses 12-bit timers to estimate the time during the current ramp up and ramp down during IPD,
when the motor start-up is configured as IPD (MTR_STARTUP is set to 10b). During IPD, the algorithm checks
for a successful current ramp-up to IPD_CURR_THR, starting with an IPD clock of 10MHz; if unsuccessful
(timer overflow before current reaches IPD_CURR_THR), IPD is repeated with lower frequency clocks of 1MHz,
100kHz, and 10kHz sequentially. If the IPD timer overflows (current does not reach IPD_CURR_THR) with
all the four clock frequencies, then the IPD_T1_FAULT gets triggered. Similarly the algorithm check sfor a
successful current decay to zero during IPD current ramp down using all the mentioned IPD clock frequencies. If
the IPD timer overflows (current does not ramp down to zero) in all the four attempts, then the IPD_T2_FAULT
gets triggered.
IPD gives incorrect results if the next IPD pulse is commanded before the complete decay of current due to
present IPD pulse. The MCT8316A can generate a fault called IPD_FREQ_FAULT during such a scenario . The
IPD_FREQ_FAULT maybe triggerd if the IPD frequency is too high for the IPD current limit and the IPD release
mode or if the motor inductance is too high for the IPD frequency, IPD current limit and IPD release mode.
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8.4 Device Functional Modes
8.4.1 Functional Modes
8.4.1.1 Sleep Mode
In sleep mode, the MOSFETs, sense amplifiers, buck regulator, charge pump, AVDD LDO regulator and the
I2C bus are disabled. The device can be configured to enter sleep (instead of standby) mode by configuring
DEV_MODE to 1b. SPEED pin determines entry and exit from sleep state as described in Table 8-19.
Note
During power-up and power-down of the device, the nFAULT pin is held low as the internal regulators
are disabled. After the regulators have been enabled, the nFAULT pin is automatically released.
8.4.1.2 Standby Mode
In standby mode the charge pump, AVDD LDO, buck regulator and I2C bus are active. The device can be
configured to enter standby mode by configuring DEV_MODE to 0b. SPEED pin determines entry and exit from
standby state as described in Table 8-19
8.4.1.3 Fault Reset (CLR_FLT)
In the case of latched faults, the device goes into a partial shutdown state to help protect the power MOSFETs
and system. When the fault condition clears, the device can go to the operating state again by setting the
CLR_FLT to 1b.
Table 8-19. Conditions to Enter or Exit Sleep or Standby Modes
SPEED
COMMAND
MODE
ENTER STANDBY
CONDITION
EXIT FROM STANDBY
CONDITION
EXIT FROM SLEEP
CONDITION
ENTER SLEEP CONDITION
SPEED pin voltage < VEN_SB SPEED pin voltage < VEN_SL SPEED pin voltage > VEX_SB SPEED pin voltage > VEX_SL
Analog
for tDET_SB_ANA
for tDET_SL_ANA
for tDET_ANA
for tDET_ANA
SPEED pin low (V <
VDIG_IL) for tDET_SL_PWM
tDET_SL_FREQ
PWM/
Frequency
SPEED pin low (V < VDIG_IL
for tEN_SB_PWM/ tEN_SB_FREQ
)
SPEED pin high (V > VDIG_IH) SPEED pin high (V > VDIG_IH)
/
for tDET_PWM
for tDET_PWM
SPEED_CTRL is programmed SPEED pin voltage < VEN_SL SPEED_CTRL is
as 0. for t > SLEEP_TIME programmed as non-zero.
SPEED pin voltage > VEX_SL
for tDET_ANA
I2C
8.5 External Interface
8.5.1 DRVOFF Functionality
When DRVOFF pin is driven high, all six MOSFETs are disabled. In this mode, if SPEED pin is high, the charge
pump, AVDD regulator, buck regulator and I2C bus are active; driver faults like OCP will be inactive.
8.5.2 DAC outputs
MCT8316A has two 12-bit DACs which output analog voltage equivalent of digital variables on DACOUT1
and DACOUT2 pins with resolution of 12 bits and maximum voltage is 3-V. Signals available on DACOUT
pins is useful in tracking algorithm variables in real-time and can be used for tuning speed controller
or motor acceleration time. The address for variables for DACOUT1 and DACOUT2 are configured using
DACOUT1_VAR_ADDR and DACOUT2_VAR_ADDR. DACOUT1 is available on pin 37 and DACOUT2 can be
configured on pin 36 by setting DAC_SOX_CONFIG to 00b. DACOUT2 is also available on pin 38.
8.5.3 SOX Output
MCT8316A can provide the built-in current sense amplifiers' output on the SOX pin. SOX output is available on
pin 36 and can be configured by DAC_SOX_CONFIG.
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8.5.4 Oscillator Source
MCT8316A has a built-in oscillator that is used as the clock source for all digital peripherals and timing
measurements. Default configuration for MCT8316A is to use the internal oscillator and it is sufficient to drive the
motor without need for any external crystal or clock sources.
In case MCT8316A does not meet accuracy requirements of timing measurement or speed loop, then
MCT8316AV has an option to support an external clock reference.
In order to improve EMI performance, MCT8316AV provides the option of modulating the clock frequency by
enabling Spread Spectrum Modulation (SSM) through SSM_CONFIG
.
8.5.4.1 External Clock Source (Available for MCT8316AV)
Speed loop accuracy of MCT8316A over wide operating temperature range can be improved by providing more
accurate optional clock reference on EXT_CLK pin as shown in Figure 8-51. EXT_CLK will be used to calibrate
internal clock oscillator and match the accuracy of the external clock. External clock source can be selected
by configuring CLK_SEL to 11b and setting EXT_CLK_EN to 1b. The external clock source frequency can be
configured through EXT_CLK_CONFIG.
Internal
Oscillator
(60 MHz)
EXT_CLK
Calibrate
Figure 8-51. External Clock Reference
Note
External clock is optional and can be used when higher clock accuracy is needed. MCT8316A will
always power up using the internal oscillator in all modes.
8.5.5 External Watchdog (Available only in MCT836AV)
MCT8316A provides an external watchdog feature - EXT_WD_EN bit should be set to 1b to enable the external
watchdog. When this feature is enabled, the device waits for a tickle (low to high transition in GPIO mode,
EXT_WD_STATUS_SET set to 1b in I2C mode) from the external watchdog input for a configured time interval;
if the time interval between two consecutive tickles is higher than the configured time, a watchdog fault is
triggered. This fault can be configured using EXT_WD_FAULT either as a report only fault or as a latched fault
with outputs in Hi-Z state. The latched fault can be cleared by writing 1b to CLR_FLT. In case, the next tickle
arrives before the configured time interval elapses, the watchdog timer is reset and it begins to wait for the next
tickle. This can be used to continuously monitor the health of an external MCU (which is the external watchdog
input) and put the MCT8316A outputs in Hi-Z in case the external MCU is in an erroneous state.
The external watchdog input is selected using EXT_WD_INPUT and can either be the EXT_WD pin or the I2C
interface . The time interval between two tickles to trigger a watchdog fault is configured by EXT_WD_FREQ;
there are 4 time (frequency) settings - 100 (10Hz), 200 (5Hz), 500 (2Hz) and 1000ms (1Hz).
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8.6 EEPROM access and I2C interface
8.6.1 EEPROM Access
MCT8316A has 1024 bits (16 rows of 64 bits each) of EEPROM, which are used to store the motor configuration
parameters. Erase operations are row-wise (all 64 bits are erased in a single erase operation), but 32-bit write
and read operations are supported. EEPROM can be written and read using the I2C serial interface but erase
cannot be performed using I2C serial interface. The shadow registers corresponding to the EEPROM are located
at addresses 0x000080-0x0000AE.
Note
MCT8316A allows EEPROM write and read operations only when the motor is not spinning.
8.6.1.1 EEPROM Write
In MCT8316A, EEPROM write procedure is as follows,
1. Write register 0x000080 (ISD_CONFIG) with ISD configuration like resync enable, reverse drive enable,
stationary detect threshold etc.,
2. Write register 0x000082 (MOTOR_STARTUP1) with motor start-up configuration like start-up method, first
cycle frequency, IPD parameters, align parameters etc.,
3. Write register 0x000084 (MOTOR_STARTUP2) with motor start-up configuration like open loop acceleration,
minimum duty cycle etc.,
4. Write register 0x000086 (CLOSED_LOOP1) with motor control configuration like closed loop acceleration,
PWM frequency, PWM modulation etc.,
5. Write register 0x000088 (CLOSED_LOOP2) with motor control configuration like FG signal parameters,
motor stop options etc.,
6. Write register 0x00008A (CLOSED_LOOP3) with motor control configuration like fast start-up and dynamic
degauss parameters including BEMF thresholds, duty cycle thresholds etc.,
7. Write register 0x00008C (CLOSED_LOOP4) with motor control configuration like fast deceleration
parameters including fast deceleration duty threshold, window, current limits etc.,
8. Write register 0x00008E (CONST_SPEED) with motor control configuration like speed loop parameters
including closed loop mode, saturation limits, Kp, Ki etc.,
9. Write register 0x000090 (CONST_PWR) with motor control configuration like input power regulation
parameters including maximum power, constant power mode, power level hysteresis, maximum speed etc.,
10. Write register 0x000092 (FAULT_CONFIG1) with fault control configuration like CBC, lock current limits and
actions, retry times etc.,
11. Write register 0x000094 (FAULT_CONFIG2) with fault control configuration like OV, UV limits and actions,
abnormal speed level, motor lock setting etc.,
12. Write registers 0x000096 and 0x000098 (150_DEG_TWO_PH_PROFILE,
150_DEG_THREE_PH_PROFILE) with PWM duty cycle configurations for 150o modulation.
13. Write registers 0x00009A and 0x00009C (TRAP_CONFIG1 and TRAP_CONFIG2) with algorithm
parameters like ISD BEMF threshold, blanking time, AVS current limits etc.,
14. Write registers 0x0000A4 and 0x0000A6 (PIN_CONFIG1 and PIN_CONFIG2) with pin configuration for DIR,
BRAKE, DACOUT1 and DACOUT2, SOX, external watchdog etc.,
15. Write register 0x0000A8 (DEVICE_CONFIG) with device configuration like device mode, external clock
enable, clock source, speed input PWM frequency range etc.,
16. Write registers 0x0000AC and 0x0000AE (GD_CONFIG1 and GD_CONFIG2) with gate driver configuration
like slew rate, CSA gain, OCP level, mode, OVP enable etc.,
17. Write 0x80000000 into register 0x0000E6 to write the shadow register (0x000080-0x0000AE) values into the
EEPROM.
18. Wait for 100ms for the EEPROM write operation to complete
Steps 1-16 can be selectively executed based on registers/parameters that need to be modified. After all shadow
registers have been updated with the required values, step 17 should be executed to copy the contents of the
shadow registers into the EEPROM.
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8.6.1.2 EEPROM Read
In MCT8316A, EEPROM read procedure is as follows,
1. Write 0x40000000 into register 0x0000E6 to read the EEPROM data into the shadow registers
(0x000080-0x0000AE).
2. Wait for 100ms for the EEPROM read operation to complete.
3. Read the shadow register values, 1 or 2 registers at a time, using the I2C read command as explained
in Section 8.6.2. Shadow register addresses are in the range of 0x000080-0x0000AE. Register address
increases in steps of 2 for 32-bit read operation (since each address is a 16-bit location).
8.6.2 I2C Serial Interface (Available only in MCT8316AV)
MCT8316A interfaces with an external MCU over an I2C serial interface. MCT8316A is an I2C target to be
interfaced with a controller. External MCU can use this interface to read/write from/to any non-reserved register
in MCT8316A
Note
For reliable communication, a 100-µs delay should be used between every byte transferred over the
I2C bus.
8.6.2.1 I2C Data Word
The I2C data word format is shown in Table 8-20.
Table 8-20. I2C Data Word Format
TARGET_ID
R/W
CONTROL WORD
DATA
CRC-8
A6 - A0
W0
CW23 - CW0
D15 / D31/ D63 - D0
C7 - C0
Target ID and R/W Bit: The first byte includes the 7-bit I2C target ID (0x00), followed by the read/write command
bit. Every packet in MCT8316A the communication protocol starts with writing a 24-bit control word and hence
the R/W bit is always 0.
24-bit Control Word: The Target Address is followed by a 24-bit control bit. The control word format is shown in
Table 8-21.
Table 8-21. 24-bit Control Word Format
OP_R/W
CRC_EN
DLEN
MEM_SEC
MEM_PAGE
MEM_ADDR
CW23
CW22
CW21- CW20
CW19 - CW16
CW15 - CW12
CW11 - CW0
Each field in the control word is explained in detail below.
OP_R/W – Read/Write: R/W bit gives information on whether this is a read operation or write operation.
Bit value 0 indicates it is a write operation. Bit value 1 indicates it is a read operation. For write operation,
MCT8316A will expect data bytes to be sent after the 24-bit control word. For read operation, MCT8316A will
expect an I2C read request with repeated start or normal start after the 24-bit control word.
CRC_EN – Cyclic Redundancy Check(CRC) Enable: MCT8316A supports CRC to verify the data integrity.
This bit controls whether the CRC feature is enabled or not.
DLEN – Data Length: DLEN field determines the length of the data that will be sent by external MCU to
MCT8316A. MCT8316A protocol supports three data lengths: 16-bit, 32-bit and 64-bit.
Table 8-22. Data Length Configuration
DLEN Value
00b
Data Length
16-bit
01b
32-bit
10b
64-bit
11b
Reserved
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MEM_SEC – Memory Section: Each memory location in MCT8316A is addressed using three separate entities
in the control word – Memory Section, Memory Page, Memory Address. Memory Section is a 4-bit field which
denotes the memory section to which the memory location belongs like RAM, ROM etc.
MEM_PAGE – Memory Page: Memory page is a 4-bit field which denotes the memory page to which the
memory location belongs.
MEM_ADDR – Memory Address: Memory address is the last 12-bits of the address. The complete 22-bit
address is constructed internally by MCT8316A using all three fields – Memory Section, Memory Page, Memory
Address. For memory locations 0x000000-0x000800, memory section is 0x0, memory page is 0x0 and memory
address is the lowest 12 bits(0x000 for 0x000000, 0x080 for 0x000080 and 0x800 for 0x000800)
Data Bytes: For a write operation to MCT8316A, the 24-bit control word is followed by data bytes. The DLEN
field in the control word should correspond with the number of bytes sent in this section.
CRC Byte: If the CRC feature is enabled in the control word, CRC byte has to be sent at the end of a write
transaction. Procedure to calculate CRC is explained in CRC Byte Calculation below.
8.6.2.2 I2C Write Operation
MCT8316A write operation over I2C involves the following sequence.
1. I2C start condition.
2. The sequence starts with I2C target start byte, made up of 7-bit target ID (0x00) to identify the MCT8316A
along with the R/W bit set to 0.
3. The start byte is followed by 24-bit control word. Bit 23 in the control word has to be 0 as it is a write
operation.
4. The 24-bit control word is then followed by the data bytes. The length of the data byte depends on the DLEN
field.
a. While sending data bytes, the LSB byte is sent first. Refer below examples for more details.
b. 16-bit/32-bit write – The data sent is written to the address mentioned in Control Word.
c. 64-bit Write – 64-bit is treated as two 32-bit writes. The address mentioned in Control word is taken as
Addr 0. Addr 1 is calculating internally by MCT8316A by incrementing Addr 0 by 2. A total of 8 data
bytes are sent. The first 4 bytes (sent in LSB first way) are written to Addr 0 and the next 4 bytes are
written to Addr 1.
5. If CRC is enabled, the packet ends with a CRC byte. CRC is calculated for the entire packet (Target ID + W
bit, Control Word, Data Bytes).
6. I2C stop condition.
2 / 4 / 8 DATA BYTES
Write – without CRC
TARGET
ID [6:0]
CONTROL
WORD [23:16]
CONTROL
WORD [15:8]
CONTROL
WORD [7:0]
DATA
BYTES
DATA
BYTES
S
0
ACK
ACK
ACK
ACK
ACK
ACK
P
2 / 4 / 8 DATA BYTES
Write – with CRC
TARGET
CONTROL
WORD [23:16]
CONTROL
WORD [15:8]
CONTROL
WORD [7:0]
DATA
BYTES
DATA
S
0
ACK
ACK
ACK
ACK
ACK
ACK CRC ACK
P
ID [6:0]
BYTES
CRC includes {TARGET ID,0}, CONTROL WORD[23:0], DATA BYTES
Figure 8-52. I2C Write Operation Sequence
8.6.2.3 I2C Read Operation
MCT8316A read operation over I2C involves the following sequence.
1. I2C start condition.
2. The sequence starts with I2C target Start Byte.
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3. The Start Byte is followed by 24-bit Control Word. Bit 23 in the control word has to be 1 as it is a read
operation.
4. The control word is followed by a repeated start or normal start.
5. MCT8316A sends the data bytes on SDA. The number of bytes sent by MCT8316A depends on the DLEN
field value in the control word.
a. While sending data bytes, the LSB byte is sent first. Refer the examples below for more details.
b. 16-bit/32-bit Read – The data from the address mentioned in Control Word is sent back.
c. 64-bit Read – 64-bit is treated as two 32-bit read. The address mentioned in Control Word is taken as
Addr 0. Addr 1 is calculating internally by MCT8316A by incrementing Addr 0 by 2. A total of 8 data
bytes are sent by MCT8316A. The first 4 bytes (sent in LSB first way) are read from Addr 0 and the next
4 bytes are read from Addr 1.
d. MCT8316A takes some time to process the control word and read data from the given address. This
involves some delay. It is quite possible that the repeated start with Target ID will be NACK’d. If the
I2C read request has been NACK’d by MCT8316A, retry after few cycles. During this retry, it is not
necessary to send the entire packet along with the control word. It is sufficient to send only the start
condition with target ID and read bit.
6. If CRC is enabled, then MCT8316A sends an additional CRC byte at the end. If CRC is enabled, external
MCU I2C controller has to read this additional byte before sending the stop bit. CRC is calculated for the
entire packet (Target ID + W bit, Control Word, Target ID + R bit, Data Bytes).
7. I2C stop condition.
2 / 4 / 8 DATA BYTES
Read – without CRC
TARGET
ID [6:0]
CONTROL
WORD [23:16]
CONTROL
WORD [15:8]
CONTROL
WORD [7:0]
TARGET
ID [6:0]
DATA
BYTES
DATA
BYTES
S
0
ACK
ACK
ACK
ACK RS
1
ACK
ACK
ACK
P
Read – with CRC
TARGET
2 / 4 / 8 DATA BYTES
CONTROL
WORD [23:16]
CONTROL
WORD [15:8]
CONTROL
WORD [7:0]
TARGET
ID [6:0]
DATA
BYTES
DATA
S
0
ACK
ACK
ACK
ACK RS
1
ACK
ACK
ACK CRC ACK
P
ID [6:0]
BYTES
CRC includes {TARGET ID,0}, CONTROL WORD[23:0], {TARGET ID,1}, DATA BYTES
Figure 8-53. I2C Read Operation Sequence
8.6.2.4 Examples of MCT8316A I2C Communication Protocol Packets
All values used in this example section are in hex format. I2C target ID used in the examples is 0x00.
Example for 32-bit Write Operation: Address – 0x00000080, Data – 0x1234ABCD, CRC Byte – 0x45 (Sample
value; does not match with the actual CRC calculation)
Table 8-23. Example for 32-bit Write Operation Packet
Start Byte
Control Word 0
Control Word 1
Control Data Bytes
Word 2
CRC
Target
ID
I2C
Write
OP_R/ CRC_E DLEN
MEM_S MEM_P MEM_A MEM_A DB0
EC AGE DDR DDR
DB1
DB2
DB3
CRC
Byte
W
N
A6-A0
W0
CW23
CW22
CW21- CW19- CW15- CW11- CW7-
D7-D0
D7-D0
D7-D0
D7-D0
C7-C0
CW20
CW16
CW12
CW8
CW0
0x80
0x80
0x00
0x00
0x0
0x0
0x1
0x1
0x0
0x0
0x0
0xCD
0xCD
0xAB
0xAB
0x34
0x34
0x12
0x12
0x45
0x45
0x50
0x00
Example for 64-bit Write Operation: Address - 0x00000080, Data Address 0x00000080 - Data 0x01234567,
Data Address 0x00000082 – Data 0x89ABCDEF, CRC Byte – 0x45 (Sample value; does not match with the
actual CRC calculation)
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Table 8-24. Example for 64-bit Write Operation Packet
Start Byte
Control Word 0
Control Word 1
Control Word Data Bytes
2
CRC
Target I2C
OP_R/W CRC_EN DLEN MEM_SEC MEM_PAGE MEM_ADDR MEM_ADDR DB0 - DB7
CRC
Byte
ID
Write
A6-A0 W0
CW23
CW22
0x1
CW21- CW19-
CW20 CW16
CW15-
CW12
CW11-CW8
0x0
CW7-CW0
[D7-D0] x 8
C7-C0
0x00
0x00
0x0
0x0
0x2
0x0
0x0
0x80
0x80
0x67452301EFCDAB89
0x67452301EFCDAB89
0x45
0x45
0x60
0x00
Example for 32-bit Read Operation: Address – 0x00000080, Data – 0x1234ABCD, CRC Byte – 0x56 (Sample
value; does not match with the actual CRC calculation)
Table 8-25. Example for 32-bit Read Operation Packet
Start Byte
Control Word 0
Control Word 1 Control Start Byte
Word 2
Byte 0 Byte 1 Byte 2 Byte 3 Byte 4
Target I2C
R/W
CRC_ DLEN MEM_ MEM_ MEM_ MEM_ Target I2C
EN SEC PAGE ADDR ADDR ID Read
DB0
DB1
DB2
DB3
CRC
Byte
ID
Write
A6-A0 W0
CW23 CW22 CW21- CW19- CW15- CW11- CW7- A6-A0 W0
D7-D0 D7-D0 D7-D0 D7-D0 C7-C0
CW20 CW16 CW12 CW8
CW0
0x80
0x80
0x00
0x00
0x0
0x1
0x1
0x1
0x0
0x0
0x0
0x00
0x01
0x1
0xCD 0xAB
0xCD 0xAB
0x34
0x34
0x12
0x12
0x56
0x56
0xD0
0x00
8.6.2.5 Internal Buffers
MCT8316A uses buffers internally to store the data received on I2C. Highest priority is given to collecting data on
the I2C Bus. There are 2 buffers (ping-pong) for I2C Rx Data and 2 buffers (ping-pong) for I2C Tx Data.
A write request from external MCU is stored in Rx Buffer 1 and then the parsing block is triggered to work on
this data in Rx Buffer 1. While MCT8316A is processing a write packet from Rx Buffer 1, if there is another new
read/write request, the entire data from the I2C bus is stored in Rx Buffer 2 and it will be processed after the
current request.
MCT8316A can accommodate a maximum of two consecutive read/write requests. If MCT8316A is busy due to
high priority interrupts, the data sent will be stored in internal buffers (Rx Buffer 1 and Rx Buffer 2). At this point,
if there is a third read/write request, the Target ID will be NACK’d as the buffers are already full.
During read operations, the read request is processed and the read data from the register is stored in the Tx
Buffer along with the CRC byte, if enabled. Now if the external MCU initiates an I2C Read (Target ID + R bit), the
data from this Tx Buffer is sent over I2C. Since there are two Tx Buffers, register data from 2 MCT8316A reads
can be buffered. Given this scenario, if there is a third read request, the control word will be stored in the Rx
Buffer 1, but it will not be processed by MCT8316A as the Tx Buffers are full.
Once a data is read from Tx Buffer, the data is no longer stored in the Tx buffer. The buffer is cleared and it
becomes available for the next data to be stored. If the read transaction was interrupted in between and if the
MCU had not read all the bytes, external MCU can initiate another I2C read (only I2C read, without any control
word information) to read all the data bytes from first.
8.6.2.6 CRC Byte Calculation
An 8-bit CCIT polynomial (x8 + x2+ x + 1) is used for CRC computation.
CRC Calculation in Write Operation: When the external MCU writes to MCT8316A, if the CRC is enabled, the
external MCU has to compute an 8-bit CRC byte and add the CRC byte at the end of the data. MCT8316A will
compute CRC using the same polynomial internally and if there is a mismatch, the write request is discarded.
Input data for CRC calculation by external MCU for write operation are listed below:
1. Target ID + write bit.
2. Control word – 3 bytes
3. Data bytes – 2/4/8 bytes
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CRC Calculation in Read Operation: When the external MCU reads from MCT8316A, if the CRC is enabled,
MCT8316A sends the CRC byte at the end of the data. The CRC computation in read operation involves the
start byte, control words sent by external MCU along with data bytes sent by MCT8316A. Input data for CRC
calculation by external MCU to verify the data sent by MCT8316A are listed below :
1. Target ID + write bit
2. Control word – 3 bytes
3. Target ID + read bit
4. Data bytes – 2/4/8 bytes
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8.7 EEPROM (Non-Volatile) Register Map
8.7.1 Algorithm_Configuration Registers
ALGORITHM_CONFIGURATION Registers lists the memory-mapped registers for the Algorithm_Configuration
registers. All register offset addresses not listed in ALGORITHM_CONFIGURATION Registers should be
considered as reserved locations and the register contents should not be modified.
Table 8-26. ALGORITHM_CONFIGURATION Registers
Address Acronym
Register Name
Section
80h
82h
84h
86h
88h
8Ah
8Ch
8Eh
90h
96h
98h
ISD_CONFIG
ISD configuration
Section 8.7.1.1
Section 8.7.1.2
Section 8.7.1.3
Section 8.7.1.4
Section 8.7.1.5
Section 8.7.1.6
Section 8.7.1.7
Section 8.7.1.8
Section 8.7.1.9
Section 8.7.1.10
Section 8.7.1.11
MOTOR_STARTUP1
MOTOR_STARTUP2
CLOSED_LOOP1
CLOSED_LOOP2
CLOSED_LOOP3
CLOSED_LOOP4
CONST_SPEED
Motor start-up configuration 1
Motor start-up configuration 2
Closed loop configuration 1
Closed loop configuration 2
Closed loop configuration 3
Closed loop configuration 4
Constant speed configuration
Constant power configuration
150° Two-ph profile
CONST_PWR
150_DEG_TWO_PH_PROFILE
150_DEG_THREE_PH_PROFIL 150° Three-ph profile
E
9Ah
9Ch
TRAP_CONFIG1
TRAP_CONFIG2
Trap configuration 1
Trap configuration 2
Section 8.7.1.12
Section 8.7.1.13
Complex bit access types are encoded to fit into small table cells. Algorithm_Configuration Access Type Codes
shows the codes that are used for access types in this section.
Table 8-27. Algorithm_Configuration Access Type
Codes
Access Type
Read Type
R
Code
Description
R
Read
Write Type
W
W
Write
Reset or Default Value
-n
Value after reset or the default
value
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8.7.1.1 ISD_CONFIG Register (Address = 80h) [Reset = 00000000h]
ISD_CONFIG is shown in ISD_CONFIG Register and described in ISD_CONFIG Register Field Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure initial speed detect settings
Figure 8-54. ISD_CONFIG Register
31
30
29
28
27
26
25
24
PARITY
ISD_EN
BRAKE_EN
HIZ_EN
RVS_DR_EN
RESYNC_EN STAT_BRK_EN STAT_DETECT
_THR
R/W-0h
23
R/W-0h
22
R/W-0h
R/W-0h
R/W-0h
19
R/W-0h
R/W-0h
17
R/W-0h
21
20
18
16
STAT_DETECT_THR
R/W-0h
BRK_MODE
R/W-0h
BRK_CONFIG
R/W-0h
BRK_CURR_THR
R/W-0h
BRK_TIME
R/W-0h
15
14
13
12
11
10
9
8
BRK_TIME
HIZ_TIME
R/W-0h
STARTUP_BRK
_TIME
R/W-0h
6
R/W-0h
0
7
5
4
3
2
1
STARTUP_BRK_TIME
R/W-0h
RESYNC_MIN_THRESHOLD
R/W-0h
RESERVED
R/W-0h
Table 8-28. ISD_CONFIG Register Field Descriptions
Bit
31
30
Field
Type
R/W
R/W
Reset
Description
PARITY
ISD_EN
0h
Parity bit
0h
ISD enable
0h = Disable
1h = Enable
29
28
27
26
25
BRAKE_EN
HIZ_EN
R/W
R/W
R/W
R/W
R/W
0h
0h
0h
0h
0h
Brake enable
0h = Disable
1h = Enable
Hi-Z enable
0h = Disable
1h = Enable
RVS_DR_EN
RESYNC_EN
STAT_BRK_EN
Reverse drive enable
0h = Disable
1h = Enable
Resynchronization enable
0h = Disable
1h = Enable
Enable or disable brake during stationary
0h = Disable
1h = Enable
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Table 8-28. ISD_CONFIG Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
24-22
STAT_DETECT_THR
R/W
0h
Stationary BEMF detect threshold
0h = 5 mV
1h = 10 mV
2h = 15 mV
3h = 20 mV
4h = 25 mV
5h = 30 mV
6h = 50 mV
7h = 100 mV
21
20
BRK_MODE
R/W
R/W
R/W
0h
0h
0h
Brake mode
0h = All three low-side FETs turned ON
1h = All three high-side FETs turned ON
BRK_CONFIG
BRK_CURR_THR
Brake configuration
0h = Brake time is used to come out of Brake state
1h = Brake current threshold is used to come out of Brake state
19-17
Brake current threshold
0h = 5 mV
1h = 10 mV
2h = 15 mV
3h = 20 mV
4h = 25 mV
5h = 30 mV
6h = 50 mV
7h = 100 mV
16-13
BRK_TIME
R/W
0h
Brake time
0h = 10 ms
1h = 50 ms
2h = 100 ms
3h = 200 ms
4h = 300 ms
5h = 400 ms
6h = 500 ms
7h = 750 ms
8h = 1 s
9h = 2 s
Ah = 3 s
Bh = 4 s
Ch = 5 s
Dh = 7.5 s
Eh = 10 s
Fh = 15 s
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Table 8-28. ISD_CONFIG Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
12-9
HIZ_TIME
R/W
0h
Hi-Z time
0h = 10 ms
1h = 50 ms
2h = 100 ms
3h = 200 ms
4h = 300 ms
5h = 400 ms
6h = 500 ms
7h = 750 ms
8h = 1 s
9h = 2 s
Ah = 3 s
Bh = 4 s
Ch = 5 s
Dh = 7.5 s
Eh = 10 s
Fh = 15 s
8-6
STARTUP_BRK_TIME
R/W
0h
Brake time when motor is stationary
0h = 1 ms
1h = 10 ms
2h = 25 ms
3h = 50 ms
4h = 100 ms
5h = 250 ms
6h = 500 ms
7h = 1000 ms
5-3
RESYNC_MIN_THRESH R/W
OLD
0h
Minimum phase BEMF below which the motor is coasted instead of
resync
0h = computed based on MIN_DUTY
1h = 300 mV
2h = 400 mV
3h = 500 mV
4h = 600 mV
5h = 800 mV
6h = 1000 mV
7h = 1250 mV
2-0
RESERVED
R/W
0h
Reserved
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8.7.1.2 MOTOR_STARTUP1 Register (Address = 82h) [Reset = 00000000h]
MOTOR_STARTUP1 is shown in MOTOR_STARTUP1 Register and described in MOTOR_STARTUP1 Register
Field Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure motor startup settings1
Figure 8-55. MOTOR_STARTUP1 Register
31
30
MTR_STARTUP
R/W-0h
29
28
27
26
25
17
24
PARITY
R/W-0h
ALIGN_RAMP_RATE
R/W-0h
ALIGN_TIME
R/W-0h
23
22
21
20
19
18
16
ALIGN_TIME
ALIGN_CURR_THR
IPD_CLK_FRE
Q
R/W-0h
14
R/W-0h
R/W-0h
8
15
13
5
12
11
10
2
9
IPD_CLK_FREQ
R/W-0h
IPD_CURR_THR
R/W-0h
IPD_RLS_MODE
R/W-0h
7
6
4
3
1
0
IPD_ADV_ANGLE
R/W-0h
IPD_REPEAT
R/W-0h
SLOW_FIRST_CYC_FREQ
R/W-0h
Table 8-29. MOTOR_STARTUP1 Register Field Descriptions
Bit
Field
Type
R/W
R/W
Reset
Description
31
PARITY
0h
Parity bit
30-29
MTR_STARTUP
0h
Motor start-up method
0h = Align
1h = Double Align
2h = IPD
3h = Slow first cycle
28-25
ALIGN_RAMP_RATE
R/W
0h
Align voltage ramp rate
0h = 0.1 V/s
1h = 0.2 V/s
2h = 0.5 V/s
3h = 1 V/s
4h = 2.5 V/s
5h = 5 V/s
6h = 7.5 V/s
7h = 10 V/s
8h = 25 V/s
9h = 50 V/s
Ah = 75 V/s
Bh = 100 V/s
Ch = 250 V/s
Dh = 500 V/s
Eh = 750 V/s
Fh = 1000 V/s
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Table 8-29. MOTOR_STARTUP1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
24-21
ALIGN_TIME
R/W
0h
Align time
0h = 5 ms
1h = 10 ms
2h = 25 ms
3h = 50 ms
4h = 75 ms
5h = 100 ms
6h = 200 ms
7h = 400 ms
8h = 600 ms
9h = 800 ms
Ah = 1 s
Bh = 2 s
Ch = 4 s
Dh = 6 s
Eh = 8 s
Fh = 10 s
20-17
ALIGN_CURR_THR
R/W
0h
Align current threshold (Align current threshold (A) =
ALIGN_CURR_THR / CSA_GAIN)
0h = N/A
1h = 0.1V
2h = 0.2 V
3h = 0.3 V
4h = 0.4 V
5h = 0.5 V
6h = 0.6 V
7h = 0.7 V
8h = 0.8 V
9h = 0.9 V
Ah = 1 V
Bh = 1.1 V
Ch = 1.2 V
Dh = 1.3 V
Eh = 1.4 V
Fh = 1.5 V
16-14
IPD_CLK_FREQ
R/W
0h
IPD clock frequency
0h = 50 Hz
1h = 100 Hz
2h = 250 Hz
3h = 500 Hz
4h = 1000 Hz
5h = 2000 Hz
6h = 5000 Hz
7h = 10000 Hz
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Table 8-29. MOTOR_STARTUP1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
13-10
IPD_CURR_THR
R/W
0h
IPD current threshold (IPD current threshold (A) = IPD_CURR_THR /
CSA_GAIN)
0h = N/A
1h = N/A
2h = 0.2 V
3h = 0.3 V
4h = 0.4 V
5h = 0.5 V
6h = 0.6 V
7h = 0.7 V
8h = 0.8 V
9h = 0.9 V
Ah = 1 V
Bh = 1.1 V
Ch = 1.2 V
Dh = 1.3 V
Eh = 1.4 V
Fh = 1.5 V
9-8
7-6
5-4
3-0
IPD_RLS_MODE
IPD_ADV_ANGLE
IPD_REPEAT
R/W
R/W
R/W
0h
0h
0h
0h
IPD release mode
0h = Brake
1h = Tristate
2h = N/A
3h = N/A
IPD advance angle
0h = 0°
1h = 30°
2h = 60°
3h = 90°
Number of times IPD is executed
0h = one
1h = average of 2 times
2h = average of 3 times
3h = average of 4 times
SLOW_FIRST_CYC_FRE R/W
Q
Frequency of first cycle
0h = 0.05 Hz
1h = 0.1 Hz
2h = 0.25 Hz
3h = 0.5 Hz
4h = 1 Hz
5h = 2 Hz
6h = 3 Hz
7h = 5 Hz
8h = 10 Hz
9h = 15 Hz
Bh = 25 Hz
Ch = 50 Hz
Dh = 100 Hz
Eh = 150 Hz
Fh = 200 Hz
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8.7.1.3 MOTOR_STARTUP2 Register (Address = 84h) [Reset = X]
MOTOR_STARTUP2 is shown in MOTOR_STARTUP2 Register and described in MOTOR_STARTUP2 Register
Field Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure motor startup settings2
Figure 8-56. MOTOR_STARTUP2 Register
31
30
29
28
27
26
25
24
PARITY
OL_ILIMIT_CO
NFIG
OL_DUTY
OL_ILIMIT
R/W-0h
R/W-0h
22
R/W-0h
R/W-0h
17
23
21
13
5
20
19
11
3
18
16
8
OL_ILIMIT
R/W-0h
OL_ACC_A1
R/W-0h
OL_ACC_A2
R/W-0h
15
14
12
10
9
1
OL_ACC_A2
R/W-0h
OPN_CL_HANDOFF_THR
R/W-0h
7
6
4
2
0
AUTO_HANDO FIRST_CYCLE
MIN_DUTY
R/W-0h
RESERVED
R-X
FF
_FREQ_SEL
R/W-0h
R/W-0h
Table 8-30. MOTOR_STARTUP2 Register Field Descriptions
Bit
31
30
Field
Type
R/W
R/W
Reset
Description
PARITY
0h
Parity bit
OL_ILIMIT_CONFIG
0h
Open loop current limit configuration
0h = Open loop current limit defined by OL_ILIMIT
1h = Open loop current limit defined by ILIMIT
29-27
OL_DUTY
R/W
0h
Duty cycle limit during open loop
0h = 10%
1h = 15%
2h = 20%
3h = 25%
4h = 30%
5h = 40%
6h = 50%
7h = 100%
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Table 8-30. MOTOR_STARTUP2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
26-23
OL_ILIMIT
R/W
0h
Open loop current limit (OL current threshold (A) = OL_CURR_THR /
CSA_GAIN)
0h = N/A
1h = 0.1V
2h = 0.2 V
3h = 0.3 V
4h = 0.4 V
5h = 0.5 V
6h = 0.6 V
7h = 0.7 V
8h = 0.8 V
9h = 0.9 V
Ah = 1 V
Bh = 1.1 V
Ch = 1.2 V
Dh = 1.3 V
Eh = 1.4 V
Fh = 1.5 V
22-18
OL_ACC_A1
R/W
0h
Open loop acceleration A1
0h = 0.005 Hz/s
1h = 0.01 Hz/s
2h = 0.025 Hz/s
3h = 0.05 Hz/s
4h = 0.1 Hz/s
5h = 0.25 Hz/s
6h = 0.5 Hz/s
7h = 1 Hz/s
8h = 2.5 Hz/s
9h = 5 Hz/s
Ah = 7.5 Hz/s
Bh = 10 Hz/s
Ch = 12.5 Hz/s
Dh = 15 Hz/s
Eh = 20 Hz/s
Fh = 30 Hz/s
10h = 40 Hz/s
11h = 50 Hz/s
12h = 60 Hz/s
13h = 75 Hz/s
14h = 100 Hz/s
15h = 125 Hz/s
16h = 150 Hz/s
17h = 175 Hz/s
18h = 200 Hz/s
19h = 250 Hz/s
1Ah = 300 Hz/s
1Bh = 400 Hz/s
1Ch = 500 Hz/s
1Dh = 750 Hz/s
1Eh = 1000 Hz/s
1Fh = No Limit (32767) Hz/s
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Table 8-30. MOTOR_STARTUP2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
17-13
OL_ACC_A2
R/W
0h
Open loop acceleration A2
0h = 0.005 Hz/s2
1h = 0.01 Hz/s2
2h = 0.025 Hz/s2
3h = 0.05 Hz/s2
4h = 0.1 Hz/s2
5h = 0.25 Hz/s2
6h = 0.5 Hz/s2
7h = 1 Hz/s2
8h = 2.5 Hz/s2
9h = 5 Hz/s2
Ah = 7.5 Hz/s2
Bh = 10 Hz/s2
Ch = 12.5 Hz/s2
Dh = 15 Hz/s2
Eh = 20 Hz/s2
Fh = 30 Hz/s2
10h = 40 Hz/s2
11h = 50 Hz/s2
12h = 60 Hz/s2
13h = 75 Hz/s2
14h = 100 Hz/s2
15h = 125 Hz/s2
16h = 150 Hz/s2
17h = 175 Hz/s2
18h = 200 Hz/s2
19h = 250 Hz/s2
1Ah = 300 Hz/s2
1Bh = 400 Hz/s2
1Ch = 500 Hz/s2
1Dh = 750 Hz/s2
1Eh = 1000 Hz/s2
1Fh = No Limit (32767) Hz/s2
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Table 8-30. MOTOR_STARTUP2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
12-8
OPN_CL_HANDOFF_TH R/W
R
0h
Open to closed loop handoff threshold
0h = 1 Hz
1h = 4 Hz
2h = 8 Hz
3h = 12 Hz
4h = 16 Hz
5h = 20 Hz
6h = 24 Hz
7h = 28 Hz
8h = 32 Hz
9h = 36 Hz
Ah = 40 Hz
Bh = 45 Hz
Ch = 50 Hz
Dh = 55 Hz
Eh = 60 Hz
Fh = 65 Hz
10h = 70 Hz
11h = 75 Hz
12h = 80 Hz
13h = 85 Hz
14h = 90 Hz
15h = 100 Hz
16h = 150 Hz
17h = 200 Hz
18h = 250 Hz
19h = 300 Hz
1Ah = 350 Hz
1Bh = 400 Hz
1Ch = 450 Hz
1Dh = 500 Hz
1Eh = 550 Hz
1Fh = 600 Hz
7
6
AUTO_HANDOFF
R/W
0h
0h
Auto handoff enable
0h = Disable Auto Handoff (and use OPN_CL_HANDOFF_THR)
1h = Enable Auto Handoff
FIRST_CYCLE_FREQ_S R/W
EL
First cycle frequency select
0h = Defined by SLOW_FIRST_CYC_FREQ
1h = 0 Hz
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Table 8-30. MOTOR_STARTUP2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
5-2
MIN_DUTY
R/W
0h
Min operational duty cycle
0h = 1.5 %
1h = 2 %
2h = 3 %
3h = 4 %
4h = 5 %
5h = 6 %
6h = 7 %
7h = 8 %
8h = 9 %
9h = 10 %
Ah = 12 %
Bh = 15 %
Ch = 17.5 %
Dh = 20 %
Eh = 25 %
Fh = 30 %
1-0
RESERVED
R
X
Reserved
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8.7.1.4 CLOSED_LOOP1 Register (Address = 86h) [Reset = 00000000h]
CLOSED_LOOP1 is shown in CLOSED_LOOP1 Register and described in CLOSED_LOOP1 Register Field
Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure close loop settings1
Figure 8-57. CLOSED_LOOP1 Register
31
30
29
28
27
26
25
17
24
16
PARITY
R/W-0h
COMM_CONTROL
R/W-0h
CL_ACC
R/W-0h
23
22
21
13
5
20
19
18
CL_DEC_CON
FIG
CL_DEC
PWM_FREQ_OUT
R/W-0h
15
R/W-0h
12
R/W-0h
14
11
3
10
9
8
PWM_FREQ_OUT
PWM_MODUL
PWM_MODE LD_ANGLE_PO
LARITY
LD_ANGLE
R/W-0h
6
R/W-0h
R/W-0h
2
R/W-0h
1
R/W-0h
7
4
0
LD_ANGLE
R/W-0h
RESERVED
R/W-0h
Table 8-31. CLOSED_LOOP1 Register Field Descriptions
Bit
31
Field
Type
R/W
R/W
Reset
Description
PARITY
0h
Parity bit
30-29
COMM_CONTROL
0h
Trapezoidal commutation mode
0h = 120° Commutation
1h = Variable commutation between 120° and 150°
2h = N/A
3h = N/A
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Table 8-31. CLOSED_LOOP1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
28-24
CL_ACC
R/W
0h
Closed loop acceleration rate
0h = 0.005 V/s
1h = 0.01 V/s
2h = 0.025 V/s
3h = 0.05 V/s
4h = 0.1 V/s
5h = 0.25 V/s
6h = 0.5 V/s
7h = 1 V/s
8h = 2.5 V/s
9h = 5 V/s
Ah = 7.5 V/s
Bh = 10 V/s
Ch = 12.5 V/s
Dh = 15 V/s
Eh = 20 V/s
Fh = 30 V/s
10h = 40 V/s
11h = 50 V/s
12h = 60 V/s
13h = 75 V/s
14h = 100 V/s
15h = 125 V/s
16h = 150 V/s
17h = 175 V/s
18h = 200 V/s
19h = 250 V/s
1Ah = 300 V/s
1Bh = 400 V/s
1Ch = 500 V/s
1Dh = 750 V/s
1Eh = 1000 V/s
1Fh = 32767 V/s
23
CL_DEC_CONFIG
R/W
0h
Closed loop decel configuration
0h = Close loop deceleration defined by CL_DEC
1h = Close loop deceleration defined by CL_ACC
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Table 8-31. CLOSED_LOOP1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
22-18
CL_DEC
R/W
0h
Closed loop deceleration rate
0h = 0.005 V/s
1h = 0.01 V/s
2h = 0.025 V/s
3h = 0.05 V/s
4h = 0.1 V/s
5h = 0.25 V/s
6h = 0.5 V/s
7h = 1 V/s
8h = 2.5 V/s
9h = 5 V/s
Ah = 7.5 V/s
Bh = 10 V/s
Ch = 12.5 V/s
Dh = 15 V/s
Eh = 20 V/s
Fh = 30 V/s
10h = 40 V/s
11h = 50 V/s
12h = 60 V/s
13h = 75 V/s
14h = 100 V/s
15h = 125 V/s
16h = 150 V/s
17h = 175 V/s
18h = 200 V/s
19h = 250 V/s
1Ah = 300 V/s
1Bh = 400 V/s
1Ch = 500 V/s
1Dh = 750 V/s
1Eh = 1000 V/s
1Fh = 32767 V/s
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Table 8-31. CLOSED_LOOP1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
17-13
PWM_FREQ_OUT
R/W
0h
Output PWM switching frequency
0h = 5 kHz
1h = 6 kHz
2h = 7 kHz
3h = 8 kHz
4h = 9 kHz
5h = 10 kHz
6h = 11 kHz
7h = 12 kHz
8h = 13 kHz
9h = 14 kHz
Ah = 15 kHz
Bh = 16 kHz
Ch = 17 kHz
Dh = 18 kHz
Eh = 19 kHz
Fh = 20 kHz
10h = 25 kHz
11h = 30 kHz
12h = 35 kHz
13h = 40 kHz
14h = 45 kHz
15h = 50 kHz
16h = 55 kHz
17h = 60 kHz
18h = 65 kHz
19h = 70 kHz
1Ah = 75 kHz
1Bh = 80 kHz
1Ch = 85 kHz
1Dh = 90 kHz
1Eh = 95 kHz
1Fh = 100 kHz
12-11
PWM_MODUL
R/W
0h
PWM modulation.
0h = High-Side Modulation
1h = Low-Side Modulation
2h = Mixed Modulation
3h = N/A
10
9
PWM_MODE
R/W
R/W
0h
0h
PWM mode
0h = Single Ended Mode
1h = Complementary Mode
LD_ANGLE_POLARITY
Polarity of applied lead angle
0h = Negative
1h = Positive
8-1
0
LD_ANGLE
RESERVED
R/W
R/W
0h
0h
Lead Angle {Lead Angle (deg) = LD_ANGLE * 0.12}
Reserved
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8.7.1.5 CLOSED_LOOP2 Register (Address = 88h) [Reset = 00000000h]
CLOSED_LOOP2 is shown in CLOSED_LOOP2 Register and described in CLOSED_LOOP2 Register Field
Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure close loop settings2
Figure 8-58. CLOSED_LOOP2 Register
31
30
29
21
13
5
28
27
FG_DIV_FACTOR
R/W-0h
26
25
17
24
PARITY
R/W-0h
FG_SEL
R/W-0h
FG_CONFIG
R/W-0h
23
22
20
19
18
10
2
16
FG_BEMF_THR
R/W-0h
MTR_STOP
R/W-0h
MTR_STOP_BRK_TIME
R/W-0h
15
14
12
11
9
8
MTR_STOP_BRK_TIME
R/W-0h
ACT_SPIN_BRK_THR
R/W-0h
BRAKE_DUTY_THRESHOLD
R/W-0h
7
6
4
3
1
0
AVS_EN
R/W-0h
CBC_ILIMIT
R/W-0h
RESERVED
R/W-0h
Table 8-32. CLOSED_LOOP2 Register Field Descriptions
Bit
31
Field
Type
R/W
R/W
Reset
Description
PARITY
FG_SEL
0h
Parity bit
30-29
0h
FG mode select
0h = Output FG in open loop and closed loop
1h = Output FG in only closed loop
2h = Output FG in open loop for the first try.
3h = N/A
28-25
FG_DIV_FACTOR
R/W
0h
FG division factor
0h = Divide by 3 (2-pole motor mechanical speed/3)
1h = Divide by 1 (2-pole motor mechanical speed)
2h = Divide by 2 (4-pole motor mechanical speed)
3h = Divide by 3 (6-pole motor mechanical speed)
4h = Divide by 4 (8-pole motor mechanical speed)
5h = Divide by 5 (10-pole motor mechanical speed)
6h = Divide by 6 (12-pole motor mechanical speed)
7h = Divide by 7 (14-pole motor mechanical speed)
8h = Divide by 8 (16-pole motor mechanical speed)
9h = Divide by 9 (18-pole motor mechanical speed)
Ah = Divide by 10 (20-pole motor mechanical speed)
Bh = Divide by 11 (22-pole motor mechanical speed)
Ch = Divide by 12 (24-pole motor mechanical speed)
Dh = Divide by 13 (26-pole motor mechanical speed)
Eh = Divide by 14 (28-pole motor mechanical speed)
Fh = Divide by 15 (30-pole motor mechanical speed)
24
FG_CONFIG
R/W
0h
FG output configuration
0h = FG active till speed drops below BEMF threshold defined by
FG_BEMF_THR
1h = FG active as long as motor is driven
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Table 8-32. CLOSED_LOOP2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
23-21
FG_BEMF_THR
R/W
0h
FG output BEMF threshold
0h = +/- 1mV
1h = +/- 2mV
2h = +/- 5mV
3h = +/- 10mV
4h = +/- 20mV
5h = +/- 30mV
6h = N/A
7h = N/A
20-18
MTR_STOP
R/W
0h
Motor stop method
0h = Hi-z
1h = Recirculation
2h = Low-side braking
3h = High-side braking
4h = Active spin down
5h = N/A
6h = N/A
7h = N/A
17-14
MTR_STOP_BRK_TIME R/W
0h
Brake time during motor stop
0h = 1 ms
1h = 2 ms
2h = 5 ms
3h = 10 ms
4h = 15 ms
5h = 25 ms
6h = 50 ms
7h = 75 ms
8h = 100 ms
9h = 250 ms
Ah = 500 ms
Bh = 1000 ms
Ch = 2500 ms
Dh = 5000 ms
Eh = 10000 ms
Fh = 15000 ms
13-11
ACT_SPIN_BRK_THR
R/W
0h
Duty cycle threshold for motor stop using active spin down, low- and
high-side braking
0h = Immediate
1h = 50 %
2h = 25 %
3h = 15 %
4h = 10 %
5h = 7.5 %
6h = 5 %
7h = 2.5 %
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Table 8-32. CLOSED_LOOP2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
10-8
BRAKE_DUTY_THRESH R/W
OLD
0h
Duty cycle threshold for BRAKE pin based low-side braking
0h = Immediate
1h = 50 %
2h = 25 %
3h = 15 %
4h = 10 %
5h = 7.5 %
6h = 5 %
7h = 2.5 %
7
AVS_EN
R/W
R/W
0h
0h
AVS enable
0h = Disable
1h = Enable
6-3
CBC_ILIMIT
Cycle by Cycle (CBC) current limit (CBC current limit (A) =
CBC_ILIMIT / CSA_GAIN)
0h = N/A
1h = 0.1 V
2h = 0.2 V
3h = 0.3 V
4h = 0.4 V
5h = 0.5 V
6h = 0.6 V
7h = 0.7 V
8h = 0.8 V
9h = 0.9 V
Ah = 1 V
Bh = 1.1 V
Ch = 1.2 V
Dh = 1.3 V
Eh = 1.4 V
Fh = 1.5 V
2-0
RESERVED
R/W
0h
Reserved
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8.7.1.6 CLOSED_LOOP3 Register (Address = 8Ah) [Reset = 14000000h]
CLOSED_LOOP3 is shown in CLOSED_LOOP3 Register and described in CLOSED_LOOP3 Register Field
Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure close loop settings3
Figure 8-59. CLOSED_LOOP3 Register
31
30
29
28
27
26
25
24
PARITY
DYN_DGS_FILT_COUNT
R/W-0h
DYN_DGS_UPPER_LIM
R/W-2h
DYN_DGS_LOWER_LIM
R/W-2h
INTEG_CYCL_
THR_LOW
R/W-0h
23
R/W-0h
16
22
21
20
19
18
17
INTEG_CYCL_
THR_LOW
INTEG_CYCL_THR_HIGH
INTEG_DUTY_THR_LOW
INTEG_DUTY_THR_HIGH
BEMF_THRES
HOLD2
R/W-0h
15
R/W-0h
R/W-0h
R/W-0h
R/W-0h
8
14
6
13
12
4
11
3
10
2
9
BEMF_THRESHOLD2
R/W-0h
BEMF_THRESHOLD1
R/W-0h
7
5
1
0
BEMF_THRESHOLD1
INTEG_ZC_ME
THOD
DEGAUSS_MAX_WIN
DYN_DEGAUS
S_EN
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 8-33. CLOSED_LOOP3 Register Field Descriptions
Bit
31
Field
Type
Reset
Description
PARITY
R/W
0h
Parity bit
30-29
DYN_DGS_FILT_COUNT R/W
DYN_DGS_UPPER_LIM R/W
DYN_DGS_LOWER_LIM R/W
INTEG_CYCL_THR_LOW R/W
0h
Number of samples needed for dynamic degauss check
0h = 2
1h = 3
2h = 4
3h = 5
28-27
26-25
24-23
2h
2h
0h
Dynamic degauss voltage upper bound
0h = (VM - 0.09) V
1h = (VM - 0.12) V
2h = (VM - 0.15) V
3h = (VM - 0.18) V
Dynamic degauss voltage lower bound
0h = 0.03 V
1h = 0.06 V
2h = 0.09 V
3h = 0.12 V
Number of BEMF samples per 30° below which commutation method
switches from integration to ZC
0h = 3
1h = 4
2h = 6
3h = 8
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Table 8-33. CLOSED_LOOP3 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
22-21
INTEG_CYCL_THR_HIG R/W
H
0h
Number of BEMF samples per 30° above which commutation
method switches from ZC to integration
0h = 4
1h = 6
2h = 8
3h = 10
20-19
18-17
INTEG_DUTY_THR_LOW R/W
0h
0h
Duty cycle below which commutation method switches from
integration to ZC
0h = 12 %
1h = 15 %
2h = 18 %
3h = 20 %
INTEG_DUTY_THR_HIG R/W
H
Duty cycle above which commutation method switches from ZC to
integration
0h = 12 %
1h = 15 %
2h = 18 %
3h = 20 %
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Table 8-33. CLOSED_LOOP3 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
16-11
BEMF_THRESHOLD2
R/W
0h
BEMF threshold for integration based commutation during falling
floating phase voltage
0h = 0
1h = 25
2h = 50
3h = 75
4h = 100
5h = 125
6h = 150
7h = 175
8h = 200
9h = 225
Ah = 250
Bh = 275
Ch = 300
Dh = 325
Eh = 350
Fh = 375
10h = 400
11h = 425
12h = 450
13h = 475
14h = 500
15h = 525
16h = 550
17h = 575
18h = 600
19h = 625
1Ah = 650
1Bh = 675
1Ch = 700
1Dh = 725
1Eh = 750
1Fh = 775
20h = 800
21h = 850
22h = 900
23h = 950
24h = 1000
25h = 1050
26h = 1100
27h = 1150
28h = 1200
29h = 1250
2Ah = 1300
2Bh = 1350
2Ch = 1400
2Dh = 1450
2Eh = 1500
2Fh = 1550
30h = 1600
31h = 1700
32h = 1800
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Table 8-33. CLOSED_LOOP3 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
33h = 1900
34h = 2000
35h = 2100
36h = 2200
37h = 2300
38h = 2400
39h = 2600
3Ah = 2800
3Bh = 3000
3Ch = 3200
3Dh = 3400
3Eh = 3600
3Fh = 3800
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Table 8-33. CLOSED_LOOP3 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
10-5
BEMF_THRESHOLD1
R/W
0h
BEMF threshold for integration based commutation during rising
floating phase voltage
0h = 0
1h = 25
2h = 50
3h = 75
4h = 100
5h = 125
6h = 150
7h = 175
8h = 200
9h = 225
Ah = 250
Bh = 275
Ch = 300
Dh = 325
Eh = 350
Fh = 375
10h = 400
11h = 425
12h = 450
13h = 475
14h = 500
15h = 525
16h = 550
17h = 575
18h = 600
19h = 625
1Ah = 650
1Bh = 675
1Ch = 700
1Dh = 725
1Eh = 750
1Fh = 775
20h = 800
21h = 850
22h = 900
23h = 950
24h = 1000
25h = 1050
26h = 1100
27h = 1150
28h = 1200
29h = 1250
2Ah = 1300
2Bh = 1350
2Ch = 1400
2Dh = 1450
2Eh = 1500
2Fh = 1550
30h = 1600
31h = 1700
32h = 1800
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Table 8-33. CLOSED_LOOP3 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
33h = 1900
34h = 2000
35h = 2100
36h = 2200
37h = 2300
38h = 2400
39h = 2600
3Ah = 2800
3Bh = 3000
3Ch = 3200
3Dh = 3400
3Eh = 3600
3Fh = 3800
4
INTEG_ZC_METHOD
DEGAUSS_MAX_WIN
R/W
R/W
0h
0h
Commutation method select
0h = ZC based
1h = Integration based
3-1
Maximum degauss window
0h = 22.5°
1h = 10°
2h = 15°
3h = 18°
4h = 30°
5h = 37.5°
6h = 45°
7h = 60°
0
DYN_DEGAUSS_EN
R/W
0h
Dynamic degauss detection
0h = Disable
1h = Enable
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8.7.1.7 CLOSED_LOOP4 Register (Address = 8Ch) [Reset = 00000000h]
CLOSED_LOOP4 is shown in CLOSED_LOOP4 Register and described in CLOSED_LOOP4 Register Field
Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure close loop settings4
Figure 8-60. CLOSED_LOOP4 Register
31
30
29
28
27
26
25
24
16
PARITY
R/W-0h
RESERVED
R/W-0h
23
15
7
22
21
20
19
18
17
RESERVED
R/W-0h
WCOMP_BLAN
K_EN
FAST_DEC_DUTY_WIN
R/W-0h
11
R/W-0h
9
14
13
5
12
4
10
8
FAST_DEC_DUTY_THR
DYN_BRK_CURR_LOW_LIM
DYNAMIC_BRK
_CURR
R/W-0h
6
R/W-0h
R/W-0h
0
3
2
1
FAST_DECEL_
EN
FAST_DECEL_CURR_LIM
FAST_BRK_DELTA
R/W-0h
R/W-0h
R/W-0h
Table 8-34. CLOSED_LOOP4 Register Field Descriptions
Bit
31
Field
Type
R/W
R/W
R/W
Reset
Description
PARITY
0h
Parity bit
30-20
19
RESERVED
0h
Reserved
WCOMP_BLANK_EN
0h
Enable WCOMP blanking during fast deceleration
0h = Disable
1h = Enable
18-16
FAST_DEC_DUTY_WIN
R/W
0h
Fast deceleration duty window
0h = 0 %
1h = 2.5 %
2h = 5 %
3h = 7.5 %
4h = 10 %
5h = 15 %
6h = 20 %
7h = 25 %
15-13
FAST_DEC_DUTY_THR R/W
0h
Fast deceleration duty threshold
0h = 100 %
1h = 95 %
2h = 90 %
3h = 85 %
4h = 80 %
5h = 75 %
6h = 70%
7h = 65 %
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Table 8-34. CLOSED_LOOP4 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
12-9
DYN_BRK_CURR_LOW_ R/W
LIM
0h
Fast deceleration dynamic current limit lower threshold (Deceleration
current lower threshold (A) = DYN_BRK_CURR_LOW_LIM /
CSA_GAIN)
0h = N/A
1h = 0.1V
2h = 0.2 V
3h = 0.3 V
4h = 0.4 V
5h = 0.5 V
6h = 0.6 V
7h = 0.7 V
8h = 0.8 V
9h = 0.9 V
Ah = 1 V
Bh = 1.1 V
Ch = 1.2 V
Dh = 1.3 V
Eh = 1.4 V
Fh = 1.5 V
8
7
DYNAMIC_BRK_CURR
FAST_DECEL_EN
R/W
R/W
0h
0h
0h
Enable dynamic decrease in current limit during fast deceleration
0h = Disable
1h = Enable
Fast deceleration enable
0h = Disable
1h = Enable
6-3
FAST_DECEL_CURR_LI R/W
M
Deceleration current threshold (Fast Deceleration current limit upper
threshold (A) = FAST_DECEL_CURR_LIM / CSA_GAIN)
0h = N/A
1h = 0.1V
2h = 0.2 V
3h = 0.3 V
4h = 0.4 V
5h = 0.5 V
6h = 0.6 V
7h = 0.7 V
8h = 0.8 V
9h = 0.9 V
Ah = 1 V
Bh = 1.1 V
Ch = 1.2 V
Dh = 1.3 V
Eh = 1.4 V
Fh = 1.5 V
2-0
FAST_BRK_DELTA
R/W
0h
Fast deceleration exit speed delta
0h = 0.5 %
1h = 1 %
2h = 1.5 %
3h = 2 %
4h = 2.5 %
5h = 3 %
6h = 4 %
7h = 5 %
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8.7.1.8 CONST_SPEED Register (Address = 8Eh) [Reset = 00000000h]
CONST_SPEED is shown in CONST_SPEED Register and described in CONST_SPEED Register Field
Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure Constant speed mode settings
Figure 8-61. CONST_SPEED Register
31
30
29
28
20
12
27
SPD_POWER_KP
R/W-0h
26
25
17
24
16
8
PARITY
R/W-0h
RESERVED
R/W-0h
23
15
7
22
21
19
18
SPD_POWER_KP
R/W-0h
SPD_POWER_KI
R/W-0h
14
13
11
10
9
SPD_POWER_KI
R/W-0h
6
5
4
3
2
1
0
SPD_POWER_V_MAX
R/W-0h
SPD_POWER_V_MIN
R/W-0h
CLOSED_LOOP_MODE
R/W-0h
Table 8-35. CONST_SPEED Register Field Descriptions
Bit
31
Field
Type
R/W
R/W
R/W
R/W
R/W
Reset
Description
PARITY
0h
Parity bit
30
RESERVED
0h
Reserved
29-20
19-8
7-5
SPD_POWER_KP
SPD_POWER_KI
SPD_POWER_V_MAX
0h
Speed/ Power loop Kp (Kp = SPD_LOOP_KP / 10000)
Speed/ Power loop Ki (Ki = SPD_LOOP_KI / 1000000)
0h
0h
Upper saturation limit for speed/ power loop
0h = 100 %
1h = 95 %
2h = 90 %
3h = 85 %
4h = 80 %
5h = 75 %
6h = 70%
7h = 65 %
4-2
SPD_POWER_V_MIN
R/W
0h
Lower saturation limit for speed/power loop
0h = 0 %
1h = 2.5 %
2h = 5 %
3h = 7.5 %
4h = 10 %
5h = 15 %
6h = 20 %
7h = 25 %
1-0
CLOSED_LOOP_MODE R/W
0h
Closed loop mode
0h = Disabled
1h = Speed Loop
2h = Power Loop
3h = Reserved
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8.7.1.9 CONST_PWR Register (Address = 90h) [Reset = 00000000h]
CONST_PWR is shown in CONST_PWR Register and described in CONST_PWR Register Field Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure Constant power mode settings
Figure 8-62. CONST_PWR Register
31
30
22
14
29
21
13
28
20
12
27
26
18
10
25
17
9
24
16
8
PARITY
R/W-0h
MAX_SPEED
R/W-0h
23
19
MAX_SPEED
R/W-0h
15
11
MAX_SPEED DEADTIME_CO
MP_EN
MAX_POWER
R/W-0h
R/W-0h
7
R/W-0h
6
5
4
3
2
1
0
MAX_POWER
R/W-0h
CONST_POWER_LIMIT_HYST
R/W-0h
CONST_POWER_MODE
R/W-0h
Table 8-36. CONST_PWR Register Field Descriptions
Bit
31
Field
Type
R/W
R/W
R/W
Reset
Description
PARITY
0h
Parity bit
30-15
14
MAX_SPEED
DEADTIME_COMP_EN
0h
Maximum Speed (Maximum Speed (Hz) = MAX_SPEED / 16)
0h
Enable dead time compensation
0h = Disable
1h = Enable
13-4
3-2
MAX_POWER
R/W
0h
0h
Maximum power (Maximum power (W) = MAX_POWER / 4)
CONST_POWER_LIMIT_ R/W
HYST
Hysteresis for input power regulation
0h = 5 %
1h = 7.5 %
2h = 10 %
3h = 12.5 %
1-0
CONST_POWER_MODE R/W
0h
Input power regulation mode
0h = Disabled
1h = Closed Loop Power Control
2h = Power Limit Control
3h = Reserved
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8.7.1.10 150_DEG_TWO_PH_PROFILE Register (Address = 96h) [Reset = 00000000h]
150_DEG_TWO_PH_PROFILE is shown in 150_DEG_TWO_PH_PROFILE Register and described in
150_DEG_TWO_PH_PROFILE Register Field Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure 150 degree modulation TWO phase duty
Figure 8-63. 150_DEG_TWO_PH_PROFILE Register
31
30
29
28
27
26
25
24
PARITY
TWOPH_STEP0
TWOPH_STEP1
TWOPH_STEP
2
R/W-0h
23
R/W-0h
21
R/W-0h
18
R/W-0h
16
22
20
19
17
TWOPH_STEP2
R/W-0h
TWOPH_STEP3
R/W-0h
TWOPH_STEP4
R/W-0h
15
14
13
5
12
11
10
2
9
8
TWOPH_STEP5
R/W-0h
TWOPH_STEP6
R/W-0h
TWOPH_STEP7
R/W-0h
7
6
4
3
1
0
TWOPH_STEP
7
RESERVED
R/W-0h
R/W-0h
Table 8-37. 150_DEG_TWO_PH_PROFILE Register Field Descriptions
Bit
31
Field
Type
R/W
R/W
Reset
Description
PARITY
0h
Parity bit
30-28
TWOPH_STEP0
0h
150° modulation , Two ph. - step duty - 0
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
27-25
TWOPH_STEP1
R/W
0h
150° modulation , Two ph. - step duty - 1
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
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Table 8-37. 150_DEG_TWO_PH_PROFILE Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
24-22
TWOPH_STEP2
R/W
0h
150° modulation, Two ph. - step duty - 2
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
21-19
18-16
15-13
12-10
TWOPH_STEP3
TWOPH_STEP4
TWOPH_STEP5
TWOPH_STEP6
R/W
R/W
R/W
R/W
0h
0h
0h
0h
150° modulation, Two ph. - step duty - 3
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
150° modulation, Two ph. - step duty - 4
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
150° modulation, Two ph. - step duty - 5
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
150° modulation, Two ph. - step duty - 6
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
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Table 8-37. 150_DEG_TWO_PH_PROFILE Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
9-7
TWOPH_STEP7
R/W
0h
150° modulation, Two ph. - step duty - 7
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
6-0
RESERVED
R/W
0h
reserved bits for algo parameter update
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8.7.1.11 150_DEG_THREE_PH_PROFILE Register (Address = 98h) [Reset = 00000000h]
150_DEG_THREE_PH_PROFILE is shown in 150_DEG_THREE_PH_PROFILE Register and described in
150_DEG_THREE_PH_PROFILE Register Field Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure 150 degree modulation Three phase duty
Figure 8-64. 150_DEG_THREE_PH_PROFILE Register
31
30
29
28
27
26
25
17
24
PARITY
THREEPH_STEP0
THREEPH_STEP1
THREEPH_ST
EP2
R/W-0h
23
R/W-0h
21
R/W-0h
18
R/W-0h
16
22
20
19
11
THREEPH_STEP2
R/W-0h
THREEPH_STEP3
R/W-0h
THREEPH_STEP4
R/W-0h
15
14
13
5
12
10
9
8
THREEPH_STEP5
R/W-0h
THREEPH_STEP6
R/W-0h
THREEPH_STEP7
R/W-0h
7
6
4
3
2
1
0
THREEPH_ST
EP7
LEAD_ANGLE_150DEG_ADV
RESERVED
R/W-0h
R/W-0h
R/W-0h
Table 8-38. 150_DEG_THREE_PH_PROFILE Register Field Descriptions
Bit
31
Field
Type
R/W
R/W
Reset
Description
PARITY
0h
Parity bit
30-28
THREEPH_STEP0
0h
150° modulation, Three ph. - step duty - 0
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
27-25
THREEPH_STEP1
R/W
0h
150° modulation, Three ph. - step duty - 1
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
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Table 8-38. 150_DEG_THREE_PH_PROFILE Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
24-22
THREEPH_STEP2
R/W
0h
150° modulation, Three ph. - step duty - 2
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
21-19
18-16
15-13
12-10
THREEPH_STEP3
THREEPH_STEP4
THREEPH_STEP5
THREEPH_STEP6
R/W
R/W
R/W
R/W
0h
0h
0h
0h
150° modulation, Three ph. - step duty - 3
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
150° modulation, Three ph. - step duty - 4
0h = 0.0 %
1h = 0.5 %
2h = 0.75 %
3h = 0.8375 %
4h = 0.875 %
5h = 0.9375 %
6h = 0.975 %
7h = 0.99 %
150° modulation, Three ph. - step duty - 5
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
150° modulation, Three ph. - step duty - 6
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
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Table 8-38. 150_DEG_THREE_PH_PROFILE Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
9-7
THREEPH_STEP7
R/W
0h
150° modulation, Three ph. - step duty - 7
0h = 0%
1h = 50 %
2h = 75 %
3h = 83.75 %
4h = 87.5 %
5h = 93.75 %
6h = 97.5 %
7h = 99 %
6-5
4-0
LEAD_ANGLE_150DEG_ R/W
ADV
0h
0h
Angle advance for 150° modulation
0h = 0°
1h = 5°
2h = 10°
3h = 15°
RESERVED
R/W
Reserved
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8.7.1.12 TRAP_CONFIG1 Register (Address = 9Ah) [Reset = 00000000h]
TRAP_CONFIG1 is shown in TRAP_CONFIG1 Register and described in TRAP_CONFIG1 Register Field
Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure internal Algorithm Variables
Figure 8-65. TRAP_CONFIG1 Register
31
30
29
21
13
28
27
26
18
10
25
17
24
16
8
PARITY
R/W-0h
RESERVED
R/W-0h
RESERVED
R/W-0h
RESERVED
R/W-0h
23
22
20
19
OL_HANDOFF_CYCLES
R/W-0h
RESERVED
R/W-0h
AVS_NEG_CURR_LIMIT
R/W-0h
15
14
12
11
9
AVS_LIMIT_HY
ST
ISD_BEMF_THR
ISD_CYCLE_THR
R/W-0h
7
R/W-0h
4
R/W-0h
6
5
3
2
1
0
ISD_CYCLE_T
HR
RESERVED
RESERVED
ZC_ANGLE_OL_THR
FAST_STARTUP_DIV_FACTOR
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 8-39. TRAP_CONFIG1 Register Field Descriptions
Bit
Field
PARITY
Type
R/W
R/W
R/W
R/W
Reset
Description
31
0h
Parity bit
30-29
28-26
25-24
23-22
RESERVED
RESERVED
RESERVED
0h
Reserved
Reserved
Reserved
0h
0h
OL_HANDOFF_CYCLES R/W
0h
Open loop handoff cycles
0h = 3
1h = 6
2h = 12
3h = 24
21-19
18-16
RESERVED
R/W
0h
0h
Reserved
AVS_NEG_CURR_LIMIT R/W
AVS negative current limit (AVS negative current limit (A) =
(AVS_NEG_CURRENT_LIMIT * 3 /4095) / CSA_GAIN)
0h = 0
1h = -40
2h = -30
3h = -20
4h = -10
5h = 10
6h = 20
7h = 30
15
AVS_LIMIT_HYST
R/W
0h
AVS current hysteresis (AVS positive current limit (A) =
((AVS_LIMIT_HYST + AVS_NEG_CURR_LIMIT) * 3 /4095) /
CSA_GAIN)
0h = 20
1h = 10
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Table 8-39. TRAP_CONFIG1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
14-10
ISD_BEMF_THR
R/W
0h
ISD BEMF threshold (ISD BEMF threshold = 200 * ISD_BEMF_THR)
0h = 0
1h = 200
2h = 400
3h = 600
4h = 800
5h = 1000
6h = 1200
7h = 1400
8h = 1600
9h = 1800
Ah = 2000
Bh = 2200
Ch = 2400
Dh = 2600
Eh = 2800
Fh = 3000
10h = 3200
11h = 3400
12h = 3600
13h = 3800
14h = 4000
15h = 4200
16h = 4400
17h = 4600
18h = 4800
19h = 5000
1Ah = 5200
1Bh = 5400
1Ch = 5600
1Dh = 5800
1Eh = 6000
1Fh = 6200
9-7
ISD_CYCLE_THR
R/W
0h
ISD cycle threshold
0h = 2,
1h = 5,
2h = 8,
3h = 11,
4h = 14,
5h = 17,
6h = 20,
7h = 23
6
RESERVED
R/W
R/W
R/W
0h
0h
0h
Reserved
Reserved
5-4
3-2
RESERVED
ZC_ANGLE_OL_THR
Angle above which the ZC detection is done during OL
0h = 5°
1h = 8°
2h = 12°
3h = 15°
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Table 8-39. TRAP_CONFIG1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
1-0
FAST_STARTUP_DIV_FA R/W
CTOR
0h
Dynamic A1, A2 change rate
0h = 1
1h = 2
2h = 4
3h = 8
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8.7.1.13 TRAP_CONFIG2 Register (Address = 9Ch) [Reset = 00200000h]
TRAP_CONFIG2 is shown in TRAP_CONFIG2 Register and described in TRAP_CONFIG2 Register Field
Descriptions.
Return to the ALGORITHM_CONFIGURATION Registers.
Register to configure internal Algorithm Variables
Figure 8-66. TRAP_CONFIG2 Register
31
30
29
28
20
12
4
27
26
18
10
2
25
24
16
8
PARITY
R/W-0h
TBLANK
R/W-0h
TPWDTH
R/W-0h
23
22
21
19
17
RESERVED
R/W-0h
RESERVED
R/W-0h
RESERVED
R/W-1h
ALIGN_DUTY
R/W-0h
RESERVED
R/W-0h
15
14
13
11
9
1
RESERVED
R/W-0h
7
6
5
3
0
RESERVED
R/W-0h
Table 8-40. TRAP_CONFIG2 Register Field Descriptions
Bit
31
Field
PARITY
Type
R/W
R/W
Reset
Description
0h
Parity bit
30-27
TBLANK
0h
Blanking time after PWM edge
0h = 0 µs
1h = 1 µs
2h = 2 µs
3h = 3 µs
4h = 4 µs
5h = 5 µs
6h = 6 µs
7h = 7 µs
8h = 8 µs
9h = 9 µs
Ah = 10 µs
Bh = 11 µs
Ch = 12 µs
Dh = 13 µs
Eh = 14 µs
Fh = 15 µs
26-24
TPWDTH
R/W
0h
Comparator deglitch time
0h = 0 µs
1h = 1 µs
2h = 2 µs
3h = 3 µs
4h = 4 µs
5h = 5 µs
6h = 6 µs
7h = 7 µs
23
RESERVED
R/W
0h
Reserved
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Table 8-40. TRAP_CONFIG2 Register Field Descriptions (continued)
Bit
22
Field
Type
R/W
R/W
R/W
Reset
Description
Reserved
Reserved
RESERVED
RESERVED
ALIGN_DUTY
0h
21
1h
20-18
0h
Duty cycle limit during align
0h = 10 %
1h = 15 %
2h = 20 %
3h = 25 %
4h = 30 %
5h = 40 %
6h = 50 %
7h = 100 %
17-0
RESERVED
R/W
0h
Reserved
8.7.2 Fault_Configuration Registers
FAULT_CONFIGURATION Registers lists the memory-mapped registers for the Fault_Configuration registers.
All register offset addresses not listed in FAULT_CONFIGURATION Registers should be considered as reserved
locations and the register contents should not be modified.
Table 8-41. FAULT_CONFIGURATION Registers
Address Acronym
Register Name
Section
92h
94h
FAULT_CONFIG1
FAULT_CONFIG2
Fault configuration 1
Fault configuration 2
Section 8.7.2.1
Section 8.7.2.2
Complex bit access types are encoded to fit into small table cells. Fault_Configuration Access Type Codes
shows the codes that are used for access types in this section.
Table 8-42. Fault_Configuration Access Type Codes
Access Type
Read Type
R
Code
Description
R
Read
Write Type
W
W
Write
Reset or Default Value
-n
Value after reset or the default
value
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8.7.2.1 FAULT_CONFIG1 Register (Address = 92h) [Reset = 00000000h]
FAULT_CONFIG1 is shown in FAULT_CONFIG1 Register and described in FAULT_CONFIG1 Register Field
Descriptions.
Return to the FAULT_CONFIGURATION Registers.
Register to configure fault settings1
Figure 8-67. FAULT_CONFIG1 Register
31
30
29
28
27
26
25
24
16
PARITY
R/W-0h
RESERVED
R/W-0h
NO_MTR_DEG_TIME
R/W-0h
CBC_ILIMIT_MODE
R/W-0h
23
22
14
6
21
20
19
18
17
CBC_ILIMIT_M
ODE
LOCK_ILIMIT
R/W-0h
LOCK_ILIMIT_MODE
R/W-0h
15
R/W-0h
13
12
11
3
10
2
9
8
0
LOCK_ILIMIT_
MODE
LOCK_ILIMIT_DEG
CBC_RETRY_PWM_CYC
R/W-0h
R/W-0h
R/W-0h
7
5
4
1
RESERVED
R/W-0h
MTR_LCK_MODE
R/W-0h
LCK_RETRY
R/W-0h
Table 8-43. FAULT_CONFIG1 Register Field Descriptions
Bit
31
Field
PARITY
Type
R/W
R/W
R/W
Reset
Description
0h
Parity bit
30
RESERVED
0h
Reserved
29-27
NO_MTR_DEG_TIME
0h
No motor detect deglitch time
0h = 1 ms
1h = 10 ms
2h = 25 ms
3h = 50 ms
4h = 100 ms
5h = 250 ms
6h = 500 ms
7h = 1000 ms
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Table 8-43. FAULT_CONFIG1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
26-23
CBC_ILIMIT_MODE
R/W
0h
Cycle by cycle current limit
0h = Automatic recovery next PWM cycle; nFAULT active; driver is in
recirculation mode
1h = Automatic recovery next PWM cycle; nFAULT inactive; driver is
in recirculation mode
2h = Automatic recovery if VSOX < ILIMIT; nFAULT active; driver is
in recirculation mode (Only available with high-side modulation)
3h = Automatic recovery if VSOX < ILIMIT; nFAULT inactive; driver is
in recirculation mode (Only available with high-side modulation)
4h = Automatic recovery after CBC_RETRY_PWM_CYC; nFAULT
active; driver is in recirculation mode
5h = Automatic recovery after CBC_RETRY_PWM_CYC; nFAULT
inactive; driver is in recirculation mode
6h = VSOX > ILIMIT is report only but no action is taken
7h = Cycle by Cycle limit is disabled
8h = Cycle by Cycle limit is disabled
9h = Cycle by Cycle limit is disabled
Ah = Cycle by Cycle limit is disabled
Bh = Cycle by Cycle limit is disabled
Ch = Cycle by Cycle limit is disabled
Dh = Cycle by Cycle limit is disabled
Eh = Cycle by Cycle limit is disabled
Fh = Cycle by Cycle limit is disabled
22-19
LOCK_ILIMIT
R/W
0h
Lock detection current limit (Lock detection current limit (A) =
LOCK_ILIMIT / CSA_GAIN)
0h = N/A
1h = 0.1 V
2h = 0.2 V
3h = 0.3 V
4h = 0.4 V
5h = 0.5 V
6h = 0.6 V
7h = 0.7 V
8h = 0.8 V
9h = 0.9 V
Ah = 1 V
Bh = 1.1 V
Ch = 1.2 V
Dh = 1.3 V
Eh = 1.4 V
Fh = 1.5 V
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Table 8-43. FAULT_CONFIG1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
18-15
LOCK_ILIMIT_MODE
R/W
0h
Lock detection current limit mode
0h = Ilimit lock detection causes latched fault; nFAULT active; Gate
driver is tristated
1h = Ilimit lock detection causes latched fault; nFAULT active; Gate
driver is in recirculation mode
2h = Ilimit lock detection causes latched fault; nFAULT active; Gate
driver is in high-side brake mode (All high-side FETs are turned ON)
3h = Ilimit lock detection causes latched fault; nFAULT active; Gate
driver is in low-side brake mode (All low-side FETs are turned ON)
4h = Automatic recovery after tLCK_RETRY; Gate driver is tristated
5h = Automatic recovery after tLCK_RETRY; Gate driver is in
recirculation mode
6h = Automatic recovery after tLCK_RETRY; Gate driver is in high-
side brake mode (All high-side FETs are turned ON)
7h = Automatic recovery after tLCK_RETRY; Gate driver is in low-
side brake mode (All low-side FETs are turned ON)
8h = Ilimit lock detection is in report only but no action is taken
9h = Ilimit lock detection is disabled
Ah = Ilimit lock detection is disabled
Bh = Ilimit lock detection is disabled
Ch = Ilimit lock detection is disabled
Dh = Ilimit lock detection is disabled
Eh = Ilimit lock detection is disabled
Fh = Ilimit lock detection is disabled
14-11
LOCK_ILIMIT_DEG
R/W
0h
Lock detection current limit deglitch time
0h = 1 ms
1h = 2 ms
2h = 5 ms
3h = 10 ms
4h = 25 ms
5h = 50 ms
6h = 75 ms
7h = 100 ms
8h = 250 ms
9h = 500 ms
Ah = 1 s
Bh = 2.5 s
Ch = 5 s
Dh = 10 s
Eh = 25 s
Fh = 50 s
10-8
CBC_RETRY_PWM_CYC R/W
0h
Number of PWM cycles for CBC current limit to retry
0h = 0
1h = 1
2h = 2
3h = 3
4h = 4
5h = 5
6h = 6
7h = 7
7
RESERVED
R/W
0h
Reserved
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Table 8-43. FAULT_CONFIG1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
6-3
MTR_LCK_MODE
R/W
0h
Motor lock mode
0h = Motor lock detection causes latched fault; nFAULT active; Gate
driver is tristated
1h = Motor lock detection causes latched fault; nFAULT active; Gate
driver is in recirculation mode
2h = Motor lock detection causes latched fault; nFAULT active; Gate
driver is in high-side brake mode (All high-side FETs are turned ON)
3h = Motor lock detection causes latched fault; nFAULT active; Gate
driver is in low-side brake mode (All low-side FETs are turned ON)
4h = Automatic recovery after tLCK_RETRY; Gate driver is tristated
5h = Automatic recovery after tLCK_RETRY; Gate driver is in
recirculation mode
6h = Automatic recovery after tLCK_RETRY; Gate driver is in high-
side brake mode (All high-side FETs are turned ON)
7h = Automatic recovery after tLCK_RETRY; Gate driver is in low-
side brake mode (All low-side FETs are turned ON)
8h = Motor lock detection is in report only but no action is taken
9h = Motor lock detection is disabled
Bh = Motor lock detection is disabled
Ch = Motor lock detection is disabled
Dh = Motor lock detection is disabled
Eh = Motor lock detection is disabled
Fh = Motor lock detection is disabled
2-0
LCK_RETRY
R/W
0h
Lock retry time
0h = 100 ms
1h = 500 ms
2h = 1000 ms
3h = 2000 ms
4h = 3000 ms
5h = 5000 ms
6h = 7500 ms
7h = 10000 ms
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8.7.2.2 FAULT_CONFIG2 Register (Address = 94h) [Reset = 00000000h]
FAULT_CONFIG2 is shown in FAULT_CONFIG2 Register and described in FAULT_CONFIG2 Register Field
Descriptions.
Return to the FAULT_CONFIGURATION Registers.
Register to configure fault settings2
Figure 8-68. FAULT_CONFIG2 Register
31
30
29
28
27
26
25
24
16
PARITY
R/W-0h
LOCK1_EN
R/W-0h
LOCK2_EN
R/W-0h
LOCK3_EN
R/W-0h
LOCK_ABN_SPEED
R/W-0h
23
22
21
13
20
12
4
19
18
10
2
17
LOSS_SYNC_TIMES
NO_MTR_THR
MAX_VM_MOD MAX_VM_MOT
E
OR
R/W-0h
14
R/W-0h
R/W-0h
R/W-0h
15
11
9
8
MAX_VM_MOTOR
MIN_VM_MOD
E
MIN_VM_MOTOR
AUTO_RETRY_TIMES
R/W-0h
R/W-0h
R/W-0h
3
R/W-0h
7
6
5
1
0
AUTO_RETRY_
TIMES
LOCK_MIN_SPEED
ABN_LOCK_SPD_RATIO
ZERO_DUTY_THR
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 8-44. FAULT_CONFIG2 Register Field Descriptions
Bit
31
30
Field
PARITY
Type
R/W
R/W
Reset
Description
0h
Parity bit
LOCK1_EN
LOCK2_EN
LOCK3_EN
0h
Lock 1 (Abnormal Speed) Enable
0h = Disable
1h = Enable
29
28
R/W
R/W
0h
0h
Lock 2 (Loss of Sync) Enable
0h = Disable
1h = Enable
Lock 3 (No Motor) Enable
0h = Disable
1h = Enable
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Table 8-44. FAULT_CONFIG2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
27-24
LOCK_ABN_SPEED
R/W
0h
Abnormal speed lock threshold
0h = 250 Hz
1h = 500 Hz
2h = 750 Hz
3h = 1000 Hz
4h = 1250 Hz
5h = 1500 Hz
6h = 1750 Hz
7h = 2000 Hz
8h = 2250 Hz
9h = 2500 Hz
Ah = 2750 Hz
Bh = 3000 Hz
Ch = 3250 Hz
Dh = 3500 Hz
Eh = 3750 Hz
Fh = 4000 Hz
23-21
LOSS_SYNC_TIMES
R/W
0h
Number of times sync lost for loss of sync lock fault
0h = Trigger after losing sync 2 times
1h = Trigger after losing sync 3 times
2h = Trigger after losing sync 4 times
3h = Trigger after losing sync 5 times
4h = Trigger after losing sync 6 times
5h = Trigger after losing sync 7 times
6h = Trigger after losing sync 8 times
7h = Trigger after losing sync 9 times
20-18
NO_MTR_THR
R/W
0h
No motor lock current threshold (No motor lock current threshold (A)
= NO_MTR_THR / CSA_GAIN)
0h = 0.005 V
1h = 0.0075 V
2h = 0.010 V
3h = 0.0125 V
4h = 0.020 V
5h = 0.025 V
6h = 0.030 V
7h = 0.04 V
17
MAX_VM_MODE
MAX_VM_MOTOR
R/W
R/W
0h
0h
0h = Latch on Overvoltage
1h = Automatic clear if voltage in bounds
16-14
Maximum voltage for running motor
0h = No Limit
1h = 20.0 V
2h = 25.0 V
3h = 30.0 V
4h = 35.0 V
5h = 40.0 V
6h = 50.0 V
7h = 60.0 V
13
MIN_VM_MODE
R/W
0h
0h = Latch on Undervoltage
1h = Automatic clear if voltage in bounds
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Table 8-44. FAULT_CONFIG2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
12-10
MIN_VM_MOTOR
R/W
0h
Minimum voltage for running motor
0h = No Limit
1h = 6.0 V
2h = 7.0 V
3h = 8.0 V
4h = 9.0 V
5h = 10.0 V
6h = 12.0 V
7h = 15.0 V
9-7
AUTO_RETRY_TIMES
R/W
0h
Number of automatic retry attempts
0h = No Limit
1h = 2
2h = 3
3h = 5
4h = 7
5h = 10
6h = 15
7h = 20
6-4
LOCK_MIN_SPEED
R/W
0h
Speed below which lock fault is triggered
0h = 0.5 Hz
1h = 1 Hz
2h = 2 Hz
3h = 3 Hz
4h = 5 Hz
5h = 10 Hz
6h = 15 Hz
7h = 25 Hz
3-2
1-0
ABN_LOCK_SPD_RATIO R/W
0h
0h
Ratio of electrical speed between two consecutive cycles above
which abnormal speed lock fault is triggered
0h = 2
1h = 4
2h = 6
3h = 8
ZERO_DUTY_THR
R/W
Duty cycle below which target speed is zero
0h = 1%
1h = 1.5%
2h = 2.0%
3h = 2.5%
8.7.3 Hardware_Configuration Registers
HARDWARE_CONFIGURATION Registers lists the memory-mapped registers for the Hardware_Configuration
registers. All register offset addresses not listed in HARDWARE_CONFIGURATION Registers should be
considered as reserved locations and the register contents should not be modified.
Table 8-45. HARDWARE_CONFIGURATION Registers
Address Acronym
Register Name
Section
A4h
A6h
A8h
PIN_CONFIG1
Hardware pin configuration
Hardware pin configuration
Device configuration
Section 8.7.3.1
Section 8.7.3.2
Section 8.7.3.3
PIN_CONFIG2
DEVICE_CONFIG
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Complex bit access types are encoded to fit into small table cells. Hardware_Configuration Access Type Codes
shows the codes that are used for access types in this section.
Table 8-46. Hardware_Configuration Access Type
Codes
Access Type
Read Type
R
Code
Description
R
Read
Write Type
W
W
Write
Reset or Default Value
-n
Value after reset or the default
value
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8.7.3.1 PIN_CONFIG1 Register (Address = A4h) [Reset = 00000000h]
PIN_CONFIG1 is shown in PIN_CONFIG1 Register and described in PIN_CONFIG1 Register Field
Descriptions.
Return to the HARDWARE_CONFIGURATION Registers.
Register to configure hardware pins
Figure 8-69. PIN_CONFIG1 Register
31
30
22
14
6
29
28
20
12
27
26
18
10
2
25
24
16
8
PARITY
R/W-0h
DACOUT1_VAR_ADDR
R/W-0h
23
15
7
21
19
11
17
DACOUT1_VAR_ADDR
R/W-0h
DACOUT2_VAR_ADDR
R/W-0h
13
9
DACOUT2_VAR_ADDR
R/W-0h
5
4
3
1
0
DACOUT2_VA
R_ADDR
BRAKE_INPUT
DIR_INPUT
R/W-0h
SPD_CTRL_MODE
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 8-47. PIN_CONFIG1 Register Field Descriptions
Bit
31
Field
PARITY
Type
R/W
R/W
R/W
R/W
Reset
Description
0h
Parity bit
30-19
18-7
6-5
DACOUT1_VAR_ADDR
DACOUT2_VAR_ADDR
BRAKE_INPUT
0h
12-bit address of variable to be monitored
12-bit address of variable to be monitored
0h
0h
Brake input configuration
0h = Hardware Pin BRAKE
1h = Overwrite Hardware pin with Active Brake
2h = Overwrite Hardware pin with brake functionality disabled
3h = N/A
4-3
2-1
0
DIR_INPUT
R/W
R/W
R/W
0h
0h
0h
Direction input configuration
0h = Hardware Pin DIR
1h = Overwrite Hardware pin with clockwise rotation OUTA-OUTB-
OUTC
3h = N/A
SPD_CTRL_MODE
RESERVED
Speed input configuration
0h = Analog mode speed Input
1h = PWM Mode Speed Input
2h = I2C Speed Input mode
3h = Frequency based speed Input mode
Reserved
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8.7.3.2 PIN_CONFIG2 Register (Address = A6h) [Reset = 00000000h]
PIN_CONFIG2 is shown in PIN_CONFIG2 Register and described in PIN_CONFIG2 Register Field
Descriptions.
Return to the HARDWARE_CONFIGURATION Registers.
Register to configure hardware pins
Figure 8-70. PIN_CONFIG2 Register
31
30
29
28
27
26
18
10
25
24
16
PARITY
DAC_SOX_CONFIG
RESERVED DAC_XTAL_CO
NFIG
RESERVED
R/W-0h
23
R/W-0h
R/W-0h
20
R/W-0h
19
R/W-0h
17
22
14
21
13
RESERVED
R/W-0h
SLEEP_TIME
EXT_WD_EN EXT_WD_INPU
T
R/W-0h
R/W-0h
9
R/W-0h
8
15
12
4
11
3
EXT_WD_FAUL
T
EXT_WD_FREQ
RESERVED
R/W-0h
7
R/W-0h
R/W-0h
2
6
5
1
0
RESERVED
R/W-0h
Table 8-48. PIN_CONFIG2 Register Field Descriptions
Bit
31
Field
PARITY
Type
R/W
R/W
Reset
Description
0h
Parity bit
30-29
DAC_SOX_CONFIG
0h
Pin 36 configuration
0h = DACOUT2
1h = SOA
2h = SOB
3h = SOC
28
27
RESERVED
R/W
R/W
0h
0h
Reserved
DAC_XTAL_CONFIG
Pin 37 and pin 38 configuration
0h = N/A
1h = Pin 37 as DACOUT1 and pin 38 as DACOUT2
26-20
19-18
RESERVED
R/W
R/W
0h
0h
Reserved
SLEEP_TIME
Sleep Time
0h = Check low for 50 µs
1h = Check low for 200 µs
2h = Check low for 20 ms
3h = Check low for 200 ms
17
16
15
EXT_WD_EN
R/W
R/W
R/W
0h
0h
0h
Enable external watchdog
0h = Disable
1h = Enable
EXT_WD_INPUT
EXT_WD_FAULT
External watchdog source
0h = I2C
1h = GPIO
External watchdog fault mode
0h = Report only
1h = Latched fault with Hi-Z outputs
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Table 8-48. PIN_CONFIG2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
14-13
EXT_WD_FREQ
R/W
0h
External watchdog frequency
0h = 10Hz
1h = 5Hz
2h = 2Hz
3h = 1Hz
12-0
RESERVED
R/W
0h
Reserved
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8.7.3.3 DEVICE_CONFIG Register (Address = A8h) [Reset = 00000000h]
DEVICE_CONFIG is shown in DEVICE_CONFIG Register and described in DEVICE_CONFIG Register Field
Descriptions.
Return to the HARDWARE_CONFIGURATION Registers.
Register to configure device
Figure 8-71. DEVICE_CONFIG Register
31
30
22
14
29
21
13
28
27
26
18
10
25
17
9
24
16
8
PARITY
R/W-0h
INPUT_MAX_FREQUENCY
R/W-0h
23
20
19
INPUT_MAX_FREQUENCY
R/W-0h
15
12
11
STL_ENABLE SSM_CONFIG
RESERVED
R/W-0h
DEV_MODE SPD_PWM_RA
NGE_SELECT
CLK_SEL
R/W-0h
R/W-0h
R/W-0h
R/W-0h
3
R/W-0h
2
7
6
5
4
1
0
RESERVED
R/W-0h
EXT_CLK_EN
R/W-0h
EXT_CLK_CONFIG
R/W-0h
RESERVED
R/W-0h
Table 8-49. DEVICE_CONFIG Register Field Descriptions
Bit
31
Field
PARITY
Type
Reset
Description
R/W
0h
Parity bit
30-16
INPUT_MAX_FREQUENC R/W
Y
0h
Maximum frequency (in Hz) for frequency based speed input
15
14
STL_ENABLE
SSM_CONFIG
R/W
R/W
0h
0h
STL enable
0h = Disable
1h = Enable
SSM enable
0h = Enable
1h = Disable
13-12
11
RESERVED
DEV_MODE
R/W
R/W
0h
0h
Reserved
Device mode select
0h = Standby mode
1h = Sleep mode
10
SPD_PWM_RANGE_SEL R/W
ECT
0h
0h
PWM frequency range select
0h = 325 Hz to 95 kHz speed PWM input
1h = 10 Hz to 325 Hz speed PWM input
9-8
CLK_SEL
R/W
Clock source
0h = Internal Oscillator
1h = N/A
2h = N/A
3h = External Clock input
7
6
RESERVED
R/W
R/W
0h
0h
Reserved
EXT_CLK_EN
External clock enable
0h = Disable
1h = Enable
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Table 8-49. DEVICE_CONFIG Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
5-3
EXT_CLK_CONFIG
R/W
0h
External clock frequency
0h = 8 kHz
1h = 16 kHz
2h = 32 kHz
3h = 64 kHz
4h = 128 kHz
5h = 256 kHz
6h = 512 kHz
7h = 1024 kHz
2-0
RESERVED
R/W
0h
Reserved
8.7.4 Gate_Driver_Configuration Registers
GATE_DRIVER_CONFIGURATION
Gate_Driver_Configuration
Registers
All
lists
register
the
memory-mapped
offset addresses
registers
not
for
listed
the
in
registers.
GATE_DRIVER_CONFIGURATION Registers should be considered as reserved locations and the register
contents should not be modified.
Table 8-50. GATE_DRIVER_CONFIGURATION Registers
Address Acronym
Register Name
Section
ACh
AEh
GD_CONFIG1
GD_CONFIG2
Gate driver configuration 1
Gate driver configuration 2
Section 8.7.4.1
Section 8.7.4.2
Complex bit access types are encoded to fit into small table cells. Gate_Driver_Configuration Access Type
Codes shows the codes that are used for access types in this section.
Table 8-51. Gate_Driver_Configuration Access Type
Codes
Access Type
Read Type
R
Code
Description
R
Read
Write Type
W
W
Write
Reset or Default Value
-n
Value after reset or the default
value
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8.7.4.1 GD_CONFIG1 Register (Address = ACh) [Reset = 00228000h]
GD_CONFIG1 is shown in GD_CONFIG1 Register and described in GD_CONFIG1 Register Field Descriptions.
Return to the GATE_DRIVER_CONFIGURATION Registers.
Register to configure gated driver settings1
Figure 8-72. GD_CONFIG1 Register
31
30
29
28
27
26
25
24
PARITY
R/W-0h
RESERVED
R/W-0h
RESERVED
R/W-0h
SLEW_RATE
R/W-0h
RESERVED
R/W-0h
23
22
21
20
19
18
17
16
RESERVED
R/W-0h
RESERVED
R/W-0h
RESERVED
R/W-1h
RESERVED
R/W-0h
OVP_SEL
R/W-0h
OVP_EN
R/W-0h
RESERVED
R/W-1h
OTW_REP
R/W-0h
15
14
13
12
11
10
9
8
RESERVED
R/W-1h
RESERVED
R/W-0h
OCP_DEG
R/W-0h
OCP_RETRY
R/W-0h
OCP_LVL
R/W-0h
OCP_MODE
R/W-0h
7
6
5
4
3
2
1
0
RESERVED
RESERVED
ADCOMP_TH_ ADCOMP_TH_
EN_ASR
EN_AAR
CSA_GAIN
R/W-0h
LS
HS
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 8-52. GD_CONFIG1 Register Field Descriptions
Bit
31
Field
PARITY
Type
R/W
R/W
R/W
R/W
Reset
Description
0h
Parity bit
30-29
28
RESERVED
RESERVED
SLEW_RATE
0h
Reserved
Reserved
0h
27-26
0h
Slew rate
0h = 25 V/µs
1h = 50 V/µs
2h = 125 V/µs
3h = 200 V/µs
25-24
23
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
OVP_SEL
R/W
R/W
R/W
R/W
R/W
R/W
0h
0h
0h
1h
0h
0h
Reserved
Reserved
Reserved
Reserved
Reserved
22
21
20
19
Overvoltage protection level
0h = VM overvoltage level is 32-V
1h = VM overvoltage level is 20-V
18
OVP_EN
R/W
0h
Overvoltage protection enable
0h = Disable
1h = Enable
17
16
RESERVED
OTW_REP
R/W
R/W
1h
0h
Reserved
Overtemperature warning reporting on nFAULT
0h = Over temperature reporting on nFAULT is disabled
1h = Over temperature reporting on nFAULT is enabled
15
14
RESERVED
RESERVED
R/W
R/W
1h
0h
Reserved
Reserved
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Table 8-52. GD_CONFIG1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
13-12
OCP_DEG
R/W
0h
OCP deglitch time
0h = 0.2 µs
1h = 0.6 µs
2h = 1.1 µs
3h = 1.6 µs
11
10
OCP_RETRY
OCP_LVL
R/W
R/W
R/W
0h
0h
0h
OCP retry time
0h = 5 ms
1h = 500 ms
OCP level
0h = 16 A (Typical)
1h = 24 A (Typical)
9-8
OCP_MODE
OCP fault mode
0h = Overcurrent causes a latched fault
1h = Overcurrent causes an automatic retrying fault
2h = Overcurrent is report only but no action is taken
3h = Overcurrent is not reported and no action is taken
7
6
5
RESERVED
R/W
R/W
R/W
0h
0h
0h
Reserved
Reserved
RESERVED
ADCOMP_TH_LS
Active demag comparator threshold for low-side
0h = 100 mA
1h = 150 mA
4
3
ADCOMP_TH_HS
EN_ASR
R/W
R/W
R/W
R/W
0h
0h
0h
0h
Active demag comparator threshold for high-side
0h = 100 mA
1h = 150 mA
Active synchronous rectification enable
0h = Disable
1h = Enable
2
EN_AAR
Active asynchronous rectification enable
0h = Disable
1h = Enable
1-0
CSA_GAIN
Current Sense Amplifier (CSA) Gain
0h = 0.15 V/A
1h = 0.3 V/A
2h = 0.6 V/A
3h = 1.2 V/A
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8.7.4.2 GD_CONFIG2 Register (Address = AEh) [Reset = 01200000h]
GD_CONFIG2 is shown in GD_CONFIG2 Register and described in GD_CONFIG2 Register Field Descriptions.
Return to the GATE_DRIVER_CONFIGURATION Registers.
Register to configure gated driver settings2
Figure 8-73. GD_CONFIG2 Register
31
30
29
28
27
26
25
24
PARITY
DELAY_COMP
_EN
TARGET_DELAY
BUCK_SR
BUCK_PS_DIS
R/W-0h
R/W-0h
22
R/W-0h
R/W-0h
17
R/W-1h
16
23
21
13
5
20
19
11
3
18
10
2
BUCK_CL
R/W-0h
BUCK_SEL
R/W-1h
BUCK_DIS
R/W-0h
RESERVED
R/W-0h
15
14
6
12
9
1
8
0
RESERVED
R/W-0h
7
4
RESERVED
R/W-0h
Table 8-53. GD_CONFIG2 Register Field Descriptions
Bit
31
30
Field
Type
R/W
R/W
Reset
Description
PARITY
0h
Parity bit
DELAY_COMP_EN
0h
Driver delay compensation enable
0h = Disable
1h = Enable
29-26
TARGET_DELAY
R/W
0h
Target delay
0h = Automatic based on slew rate
1h = 0.4 µs
2h = 0.6 µs
3h = 0.8 µs
4h = 1 µs
5h = 1.2 µs
6h = 1.4 µs
7h = 1.6 µs
8h = 1.8 µs
9h = 2 µs
Ah = 2.2 µs
Bh = 2.4 µs
Ch = 2.6 µs
Dh = 2.8 µs
Eh = 3 µs
Fh = 3.2 µs
25
24
BUCK_SR
R/W
R/W
0h
1h
Buck slew rate
0h = Buck's FET slew rate is 1000V/µs
1h = Buck's FET slew rate is 200V/µs
BUCK_PS_DIS
Buck power sequencing disable
0h = Buck power sequencing is enabled
1h = Buck power sequencing is disabled
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Table 8-53. GD_CONFIG2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
23
BUCK_CL
R/W
0h
Buck current limit
0h = 600 mA
1h = 150 mA
22-21
BUCK_SEL
R/W
1h
Buck voltage selection
0h = Buck voltage is 3.3 V
1h = Buck voltage is 5.0 V
2h = Buck voltage is 4.0 V
3h = Buck voltage is 5.7 V
20
BUCK_DIS
RESERVED
R/W
R/W
0h
0h
Buck disable
0h = Buck regulator is enabled
1h = Buck regulator is disabled
19-0
Reserved
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8.8 RAM (Volatile) Register Map
8.8.1 Fault_Status Registers
FAULT_STATUS Registers lists the memory-mapped registers for the Fault_Status registers. All register offset
addresses not listed in FAULT_STATUS Registers should be considered as reserved locations and the register
contents should not be modified.
Table 8-54. FAULT_STATUS Registers
Address Acronym
Register Name
Section
E0h
E2h
GATE_DRIVER_FAULT_STATUS Fault Status Register
CONTROLLER_FAULT_STATUS Fault Status Register
Section 8.8.1.1
Section 8.8.1.2
Complex bit access types are encoded to fit into small table cells. Fault_Status Access Type Codes shows the
codes that are used for access types in this section.
Table 8-55. Fault_Status Access Type Codes
Access Type
Read Type
R
Code
Description
R
Read
Reset or Default Value
-n
Value after reset or the default
value
8.8.1.1 GATE_DRIVER_FAULT_STATUS Register (Address = E0h) [Reset = 00000000h]
GATE_DRIVER_FAULT_STATUS is shown in GATE_DRIVER_FAULT_STATUS Register and described in
GATE_DRIVER_FAULT_STATUS Register Field Descriptions.
Return to the FAULT_STATUS Registers.
Status of various faults
Figure 8-74. GATE_DRIVER_FAULT_STATUS Register
31
30
29
28
27
26
25
24
DRIVER_FAUL
T
BK_FLT
RESERVED
OCP
NPOR
OVP
OT
RESERVED
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
23
22
21
20
19
18
17
16
OTW
R-0h
TSD
R-0h
OCP_HC
R-0h
OCP_LC
R-0h
OCP_HB
R-0h
OCP_LB
R-0h
OCP_HA
R-0h
OCP_LA
R-0h
15
14
13
12
11
10
9
8
RESERVED
R-0h
OTP_ERR
R-0h
BUCK_OCP
R-0h
BUCK_UV
R-0h
VCP_UV
R-0h
RESERVED
R-0h
7
6
5
4
3
2
1
0
RESERVED
R-0h
Table 8-56. GATE_DRIVER_FAULT_STATUS Register Field Descriptions
Bit
Field
Type
Reset
Description
31
DRIVER_FAULT
R
0h
Logic OR of driver fault registers
0h = No Gate Driver fault condition is detected
1h = Gate Driver fault condition is detected
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Table 8-56. GATE_DRIVER_FAULT_STATUS Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
30
BK_FLT
R
0h
Buck fault
0h = No buck regulator fault condition is detected
1h = Buck regulator fault condition is detected
29
28
RESERVED
OCP
R
R
0h
0h
Reserved
Overcurrent protection status
0h = No overcurrent condition is detected
1h = Overcurrent condition is detected
27
26
25
NPOR
OVP
OT
R
R
R
0h
0h
0h
Supply power on reset
0h = Power on reset condition is detected on VM
1h = No power-on-reset condition is detected on VM
Supply overvoltage protection status
0h = No overvoltage condition is detected on VM
1h = Overvoltage condition is detected on VM
Overtemperature fault status
0h = No overtemperature warning / shutdown is detected
1h = Overtemperature warning / shutdown is detected
24
23
RESERVED
OTW
R
R
0h
0h
Reserved
Overtemperature warning status
0h = No overtemperature warning is detected
1h = Overtemperature warning is detected
22
21
20
19
18
17
16
TSD
R
R
R
R
R
R
R
0h
0h
0h
0h
0h
0h
0h
Overtemperature shutdown status
0h = No overtemperature shutdown is detected
1h = Overtemperature shutdown is detected
OCP_HC
OCP_LC
OCP_HB
OCP_LB
OCP_HA
OCP_LA
Overcurrent status on high-side switch of OUTC
0h = No overcurrent detected on high-side switch of OUTC
1h = Overcurrent detected on high-side switch of OUTC
Overcurrent status on low-side switch of OUTC
0h = No overcurrent detected on low-side switch of OUTC
1h = Overcurrent detected on low-side switch of OUTC
Overcurrent status on high-side switch of OUTB
0h = No overcurrent detected on high-side switch of OUTB
1h = Overcurrent detected on high-side switch of OUTB
Overcurrent status on low-side switch of OUTB
0h = No overcurrent detected on low-side switch of OUTB
1h = Overcurrent detected on low-side switch of OUTB
Overcurrent status on high-side switch of OUTA
0h = No overcurrent detected on high-side switch of OUTA
1h = Overcurrent detected on high-side switch of OUTA
Overcurrent status on low-side switch of OUTA
0h = No overcurrent detected on low-side switch of OUTA
1h = Overcurrent detected on low-side switch of OUTA
15
14
RESERVED
OTP_ERR
R
R
0h
0h
Reserved
One-time programmable (OTP) error
0h = No OTP error is detected
1h = OTP Error is detected
13
BUCK_OCP
R
0h
Buck regulator overcurrent status
0h = No buck regulator overcurrent is detected
1h = Buck regulator overcurrent is detected
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Table 8-56. GATE_DRIVER_FAULT_STATUS Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
12
BUCK_UV
R
0h
Buck regulator undervoltage status
0h = No buck regulator undervoltage is detected
1h = Buck regulator undervoltage is detected
11
VCP_UV
R
R
0h
0h
Charge pump undervoltage status
0h = No charge pump undervoltage is detected
1h = Charge pump undervoltage is detected
10-0
RESERVED
Reserved
8.8.1.2 CONTROLLER_FAULT_STATUS Register (Address = E2h) [Reset = 00000000h]
CONTROLLER_FAULT_STATUS is shown in CONTROLLER_FAULT_STATUS Register and described in
CONTROLLER_FAULT_STATUS Register Field Descriptions.
Return to the FAULT_STATUS Registers.
Status of various faults
Figure 8-75. CONTROLLER_FAULT_STATUS Register
31
30
29
28
27
26
25
24
16
CONTROLLER
_FAULT
RESERVED
IPD_FREQ_FA IPD_T1_FAULT IPD_T2_FAULT
ULT
RESERVED
R-0h
23
R-0h
22
R-0h
R-0h
R-0h
R-0h
17
21
20
19
18
ABN_SPEED LOSS_OF_SYN
C
NO_MTR
MTR_LCK
CBC_ILIMIT
LOCK_ILIMIT MTR_UNDER_ MTR_OVER_V
VOLTAGE
OLTAGE
R-0h
15
R-0h
14
R-0h
13
R-0h
12
R-0h
R-0h
10
R-0h
R-0h
11
9
8
EXT_WD_TIME
OUT
RESERVED
R-0h
7
R-0h
3
6
5
4
2
1
0
RESERVED
R-0h
STL_EN
R-0h
STL_STATUS
R-0h
APP_RESET
R-0h
Table 8-57. CONTROLLER_FAULT_STATUS Register Field Descriptions
Bit
Field
Type
Reset
Description
31
CONTROLLER_FAULT
R
0h
Logic OR of controller fault registers
0h = No controller fault condition is detected
1h = Controller fault condition is detected
30
29
RESERVED
R
R
0h
0h
Reserved
IPD_FREQ_FAULT
Indicates IPD frequency fault
0h = No IPD frequency fault detected
1h = IPD frequency fault detected
28
27
IPD_T1_FAULT
IPD_T2_FAULT
RESERVED
R
R
R
0h
0h
0h
Indicates IPD T1 fault
0h = No IPD T1 fault detected
1h = IPD T1 fault detected
Indicates IPD T2 fault
0h = No IPD T2 fault detected
1h = IPD T2 fault detected
26-24
Reserved
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Table 8-57. CONTROLLER_FAULT_STATUS Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
23
ABN_SPEED
R
0h
Indicates abnormal speed motor lock condition
0h = No abnormal speed fault detected
1h = Abnormal speed fault detected
22
21
20
19
18
17
16
15
LOSS_OF_SYNC
NO_MTR
R
R
R
R
R
R
R
R
0h
0h
0h
0h
0h
0h
0h
0h
Indicates sync lost motor lock condition
0h = No sync lost fault detected
1h = Sync lost fault detected
Indicates no motor fault
0h = No motor fault not detected
1h = No motor fault detected
MTR_LCK
Indicates when one of the motor lock is triggered
0h = Motor lock fault not detected
1h = Motor lock fault detected
CBC_ILIMIT
Indicates CBC current limit fault
0h = No CBC fault detected
1h = CBC fault detected
LOCK_ILIMIT
Indicates lock detection current limit fault
0h = No lock current limit fault detected
1h = Lock current limit fault detected
MTR_UNDER_VOLTAGE
MTR_OVER_VOLTAGE
EXT_WD_TIMEOUT
Indicates motor undervoltage fault
0h = No motor undervoltage detected
1h = Motor undervoltage detected
Indicates motor overvoltage fault
0h = No motor overvoltage detected
1h = Motor overvoltage detected
Indicates external watchdog timeout fault
0h = No external watchdog timeout fault detected
1h = External watchdog timeout fault detected
14-3
2
RESERVED
STL_EN
R
R
0h
0h
Reserved
Indicates STL is enabled in EEPROM
0h = STL Disable
1h = STL Enable
1
0
STL_STATUS
APP_RESET
R
R
0h
0h
Indicates STL success criteria Pass = 1b; Fail = 0b
0h = STL Fail
1h = STL Pass
App reset
0h = App Reset Fail
1h = App Reset Successful
8.8.2 System_Status Registers
SYSTEM_STATUS Registers lists the memory-mapped registers for the System_Status registers. All register
offset addresses not listed in SYSTEM_STATUS Registers should be considered as reserved locations and the
register contents should not be modified.
Table 8-58. SYSTEM_STATUS Registers
Address Acronym
Register Name
Section
E4h
EAh
ECh
SYS_STATUS1
System Status Register1
System Status Register2
System Status Register3
Section 8.8.2.1
Section 8.8.2.2
Section 8.8.2.3
SYS_STATUS2
SYS_STATUS3
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Complex bit access types are encoded to fit into small table cells. System_Status Access Type Codes shows the
codes that are used for access types in this section.
Table 8-59. System_Status Access Type Codes
Access Type
Read Type
R
Code
Description
R
Read
Reset or Default Value
-n
Value after reset or the default
value
8.8.2.1 SYS_STATUS1 Register (Address = E4h) [Reset = 00000000h]
SYS_STATUS1 is shown in SYS_STATUS1 Register and described in SYS_STATUS1 Register Field
Descriptions.
Return to the SYSTEM_STATUS Registers.
Status of various system and motor parameters
Figure 8-76. SYS_STATUS1 Register
31
23
15
7
30
22
14
6
29
21
13
5
28
20
12
4
27
19
11
3
26
18
10
2
25
17
9
24
16
8
VOLT_MAG
R-0h
VOLT_MAG
R-0h
SPEED_CMD
R-0h
1
0
SPEED_CMD
I2C_ENTRY_S
TATUS
R-0h
R-0h
Table 8-60. SYS_STATUS1 Register Field Descriptions
Bit
Field
Type
Reset
Description
31-16
15-1
VOLT_MAG
R
0h
Applied DC input voltage (/10 to get DC input voltage in V)
SPEED_CMD
R
0h
Decoded speed command in PWM/Analog/Freq. mode
(SPEED_CMD (%) = SPEED_CMD/32767 * 100%)
0
I2C_ENTRY_STATUS
R
0h
Indicates if I2C entry has happened
0h = I2C mode not entered through pin sequence
1h = I2C mode entered through pin sequence
8.8.2.2 SYS_STATUS2 Register (Address = EAh) [Reset = 00000000h]
SYS_STATUS2 is shown in SYS_STATUS2 Register and described in SYS_STATUS2 Register Field
Descriptions.
Return to the SYSTEM_STATUS Registers.
Status of various system and motor parameters
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Figure 8-77. SYS_STATUS2 Register
31
23
15
7
30
22
14
6
29
21
13
5
28
20
12
27
19
11
26
18
10
2
25
17
24
STATE
R-0h
RESERVED
R-0h
16
RESERVED
R-0h
STL_FAULT
R-0h
RESERVED
R-0h
8
9
MOTOR_SPEED
R-0h
4
3
1
0
MOTOR_SPEED
R-0h
Table 8-61. SYS_STATUS2 Register Field Descriptions
Bit
Field
Type
Reset
Description
31-28
STATE
R
0h
Current status of state machine; 4-bit value indicating status of state
machine
0h = SYSTEM_IDLE
1h = MOTOR_START
2h = MOTOR_RUN
3h = SYSTEM_INIT
4h = MOTOR_IPD
5h = MOTOR_ALIGN
6h = MOTOR_IDLE
7h = MOTOR_STOP
8h = FAULT
9h = MOTOR_DIRECTION
Ah = HALL_ALIGN
Ch = MOTOR_FREEWHEEL
Dh = MOTOR_DESCEL
Eh = MOTOR_BRAKE
Fh = N/A
27-18
17
RESERVED
STL_FAULT
R
R
0h
0h
Reserved
STL fault status
0h = Pass
1h = Fail
16
RESERVED
R
R
0h
0h
Reserved
15-0
MOTOR_SPEED
Speed output (/10 to get motor electrical speed in Hz)
8.8.2.3 SYS_STATUS3 Register (Address = ECh) [Reset = 00000000h]
SYS_STATUS3 is shown in SYS_STATUS3 Register and described in SYS_STATUS3 Register Field
Descriptions.
Return to the SYSTEM_STATUS Registers.
Status of various system and motor parameters
Figure 8-78. SYS_STATUS3 Register
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
0
DC_BUS_CURR
DC_BATT_POW
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Figure 8-78. SYS_STATUS3 Register (continued)
R-0h
R-0h
Table 8-62. SYS_STATUS3 Register Field Descriptions
Bit
Field
Type
Reset
Description
31-16
15-0
DC_BUS_CURR
DC_BATT_POW
R
0h
DC bus current (/256 to get DC bus current in A)
Battery (input) power (/64 to get battery power in W)
R
0h
8.8.3 Algo_Control Registers
ALGO_CONTROL Registers lists the memory-mapped registers for the Algo_Control registers. All register offset
addresses not listed in ALGO_CONTROL Registers should be considered as reserved locations and the register
contents should not be modified.
Table 8-63. ALGO_CONTROL Registers
Address Acronym
E6h ALGO_CTRL1
Register Name
Section
Algorithm Control Parameters
Section 8.8.3.1
Complex bit access types are encoded to fit into small table cells. Algo_Control Access Type Codes shows the
codes that are used for access types in this section.
Table 8-64. Algo_Control Access Type Codes
Access Type
Write Type
W
Code
Description
W
Write
Reset or Default Value
-n
Value after reset or the default
value
8.8.3.1 ALGO_CTRL1 Register (Address = E6h) [Reset = 00000000h]
ALGO_CTRL1 is shown in ALGO_CTRL1 Register and described in ALGO_CTRL1 Register Field Descriptions.
Return to the ALGO_CONTROL Registers.
Algorithm Control Parameters
Figure 8-79. ALGO_CTRL1 Register
31
30
29
28
27
26
25
24
EEPROM_WRT EEPROM_REA
D
CLR_FLT
CLR_FLT_RET
RY_COUNT
EEPROM_WRITE_ACCESS_KEY
W-0h
W-0h
23
W-0h
22
W-0h
21
W-0h
20
19
11
3
18
10
2
17
16
8
EEPROM_WRITE_ACCESS_KEY
W-0h
RESERVED
W-0h
15
7
14
13
12
9
RESERVED
W-0h
6
5
4
1
0
RESERVED
EXT_WD_STAT
US_SET
W-0h
W-0h
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Table 8-65. ALGO_CTRL1 Register Field Descriptions
Bit
Field
Type
Reset
Description
31
EEPROM_WRT
W
0h
Write the configuration to EEPROM
1h = Write to the EEPROM registers from shadow registers
30
29
EEPROM_READ
CLR_FLT
W
W
W
W
0h
0h
0h
0h
Read the default configuration from EEPROM
1h = Read the EEPROM registers to shadow registers
Clears all faults
1h = Clear all the driver and controller faults
28
CLR_FLT_RETRY_COUN
T
Clears fault retry count
1h = clear the lock fault retry counts
27-20
EEPROM_WRITE_ACCE
SS_KEY
EEPROM write access key; 8-bit key to unlock the EEPROM write
command
19-1
0
RESERVED
W
W
0h
0h
Reserved
EXT_WD_STATUS_SET
Watchdog status to be set by external MCU in I2C watchdog mode
0h = Reset automatically by the MCC
1h = To set the EXT_WD_STATUS_SET
8.8.4 Device_Control Registers
DEVICE_CONTROL Registers lists the memory-mapped registers for the Device_Control registers. All register
offset addresses not listed in DEVICE_CONTROL Registers should be considered as reserved locations and the
register contents should not be modified.
Table 8-66. DEVICE_CONTROL Registers
Address Acronym
E8h DEVICE_CTRL
Register Name
Section
Device Control Parameters
Section 8.8.4.1
Complex bit access types are encoded to fit into small table cells. Device_Control Access Type Codes shows the
codes that are used for access types in this section.
Table 8-67. Device_Control Access Type Codes
Access Type
Read Type
R
Code
Description
R
Read
Write Type
W
W
Write
Reset or Default Value
-n
Value after reset or the default
value
8.8.4.1 DEVICE_CTRL Register (Address = E8h) [Reset = 00000000h]
DEVICE_CTRL is shown in DEVICE_CTRL Register and described in DEVICE_CTRL Register Field
Descriptions.
Return to the DEVICE_CONTROL Registers.
Device Control Parameters
Figure 8-80. DEVICE_CTRL Register
31
30
29
28
27
26
18
25
17
24
16
RESERVED
W-0h
SPEED_CTRL
W-0h
23
22
21
20
19
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Figure 8-80. DEVICE_CTRL Register (continued)
SPEED_CTRL
W-0h
15
14
6
13
5
12
4
11
10
2
9
1
8
0
OVERRIDE
RESERVED
R-0h
W-0h
7
3
RESERVED
R-0h
Table 8-68. DEVICE_CTRL Register Field Descriptions
Bit
31
Field
Type
Reset
Description
RESERVED
W
0h
Reserved
30-16
SPEED_CTRL
W
0h
Digital speed command (SPEED_CTRL (%) = SPEED_CTRL/32767
* 100%)
15
OVERRIDE
RESERVED
W
R
0h
0h
Speed input select for I2C vs speed pin
0h = SPEED_CMD using Analog/Freq/PWM mode
1h = SPEED_CMD using SPD_CTRL[14:0]
14-0
Reserved
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9 Application and Implementation
Note
Information in the following applications sections is not part of the TI component specification, and
TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining
suitability of components for their purposes. Customers should validate and test their design
implementation to confirm system functionality.
9.1 Application Information
The MCT8316A device is used in sensorless 3-phase BLDC motor control. The driver provides a high
performance, high-reliability, flexible solution for robotic vacuum, fuel pumps, automotive fans and blowers,
medical CPAP blowers etc., The following section shows a common application of the MCT8316A device.
9.2 Typical Applications
Figure 9-1 shows the typical schematic of MCT8316AV.
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VVM
+
47 nF
CPL
1 µF
VM
0.1 µF
>10 µF
CPH
CP
AVDD
AGND
SPEED/WAKE (PWM/Analog/Freq)
CAVDD
1 µF
1 µF
DRVOFF
BRAKE
DIR
DVDD
AGND
CDVDD
EXT_CLK
EXT_WD
Replace resistor (RBK) with
inductor (LBK) for larger
external load or to reduce
power dissipaꢀon
Optional
Control
Interface
LBK
SW_BK
External
Load
RBK
CBK
MCT8316AV
GND_BK
DACOUT1
DACOUT2
SOX
FB_BK
OUTA
AVDD or EXT SUPPLY
RFG
RnFAULT
FG
nFAULT
OUTB
AVDD or EXT SUPPLY
RSDA
RSCL
OUTC
PGND
Optional
Serial
Interface
SDA
I2C
SCL
Figure 9-1. Primary Application Schematic
Table 9-1 lists the recommended values of the external components for MCT8316A.
Table 9-1. MCT8316A External Components
COMPONENTS
PIN 1
PIN 2
RECOMMENDED
X5R or X7R, 0.1-µF, TI recommends a capacitor
voltage rating at least twice the normal operating
voltage of the device
CVM1
VM
PGND
≥ 10-µF, TI recommends a capacitor voltage rating at
least twice the normal operating voltage of the device
CVM2
CCP
VM
CP
PGND
VM
X5R or X7R, 16-V, 1-µF capacitor
X5R or X7R, 47-nF, TI recommends a capacitor
voltage rating at least twice the normal operating
voltage of the pin
CFLY
CPH
CPL
X5R or X7R, 1-µF, ≥ 6.3-V. In order for AVDD to
accurately regulate output voltage, capacitor should
have effective capacitance between 0.7-µF to 1.3-µF
at 3.3-V across operating temperature.
CAVDD
AVDD
AGND
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Table 9-1. MCT8316A External Components (continued)
COMPONENTS
PIN 1
PIN 2
RECOMMENDED
X5R or X7R, 1-µF, ≥ 4-V. In order for DVDD to
accurately regulate output voltage, capacitor should
have effective capacitance between 0.6-µF to 1.3-µF
at 1.5-V across operating temperature.
CDVDD
AVDD
AGND
CBK
LBK
SW_BK
GND_BK
FB_BK
FG
X5R or X7R, buck-output rated capacitor
Buck-output inductor
SW_BK
RFG
1.8 to 5-V Supply
1.8 to 5-V Supply
1.8 to 3.3-V Supply
1.8 to 3.3-V Supply
5.1-kΩ, Pull-up resistor
RnFAULT
RSDA
RSCL
nFAULT
SDA
5.1-kΩ, Pull-up resistor
5.1-kΩ, Pull-up resistor
SCL
5.1-kΩ, Pull-up resistor
Recommended application range for MCT8316A is shown in Table 9-2.
Table 9-2. Recommended Application Range
Parameter
Min
Max
Unit
V
Motor voltage
4.5
35
Motor electrical speed
Peak motor phase current
-
-
3000
8
Hz
A
Default EEPROM configuration for MCT8316A is listed in Table 9-3. Default values are chosen for reliable motor
startup and closed loop operation. Refer to MCT8316A tuning guide which provides step by step procedure to
tune a 3-phase BLDC motor in closed loop, conform to use-case and explore features in the device.
Table 9-3. Recommended Default Values
Address Name
Address
Recommended Value
0x6EC4C100
0x2EA610E4
0x1221109C
0x0C321200
0x024224B0
0x4CCC03E0
0x000CE944
0x00A00510
0x5DC04C84
0x60F43025
0x7F87A009
0x0548A186
0x3A840000
0x6ADB44A6
0x392DFF80
0x2D720600
0x08000000
0x7FFF0000
0x00000000
0x1C440000
0x00000000
ISD_CONFIG
0x00000080
0x00000082
0x00000084
0x00000086
0x00000088
0x0000008A
0x0000008C
0x0000008E
0x00000090
0x00000092
0x00000094
0x0000009A
0x0000009C
0x00000096
0x00000098
0x000000A4
0x000000A6
0x000000A8
0x000000AA
0x000000AC
0x000000AE
MOTOR_STARTUP1
MOTOR_STARTUP2
CLOSED_LOOP1
CLOSED_LOOP2
CLOSED_LOOP3
CLOSED_LOOP4
CONST_SPEED
CONST_PWR
FAULT_CONFIG1
FAULT_CONFIG2
TRAP_CONFIG1
TRAP_CONFIG2
150_DEG_TWO_PH_PROFILE
150_DEG_THREE_PH_PROFILE
PIN_CONFIG1
PIN_CONFIG2
DEVICE_CONFIG
PERIPH_CONFIG
GD_CONFIG1
GD_CONFIG2
Once the device EEPROM is programmed with the desired configuration, device can be operated stand-alone
and I2C serial interface is not required anymore. Speed can be commanded using SPEED pin.
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Below are the two essential parameters that are required to spin the motor in closed loop.
1. Maximum motor speed.
2. Cycle by cycle (CBC) current limit.
9.2.1 Application curves
9.2.1.1 Motor startup
Figure 9-2 shows the phase current waveforms of various startup methods in MCT8316A such as align, double
align, IPD and slow first cycle.
Figure 9-2. Motor phase current waveforms of all startup methods
9.2.1.2 120o and variable commutation
In 120° commutation scheme, each motor phase is driven for 120° and Hi-Z for 60° within each half electrical
cycle, resulting in six different commutation states for a motor. Figure 9-3 shows the phase current and current
waveform FFT in 120° commutation mode. In variable commutation scheme, MCT8316A device switches
dynamically between 120° and 150° trapezoidal commutation depending on motor speed. The device operates
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in 150° mode at lower speeds and moves to 120° mode at higher speeds. Figure 9-4 shows the phase current
and current waveform FFT in 150° commutation.
Phase current
FFT
Figure 9-3. Phase current and FFT - 120 ocommutation
Phase current
FFT
Figure 9-4. Phase current and FFT - 150ocommutation
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9.2.1.3 Faster startup time
Startup time is the time taken for the motor to reach the target speed from zero speed. Faster startup time can
be achieved in MCT8316A by tuning motor startup, open loop and closed loop settings. Figure 9-5 shows FG,
phase current and motor electrical speed waveform. Motor takes 50 ms to reach target speed from zero speed.
FG
Phase current
Speed
Figure 9-5. Phase current, FG and motor speed - Faster startup time
9.2.1.4 Setting the BEMF threshold
The BEMF_THRESHOLD1 and BEMF_THRESHOLD2 values used for commutation instant detection in
MCT8316A can be computed from the motor phase voltage waveforms during coasting. For example, consider
the three-phase voltage waveforms of a BLDC motor while coasting as in Figure 9-6. The motor phase voltage
during coasting is the motor back-EMF.
Figure 9-6. Motor phase voltage during coasting
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In Figure 9-6, one floating phase voltage interval is denoted by the vertical markers on channel 3. The Vpeak
(peak-peak back-EMF) on channel 3 is 208-mV and Tc (commutation interval) is 2.22-ms as denoted by the
horizontal and vertical markers on channel 3. The digital equivalent counts for Vpeak and Tc are calculated as
follows.
In MCT8316A, a 3-V analog input corresponds to 4095 counts(12-bit) and phase voltage is scaled down by
10x factor before ADC input; therfore, Vpeak of 208-mV corresponds to an ADC input of 20.8mV, which in turn
equals 29 ADC counts. Assuming the PWM switching frequency is 25-kHz, one back-EMF sample is available
every 40-μs. So, in a time interval of 2.22-ms, a total of 55 back-EMF samples are integrated. Therefore, the
BEMF_THRESHOLD1 or BEMF_THRESHOLD2 value calculated as per Equation 8 is (½) * (29/2) * (55/2) =
199. Hence, in this example, BEMF_THRESHOLD1 and BEMF_THRESHOLD2 are set to 8h (corresponding to
200 which is the closest value to 199) for commutation instant detection using back-EMF integration method
during fast start-up. The exact speed at which the Vpeak and Tc values are measured to calculate the
BEMF_THRESHOLD1 and BEMF_THRESHOLD2 values is not critical (as long as there is sufficient resolution
in digital counts) since the product (Vpeak * Tc) is, largely, a constant for a given BLDC motor.
9.2.1.5 Maximum speed
Figure 9-7 shows phase current, phase voltage and FG of a motor that spins at maximum electrical speed of 3
kHz.
Phase current
Phase voltage
FG
Figure 9-7. Phase current, Phase voltage and FG at Maximum speed
9.2.1.6 Faster deceleration
MCT8316A has features to decelerate the motor quickly. Figure 9-8 shows phase current and motor electrical
speed waveform when the motor decelerates from 100% duty cycle to 10% duty cycle. Time taken for the motor
to decelerate from 100% duty cycle to 10% duty cycle when fast deceleration is disabled is around 10 seconds.
Figure 9-9 shows phase current and motor electrical speed waveform when the motor decelerates from 100%
duty cycle to 10% duty cycle. Time taken for the motor to decelerate from 100% duty cycle to 10% duty cycle
when fast deceleration is enabled is around 1.5 seconds.
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Note
Please note that when fast deceleration is enabled and anti-voltage surge (AVS) is disabled, there
might be voltage spikes seen in supply voltage. Enable AVS to protect the power supply from voltage
overshoots during motor deceleration.
Phase current
Speed
Figure 9-8. Phase current and motor speed - Faster deceleration disabled
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Phase current
Speed
Figure 9-9. Phase current and motor speed -Faster deceleration enabled
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10 Power Supply Recommendations
10.1 Bulk Capacitance
Having an appropriate local bulk capacitance is an important factor in motor drive system design. It is generally
beneficial to have more bulk capacitance, while the disadvantages are increased cost and physical size.
The amount of local capacitance needed depends on a variety of factors, including:
•
•
•
•
•
•
The highest current required by the motor system
The capacitance and current capability of the power supply
The amount of parasitic inductance between the power supply and motor system
The acceptable voltage ripple
The type of motor used (brushed DC, brushless DC, stepper)
The motor braking method
The inductance between the power supply and the motor drive system limits the rate at which current can
change from the power supply. If the local bulk capacitance is too small, the system responds to excessive
current demands or dumps from the motor with a change in VM voltage. When adequate bulk capacitance is
used, the VM voltage remains stable and high current can be quickly supplied.
The data sheet generally provides a recommended value, but system-level testing is required to determine the
appropriate bulk capacitor.
Parasitic Wire
Inductance
Motor Drive System
Power Supply
VM
+
+
Motor Driver
œ
GND
Local
Bulk Capacitor
IC Bypass
Capacitor
Figure 10-1. Example Setup of Motor Drive System With External Power Supply
The voltage rating for bulk capacitors should be higher than the operating voltage, to provide margin for cases
when the motor transfers energy to the supply.
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11 Layout
11.1 Layout Guidelines
The bulk capacitor should be placed to minimize the distance of the high-current path through the motor driver
device. The connecting metal trace widths should be as wide as possible, and numerous vias should be used
when connecting PCB layers. These practices minimize parasitic inductance and allow the bulk capacitor to
deliver high current.
Small-value capacitors should be ceramic, and placed closely to device pins.
The high-current device outputs should use wide metal traces.
To reduce noise coupling and EMI interference from large transient currents into small-current signal paths,
grounding should be partitioned between PGND and AGND. TI recommends connecting all non-power stage
circuitry (including the thermal pad) to AGND to reduce parasitic effects and improve power dissipation from the
device. Optionally, GND_BK can be split. Ensure grounds are connected through net-ties or wide resistors to
reduce voltage offsets and maintain gate driver performance.
The device thermal pad should be soldered to the PCB top-layer ground plane. Multiple vias should be used to
connect to a large bottom-layer ground plane. The use of large metal planes and multiple vias helps dissipate
the I2 × RDS(on) heat that is generated in the device.
To improve thermal performance, maximize the ground area that is connected to the thermal pad ground across
all possible layers of the PCB. Using thick copper pours can lower the junction-to-air thermal resistance and
improve thermal dissipation from the die surface.
Separate the SW_BK and FB_BK traces with ground separation to reduce buck switching from coupling as noise
into the buck outer feedback loop. Widen the FB_BK trace as much as possible to allow for faster load switching.
Figure 11-1 shows a layout example for the MCT8316A. Also, for layout example, refer to MCT8316A EVM.
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11.2 Layout Example
Figure 11-1. Recommended Layout Example
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11.3 Thermal Considerations
The MCT8316A has thermal shutdown (TSD) as previously described. A die temperature in excess of 150°C
(minimally) disables the device until the temperature drops to a safe level.
Any tendency of the device to enter thermal shutdown is an indication of excessive power dissipation, insufficient
heatsinking, or too high an ambient temperature.
11.3.1 Power Dissipation
The power dissipated in the output FET resistance (RDS(on)) dominates power dissipation in MCT8316A.
At start-up and fault conditions, the FET current is much higher than normal operating FET current; remember to
take these peak currents and their duration into consideration.
The total device power dissipation is the power dissipated in each of the three half-bridges added together along
with standby power, LDO and buck regulator losses.
The maximum amount of power that the device can dissipate depends on ambient temperature and heatsinking.
Note that RDS(on) increases with temperature, so as the device heats, the power dissipation increases. Take this
into consideration when sizing the heatsink.
A summary of equations for calculating each loss is shown below in Table 11-1.
Table 11-1. Power Losses for MCT8316A
Loss type
Standby power
LDO
MCT8316A
Pstandby = VM x IVM_TA
PLDO = (VM-VAVDD) x IAVDD, if BUCK_PS_DIS = 1b
PLDO = (VBK-VAVDD) x IAVDD, if BUCK_PS_DIS = 0b
PCON = 2 x (IRMS(trap))2 x Rds,on(TA)
FET conduction
FET switching
Diode
PSW = IPK(trap) x VPK(trap) x trise/fall x fPWM
Pdiode = IPK(trap) x Vdiode x tdead x fPWM
Demagnetization
Without Active Demag: 3 x IPK(trap) x Vdiode x tcommutation x fmotor_elec
With Active Demag: 3 x (IRMS(trap))2 x Rds,on(TA) x tcommutation
x
fmotor_elec
PBK = 0.11 x VBK x IBK (ηBK = 90%)
Buck
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12 Device and Documentation Support
12.1 Support Resources
TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight
from the experts. Search existing answers or ask your own question to get the quick design help you need.
Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do
not necessarily reflect TI's views; see TI's Terms of Use.
12.2 Trademarks
TI E2E™ is a trademark of Texas Instruments.
All trademarks are the property of their respective owners.
12.3 Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled
with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may
be more susceptible to damage because very small parametric changes could cause the device not to meet its published
specifications.
12.4 Glossary
TI Glossary
This glossary lists and explains terms, acronyms, and definitions.
13 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most-
current data available for the designated device. This data is subject to change without notice and without
revision of this document. For browser-based versions of this data sheet, see the left-hand navigation pane.
13.1 Tape and Reel Information
REEL DIMENSIONS
TAPE DIMENSIONS
K0
P1
W
B0
Reel
Diameter
Cavity
A0
A0 Dimension designed to accommodate the component width
B0 Dimension designed to accommodate the component length
K0 Dimension designed to accommodate the component thickness
Overall width of the carrier tape
W
P1 Pitch between successive cavity centers
Reel Width (W1)
QUADRANT ASSIGNMENTS FOR PIN 1 ORIENTATION IN TAPE
Sprocket Holes
Q1 Q2
Q3 Q4
Q1 Q2
Q3 Q4
User Direction of Feed
Pocket Quadrants
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Reel
Diameter
(mm)
Reel
Width W1
(mm)
Package
Type
Package
Drawing
A0
(mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
(mm)
Pin1
Quadrant
Device
Pins
SPQ
MCT8316A1TRGFR
VQFN
RGF
40
3000
330.0
16.4
5.25
7.25
1.45
8.0
16.0
Q1
TAPE AND REEL BOX DIMENSIONS
Width (mm)
H
W
L
Device
Package Type
Package Drawing Pins
RGF 40
SPQ
3000
Length (mm) Width (mm)
367.0 367.0
Height (mm)
MCT8316A1TRGFR
VQFN
38.0
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PACKAGE OPTION ADDENDUM
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5-Jan-2022
PACKAGING INFORMATION
Orderable Device
Status Package Type Package Pins Package
Eco Plan
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
Samples
Drawing
Qty
(1)
(2)
(3)
(4/5)
(6)
MCT8316A1VRGFR
ACTIVE
VQFN
RGF
40
3000 RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 125
MCT83
16A1V
PMCT8316A1TRGFR
PMCT8316A1VRGFR
ACTIVE
ACTIVE
VQFN
VQFN
RGF
RGF
40
40
3000
3000
TBD
TBD
Call TI
Call TI
Call TI
Call TI
-40 to 125
-40 to 125
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based
flame retardants must also meet the <=1000ppm threshold requirement.
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two
lines if the finish value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
Addendum-Page 1
PACKAGE OPTION ADDENDUM
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5-Jan-2022
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
2-Jan-2022
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
B0
K0
P1
W
Pin1
Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant
(mm) W1 (mm)
MCT8316A1VRGFR
VQFN
RGF
40
3000
330.0
16.4
5.25
7.25
1.45
8.0
16.0
Q1
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
2-Jan-2022
*All dimensions are nominal
Device
Package Type Package Drawing Pins
VQFN RGF 40
SPQ
Length (mm) Width (mm) Height (mm)
367.0 367.0 35.0
MCT8316A1VRGFR
3000
Pack Materials-Page 2
PACKAGE OUTLINE
VQFN - 1 mm max height
PLASTIC QUAD FLAT PACK- NO LEAD
A
RGF0040E
5.1
4.9
B
PIN 1 INDEX AREA
7.1
6.9
1 MAX
C
SEATING PLANE
0.08 C
3.8
3.6
3.5
0.05
0.00
(0.1) TYP
20
13
36X 0.5
21
12
SYMM
41
5.8
5.6
5.5
1
32
0.3
40X
PIN 1 ID
(OPTIONAL)
0.2
33
40
SYMM
0.1
C A B
C
0.5
0.3
40X
0.05
4224999/B 06/2021
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. The package thermal pad must be soldered to the printed circuit board for optimal thermal and mechanical performance.
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EXAMPLE BOARD LAYOUT
VQFN - 1 mm max height
RGF0040E
PLASTIC QUAD FLAT PACK- NO LEAD
(4.8)
(3.7)
(3.5)
40
33
40X (0.6)
40X (0.25)
1
32
(Ø0.2) TYP
VIA
SYMM
41
(5.7) (5.5)
(6.8)
(1.35)
(1.25)
21
12
13
20
(R0.05) TYP
36x (0.5)
(0.625)
(0.975)
SYMM
LAND PATTERN EXAMPLE
EXPOSED METAL SHOWN
SCALE: 12X
0.07 MIN
ALL AROUND
0.07 MAX
ALL AROUND
SOLDER MASK
OPENING
METAL
EXPOSED METAL
SOLDER MASK
OPENING
EXPOSED METAL
METAL UNDER
SOLDER MASK
NON- SOLDER MASK
DEFINED
SOLDER MASK
DEFINED
(PREFERRED)
SOLDER MASK DETAILS
4224999/B 06/2021
NOTES: (continued)
4. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas Instruments literature
number SLUA271 (www.ti.com/lit/slua271).
5. Vias are optional depending on application, refer to device data sheet. If any vias are implemented, refer to their locations shown
on this view. It is recommended that vias under paste be filled, plugged or tented.
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EXAMPLE STENCIL DESIGN
VQFN - 1 mm max height
RGF0040E
PLASTIC QUAD FLAT PACK- NO LEAD
(4.8)
(3.5)
36X (0.5)
40
33
40X (0.6)
40X (0.25)
41
1
32
12X
(1.15)
SYMM
(5.5)
(6.8)
(0.675)
(1.35)
12
21
(R0.05) TYP
13
20
(1.25)
12X (1.05)
SYMM
SOLDER PASTE EXAMPLE
BASED ON 0.125 mm THICK STENCIL
EXPOSED PAD
69% PRINTED COVERAGE BY AREA
SCALE: 12X
4224999/B 06/2021
NOTES: (continued)
6. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
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