ADM1064ACP-REEL [ADI]
Super Sequencer with Voltage Readback ADC; 超音序器与电压回读ADC型号: | ADM1064ACP-REEL |
厂家: | ADI |
描述: | Super Sequencer with Voltage Readback ADC |
文件: | 总32页 (文件大小:531K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Super Sequencer™ with
Voltage Readback ADC
ADM1064
FEATURES
FUNCTIONAL BLOCK DIAGRAM
AUX1 AUX2
REFIN
REFOUT REFGND SDA SCL A1
A0
Complete supervisory and sequencing solution for up to
10 supplies
10 supply fault detectors enable supervision of supplies to
better than 1% accuracy
ADM1064
SMBus
VREF
INTERFACE
5 selectable input attenuators allow supervision:
Supplies up to 14.4 V on VH
12-BIT
SAR ADC
EEPROM
Supplies up to 6 V on VP1–4
5 dual-function inputs, VX1–5:
High impedance input to supply fault detector with
thresholds between 0.573 V and 1.375 V
CONFIGURABLE
OUTPUT
DRIVERS
VX1
VX2
VX3
VX4
VX5
PDO1
PDO2
PDO3
PDO4
PDO5
PDO6
DUAL-
FUNCTION
INPUTS
(HV CAPABLE
OF DRIVING
GATES OF
(LOGIC INPUTS
OR
SFDs)
N-CHANNEL FET)
General-purpose logic input
SEQUENCING
ENGINE
10 programmable output drivers (PDO1–10):
Open collector with external pull-up
Push/pull output, driven to VDDCAP or VPn
Open collector with weak pull-up to VDDCAP or VPn
VP1
VP2
VP3
VP4
VH
PDO7
PDO8
PDO9
CONFIGURABLE
OUTPUT
DRIVERS
PROGRAMMABLE
RESET
GENERATORS
(LV CAPABLE
OF DRIVING
LOGIC SIGNALS)
(SFDs)
PDO10
Internally charge-pumped high drive for use with external
N-FET (PDO1–6 only)
AGND
PDOGND
VDDCAP
VDD
ARBITRATOR
Sequencing engine (SE) implements state machine control of
PDO outputs:
GND
State changes conditional on input events
Enables complex control of boards
Power-up and power-down sequence control
Fault event handling
Figure 1.
APPLICATIONS
Central office systems
Servers/routers
Interrupt generation on warnings
Multivoltage system line cards
DSP/FPGA supply sequencing
In-circuit testing of margined supplies
Watchdog function can be integrated in SE
Program software control of sequencing through SMBus
12-bit ADC for readback of all supervised voltages
2 auxiliary (single-ended) ADC inputs
Reference input, REFIN, has 2 input options:
Driven directly from 2.048V ( 0.25%) REFOUT pin
More accurate external reference for improved ADC
performance
Device powered by the highest of VP1–4, VH for improved
redundancy
User EEPROM: 256 bytes
GENERAL DESCRIPTION
The ADM1064 is a configurable supervisory/sequencing device
that offers a single-chip solution for supply monitoring and
sequencing in multiple supply systems. In addition to these
functions, the ADM1064 integrates a 12-bit ADC which can be
used to accurately read back up to 12 separate voltages.
Industry-standard 2-wire bus interface (SMBus)
Guaranteed PDO low with VH, VPn = 1.2 V
(continued on Page 3)
40-lead 6 mm × 6 mm LFCSP and
48-lead 7 mm × 7 mm TQFP packages
Rev. 0
Information furnished by Analog Devices is believed to be accurate and reliable.
However, no responsibility is assumed by Analog Devices for its use, nor for any
infringements of patents or other rights of third parties that may result from its use.
Specifications subject to change without notice. No license is granted by implication
or otherwise under any patent or patent rights of Analog Devices. Trademarks and
registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
Fax: 781.326.8703
www.analog.com
© 2004 Analog Devices, Inc. All rights reserved.
ADM1064
TABLE OF CONTENTS
General Description......................................................................... 3
SMBus Jump/Unconditional Jump .......................................... 17
Sequencing Engine Application Example ............................... 18
Sequence Detector...................................................................... 19
Monitoring Fault Detector........................................................ 19
Timeout Detector....................................................................... 19
Fault Reporting........................................................................... 19
Voltage Readback............................................................................ 20
Supply Supervision with the ADC ........................................... 20
Applications Diagram.................................................................... 21
Communicating with the ADM1064........................................... 22
Configuration Download at Power-Up................................... 22
Updating the Configuration ..................................................... 22
Updating the Sequencing Engine............................................. 23
Internal Registers........................................................................ 23
EEPROM ..................................................................................... 23
Serial Bus Interface..................................................................... 23
Write Operations........................................................................ 25
Read Operations......................................................................... 27
Outline Dimensions....................................................................... 29
Ordering Guide .......................................................................... 29
Specifications..................................................................................... 4
Pin Configurations and Function Descriptions ........................... 7
Absolute Maximum Ratings............................................................ 8
Thermal Characteristics .............................................................. 8
ESD Caution.................................................................................. 8
Typical Performance Characteristics ............................................. 9
Powering the ADM1064 ................................................................ 12
Inputs................................................................................................ 13
Supply Supervision..................................................................... 13
Programming the Supply Fault Detectors............................... 13
Input Comparator Hysteresis.................................................... 14
Input Glitch Filtering ................................................................. 14
Supply Supervision with VXn Inputs....................................... 14
VXn Pins as Digital Inputs........................................................ 15
Outputs ............................................................................................ 16
Supply Sequencing through Configurable Output Drivers .. 16
Sequencing Engine ......................................................................... 17
Overview...................................................................................... 17
Warnings ...................................................................................... 17
REVISION HISTORY
10/04—Revision 0: Initial Version
Rev. 0 | Page 2 of 32
ADM1064
GENERAL DESCRIPTION
(continued from Page 1)
This design enables very flexible sequencing of the outputs,
based on the condition of the inputs.
The device also provides up to ten programmable inputs for
monitoring under, over, or out-of-window faults on up to ten
supplies. In addition, ten programmable outputs can be used as
logic enables. Six of them can also provide up to a 12 V output
for driving the gate of an N-channel FET, which can be placed
in the path of a supply.
The device is controlled via configuration data that can be
programmed into an EEPROM. The whole configuration can
be programmed using an intuitive GUI-based software package
provided by ADI.
The logical core of the device is a sequencing engine. This state-
machine-based construction provides up to 63 different states.
AUX2 AUX1
REFIN REFOUT REFGND SDA SCL A1
A0
SMBus
INTERFACE
ADM1064
VREF
OSC
12-BIT
SAR ADC
DEVICE
CONTROLLER
EEPROM
GPI SIGNAL
CONDITIONING
CONFIGURABLE
O/P DRIVER
(HV)
PDO1
VX1
SFD
PDO2
PDO3
PDO4
PDO5
VX2
VX3
VX4
GPI SIGNAL
CONDITIONING
CONFIGURABLE
O/P DRIVER
(HV)
PDO6
SEQUENCING
ENGINE
VX5
VP1
SFD
SFD
CONFIGURABLE
O/P DRIVER
(LV)
SELECTABLE
ATTENUATOR
PDO7
VP2
VP3
VP4
PDO8
PDO9
CONFIGURABLE
O/P DRIVER
(LV)
SELECTABLE
ATTENUATOR
VH
SFD
PDO10
AGND
PDOGND
REG 5.25V
CHARGE PUMP
VDD
ARBITRATOR
VDDCAP
GND
VCCP
Figure 2. Detailed Block Diagram
Rev. 0 | Page 3 of 32
ADM1064
SPECIFICATIONS
VH = 3.0 V to 14.4 V1, VPn = 3.0 V to 6.0 V1, TA = −40°C to +85°C, unless otherwise noted.
Table 1.
Parameter
Min
Typ
Max
Unit
Test Conditions/Comments
POWER SUPPLY ARBITRATION
VH, VPn
VP
VH
VDDCAP
3.0
V
V
V
V
Minimum supply required on one of VPn, VH
Maximum VDDCAP = 5.1 V, typical
VDDCAP = 4.75 V
Regulated LDO output
Minimum recommended decoupling capacitance
6.0
14.4
5.4
2.7
10
4.75
CVDDCAP
µF
POWER SUPPLY
Supply Current, IVH, IVPn
Additional Currents
All PDO FET Drivers On
4.2
1
6
2
mA
VDDCAP = 4.75 V, PDO1–10 off, DACs off, ADC off
mA
mA
VDDCAP = 4.75 V, PDO1-6 loaded with 1 µA each,
PDO7–10 off
Maximum additional load that can be drawn from
all PDO pull-ups to VDDCAP
Current Available from VDDCAP
DACs Supply Current
ADC Supply Current
EEPROM Erase Current
SUPPLY FAULT DETECTORS
VH Pin
2.2
1
10
mA
mA
mA
6 DACs on with 100 µA maximum load on each
Running round-robin loop
1 ms duration only, VDDCAP = 3 V
Input Attenuator Error
Detection Ranges
High Range
0.05
%
Midrange and high range
6
2.5
14.4
6
V
V
Midrange
VPn Pins
Input Attenuator Error
Detection Ranges
Midrange
Low Range
Ultralow Range
VX Pins
Input Impedance
Detection Ranges
Ultralow Range
Absolute Accuracy
0.05
%
Low range and midrange
No input attenuation error
No input attenuation error
2.5
1.25
0.573
6
3
V
V
V
1.375
1
MΩ
0.573
1.375
1
V
%
VREF error + DAC nonlinearity + comparator offset
error + input attenuation error
Threshold Resolution
Digital Glitch Filter
8
0
100
Bits
µs
µs
Minimum programmable filter length
Maximum programmable filter length
ANALOG-TO-DIGITAL CONVERTER
Signal Range
0
VREFIN
V
The ADC can convert signals presented to the VH,
VPn, and VX_GPIn pins. VPn and VH input signals
are attenuated depending on selected range. A
signal at the pin corresponding to the selected
range is from 0.573 V to 1.375 V at the ADC input.
Rev. 0 | Page 4 of 32
ADM1064
Parameter
Min
Typ
Max
Unit
Test Conditions/Comments
Input Reference Voltage on REFIN Pin,
VREFIN
2.048
V
Resolution
INL
Gain Error
Conversion Time
12
Bits
LSB
%
ms
ms
LSB
2.5
0.05
Endpoint corrected, VREFIN = 2.048 V
VREFIN = 2.048 V
One conversion on one channel
All 12 channels selected, 16x averaging enabled
VREFIN = 2.048 V
0.44
84
Offset Error
2
Input Noise
0.25
LSBrms Direct input (no attenuator)
REFERENCE OUTPUT
Reference Output Voltage
Load Regulation
2.043
1
2.048
−0.25
0.25
2.053
V
No load
mV
mV
µF
mV
dB
Sourcing current, IDACnMAX = −100 µA
Sinking current, IDACnMAX = 100 µA
Capacitor required for decoupling, stability
Per 100 µA
Minimum Load Capacitance
Load Regulation
PSRR
2
60
DC
PROGRAMMABLE DRIVER OUTPUTS
High Voltage (Charge Pump) Mode
(PDO1–6)
Output Impedance
VOH
500
12.5
12
kΩ
V
V
11
10.5
14
13.5
IOH = 0
IOH = 1µA
2 V < VOH < 7 V
IOUTAVG
20
µA
Standard (Digital Output) Mode (PDO1–10)
VOH
2.4
V
V
V
V
mA
mA
kΩ
mA
VPU (pull-up to VDDCAP or VPN) = 2.7 V, IOH = 0.5 mA
VPU to Vpn = 6.0 V, IOH = 0 mA
VPU ≤ 2.7 V, IOH = 0.5 mA
4.5
VPU − 0.3
0
VOL
0.50
20
60
IOL = 20 mA
2
IOL
Maximum sink current per PDO pin
Maximum total sink for all PDOs
Internal pull-up
Current load on any VPn pull-ups, that is, total
source current available through any number of
PDO pull-up switches configured onto any one
2
ISINK
RPULL-UP
ISOURCE (VPn)2
20
2
Three-State Output Leakage Current
Oscillator Frequency
10
110
µA
kHz
VPDO = 14.4 V
All on-chip time delays derived from this clock
90
2.0
−1
100
DIGITAL INPUTS (VXn, A0, A1)
Input High Voltage, VIH
Input Low Voltage, VIL
Input High Current, IIH
Input Low Current, IIL
Input Capacitance
V
V
µA
µA
pF
µA
Maximum VIN = 5.5 V
Maximum VIN = 5.5 V
VIN = 5.5 V
0.8
1
VIN = 0
5
20
Programmable Pull-Down Current,
IPULL-DOWN
VDDCAP = 4.75, TA = 25°C, if known logic state is
required
SERIAL BUS DIGITAL INPUTS (SDA, SCL)
Input High Voltage, VIH
2.0
V
V
V
Input Low Voltage, VIL
0.8
0.4
2
Output Low Voltage, VOL
IOUT = −3.0 mA
Rev. 0 | Page 5 of 32
ADM1064
Parameter
Min
Typ
Max
Unit
Test Conditions/Comments
SERIAL BUS TIMING
Clock Frequency, fSCLK
Bus Free Time, tBUF
Start Setup Time, tSU;STA
Start Hold Time, tHD;STA
SCL Low Time, tLOW
SCL High Time, tHIGH
SCL, SDA Rise Time, tr
SCL, SDA Fall Time, tf
Data Setup Time, tSU;DAT
Data Hold Time, tHD;DAT
Input Low Current, IIL
SEQUENCING ENGINE TIMING
State Change Time
400
kHz
µs
µs
µs
µs
µs
µs
µs
ns
ns
µA
4.7
4.7
4
4.7
4
1000
300
250
5
1
VIN = 0
10
µs
1 At least one of the VH, VP1-4 pins must be ≥ 3.0 V to maintain the device supply on VDDCAP.
2 Specification is not production tested, but is supported by characterization data at initial product release.
Rev. 0 | Page 6 of 32
ADM1064
PIN CONFIGURATIONS AND FUNCTION DESCRIPTIONS
48 47 46 45 44 43 42 41 40 39 38 37
40 39 38 37 36 35 34 33 32 31
NC
1
2
3
4
5
6
7
8
9
36 NC
VX1
VX2
VX3
VX4
VX5
VP1
VP2
VP3
VP4
1
2
3
4
5
6
7
8
9
30 PDO1
29 PDO2
28 PDO3
27 PDO4
26 PDO5
25 PDO6
24 PDO7
23 PDO8
22 PDO9
21 PDO10
PIN 1
INDICATOR
PIN 1
VX1
VX2
VX3
VX4
VX5
VP1
VP2
VP3
35 PDO1
34 PDO2
33 PDO3
32 PDO4
31 PDO5
30 PDO6
29 PDO7
28 PDO8
27 PDO9
26 PDO10
25 NC
INDICATOR
ADM1064
ADM1064
TOP VIEW
TOP VIEW
(Not to Scale)
(Not to Scale)
VP4 10
VH 11
NC 12
VH 10
11 12 13 14 15 16 17 18 19 20
13 14 15 16 17 18 19 20 21 22 23 24
NC = NO CONNECT
NC = NO CONNECT
Figure 3. LFCSP Pin Configuration
Figure 4. TQFP Pin Configuration
Table 2. Pin Function Descriptions
Pin No.
Mnemonic Description
LFCSP TQFP
15-20
1, 12–13,
NC
No connection.
18–25,
36–37, 48
1–5
6–9
2–6
VX1–5
VP1–4
High Impedance Inputs to Supply Fault Detectors. Fault thresholds can be set from 0.573 V to 1.375 V.
Alternatively, these pins can be used as general-purpose digital inputs.
Low Voltage Inputs to Supply Fault Detectors. Three input ranges can be set by altering the input
attenuation on a potential divider connected to these pins, the output of which connects to a supply
fault detector. These pins allow thresholds from 2.5 V to 6.0 V, 1.25 V to 3.00 V, and 0.573 V to 1.375 V.
7–10
10
11
VH
High Voltage Input to Supply Fault Detectors. Three input ranges can be set by altering the input
attenuation on a potential divider connected to this pin, the output of which connects to a supply
fault detector. This pin allows thresholds from 6.0 V to 14.4 V and 2.5 V to 6.0 V.
11
12
13
14
14
15
16
17
AGND
REFGND
REFIN
REFOUT
PDO10–1
PDOGND
VCCP
Ground Return for Input Attenuators.
Ground Return for On-Chip Reference Circuits.
Reference Input for ADC. Nominally, 2.048 V.
2.048 V Reference Output.
Programmable Output Drivers.
Ground Return for Output Drivers.
21–30 26–35
31
32
38
39
Central Charge-Pump Voltage of 5.25 V. A reservoir capacitor must be connected between this pin
and GND.
33
34
35
36
37
38
39
40
40
41
42
43
44
45
46
47
A0
A1
SCL
SDA
AUX2
AUX1
VDDCAP
GND
Logic Input. This pin sets the seventh bit of the SMBus interface address.
Logic Input. This pin sets the sixth bit of the SMBus interface address.
SMBus Clock Pin. Open-drain output requires external resistive pull-up.
SMBus Data I/O Pin. Open-drain output requires external resistive pull-up.
Auxiliary, Single-Ended ADC Input.
Auxiliary, Single-Ended ADC Input.
Device Supply Voltage. Linearly regulated from the highest of the VP1–4, VH pins to a typical of 4.75 V.
Supply Ground.
Rev. 0 | Page 7 of 32
ADM1064
ABSOLUTE MAXIMUM RATINGS
Table 3.
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
Parameter
Rating
Voltage on VH Pin
16 V
Voltage on VP Pins
7 V
Voltage on VX Pins
−0.3 V to +6.5 V
−0.3 V to +5 V
5 mA
20 mA
150°C
Voltage on AUX1, AUX2, REFIN Pins
Input Current at Any Pin
Package Input Current
Maximum Junction Temperature (TJ max)
Storage Temperature Range
Lead Temperature, Soldering
Vapor Phase, 60 s
THERMAL CHARACTERISTICS
−65°C to +150°C
40-lead LFCSP package: θJA = 25°C/W
215°C
48-lead TQFP package: θJA = 14.8°C/W
ESD CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on
the human body and test equipment and can discharge without detection. Although this product features
proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy
electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance
degradation or loss of functionality.
Rev. 0 | Page 8 of 32
ADM1064
TYPICAL PERFORMANCE CHARACTERISTICS
6
180
160
140
120
100
80
5
4
3
2
1
0
60
40
20
0
0
0
0
1
2
3
4
5
6
16
6
0
0
0
1
2
3
4
5
6
16
6
V
(V)
V
(V)
VP1
VP1
Figure 5. VVDDCAP vs. VVP1
Figure 8. IVP1 vs. VVP1 (VP1 Not as Supply)
5.0
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0
6
5
4
3
2
1
0
2
4
6
8
10
12
14
2
4
6
8
10
12
14
V
(V)
V
(V)
VH
VH
Figure 9. IVH vs. VVH (VH as Supply)
Figure 6. VVDDCAP vs. VVH
350
300
250
200
150
100
50
5.0
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0
0
1
2
3
4
5
1
2
3
4
5
V
(V)
V
(V)
VH
VP1
Figure 10. IVH vs. VVH (VH Not as Supply)
Figure 7. IVP1 vs. VVP1 (VP1 as Supply)
Rev. 0 | Page 9 of 32
ADM1064
14
12
10
8
1.0
0.8
0.6
0.4
0.2
0
6
–0.2
–0.4
–0.6
–0.8
–1.0
4
2
0
0
2.5
5.0
I
7.5
10.0
A)
12.5
15.0
0
1000
2000
3000
4000
CURRENT (
µ
CODE
LOAD
Figure 11. VPDO1 (FET Drive Mode) vs. ILOAD
Figure 14. DNL for ADC
5.0
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
1.0
0.8
0.6
0.4
0.2
VP1 = 5V
0
VP1 = 3V
–0.2
–0.4
–0.6
–0.8
–1.0
0
0
1
2
3
4
5
6
0
1000
2000
3000
4000
I
(mA)
CODE
LOAD
Figure 12. VPDO1 (Strong Pull-Up VP) vs. ILOAD
Figure 15. INL for ADC
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
12000
10000
8000
6000
4000
2000
0
9894
VP1 = 5V
VP1 = 3V
25
81
0
0
10
20
30
40
50
60
2047
2048
2049
I
(µA)
LOAD
CODE
Figure 16. ADC Noise, Midcode Input, 10,000 Reads
Figure 13. VPDO1 (Weak Pull-Up to VP) vs. ILOAD
Rev. 0 | Page 10 of 32
ADM1064
2.058
2.053
2.048
2.043
2.038
VP1 = 3.0V
VP1 = 4.75V
–40
–20
0
20
40
60
80
100
TEMPERATURE (°C)
Figure 17. REFOUT vs. Temperature
Rev. 0 | Page 11 of 32
ADM1064
POWERING THE ADM1064
The ADM1064 is powered from the highest voltage input on
either the positive-only supply inputs (VPn) or the high voltage
supply input (VH). This technique offers improved redundancy
as the device is not dependent on any particular voltage rail to
keep it operational. The same pins are used for supply fault
detection (discussed later in the next section). A VDD arbitrator
on the device chooses which supply to use. The arbitrator can
be considered an OR’ing of five LDOs together. A supply
comparator chooses which of the inputs is highest and selects
this one to provide the on-chip supply. There is minimal
switching loss with this architecture (~0.2 V), resulting in the
ability to power the ADM1064 from a supply as low as 3.0 V.
Note that the supply on the VXn pins cannot be used to power
the device.
Note that when two or more supplies are within 100 mV of each
other, the supply that takes control of VDD first keeps control.
For example, if VP1 is connected to a 3.3 V supply, then VDD
powers up to approximately 3.1 V through VP1. If VP2 is then
connected to another 3.3 V supply, VP1 still powers the device,
unless VP2 goes 100 mV higher than VP1.
VDDCAP
VP1
VP2
VP3
VP4
VH
IN
OUT
4.75V
LDO
EN
IN
OUT
4.75V
LDO
EN
IN
OUT
4.75V
LDO
EN
IN
An external capacitor to GND is required to decouple the on-
chip supply from noise. This capacitor should be connected to
the VDDCAP pin, as shown in Figure 18. The capacitor has
another use during brownouts (momentary loss of power).
Under these conditions, when the input supply (VPn or VH)
dips transiently below VDD, the synchronous rectifier switch
immediately turns off so that it does not pull VDD down. The
VDD cap can then act as a reservoir to keep the device active
until the next highest supply takes over the powering of the
device. 10 µF is recommended for this reservoir/decoupling
function.
OUT
4.75V
LDO
EN
IN
INTERNAL
DEVICE
SUPPLY
OUT
4.75V
LDO
EN
SUPPLY
COMPARATOR
Figure 18. VDD Arbitrator Operation
Rev. 0 | Page 12 of 32
ADM1064
INPUTS
SUPPLY SUPERVISION
The resolution is given by
The ADM1064 has ten programmable inputs. Five of these are
dedicated supply fault detectors (SFDs). These dedicated inputs
are called VH and VP1–4 by default. The other five inputs are
labeled VX1–VX5 and have dual functionality. They can be
used as either supply fault detectors, with similar functionality
to VH and VP1–4, or CMOS/TTL-compatible logic inputs to
the devices. Therefore, the ADM1064 can have up to ten analog
inputs, a minimum of five analog inputs and five digital inputs,
or a combination. If an input is used as an analog input, it
cannot be used as a digital input. Therefore, a configuration
requiring ten analog inputs has no digital inputs available. Table
5 shows the details of each of the inputs.
Step Size = Threshold Range/255
Therefore, if the high range is selected on VH, the step size can
be calculated as follows:
(14.4 V − 4.8 V)/255 = 37.6 mV
Table 4 lists the upper and lower limit of each available range,
the bottom of each range (VB), and the range itself (VR).
Table 4. Voltage Range Limits
Voltage Range (V)
0.573 to 1.375
1.25 to 3.00
VB (V)
0.573
1.25
2.5
VR (V)
0.802
1.75
3.5
RANGE
SELECT
2.5 to 6.0
ULTRA
LOW
OV
4.8 to 14.4
4.8
9.6
COMPARATOR
+
–
VPn
The threshold value required is given by
VT = (VR × N)/255 + VB
where:
GLITCH
FILTER
FAULT
OUTPUT
VREF
+
–
LOW
MID
UV
FAULT TYPE
SELECT
COMPARATOR
VT is the desired threshold voltage (UV or OV).
VR is the voltage range.
N is the decimal value of the 8-bit code.
Figure 19. Supply Fault Detector Block
VB is the bottom of the range.
PROGRAMMING THE SUPPLY FAULT DETECTORS
The ADM1064 has up to ten supply fault detectors (SFDs) on its
ten input channels. These highly programmable reset generators
enable the supervision of up to ten supply voltages. The supplies
can be as low as 0.573 V and as high as 14.4 V. The inputs can be
configured to detect an undervoltage fault (the input voltage
droops below a preprogrammed value), an overvoltage fault (the
input voltage rises above a preprogrammed value) or an out-of-
window fault (undervoltage or overvoltage). The thresholds can
be programmed to an 8-bit resolution in registers provided in
the ADM1064. This translates to a voltage resolution that is
dependent on the range selected.
Reversing the equation, the code for a desired threshold is
given by
N = 255 × (VT − VB)/VR
For example, if the user wants to set a 5 V OV threshold on VP1,
the code to be programmed in the PS1OVTH register
(discussed in the AN-698 application note) is given by
N = 255 × (5 − 2.5)/3.5
Therefore, N = 182 (1011 0110 or 0xB6).
Table 5. Input Functions, Thresholds, and Ranges
Input
Function
Voltage Range (V)
Maximum Hysteresis
425 mV
1.16 V
97.5 mV
212 mV
425 mV
97.5 mV
N/A
Voltage Resolution (mV)
Glitch Filter (µs)
0–100
0–100
0–100
0–100
0–100
0–100
0–100
VH
High V Analog Input
2.5–6.0
4.8–14.4
13.7
37.6
3.14
6.8
13.7
3.14
N/A
VPn
VXn
Positive Analog Input
0.573–1.375
1.25–3.00
2.5–6.0
0.573–1.375
0–5
High Z Analog Input
Digital Input
Rev. 0 | Page 13 of 32
ADM1064
INPUT PULSE SHORTER
THAN GLITCH FILTER TIMEOUT
INPUT PULSE LONGER
THAN GLITCH FILTER TIMEOUT
INPUT COMPARATOR HYSTERESIS
PROGRAMMED
TIMEOUT
PROGRAMMED
TIMEOUT
The UV and OV comparators shown in Figure 19 are always
looking at VPn. To avoid chattering (multiple transitions when
the input is very close to the set threshold level), these compara-
tors have digitally programmable hysteresis. The hysteresis can
be programmed up to the values shown in Table 5.
INPUT
INPUT
The hysteresis is added after a supply voltage goes out of
tolerance. Therefore, the user can program how much above the
UV threshold the input must rise again before a UV fault is
deasserted. Similarly, the user can program how much below the
OV threshold an input must fall again before an OV fault is
deasserted.
T
T
T
T
GF
0
GF
0
OUTPUT
OUTPUT
The hysteresis figure is given by
T
T
T
T
GF
0
GF
0
V
HYST = VR × NTHRESH/255
Figure 20. Input Glitch Filter Function
SUPPLY SUPERVISION WITH VXn INPUTS
where:
The VXn inputs have two functions. They can be used as either
supply fault detectors or digital logic inputs. When selected as
an analog (SFD) input, the VXn pins have very similar func-
tionality to the VH and VPn pins. The major difference is that
the VXn pins have only one input range: 0.573 V to 1.375 V.
Therefore, these inputs can directly supervise only the very low
supplies. However, the input impedance of the VXn pins is high,
allowing an external resistor divide network to be connected to
the pin. Thus, any supply can be potentially divided down into
the input range of the VXn pin and supervised. This enables the
ADM1064 to monitor other supplies such as +24 V, +48 V, and
−5 V.
V
N
HYST is the desired hysteresis voltage.
THRESH is the decimal value of the 5-bit hysteresis code.
Note that NTHRESH has a maximum value of 31. The maximum
hysteresis for the ranges is listed in Table 5.
INPUT GLITCH FILTERING
The final stage of the SFDs is a glitch filter. This block provides
time-domain filtering on the output of the SFD comparators.
This allows the user to remove any spurious transitions such as
supply bounce at turn-on. The glitch filter function is additional
to the digitally programmable hysteresis of the SFD compara-
tors. The glitch filter timeout is programmable up to 100 µs.
An additional supply supervision function is available when the
VXn pins are selected as digital inputs. In this case, the analog
function is available as a second detector on each of the dedi-
cated analog inputs, VP1–4 and VH. The analog function of
VX1 is mapped to VP1, VX2 is mapped to VP2, and so on. VX5
is mapped to VH. In this case, these SFDs can be viewed as a
secondary or warning SFD.
For example, when the glitch filter timeout is 100 µs, any pulses
appearing on the input of the glitch filter block that are less than
100 µs in duration are prevented from appearing on the output
of the glitch filter block. Any input pulse that is longer than
100 µs does appear on the output of the glitch filter block. The
output is delayed with respect to the input by 100 µs. The
filtering process is shown in Figure 20.
The secondary SFDs are fixed to the same input range as the
primary SFD. They are used to indicate warning levels rather
than failure levels. This allows faults and warnings to be gener-
ated on a single supply using only one pin. For example, if VP1
is set to output a fault if a 3.3 V supply droops to 3.0 V, VX1 can
be set to output a warning at 3.1 V. Warning outputs are available
for readback from the status registers. They are also OR’ed
together and fed into the sequencing engine (SE), allowing
warnings to generate interrupts on the PDOs. Therefore, in the
example above, if the supply droops to 3.1 V, a warning is
generated, and remedial action can be taken before the supply
drops out of tolerance.
Rev. 0 | Page 14 of 32
ADM1064
The digital blocks feature the same glitch filter function that is
available on the SFDs. This enables the user to ignore spurious
transitions on the inputs. For example, the filter can be used to
debounce a manual reset switch.
VXn PINS AS DIGITAL INPUTS
As mentioned previously, the VXn input pins on the ADM1064
have dual functionality. The second function is as a digital input
to the device. Therefore, the ADM1064 can be configured for up
to five digital inputs. These inputs are TTL/CMOS-compatible.
Standard logic signals can be applied to the pins: RESET from
reset generators, PWRGOOD signals, fault flags, manual resets,
and so on. These signals are available as inputs to the SE, and
can be used to control the status of the PDOs. The inputs can be
configured to detect either a change in level or an edge.
When configured as digital inputs, each of the VXn pins has a
weak (10 µA) pull-down current source available for placing the
input in a known condition, even if left floating. The current
source, if selected, weakly pulls the input to GND.
VXn
+
(DIGITAL INPUT)
TO
GLITCH
SEQUENCING
When configured for level detection, the output of the digital
block is a buffered version of the input. When configured for
edge detection, once the logic transition is detected, a pulse of
programmable width is output from the digital block. The width
is programmable from 0 µs to 100 µs.
DETECTOR
FILTER
ENGINE
–
VREF = 1.4V
Figure 21. VXn Digital Input Function
Rev. 0 | Page 15 of 32
ADM1064
OUTPUTS
from a backplane supply (a PDO can sustain greater than 10.5 V
into a 1 µA load). The pull-down switches can also be used to
drive status LEDs directly.
SUPPLY SEQUENCING THROUGH
CONFIGURABLE OUTPUT DRIVERS
Supply sequencing is achieved with the ADM1064 using the
programmable driver outputs (PDOs) on the device as control
signals for supplies. The output drivers can be used as logic
enables or as FET drivers.
The data driving each of the PDOs can come from one of three
sources. The source can be enabled in the PnPDOCFG
configuration register (see the AN-698 application note for
details).
The sequence in which the PDOs are asserted (and, therefore,
the supplies are turned on) is controlled by the sequencing
engine (SE). The SE determines what action is to be taken with
the PDOs based on the condition of the inputs of the ADM1064.
Therefore, the PDOs can be set up to assert when the SFDs are
in tolerance, the correct input signals are received on the VXn
digital pins, no warnings are received from any of the inputs of
the device, and so on. The PDOs can be used for a variety of
functions. The primary function is to provide enable signals for
LDOs or dc/dc converters, which generate supplies locally on a
board. The PDOs can also be used to provide a POWER_GOOD
signal when all the SFDs are in tolerance, or a RESET output if
one of the SFDs goes out of specification (this can be used as a
status signal for a DSP, FPGA, or other microcontroller).
The data sources are
• Output from the SE.
• Directly from the SMBus. A PDO can be configured so that
the SMBus has direct control over it. This enables software
control of the PDOs. Therefore, a microcontroller can be
used to initiate a software power-up/power-down sequence.
• On-Chip Clock. A 100 kHz clock is generated on the device.
This clock can be made available on any of the PDOs. It can
be used, for example, to clock an external device such as
an LED.
By default, the PDOs are pulled to GND by a weak (20 kΩ) on-
chip pull-down resistor. This is also the condition of the PDOs
on power-up, until the configuration is downloaded from
EEPROM and the programmed setup is latched. The outputs
are actively pulled low once a supply of 1 V or greater is on VPn
or VH. The outputs remain high impedance prior to 1 V
appearing on VPn or VH. This provides a known condition for
the PDOs during power-up. The internal pull-down can be
overdriven with an external pull-up of suitable value tied from
the PDO pin to the required pull-up voltage. The 20 kΩ resistor
must be accounted for in calculating a suitable value. For
example, if PDOn must be pulled up to 3.3 V, and 5 V is avail-
able as an external supply, the pull-up resistor value is given by
The PDOs can be programmed to pull up to a number of
different options. The outputs can be programmed as follows:
• Open-drain (allowing the user to connect an external pull-up
resistor)
• Open-drain with weak pull-up to VDD
• Push/pull to VDD
• Open-drain with weak pull-up to VPn
• Push/pull to VPn
• Strong pull-down to GND
3.3 V = 5 V × 20 kΩ/(RUP + 20 kΩ)
• Internally charge-pumped high drive (12 V, PDO1–6 only)
The last option (available only on PDO1–6) allows the user to
directly drive a voltage high enough to fully enhance an external
N-FET, which is used to isolate, for example, a card-side voltage
Therefore,
R
UP = (100 kΩ − 66 kΩ)/3.3 = 10 kΩ
VFET (PDO1-6 ONLY)
V
DD
VP4
VP1
SEL
CFG4 CFG5 CFG6
SE DATA
SMBus DATA
CLK DATA
PDO
Figure 22. Programmable Driver Output
Rev. 0 | Page 16 of 32
ADM1064
SEQUENCING ENGINE
OVERVIEW
• Transition from one state to the next is made in less than
20 µs, which is the time needed to download a state definition
from EEPROM to the SE.
The ADM1064’s sequencing engine (SE) provides the user with
powerful and flexible control of sequencing. The SE implements
a state machine control of the PDO outputs, with state changes
conditional on input events. SE programs can enable complex
control of boards such as power-up and power-down sequence
control, fault event handling, interrupt generation on warnings,
and so on. A watchdog function that verifies the continued
operation of a processor clock can be integrated into the SE
program. The SE can also be controlled via the SMBus, giving
software or firmware control of the board sequencing.
MONITOR
FAULT
STATE
TIMEOUT
SEQUENCE
Figure 23. State Cell
The SE state machine comprises 63 state cells. Each state has the
following attributes:
The ADM1064 offers up to 63 state definitions. The signals
monitored to indicate the status of the input pins are the
outputs of the SFDs.
• Monitors signals indicating the status of the 10 input pins,
VP1 to VP4, VH, and VX1 to VX5.
WARNINGS
The SE also monitors warnings. These warnings can be
generated when the ADC readings violate their limit register
value or when the secondary voltage monitors on VP1–4 and
VH. The warnings are all OR’ed together and are available as a
single warning input to each of the three blocks that enable
exiting from a state.
• Can be entered from any other state.
• Three exit routes move the state machine on to a next state:
sequence detection, fault monitoring, and timeout.
• Delay timers for the sequence and timeout blocks can be
programmed independently, and change with each state
change. The range of timeouts is from 0 ms to 400 ms.
SMBUS JUMP/UNCONDITIONAL JUMP
The SE can be forced to advance to the next state uncondition-
ally. This enables the user to force the SE to advance. Examples
of where this might be used include moving to a margining
state or debugging a sequence. The SMBus jump or go-to
command can be seen as another input to sequence and
timeout blocks, which provide an exit from each state.
• Output condition of the 10 PDO pins is defined and fixed
within a state.
Table 6. Sample Sequence State Entries
State
IDLE1
IDLE2
EN3V3
Sequence
Timeout
Monitor
If VX1 is low , go to state IDLE2.
If VP1 is okay, go to state EN3V3.
If VP2 is okay, go to state EN2V5.
If VP2 is not okay after 10 ms, go to
state DIS3V3.
If VP1 is not okay, go to state IDLE1.
DIS3V3
EN2V5
If VX1 is high, go to state IDLE1.
If VP3 is okay, go to state PWRGD.
If VP3 is not okay after 20 ms, go to
state DIS2V5.
If VP1 or VP2 is not okay, go to state FSEL2.
DIS2V5
FSEL1
FSEL2
If VX1 is high, go to state IDLE1.
If VP3 is not okay, go to state DIS2V5.
If VP2 is not okay, go to state DIS3V3.
If VX1 is high, go to state DIS2V5.
If VP1 or VP2 is not okay, go to state FSEL2.
If VP1 is not okay, go to state IDLE1.
If VP1, VP2, or VP3 is not okay, go to state
FSEL1.
PWRGD
Rev. 0 | Page 17 of 32
ADM1064
SEQUENCE
STATES
SEQUENCING ENGINE APPLICATION EXAMPLE
The application in this section demonstrates the operation of
the SE. Figure 24 shows how the simple building block of a
single SE state can be used to build a power-up sequence for a
3-supply system.
IDLE1
VX1 = 0
Table 7 lists the PDO outputs for each state in the same SE
implementation. In this system, the presence of a good 5 V
supply on VP1 and the VX1 pin held low are the triggers
required for a power-up sequence to start. The sequence intends
to turn on the 3.3 V supply next, then the 2.5 V supply (assuming
successful turn-on of the 3.3 V supply). Once all three supplies
are good, the PWRGD state is entered, where the SE remains
until a fault occurs on one of the three supplies, or it is instructed
to go through a power-down sequence by VX1 going high.
IDLE2
VP1 = 1
MONITOR FAULT
STATES
TIMEOUT
STATES
EN3V3
10ms
VP1 = 0
VP2 = 1
EN2V5
DIS3V3
20ms
Faults are dealt with throughout the power-up sequence on a
case-by-case basis. The following sections, which describe the
individual blocks, use this sample application to demonstrate
the state machine’s actions.
(VP1 + VP2) = 0
VX1 = 1
VP3 = 1
PWRGD
DIS2V5
VP2 = 0
(VP1 + VP2 + VP3) = 0
VX1 = 1
VX1 = 1
FSEL1
(VP1 +
VP2) = 0
VP3 = 0
FSEL2
VP1 = 0
VP2 = 0
Figure 24. Sample Application Flow Diagram
Table 7. PDO Outputs for Each State
PDO Outputs
PDO1 = 3V3ON
PDO2 = 2V5ON
PDO3 = FAULT
IDLE1
IDLE2
EN3V3
EN2V5
DIS3V3
DIS2V5
PWRGD
FSEL1
FSEL2
0
0
0
0
0
0
1
0
0
1
1
0
0
1
1
1
0
1
1
1
0
1
1
1
1
1
1
Rev. 0 | Page 18 of 32
ADM1064
MONITORING FAULT
DETECTOR
SEQUENCE DETECTOR
1-BIT FAULT
DETECTOR
The sequence detector block is used to detect when a step in a
sequence has been completed. It looks for one of the inputs to
the SE to change state, and is most often used as the gate on
successful progress through a power-up or power-down
sequence. A timer block is included in this detector, which can
insert delays into a power-up or power-down sequence, if
required. Timer delays can be set from 10 µs to 400 ms.
Figure 25 is a block diagram of the sequence detector.
FAULT
SUPPLY FAULT
DETECTION
VP1
MASK
SENSE
1-BIT FAULT
DETECTOR
FAULT
LOGIC INPUT CHANGE
OR FAULT DETECTION
VX5
SUPPLY FAULT
DETECTION
VP1
MASK
SENSE
SEQUENCE
DETECTOR
1-BIT FAULT
DETECTOR
LOGIC INPUT CHANGE
VX5
OR FAULT DETECTION
TIMER
FAULT
WARNINGS
WARNINGS
INVERT
MASK
FORCE FLOW
(UNCONDITIONAL JUMP)
Figure 26. Monitoring Fault Detector Block Diagram
SELECT
TIMEOUT DETECTOR
Figure 25. Sequence Detector Block Diagram
The timeout detector allows the user to trap a failure to make
proper progress through a power-up or power-down sequence.
The sequence detector can also help to identify monitoring
faults. In the sample application shown in Figure 24, the FSEL1
and FSEL2 states first identify which of the VP1,VP2, or VP3
pins has faulted, and then they take the appropriate action.
In the sample application shown in Figure 24, the timeout next-
state transition is from the EN3V3 and EN2V5 states. For the
EN3V3 state, the signal 3V3ON is asserted upon entry to this
state (on the PDO1 output pin) to turn on a 3.3 V supply. This
supply rail is connected to the VP2 pin, and the sequence detec-
tor looks for the VP2 pin to go above its UV threshold, which is
set in the supply fault detector (SFD) attached to that pin.
MONITORING FAULT DETECTOR
The monitoring fault detector block is used to detect a failure
on an input. The logical function implementing this is a wide
OR gate, which can detect when an input deviates from its
expected condition. The clearest demonstration of the use of
this block is in the PWRGD state, where the monitor block
indicates that a failure on one or more of the VP1,VP2, or VP3
inputs has occurred.
The power-up sequence progresses when this change is
detected. If, however, the supply fails (perhaps due to a short
circuit overloading this supply), then the timeout block traps
the problem. In this example, if the 3.3 V supply fails within
10 ms, then the SE moves to the DIS3V3 state and turns off this
supply by bringing PDO1 low. It also indicates that a fault has
occurred by taking PDO3 high. Timeout delays of from 100 µs
to 400 ms can be programmed.
No programmable delay is available in this block, because the
triggering of a fault condition is likely to be caused when a
supply falls out of tolerance. In this situation, the user would
want to react as quickly as possible. Some latency occurs when
moving out of this state, however, because it takes a finite
amount of time (~20 µs) for the state configuration to
download from EEPROM into the SE. Figure 26 is a block
diagram of the monitoring fault detector.
FAULT REPORTING
The ADM1064 has a fault latch for recording faults. Two
registers are set aside for this purpose. A single bit is assigned to
each input of the device, and a fault on that input sets the
relevant bit. The contents of the fault register can be read out
over the SMBus to determine which input(s) faulted. The fault
register can be enabled/disabled in each state. This ensures that
only real faults are captured and not, for example, undervoltage
trips when the SE is executing a power-down sequence.
Rev. 0 | Page 19 of 32
ADM1064
VOLTAGE READBACK
Table 8. ADC Input Voltage Ranges
The ADM1064 has an on-board 12-bit accurate ADC for
voltage readback over the SMBus. The ADC has a 12-channel
analog mux on the front end. The twelve channels consist of the
ten SFD inputs (VH, VP1-4, VX1-5) and two auxiliary (single-
ended) ADC inputs (AXU1, AUX2). Any or all of these inputs
can be selected to be read, in turn, by the ADC. The circuit
controlling this operation is called round-robin. The round-
robin circuit can be selected to run through its loop of conver-
sions just once or continuously. Averaging is also provided for
each channel. In this case, the round-robin circuit runs through
its loop of conversions 16 times before returning a result for
each channel. At the end of this cycle, the results are all written
to the output registers.
SFD Input
ADC Input Voltage
Range (V)
Range (V)
0.573–1.375
1.25–3
2.5–6
4.8–14.4
Attenuation Factor
1
0–2.048
0–4.46
0–6.01
2.181
4.363
10.472
0–14.41
_______________________________________________
1 The upper limit is the absolute maximum allowed voltage on these pins.
The normal way to supply the reference to the ADC on the
REFIN pin is to simply connect the REFOUT pin to the REFIN
pin. REFOUT provides a 2.048 V reference. As such, the
supervising range covers less than half of the normal ADC
range. It is possible, however, to provide the ADC with a more
accurate external reference for improved readback accuracy.
The ADC samples single-sided inputs with respect to the
AGND pin. A 0 V input gives out Code 0, and an input equal to
the voltage on REFIN gives out full code (4095 decimal).
Supplies can also be connected to the input pins purely for ADC
readback, even though they might go above the expected super-
visory range limits (but not above 6 V, because this violates the
absolute maximum ratings on these pins). For instance, a 1.5 V
supply connected to the VX1 pin can be correctly read out as an
ADC code of approximately 3/4 full scale, but it always sits
above any supervisory limits that can be set on that pin. The
maximum setting for the REFIN pin is 2.048 V.
The inputs to the ADC come directly from the VXn pins and
from the back of the input attenuators on the VPn and VH pins,
as shown in Figure 27 and Figure 28.
DIGITIZED
VOLTAGE
READING
NO ATTENUATION
12-BIT
ADC
VXn
SUPPLY SUPERVISION WITH THE ADC
2.048V VREF
In addition to the readback capability, a further level of supervi-
sion is provided by the on-chip 12-bit ADC. The ADM1064 has
limit registers on which the user can program to a maximum or
minimum allowable threshold. Exceeding the threshold generates
a warning that can either be read back from the status registers
or input into the SE to determine what sequencing action the
ADM1064 should take. Only one register is provided for each
input channel, so a UV or OV threshold (but not both) can be
set for a given channel. The round-robin circuit can be enabled
via an SMBus write, or it can be programmed to turn on in any
state in the SE program. For example, it can be set to start once
a power-up sequence is complete and all supplies are known to
be within expected tolerance limits.
Figure 27. ADC Reading on VXn Pins
ATTENUATION NETWORK
(DEPENDS ON RANGE SELECTED)
VPn/VH
DIGITIZED
VOLTAGE
READING
12-BIT
ADC
2.048V VREF
Figure 28. ADC Reading on VPn/VH Pins
The voltage at the input pin can be derived from the following
equation:
Note that a latency is built into this supervision, dictated by the
conversion time of the ADC. With all 12 channels selected, the
total time for the round-robin operation (averaging off) is
approximately 6 ms (500 µs per channel selected). Supervision
using the ADC, therefore, does not provide the same real time
response as the SFDs.
ADC Code
V =
× Attenuation Factor × 2.048 V
4095
The ADC input voltage ranges for the SFD input ranges are
listed in Table 8.
Rev. 0 | Page 20 of 32
ADM1064
APPLICATIONS DIAGRAM
12V IN
5V IN
3V IN
12V OUT
5V OUT
3V OUT
IN
DC-DC1
EN
OUT
3.3V OUT
2.5V OUT
1.8V OUT
VH
ADM1064
5V OUT
3V OUT
VP1
VP2
VP3
VP4
VX1
VX2
VX3
PDO1
PDO2
3.3V OUT
2.5V OUT
1.8V OUT
1.2V OUT
0.9V OUT
IN
DC-DC2
PDO3
PDO4
PDO5
EN
OUT
POWER_GOOD
SIGNAL_VALID
SYSTEM RESET
POWER_ON
PDO6
PDO7
VX4
VX5
RESET_L
IN
DC-DC3
PDO8
PDO9
EN
OUT
PDO10
3.3V OUT
REFIN VCCP VDDCAP GND
IN
LDO
10µF 10µF
10µF
EN
OUT
0.9V OUT
1.2V OUT
3.3V OUT
IN
OUT
EN
DC-DC4
Figure 29. Applications Diagram
Rev. 0 | Page 21 of 32
ADM1064
COMMUNICATING WITH THE ADM1064
The ADM1064 provides several options that allow the user to
update the configuration over the SMBus interface. The
following options are controlled in the UPDCFG register:
CONFIGURATION DOWNLOAD AT POWER-UP
The configuration of the ADM1064 (UV/OV thresholds, glitch
filter timeouts, PDO configurations, and so on) is dictated by
the contents of RAM. The RAM is comprised of digital latches
that are local to each of the functions on the device. The latches
are double-buffered and have two identical latches, Latch A and
Latch B. Therefore, when an update to a function occurs, the
contents of Latch A are updated first, and then the contents of
Latch B are updated with identical data. The advantages of this
architecture are explained in detail in this section.
1. Update the configuration in real time. The user writes to
RAM across the SMBus and the configuration is updated
immediately.
2. Update the Latch As without updating the Latch Bs. With
this method, the configuration of the ADM1064 remains
unchanged and continues to operate in the original setup
until the instruction is given to update the Latch Bs.
The latches are volatile memory and lose their contents at
power-down. Therefore, the configuration in the RAM must be
restored at power-up by downloading the contents of the
EEPROM (nonvolatile memory) to the local latches. This
download occurs in steps, as follows:
3. Change EEPROM register contents without changing the
RAM contents, and then download the revised EEPROM
contents to the RAM registers. Again, with this method, the
configuration of the ADM1064 remains unchanged and
continues to operate in the original setup until the
instruction is given to update the RAM.
1. With no power applied to the device, the PDOs are all high
impedance.
The instruction to download from the EEPROM in Option 3 is
also a useful way to restore the original EEPROM contents, if
revisions to the configuration are unsatisfactory. For example, if
the user needs to alter an OV threshold, this can be done by
updating the RAM register as described in Option 1. However,
if the user is not satisfied with the change and wants to revert to
the original programmed value, then the device controller can
issue a command to download the EEPROM contents to the
RAM again, as described in Option 3, restoring the ADM1064
to its original configuration.
2. When 1 V appears on any of the inputs connected to the
VDD arbitrator (VH or VPn), the PDOs are all weakly
pulled to GND with a 20 kΩ impedance.
3. When the supply rises above the undervoltage lockout of
the device (UVLO is 2.5 V), the EEPROM starts to
download to the RAM.
4. The EEPROM downloads its contents to all Latch As.
5. Once the contents of the EEPROM are completely
downloaded to the Latch As, the device controller signals
all Latch As to download to all Latch Bs simultaneously,
completing the configuration download.
The topology of the ADM1064 makes this type of operation
possible. The local, volatile registers (RAM) are all double-
buffered latches. Setting Bit 0 of the UPDCFG register to 1
leaves the double-buffered latches open at all times. If Bit 0 is set
to 0, then, when a RAM write occurs across the SMBus, only the
first side of the double-buffered latch is written to. The user
must then write a 1 to Bit 1 of the UPDCFG register. This
generates a pulse to update all the second latches at once.
EEPROM writes occur in a similar way.
6. At 0.5 ms after the configuration download completes, the
first state definition is downloaded from EEPROM into
the SE.
Note that any attempt to communicate with the device prior to
the completion of the download causes the ADM1064 to issue
a no acknowledge (NACK).
The final bit in this register can enable or disable EEPROM
page erasure. If this bit is set high, the contents of an EEPROM
page can all be set to 1. If low, then the contents of a page
cannot be erased, even if the command code for page erasure is
programmed across the SMBus. The bitmap for the UPDCFG
register is shown in the AN-698 application note. A flow chart
for download at power-up and subsequent configuration
updates is shown in Figure 30.
UPDATING THE CONFIGURATION
After power-up, with all the configuration settings loaded from
EEPROM into the RAM registers, the user might need to alter
the configuration of functions on the ADM1064, such as chang-
ing the UV or OV limit of an SFD, changing the fault output of
an SFD, or adjusting the rise time delay of one of the PDOs.
Rev. 0 | Page 22 of 32
ADM1064
SMBus
POWER-UP
CC
DEVICE
(V > 2.5V)
CONTROLLER
E
E
P
R
O
M
L
R
A
M
L
U
P
D
D
A
T
D
A
LATCH A
LATCH B
FUNCTION
(OV THRESHOLD
ON VP1)
D
EEPROM
Figure 30. Configuration Update Flow Diagram
The major differences between the EEPROM and other
registers are
UPDATING THE SEQUENCING ENGINE
Sequencing engine (SE) functions are not updated in the same
way as regular configuration latches. The SE has its own
dedicated 512-byte EEPROM for storing state definitions,
providing 63 individual states with a 64-bit word each (one state
is reserved). At power-up, the first state is loaded from the SE
EEPROM into the engine itself. When the conditions of this
state are met, the next state is loaded from EEPROM into the
engine, and so on. The loading of each new state takes approxi-
mately 10 µs.
•
An EEPROM location must be blank before it can be
written to. If it contains data, it must first be erased.
•
•
Writing to EEPROM is slower than writing to RAM.
Writing to the EEPROM should be restricted, because it
has a limited write/cycle life of typically 10,000 write
operations due to the usual EEPROM wear-out
mechanisms.
To alter a state, the required changes must be made directly to
EEPROM. RAM for each state does not exist. The relevant
alterations must be made to the 64-bit word, which is then
uploaded directly to EEPROM.
The first EEPROM is split into 16 (0 to 15) pages of 32 bytes
each. Pages 0 to 6, starting at Address 0xF800, hold the
configuration data for the applications on the ADM1064 (the
SFDs, PDOs, and so on). These EEPROM addresses are the
same as the RAM register addresses, prefixed by F8. Page 7 is
reserved. Pages 8 to 15 are for customer use.
INTERNAL REGISTERS
The ADM1064 contains a large number of data registers. The
principal registers are the address pointer register and the
configuration registers.
Data can be downloaded from EEPROM to RAM in one of the
following ways:
Address Pointer Register
•
•
At power-up, when Pages 0 to 6 are downloaded.
This register contains the address that selects one of the other
internal registers. When writing to the ADM1064, the first byte
of data is always a register address, which is written to the
address pointer register.
By setting Bit 0 of the UDOWNLD register (0xD8), which
performs a user download of Pages 0 to 6.
SERIAL BUS INTERFACE
Configuration Registers
The ADM1064 is controlled via the serial system management
bus (SMBus). The ADM1064 is connected to this bus as a slave
device, under the control of a master device. It takes approxi-
mately 1 ms after power-up for the ADM1064 to download
from its EEPROM. Therefore, access to the ADM1064 is re-
stricted until the download is completed.
These registers provide control and configuration for various
operating parameters of the ADM1064.
EEPROM
The ADM1064 has two 512-byte cells of nonvolatile, electrically
erasable, programmable read-only memory (EEPROM), from
Register Addresses 0xF800 to 0xFBFF. The EEPROM is used for
permanent storage of data that is not lost when the ADM1064 is
powered down. One EEPROM cell contains the configuration
data of the device; the other contains the state definitions for
the SE. Although referred to as read-only memory, the
Identifying the ADM1064 on the SMBus
The ADM1060 has a 7-bit serial bus slave address. The device is
powered up with a default serial bus address. The five MSBs of
the address are set to 01101; the two LSBs are determined by the
logical states of Pins A1 and A0. This allows the connection of
four ADM1064s to one SMBus.
EEPROM can be written to as well as read from via the serial
bus in exactly the same way as the other registers.
Rev. 0 | Page 23 of 32
ADM1064
The device also has several identification registers (read-only),
which can be read across the SMBus. Table 9 lists these registers
with their values and functions.
All other devices on the bus remain idle while the selected
device waits for data to be read from or written to it. If the
R/ bit is a 0, the master writes to the slave device. If the
W
R/ bit is a 1, the master reads from the slave device.
W
Table 9. Identification Register Values and Functions
Name
Address Value Function
2. Data is sent over the serial bus in sequences of nine clock
pulses, eight bits of data followed by an acknowledge bit
from the slave device. Data transitions on the data line
must occur during the low period of the clock signal and
remain stable during the high period, because a low-to-
high transition when the clock is high might be interpreted
as a stop signal. If the operation is a write operation, the
first data byte after the slave address is a command byte.
This tells the slave device what to expect next. It might be
an instruction telling the slave device to expect a block
write, or it might simply be a register address that tells the
slave where subsequent data is to be written. Because data
MANID
0xF4
0x41
Manufacturer ID for Analog
Devices
REVID
MARK1
MARK2
0xF5
0xF6
0xF7
0x00
0x00
0x00
Silicon revision
S/w brand
S/w brand
General SMBus Timing
Figure 31, Figure 32, and Figure 33 are timing diagrams for
general read and write operations using the SMBus. The SMBus
specification defines specific conditions for different types of
read and write operations, which are discussed in the Write
Operations and Read Operations sections.
can flow in only one direction, as defined by the R/ bit,
W
sending a command to a slave device during a read
operation is not possible. Before a read operation, it might
be necessary to perform a write operation to tell the slave
what sort of read operation to expect and/or the address
from which data is to be read.
The general SMBus protocol operates as follows:
1. The master initiates data transfer by establishing a start
condition, defined as a high-to-low transition on the serial
data-line SDA, while the serial clock-line SCL remains
high. This indicates that a data stream follows. All slave
peripherals connected to the serial bus respond to the start
condition and shift in the next 8 bits, consisting of a 7-bit
3. When all data bytes have been read or written, stop condi-
tions are established. In write mode, the master pulls the
data line high during the 10th clock pulse to assert a stop
condition. In read mode, the master device releases the
SDA line during the low period before the ninth clock
pulse, but the slave device does not pull it low. This is
known as no acknowledge. The master then takes the data
line low during the low period before the tenth clock pulse,
then high during the tenth clock pulse to assert a stop
condition.
slave address (MSB first) plus a R/ bit. This bit deter-
W
mines the direction of the data transfer, that is, whether
data is written to or read from the slave device (0 = write,
1 = read).
The peripheral whose address corresponds to the transmit-
ted address responds by pulling the data line low during
the low period before the ninth clock pulse, known as the
acknowledge bit, and holding it low during the high period
of this clock pulse.
1
9
1
9
SCL
SDA
0
1
1
0
1
A1
A0 R/W
D7
D6 D5 D4
D3 D2 D1
D0
ACK. BY
SLAVE
ACK. BY
SLAVE
START BY
MASTER
FRAME 1
SLAVE ADDRESS
FRAME 2
COMMAND CODE
1
9
1
9
SCL
(CONTINUED)
SDA
(CONTINUED)
D7 D6
D5 D4
D3 D2 D1
D7
D6 D5 D4
D3 D2 D1
D0
D0
STOP
BY
MASTER
ACK. BY
SLAVE
ACK. BY
SLAVE
FRAME 3
FRAME N
DATA BYTE
DATA BYTE
Figure 31. General SMBus Write Timing Diagram
Rev. 0 | Page 24 of 32
ADM1064
1
9
1
9
SCL
SDA
0
1
1
0
1
A1
A0 R/W
D7
D6 D5 D4
D3 D2 D1
D0
ACK. BY
SLAVE
ACK. BY
MASTER
START BY
MASTER
FRAME 1
SLAVE ADDRESS
FRAME 2
DATA BYTE
1
9
1
9
SCL
(CONTINUED)
SDA
(CONTINUED)
D7 D6
D5 D4
D3 D2 D1
D0
D7
D6 D5 D4
D3 D2 D1
D0
NO ACK.
STOP
BY
MASTER
ACK. BY
MASTER
FRAME 3
FRAME N
DATA BYTE
DATA BYTE
Figure 32. General SMBus Read Timing Diagram
tR
tF
tHD;STA
tLOW
tHD;STA
tHD;DAT
SCL
SDA
tHIGH
tSU;STA
tSU;STO
tSU;DAT
tBUF
P
S
S
P
Figure 33. Serial Bus Timing Diagram
SMBUS PROTOCOLS FOR RAM AND EEPROM
The ADM1064 contains volatile registers (RAM) and nonvola-
tile registers (EEPROM). User RAM occupies address locations
from 0x00 to 0xDF; EEPROM occupies addresses from 0xF800
to 0xFBFF.
The ADM1064 uses the following SMBus write protocols.
Send Byte
In a send byte operation, the master device sends a single
command byte to a slave device, as follows:
Data can be written to and read from both RAM and EEPROM
as single data bytes. Data can be written only to unprogrammed
EEPROM locations. To write new data to a programmed loca-
tion, it must first be erased. EEPROM erasure cannot be done at
the byte level. The EEPROM is arranged as 32 pages of 32 bytes
each, and an entire page must be erased.
1. The master device asserts a start condition on SDA.
2. The master sends the 7-bit slave address followed by the
write bit (low).
3. The addressed slave device asserts ACK on SDA.
4. The master sends a command code.
5. The slave asserts ACK on SDA.
Page erasure is enabled by setting Bit 2 in the UPDCFG register
(Address 0x90) to 1. If this bit is not set, page erasure cannot
occur, even if the command byte (0xFE) is programmed across
the SMBus.
6. The master asserts a stop condition on SDA and the
transaction ends.
WRITE OPERATIONS
In the ADM1064, the send byte protocol is used for two
purposes:
The SMBus specification defines several protocols for different
types of read and write operations. The following abbreviations
are used in the diagrams:
•
To write a register address to RAM for a subsequent single
byte read from the same address, or a block read or write
starting at that address, as shown in Figure 34.
S
Start
P
Stop
R
W
A
A
Read
Write
Acknowledge
No acknowledge
1
2
3
4
5
6
REGISTER
ADDRESS
(0x00 TO 0xDF)
SLAVE
ADDRESS
S
W
A
A
P
Figure 34. Setting a RAM Address for Subsequent Read
Rev. 0 | Page 25 of 32
ADM1064
•
To erase a page of EEPROM memory. EEPROM memory
In the ADM1064, the write byte/word protocol is used for three
purposes:
can be written to only if it is unprogrammed. Before
writing to one or more EEPROM memory locations that
are already programmed, the page or pages containing
those locations must first be erased. EEPROM memory is
erased by writing a command byte.
•
To write a single byte of data to RAM. In this case, the
command byte is the RAM address from 0x00 to 0xDF and
the only data byte is the actual data, as shown in Figure 36.
1
2
3
4
5
6
7
8
The master sends a command code that tells the slave
device to erase the page. The ADM1064 command code for
a page erasure is 0xFE (1111 1110). Note that, for a page
erasure to take place, the page address has to be given in
the previous write word transaction (see the Write
Byte/Word section). Also, Bit 2 in the UPDCFG register
(Address 0x90) must be set to 1.
RAM
SLAVE
ADDRESS
S
W
A
ADDRESS
A
DATA
A
P
(0x00 TO 0xDF)
Figure 36. Single Byte Write to RAM
•
To set up a 2-byte EEPROM address for a subsequent read,
write, block read, block write, or page erase. In this case, the
command byte is the high byte of the EEPROM address
from 0xF8 to 0xFB. The only data byte is the low byte of
the EEPROM address, as shown in Figure 37.
1
2
3
4
5
6
COMMAND
BYTE
(0xFE)
SLAVE
ADDRESS
S
W
A
A
P
1
2
3
4
5
6
7
8
EEPROM
ADDRESS
EEPROM
ADDRESS
Figure 35. EEPROM Page Erasure
SLAVE
S
W
A
A
A
P
ADDRESS
HIGH BYTE
(0xF8 TO 0xFB)
LOW BYTE
(0x00 TO 0xFF)
As soon as the ADM1064 receives the command byte, page
erasure begins. The master device can send a stop
command as soon as it sends the command byte. Page
erasure takes approximately 20 ms. If the ADM1064 is
accessed before erasure is complete, it responds with a no
acknowledge (NACK).
Figure 37. Setting an EEPROM Address
Note, for page erasure, that because a page consists of
32 bytes, only the three MSBs of the address low byte are
important. The lower five bits of the EEPROM address low
byte specify the addresses within a page and are ignored
during an erase operation.
Write Byte/Word
In a write byte/word operation, the master device sends a
command byte and one or two data bytes to the slave device, as
follows:
•
To write a single byte of data to EEPROM. In this case, the
command byte is the high byte of the EEPROM address
from 0xF8 to 0xFB. The first data byte is the low byte of the
EEPROM address, and the second data byte is the actual
data, as shown in Figure 38.
1. The master device asserts a start condition on SDA.
2. The master sends the 7-bit slave address followed by the
write bit (low).
1
2
3
4
5
6
7
8
9
10
EEPROM
ADDRESS
HIGH BYTE
(0xF8 TO 0xFB)
EEPROM
ADDRESS
LOW BYTE
(0x00 TO 0xFF)
SLAVE
ADDRESS
S
W
A
A
A
DATA
A
P
3. The addressed slave device asserts ACK on SDA.
4. The master sends a command code.
5. The slave asserts ACK on SDA.
Figure 38. Single Byte Write to EEPROM
Block Write
In a block write operation, the master device writes a block of
data to a slave device. The start address for a block write must
have been set previously. In the ADM1064, a send byte opera-
tion sets a RAM address, and a write byte/word operation sets
an EEPROM address, as follows:
6. The master sends a data byte.
7. The slave asserts ACK on SDA.
8. The master sends a data byte (or asserts a stop condition at
this point).
1. The master device asserts a start condition on SDA.
9. The slave asserts ACK on SDA.
2. The master sends the 7-bit slave address followed by
the write bit (low).
10. The master asserts a stop condition on SDA to end the
transaction.
3. The addressed slave device asserts ACK on SDA.
4. The master sends a command code that tells the slave
device to expect a block write. The ADM1064 command
code for a block write is 0xFC (1111 1100).
Rev. 0 | Page 26 of 32
ADM1064
5. The slave asserts ACK on SDA.
In the ADM1064, the receive byte protocol is used to read a
single byte of data from a RAM or EEPROM location whose
address has previously been set by a send byte or write
byte/word operation, as shown in Figure 40.
6. The master sends a data byte that tells the slave device how
many data bytes are being sent. The SMBus specification
allows a maximum of 32 data bytes in a block write.
1
2
3
4
5
6
7. The slave asserts ACK on SDA.
SLAVE
ADDRESS
S
R
A
DATA
A
P
8. The master sends N data bytes.
Figure 40. Single Byte Read from EEPROM or RAM
9. The slave asserts ACK on SDA after each data byte.
Block Read
In a block read operation, the master device reads a block of
data from a slave device. The start address for a block read must
have been set previously. In the ADM1064, this is done by a
send byte operation to set a RAM address, or a write byte/word
operation to set an EEPROM address. The block read operation
itself consists of a send byte operation that sends a block read
command to the slave, immediately followed by a repeated start
and a read operation that reads out multiple data bytes, as
follows:
10. The master asserts a stop condition on SDA to end the
transaction.
1
2
3
4
5
6
7
8
9
10
P
SLAVE
ADDRESS
COMMAND 0xFC
(BLOCK WRITE)
BYTE
COUNT
DATA
1
DATA
2
DATA
A
N
S
W
A
A
A
A
A
Figure 39. Block Write to EEPROM or RAM
Unlike some EEPROM devices that limit block writes to within
a page boundary, there is no limitation on the start address
when performing a block write to EEPROM, except
1. The master device asserts a start condition on SDA.
2. The master sends the 7-bit slave address followed by the
write bit (low).
•
There must be at least N locations from the start address to
the highest EEPROM address (0xFBFF), to avoid writing to
invalid addresses.
3. The addressed slave device asserts ACK on SDA.
•
If the addresses cross a page boundary, both pages must be
erased before programming.
4. The master sends a command code that tells the slave
device to expect a block read. The ADM1064 command
code for a block read is 0xFD (1111 1101).
Note that the ADM1064 features a clock extend function for
writes to EEPROM. Programming an EEPROM byte takes
approximately 250 µs, which would limit the SMBus clock for
repeated or block write operations. The ADM1064 pulls SCL
low and extends the clock pulse when it cannot accept any
more data.
5. The slave asserts ACK on SDA.
6. The master asserts a repeat start condition on SDA.
7. The master sends the 7-bit slave address followed by the
read bit (high).
READ OPERATIONS
8. The slave asserts ACK on SDA.
The ADM1064 uses the following SMBus read protocols.
Receive Byte
9. The ADM1064 sends a byte-count data byte that tells the
master how many data bytes to expect. The ADM1064
always returns 32 data bytes (0x20), which is the maximum
allowed by the SMBus 1.1 specification.
In a receive byte operation, the master device receives a single
byte from a slave device, as follows:
1. The master device asserts a start condition on SDA.
10. The master asserts ACK on SDA.
2. The master sends the 7-bit slave address followed by the
read bit (high).
11. The master receives 32 data bytes.
12. The master asserts ACK on SDA after each data byte.
3. The addressed slave device asserts ACK on SDA.
4. The master receives a data byte.
13. The master asserts a stop condition on SDA to end the
transaction.
5. The master asserts no acknowledge on SDA.
6. The master asserts a stop condition on SDA, and the
transaction ends.
Rev. 0 | Page 27 of 32
ADM1064
1
2
3
4
5
6
7
8
9
10 11 12
DATA
2. A no acknowledge (NACK) is generated after the PEC byte
to signal the end of the read.
SLAVE
ADDRESS
COMMAND 0xFD
(BLOCK READ)
SLAVE
ADDRESS
BYTE
COUNT
S
W
A
A
S
R A
A
A
1
Note that the PEC byte is calculated using CRC-8. The frame
check sequence (FCS) conforms to CRC-8 by the polynomial
13 14
DATA
32
A
P
C(x) = x8 + x2 + x1 + 1
Figure 41. Block Read from EEPROM or RAM
See the SMBus 1.1 specification for details.
Error Correction
An example of a block read with the optional PEC byte is
shown in Figure 42.
The ADM1064 provides the option of issuing a PEC (packet
error correction) byte after a write to RAM, a write to
EEPROM, a block write to RAM/EEPROM, or a block read
from RAM/EEPROM. This enables the user to verify that the
data received by or sent from the ADM1064 is correct. The PEC
byte is an optional byte sent after that last data byte has been
written to or read from the ADM1064. The protocol is as
follows:
1
2
3
4
5
6
7
8
9
10 11 12
SLAVE
ADDRESS
COMMAND 0xFD
(BLOCK READ)
SLAVE
ADDRESS
BYTE
COUNT
DATA
1
S
W
A
A
S
R A
A
A
13 14 15
DATA
32
A
PEC A P
1. The ADM1064 issues a PEC byte to the master. The master
checks the PEC byte and issues another block read, if the
PEC byte is incorrect.
Figure 42. Block Read from EEPROM or RAM with PEC
Rev. 0 | Page 28 of 32
ADM1064
OUTLINE DIMENSIONS
6.00
BSC SQ
0.60 MAX
0.60 MAX
PIN 1
INDICATOR
31
40
1
30
PIN 1
INDICATOR
0.50
BSC
4.25
4.10 SQ
3.95
TOP
VIEW
5.75
BCS SQ
EXPOSED
PAD
(BOTTOM VIEW)
0.50
0.40
0.30
21
10
11
20
0.25 MIN
4.50
REF
12° MAX
0.80 MAX
0.65 TYP
0.05 MAX
0.02 NOM
1.00
0.85
0.80
0.30
0.23
0.18
COPLANARITY
0.08
0.20 REF
SEATING
PLANE
COMPLIANT TO JEDEC STANDARDS MO-220-VJJD-2
Figure 43. 40-Lead Lead Frame Chip Scale Package [LFCSP]
(CP-40)
Dimensions shown in millimeters
1.20
9.00
0.75
0.60
0.45
MAX
BSC SQ
37
36
48
1
SEATING
PLANE
PIN 1
7.00
BSC SQ
TOP VIEW
(PINS DOWN)
VIEW A
0° MIN
1.05
1.00
0.95
0.20
0.09
12
25
24
13
7°
3.5°
0°
0.08 MAX
COPLANARITY
0.50
BSC
0.27
0.22
0.17
0.15
0.05
SEATING
PLANE
VIEW A
ROTATED 90° CCW
COMPLIANT TO JEDEC STANDARDS MS-026ABC
Figure 44. 48-Lead Thin Plastic Quad Flat Package [TQFP]
(SU-48)
Dimensions shown in millimeters
ORDERING GUIDE
Model
ADM1064ACP
ADM1064ACP-REEL
ADM1064ACP-REEL7
ADM1064ASU
ADM1064ASU-REEL
ADM1064ASU-REEL7
EVAL-ADM1064LFEB
EVAL-ADM1064TQEB
Temperature Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Package Description
40-Lead LFCSP
40-Lead LFCSP
40-Lead LFCSP
48-Lead TQFP
48-Lead TQFP
48-Lead TQFP
ADM1064 Evaluation Kit (LFSCP Version)
ADM1064 Evaluation Kit (TQFP Version)
Package Option
CP-40
CP-40
CP-40
SU-48
SU-48
SU-48
Rev. 0 | Page 29 of 32
ADM1064
NOTES
Rev. 0 | Page 30 of 32
ADM1064
NOTES
Rev. 0 | Page 31 of 32
ADM1064
NOTES
©
2004 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D04633–0–10/04(0)
Rev. 0 | Page 32 of 32
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