ADP1071-1ARWZ [ADI]
Isolated Synchronous Flyback Controller with Integrated iCoupler;型号: | ADP1071-1ARWZ |
厂家: | ADI |
描述: | Isolated Synchronous Flyback Controller with Integrated iCoupler 开关 光电二极管 |
文件: | 总24页 (文件大小:476K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Isolated Synchronous Flyback Controller
with Integrated iCoupler
Data Sheet
ADP1071-1/ADP1071-2
FEATURES
FUNCTIONAL BLOCK DIAGRAM
Current mode controller for flyback topology
ADP1071-1: programmable LLM or CCM for high VIN
applications
FLYBACK
TOPOLOGY
SYNCHRONOUS
RECTIFIER
INPUT
OUTPUT
BIAS
WINDING
ADP1071-2: forced CCM operation
OPTIONAL
START-UP
CIRCUITRY
Programmable slope compensation
Integrated 5 kV isolation with Analog Devices, Inc., iCoupler
technology
ADP1071-1/
ADP1071-2
Wide voltage supply range
Primary VDD: up to 60 V (ADP1071-2 only)
Secondary VDD2: up to 36 V
Figure 1.
Integrated 1 A primary side MOSFET driver
Integrated 1 A secondary side MOSFET drivers for
synchronous rectification
Integrated error amplifier and <1% accurate reference voltage
Programmable frequency range: 50 kHz to 600 kHz
Duty cycle clamp limit 85%
Programmable soft start and soft start from precharged load
Protection features such as short circuit, output overvoltage,
and overtemperature protection
Power saving LLM using MODE pin (ADP1071-1only)
Cycle by cycle input overcurrent protection
Precision enable UVLO with hysteresis
Frequency synchronization
GENERAL DESCRIPTION
The ADP1071-1/ADP1071-2 are pulse-width modulation
(PWM) current mode fixed frequency synchronous flyback
controllers designed for isolated dc-to-dc power supplies.
Analog Devices proprietary iCouplers® are integrated in the
ADP1071-1/ADP1071-2 to eliminate the bulky signal trans-
formers and optocouplers that transmit signals over the isolation
boundary. Integrating the iCouplers reduces system design
complexity, cost, and component count and improves overall
system reliability. With the integrated isolators and metal-oxide
semiconductor field effect transistor (MOSFET) drivers on both
the primary and the secondary side, the ADP1071-1/ADP1071-2
offer a compact system level design and yield a higher efficiency
than a diode rectified flyback converter at heavy loads.
Safety and regulatory approvals (pending)
UL recognition
Output regulation is achieved by sensing the output voltage on
the secondary side, where the feedback and the PWM signals
are transmitted between the primary and secondary sides
through the iCouplers.
5000 V rms for 1 minute per UL 1577
CSA Component Acceptance Notice 5A
VDE certificate of conformity
DIN V VDE V 0884-10 (VDE V 0884-10):2006-12
V
IORM = 849 V peak
The ADP1071-1/ADP1071-2 are offered in a 16-lead SOIC_W
package with an isolation voltage rating of 5 kV rms. The
ADP1071-2 is designed for isolated dc-to-dc applications
typically with an input voltage less than 36 V, and the
ADP1071-1 targets high input voltage applications, in which the
dc input voltage can exceed 60 V.
CQC certification per GB4943.1-2011
Available in 16-lead SOIC_W package
APPLICATIONS
Isolated dc-to-dc or ac-to-dc power conversion
Telecom, industrial
The ADP1071-1/ADP1071-2 offer features such as input
current protection, output overvoltage protection (OVP),
undervoltage lockout (UVLO), precision enable with adjustable
hysteresis, overtemperature protection (OTP), and power
saving light load mode (LLM).
Small cell
PoE powered device
Enterprise switches and routers
Rev. A
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ADP1071-1/ADP1071-2
Data Sheet
TABLE OF CONTENTS
Features .............................................................................................. 1
Input/Output Current-Limit Protection .................................... 16
Temperature Sensing ................................................................. 17
Frequency Setting (RT Pin) ...................................................... 17
Maximum Duty Cycle ............................................................... 17
Frequency Synchronization ...................................................... 17
Synchronous Rectifier (SR) Driver .......................................... 18
Output Overvoltage Protection (OVP) ................................... 18
SR Dead Time............................................................................. 18
Applications....................................................................................... 1
Functional Block Diagram .............................................................. 1
General Description......................................................................... 1
Revision History ............................................................................... 2
Specifications..................................................................................... 3
Insulation and Safety Related Specifications ............................ 6
Regulatory Information............................................................... 7
Absolute Maximum Ratings............................................................ 8
Thermal Resistance ...................................................................... 8
ESD Caution.................................................................................. 8
Pin Configurations and Function Descriptions ........................... 9
Typical Performance Characteristics ........................................... 10
Theory of Operation ...................................................................... 12
Detailed Block Diagram ............................................................ 13
Primary Side Supply, Input Voltage, and LDO........................... 14
Secondary Side Supply and LDO ............................................. 14
Precision Enable ......................................................................... 14
Soft Start Procedure ................................................................... 15
Output Voltage Sensing and Feedback .................................... 16
Loop Compensation and Steady State Operation.................. 16
Slope Compensation .................................................................. 16
Light Load Mode (LLM) and Continuous Conduction
Mode (CCM) .............................................................................. 18
Soft Stop....................................................................................... 19
OCP/Feedback Recovery .......................................................... 19
Output Voltage Tracking ........................................................... 19
Remote System Reset................................................................. 19
OCP Counter .............................................................................. 20
External Start-Up Circuit.......................................................... 21
Insulation Lifetime..................................................................... 21
Layout Guidelines....................................................................... 22
Applications Information.............................................................. 23
Typical Application Circuits ..................................................... 23
Outline Dimensions....................................................................... 24
Ordering Guide .......................................................................... 24
REVISION HISTORY
11/2018—Rev. 0 to Rev. A
Changes to Frequency Setting (RT Pin) Section ........................ 17
9/2018—Revision 0: Initial Version
Rev. A | Page 2 of 24
Data Sheet
ADP1071-1/ADP1071-2
SPECIFICATIONS
ADP1071-1: VREG1 = 9 V, VDD2 = 12 V, TA = −40°C to +125°C, unless otherwise noted. ADP1071-2: VIN = 24 V, VDD2 = 12 V, TA =
−40°C to +125°C, unless otherwise noted.
Table 1.
Parameter
Symbol
Test Conditions/Comments
Min
Typ
Max
Unit
ADP1071-1 SUPPLY
(PRIMARY)
Supply Voltage
Quiescent Supply
Current
VREG1
IVREG1
1 µF capacitor from VREG1 to AGND1
VREG1 > VREG1 UVLO, GATE pin unloaded
4.7
8
12.5
V
At 100 kHz
At 300 kHz
At 600 kHz
3.8
4.6
6.8
mA
mA
mA
IVREG1
VREG1 > VREG1 UVLO, GATE pin loaded
with 2.2 nF
At 100 kHz
At 300 kHz
At 600 kHz
VEN < 1.2 V
VREG1 rising
VREG1 falling
5.5
10
16.6
mA
mA
mA
µA
V
VREG1 Start-Up Current IVREG1_STARTUP
VREG1 UVLO
160
4.7
4
V
UVLO Hysteresis
0.19
24
V
ADP1071-2 SUPPLY
(PRIMARY)
Supply Voltage
VIN
IVIN
4.7 µF capacitor from VIN to AGND1,
1 µF capacitor from VREG1 to AGND1
VIN > VIN UVLO, GATE pin unloaded
4.7
60
V
Quiescent Supply
Current
At 100 kHz
At 300 kHz
At 600 kHz
3.8
4.4
6.8
mA
mA
mA
IVIN
VIN > VIN UVLO, GATE pin loaded with
2.2 nF
At 100 kHz
At 300 kHz
At 600 kHz
EN pin voltage (VEN) < 1.2 V, VREG1 = 0 V,
VIN = 60 V
5.5
11
22
mA
mA
mA
µA
VIN Shutdown Current
55
VIN and VREG1 Start-Up
Current
VIN UVLO
IVIN_STARTUP
VEN < 1.2 V, VREG1 = 12 V, VIN = 12 V
160
4.7
µA
VIN rising
VIN falling
V
V
V
4
UVLO Hysteresis
SWITCHING TIME
Time from EN High to
GATE Output
0.19
1
VEN > 1.2 V, 1 µF capacitor on VREG1
ms
µs
Switching
Time from EN Low to
GATE Output Stops
Switching
V
EN < 1.0 V, 1 µF capacitor on VREG1
1
Rev. A | Page 3 of 24
ADP1071-1/ADP1071-2
Data Sheet
Parameter
Symbol
Test Conditions/Comments
Min
Typ
Max
Unit
SUPPLY (SECONDARY)
Supply Voltage
VDD2
IDD2
4.7 µF capacitor from VDD2 to AGND2, 1 µF
capacitor from VREG2 to AGND2
SR unloaded
4.5
12
36
V
Quiescent Supply
Current
At 100 kHz
At 300 kHz
At 600 kHz
5.3
5.5
5.6
mA
mA
mA
IDD2
SR loaded with 2.2 nF
At 100 kHz
6.4
8.7
12.1
mA
mA
mA
V
At 300 kHz
At 600 kHz
VDD2 UVLO Threshold
UVLO Hysteresis
Secondary UVLO
Hiccup Time
VDD2 rising
VDD2 falling
3.55
3
V
mV
ms
145
200
OSCILLATOR
Switching Frequency
(fS)
RT resistance (RRT) = 480 kΩ ( 1%)
50 − 10%
50
50 + 10%
kHz
RRT = 240 kΩ ( 1%)
RRT = 120 kΩ ( 1%)
RRT = 80 kΩ ( 1%)
RRT = 60 kΩ ( 1%)
RRT = 40 kΩ ( 1%)
100 − 10% 100
200 − 10% 200
300 − 10% 300
400 − 10% 400
600 − 10% 600
100 + 10% kHz
200 + 10% kHz
300 + 10% kHz
400 + 10% kHz
600 + 10% kHz
VREG1 PIN
VREG1 Voltage Clamp
VREG1 Clamp Series
Resistance
VREG1 current (IVREG1) = 3 mA, VEN < 1.2 V
VREG1 forced current of 5 mA and 10 mA
13.5
14.3
16
15.2
V
Ω
GATE DRIVERS (PRIMARY)
GATE High Voltage
Gate Short-Circuit Peak
Current1
IVREG1 = 20 mA, VIN > 9 V (ADP1071-2 only)
8 V on VREG1
7.8
8
1.0
8.2
V
A
GATE Rise Time
GATE Fall Time
GATE Source Resistance RON_SOURCE
GATE loaded with 2.2 nF, 10% to 90%
GATE loaded with 2.2 nF, 90% to 10%
Source = 100 mA
17
15
4
ns
ns
Ω
GATE Sink Resistance
RON_SINK
Sink = 100 mA
2
Ω
GATE Maximum Duty
Cycle
84
%
GATE Minimum On
Time
At 300 kHz, includes blanking time
175
ns
SR DRIVER (SECONDARY)
SR High Voltage
SR Short Circuit Peak
Current1
IVREG2 = 15 mA, VDD2 > 5.5 V
5 V on VREG2
4.9
5
1.0
5.1
V
A
SR Rise Time
SR Fall Time
SR Minimum On Time
SR Source Resistance
SR Sink Resistance
SR loaded with 2.2 nF, 10% to 90%
SR loaded with 2.2 nF, 90% to 10%
At 300 kHz
Source = 100 mA
Sink = 100 mA
13
10
462
3
1.5
30
ns
ns
ns
Ω
RON_SR_SOURCE
RON_SR_SINK
Ω
DEAD TIME SETTING
(GATE TO SR)
Dead time between SR falling and GATE
rising
ns
Dead time between GATE falling and SR
rising
52
ns
Rev. A | Page 4 of 24
Data Sheet
ADP1071-1/ADP1071-2
Parameter
Symbol
Test Conditions/Comments
Overcurrent sense limit threshold
Switching period (tS) = 1/fS
Min
Typ
Max
Unit
CURRENT-LIMIT SENSE
(PRIMARY)
CS Limit Threshold
CS Leading Edge
Blanking Time
Current Source di/dt for
Slope Compensation
VCS_LIM
120
150
mV
ns
20
40
µA per tS
ns
Overcurrent Protection
(OCP) Comparator
Delay
Time in OCP Before
Entering Hiccup
Mode
1.5
40
ms
ms
OCP Hiccup Time
See the Input/Output Current-Limit
Protection section
FB PIN AND ERROR
AMPLIFIER
Feedback Accuracy
Voltage
VFB
TJ = −40°C to +85°C
TJ = −40°C to +125°C
−0.85%
−1.25%
+1.2
+1.2
+0.85%
V
+1.25%
76
V
Temperature
Coefficient
ppm/°C
FB Input Bias Current
Transconductance
Output Current Clamp
Minimum
−100
230
1
250
+100
270
nA
µS
gm
−57
43
µA
µA
Maximum
COMP Clamp Voltage
Maximum
Minimum
Open-Loop Gain
Output Shunt Resistance
Gain Bandwidth Product
2.52
0.7
80
5
V
V
dB
GΩ
MHz
1
PRECISION ENABLE
THRESHOLD
EN Threshold
EN Hysteresis
VEN
EN rising
VEN < 1.2 V
VEN > 1.2 V
1.14
5.5
1.2
4
1
1.26
7.5
V
µA
µA
µA
EN Hysteresis Current
3
LIGHT LOAD MODE
(ADP1071-1 ONLY )
LLM Current Source
TEMPERATURE
Thermal Shutdown
Hysteresis
Resistor from MODE to AGND1
6.5
µA
155
−15
°C
°C
SOFT START
Open Loop Soft Start
Time on Primary
tSS1
GATE resistor = 10 kΩ
16 × 775
tS
GATE resistor = 22 kΩ
GATE resistor = 47 kΩ
GATE resistor = 100 kΩ
During startup
64 × 775
256 × 775
4 × 775
20
tS
tS
tS
µA
µA
SS2 Current Source
SS2 Discharging
Current
During a fault condition or soft stop
30
Rev. A | Page 5 of 24
ADP1071-1/ADP1071-2
Data Sheet
Parameter
Symbol
Test Conditions/Comments
Min
Typ
Max
Unit
SYNC PIN
Synchronization Range
Input Pulse Width
100
100
600
kHz
ns
Number of Cycles
Before
7
Cycles
Synchronization
Input Voltage
Low
High
Leakage Current
iCOUPLER DELAY
0.4
1
V
V
µA
3
COMP Signal Delay
600
ns
Through iCoupler
OVP PIN THRESHOLDS
OVP Pin OV Threshold
OVP Pin OV Hysteresis
OVP Comparator Delay
(Includes iCoupler
Delay)
Overvoltage (OV) threshold for OVP pin
1.3
1.36
36
320
1.42
V
mV
ns
OVP Pin Leakage Current
OVP Hiccup
1
µA
ms
ms
Time before entering OVP hiccup mode
Hiccup time trigged by OVP event
200
200
1 Short-circuit duration is less than 1 μs. Average power must conform to the limit shown in the Absolute Maximum Ratings section.
INSULATION AND SAFETY RELATED SPECIFICATIONS
Table 2.
Parameter
Symbol Test Conditions/Comments
Min Typ
Max Unit
iCOUPLER
Rated Dielectric Insulation
Voltage
1 minute duration
5
kV
Minimum External Air Gap
(Clearance)
Minimum External Air Gap
(Creepage)
Minimum Internal Gap (Internal
Clearance)
Tracking Resistance
Measured from input terminals to output terminals,
shortest distance through air
Measured from input terminals to output terminals,
shortest distance path along body
Insulation distance through insulation
7.6
mm
mm
mm
V
7.6
0.030
CTI
>400
II
(Comparative Tracking Index)
Isolation Group
Material Group (DIN VDE 0110, 1/89, Table 1)
Common-Mode Transient
Immunity, Dynamic
−25
+25 kV/µs
Rev. A | Page 6 of 24
Data Sheet
ADP1071-1/ADP1071-2
REGULATORY INFORMATION
See Table 3 and the Insulation Lifetime section for details regarding recommended maximum working voltages for specific cross isolation
waveforms and insulation levels.
Table 3
UL (Pending)
CSA (Pending)
VDE (Pending)
CQC (Pending)
Recognized Under UL 1577
Component Recognition
Program1
Approved under CSA Component
Acceptance Notice 5A
Certified according to DIN V VDE V Certified by
0884-10 (VDE V 0884-10):2006-122 CQC11-471543-2012,
GB4943.1-2011:
Single Protection, 5000 V rms CSA 60950-1-07+A1+A2 and IEC 60950-1,
Reinforced insulation, VIORM
849 peak, VIOTM = 8000 V peak
=
Basic insulation at
780 V rms (1103 V peak)
Isolation Voltage
second edition, +A1+A2:
Basic insulation at 780 V rms (1103 V peak)
Reinforced insulation at 390 V rms
(552 V peak)
Reinforced insulation at
389 V rms (552 V peak),
tropical climate,
altitude ≤ 5000 meters
IEC 60601-1 Edition 3.1:
Basic insulation (1 means of patient
protection (1 MOPP)), 490 V rms
(686 V peak)
Reinforced insulation (2 MOPP), 238 V rms
(325 V peak)
CSA 61010-1-12 and IEC 61010-1 third
edition:
Basic insulation at 300 V rms mains, 780 V
secondary (1103 V peak)
File E214100
File 205078
File 2471900-4880-0001
File (pending)
1 In accordance with UL 1577, each product is proof tested by applying an insulation test voltage ≥ 6000 V rms for 1 sec.
2 In accordance with DIN V VDE V 0884-10, each product is proof tested by applying an insulation test voltage ≥ 1592 V peak for 1 sec (partial discharge detection limit =
5 pC). The * marking branded on the component designates DIN V VDE V 0884-10 approval.
Rev. A | Page 7 of 24
ADP1071-1/ADP1071-2
Data Sheet
ABSOLUTE MAXIMUM RATINGS
Table 4.
THERMAL RESISTANCE
Thermal performance is directly linked to printed circuit board
(PCB) design and operating environment. Careful attention to
PCB thermal design is required.
Parameter
Rating
VIN, EN
VDD2
66 V
42 V
VREG1
VREG2
GATE
16 V
6 V
−0.3 V to +16 V
6.5 V
0.3 V
−40°C to +125°C
50 kV/µs
150°C
Table 5. Thermal Resistance
Package Type
RW-161
θJA
θJC
Unit
79.3
44.6
°C/W
RT, CS, SYNC, SS2, FB, COMP, OVP, MODE, SR
AGND1, AGND2
1 Thermal impedance simulated values are based on JEDEC 2S2P thermal test
board. See JEDEC JESD-51.
Operating Temperature Range
Common-Mode Transients1
Junction Temperature
Peak Solder Reflow Temperature
SnPb Assemblies (10 sec to 30 sec)
RoHS Compliant Assemblies
(20 sec to 40 sec)
Electrostatic Discharge (ESD)
Charged Device Model (CDM)
Human Body Model (HBM)
Table 6. Maximum Continuous Working Voltage1
Parameter
Waveform
AC Voltage
Bipolar
Max
Unit
Constraint
240°C
260°C
560
V peak
50-year minimum lifetime
50-year minimum lifetime
50-year minimum lifetime
Unipolar
DC Voltage
1131 V peak
1131 V peak
250 V
1 kV
1 Refers to continuous voltage magnitude imposed across the isolation
barrier. See the Insulation Lifetime Section for more details.
1 Refers to common-mode transients across the insulation barrier. Common-
mode transients exceeding the absolute maximum rating can cause latch up
or permanent damage.
ESD CAUTION
Stresses at or above those listed under Absolute Maximum
Ratings may cause permanent damage to the product. This is a
stress rating only; functional operation of the product at these
or any other conditions above those indicated in the operational
section of this specification is not implied. Operation beyond
the maximum operating conditions for extended periods may
affect product reliability.
Rev. A | Page 8 of 24
Data Sheet
ADP1071-1/ADP1071-2
PIN CONFIGURATIONS AND FUNCTION DESCRIPTIONS
GATE
AGND1
VREG1
MODE
EN
1
2
3
4
5
6
7
8
16 SR
GATE
AGND1
VREG1
VIN
1
2
3
4
5
6
7
8
16 SR
15 AGND2
14 VREG2
13 VDD2
15 AGND2
14 VREG2
ADP1071-1
ADP1071-2
13 VDD2
TOP VIEW
TOP VIEW
(Not to Scale) 12 OVP
11 FB
EN
(Not to Scale) 12 OVP
11 FB
CS
CS
RT
10 COMP
RT
10 COMP
SYNC
9 SS2
SYNC
9 SS2
Figure 2. ADP1071-1 Pin Configuration
Figure 3. ADP1071-2 Pin Configuration
Table 7. Pin Function Descriptions
Pin No.
ADP1071-1 ADP1071-2 Mnemonic Description
1
1
GATE
Driver Output for the Main Power MOSFET on the Primary Side. GATE is a multiple function
pin. Connect a resistor from GATE to AGND1 to set up the open loop soft start time.
2
3
2
3
AGND1
VREG1
Ground for the Primary Side.
8 V Regulated Low Dropout (LDO) Output for the MOSFET Driver. Connect 1 µF or greater
from VREG1 to AGND1.
4
Not
applicable
MODE
VIN
Light Load Mode Pin. ADP1071-1 Only. This pin sets the light load mode threshold. Connect
MODE to AGND1 to enable forced continuous conduction mode (CCM), or to a high logic (2.5 V
or higher) to force an LLM operation, or to a resistor to set up an LLM threshold voltage.
Input Voltage (ADP1071-2 Only). See the Primary Side Supply, Input Voltage, and LDO section.
Connect a 4.7 µF capacitor to this pin. The size of this capacitor can be reduced if the input
voltage to this pin is guaranteed stable. Reference this pin to AGND1.
Not
applicable
4
5
6
5
6
EN
CS
Precision Enable Input. The controller is enabled when EN is above the EN threshold voltage.
This pin also has a programmable EN hysteresis. This pin is referenced to AGND1.
Input Current Sensing. This pin senses the input PWM current. Place a current sense resistor
between the source terminal of the power MOSFET and AGND1. This current sense resistor
sets up the input current limit. This pin is also used for the external slope compensator.
Connect a resistor from CS to the current sense resistor to generate a voltage ramp for the
slope compensation. Reference this pin to AGND1. Connect a 33 pF to 100 pF capacitor at this
pin to act as a resistor capacitor (RC) filter along with the slope compensation resistor in noisy
environments.
7
8
7
8
RT
SYNC
Switching Period Resistor. Connect a resistor from RT to AGND1 to set the oscillator frequency.
Frequency Synchronization. Connect an external clock to the SYNC pin to synchronize the
internal oscillator to this external clock frequency. Connect SYNC to AGND1 if this feature is
not used. It is recommended that the SYNC frequency be within 10% of the frequency set by
the RT pin.
9
9
SS2
Soft Start on the Secondary Side. Connect a capacitor from SS2 to AGND2 to set up the soft
start time on the secondary side.
10
11
10
11
COMP
FB
Compensation Node on the Secondary Side. This pin is the output of the transconductance
(gm) amplifier. Reference this pin to AGND2.
Feedback Node on the Secondary Side. Set up the resistive divider from the output voltage
such that the nominal voltage, when the power supply is in regulation, is 1.2 V. Reference this
pin to AGND2.
12
13
12
13
OVP
Output Overvoltage Protection. The OVP threshold is set at 1.36 V. Connect a resistive divider
from OVP to the output and AGND2.
Input Supply on the Secondary Side. Connect VDD2 to the output voltage of the power
supply for a self driven configuration. Connect a 4.7 µF capacitor from VDD2 to AGND2. The
size of this capacitor can be reduced if the input voltage to VDD2 is guaranteed to be stable.
VDD2
14
14
VREG2
5 V Regulated LDO Output for Internal Bias and Powering of the Drivers of the Synchronous
Rectifiers. Do not use VREG2 as a reference or load. Connect a 1 µF capacitor from VREG2 to
AGND2.
15
16
15
16
AGND2
SR
Analog Ground on Secondary Side.
Driver Output for Synchronous Rectifier MOSFET.
Rev. A | Page 9 of 24
ADP1071-1/ADP1071-2
Data Sheet
TYPICAL PERFORMANCE CHARACTERISTICS
5.05
5.04
5.03
5.02
5.01
5.00
4.99
4.98
4.97
8.08
8.06
8.04
8.02
8.00
7.98
MAXIMUM
MEAN
MINIMUM
7.96
MAXIMUM
MEAN
7.94
7.92
7.90
MINIMUM
–40
–20
0
20
40
60
80
100
120
120
120
–40
–20
0
20
40
60
80
100
100
100
120
120
120
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 4. VREG1 Voltage vs. Temperature
Figure 7. VREG2 Voltage vs. Temperature
1.23
1.22
1.21
1.20
1.19
1.18
1.17
1.16
1.15
1.204
1.202
1.200
1.198
1.196
1.194
1.192
MAXIMUM
MEAN
MINIMUM
MAXIMUM
MEAN
MINIMUM
–40
–20
0
20
40
60
80
100
–40
–20
0
20
40
60
80
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 5. Rising EN Threshold Accuracy vs. Temperature
Figure 8. FB Threshold vs. Temperature
6.9
6.8
6.7
6.6
6.5
6.4
6.3
6.2
6.1
125
120
115
110
105
100
MAXIMUM
MEAN
MINIMUM
MAXIMUM
MEAN
MINIMUM
–40
–20
0
20
40
60
80
100
–40
–20
0
20
40
60
80
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 6. Rising CS Comparator Accuracy vs. Temperature
Figure 9. MODE Pin Current Source Accuracy vs. Temperature
Rev. A | Page 10 of 24
Data Sheet
ADP1071-1/ADP1071-2
58
56
54
52
50
48
46
44
42
40
4.20
4.15
4.10
4.05
4.00
3.95
3.90
3.85
3.80
3.75
3.70
MAXIMUM
MEAN
MINIMUM
MAXIMUM
MEAN
MINIMUM
–40
–20
0
20
40
60
80
100
120
–40
–20
0
20
40
60
80
100
120
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 10. GATE Delay vs. Temperature (GATE Falling to SR Rising)
Figure 13. EN Pin Hysteresis Current vs. Temperature, EN < 1.2 V
45
160
MAXIMUM
158
156
154
152
150
148
146
144
142
140
MEAN
MINIMUM
40
MAXIMUM
MEAN
MINIMUM
35
40
25
20
–40
–20
0
20
40
60
80
100
120
–40
–20
0
20
40
60
80
100
120
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 11. GATE Delay vs. Temperature (GATE Falling to SR Rising)
Figure 14. Blanking Time vs. Temperature
1.12
1.10
MAXIMUM
MEAN
1.08
1.06
1.04
1.02
1.00
0.98
MINIMUM
–40
–20
0
20
40
60
80
100
120
TEMPERATURE (°C)
Figure 12. EN Pin Hysteresis Current vs. Temperature, EN > 1.2 V
Rev. A | Page 11 of 24
ADP1071-1/ADP1071-2
Data Sheet
THEORY OF OPERATION
The ADP1071-1/ADP1071-2 are PWM, current mode, fixed
frequency, synchronous flyback controllers designed for isolated
dc-to-dc power supplies. Analog Devices iCouplers are integrated
in the ADP1071-1/ADP1071-2 to eliminate the bulky signal
transformers and optocouplers that transmit signals over the
isolation boundary. Integrating the iCouplers reduces system
design complexity, cost, and component count and improves
overall system reliability. With the integrated isolators and
MOSFET drivers on both the primary and the secondary side, the
ADP1071-1/ADP1071-2 offer a compact system level design
and yield a higher efficiency than a diode rectified flyback
converter at heavy loads.
The PWM controls are performed on the primary side by sensing
the input peak current cycle by cycle with a sense resistor at the
source of the main switching MOSFET. The output of the converter
is sensed by the secondary circuitry, which sends the feedback
and PWM signals to the primary side via the 5 kV integrated
isolators for a complete control loop solution.
The primary circuitry in the ADP1071-1/ADP1071-2 includes
an 8 V LDO, input current sensing, bias circuit, and MOSFET
drivers including an active clamp reset driver, slope compensation,
external frequency synchronization, PWM generator, and a
programmable maximum duty cycle setting. The primary side
also has pins for differential sensing of the current sense signal.
Traditionally in a forward or flyback converter, a discrete
optocoupler is used in the feedback path to transmit the signal
from the secondary to the primary side, and an external trans-
former is used for transmitting the PWM signal from the
primary to the secondary side for synchronous rectification.
However, the current transfer ratio (CTR) of the optocouplers
degrades over time and over temperature and so the optocoupler
must be replaced every 5 to 10 years, depending on the manu-
facturing quality and optocoupler grade that determines the
initial CTR. The ADP1071-1/ADP1071-2 eliminate the use of
an optocoupler and signal transformer, thus reducing system
cost, PCB area, and complexity, while improving system reliability
without the issue of CTR degradation of the optocouplers.
The secondary circuitry includes the feedback compensation, a
5 V LDO regulator, an internal reference, two MOSFET drivers for
synchronous rectification, and a dedicated pin for overvoltage
protection. Additionally, the secondary side features differential
output voltage sensing and a programmable LLM setting.
The integrated iCouplers carry out the communications between
the primary and secondary sides by transmitting the feedback
signal and the PWMs over the isolation barrier.
The feedback signal and timing of synchronous rectifier PWMs
are transmitted between the primary and the secondary sides,
or between the secondary and primary sides, through the
iCouplers using a proprietary transmission scheme.
The ADP1071-1/ADP1071-2 also offer features such as input
current protection, OV P, UVLO, precision enable with adjustable
hysteresis, O TP, LLM, and tracking.
The ADP1071-1/ADP1071-2 controllers offer a complete
solution for an isolated dc-to-dc power supply by integrating
the 5 kV isolators and the primary and secondary control
circuitries in one package.
Rev. A | Page 12 of 24
Data Sheet
ADP1071-1/ADP1071-2
DETAILED BLOCK DIAGRAM
Figure 15 shows a detailed block diagram of the ADP1071-1/ADP1071-2.
5V
ADP1071-1/ADP1071-2
VDD2
VIN/MODE1
5V LDO
8V LDO
RCLM
VREG2
VREF2
VREG1
BIAS
VREF
1.2V
OVP
14V
1.36V
OV
1.2V
EN
LOGIC
1µA
4µA
THERMAL
LIMIT
COMP
PRIMARY
INTERNAL
SOFT
START
VREG2
TO SECONDARY
HANDOVER LOGIC
fOSC
DC
SS2
RT
OSCILLATOR
OV DETECT
OCP RECOVERY
FB
gm
AMPLIFIER
SYNC
COMP
1.2VREF
Tx
COMP
RAMP
SLOPE RAMP
SLOPE
COMP
VREG
DRV
GATE
S
SR
VREG2
DRV
LOGIC
AND
DEAD
TIME
CTRL
Q
SR
R
Tx
LOGIC
RSOFT START
LOGIC
OCP
PWM
COMPARATOR
AGND2
OV
OV
CONTROL
OCP
THRESHOLD
CS
LUM
CONTROL
AGND1
VMODE
1THIS PIN IS VIN ON THE ADP1071-2, AND MODE ON THE ADP1071-1
Figure 15. Detailed Block Diagram
Rev. A | Page 13 of 24
ADP1071-1/ADP1071-2
Data Sheet
PRIMARY SIDE SUPPLY, INPUT VOLTAGE, AND LDO
PRECISION ENABLE
The voltage at the VREG1 pin powers the internal circuitry,
primary side iCouplers, housekeeping circuits, and the primary
MOSFET driver at the GATE pin.
The enable threshold at the EN pin is precision voltage
referenced at 1.2 V.
In the ADP1071-1, the soft start procedure commences
immediately when VIN is above the UVLO voltage (typically
4.5 V) and the voltage at the EN pin rises above 1.2 V.
In the ADP1071-1, power must be supplied to the VREG1 using
an external start-up circuit.
In the ADP1071-2, the soft start procedure commences after a
small delay when VIN is above the UVLO voltage (typically
4.5 V) and the voltage at the EN pin rises above 1.2 V. This
delay comprises the time taken to charge the capacitor at the
VREG1 pin through the internal 8 V LDO. After the internal
biasing is finished, the soft start procedure initiates.
In the ADP1071-2, a high voltage LDO regulator is connected
to the VIN pin and has a regulated output of 8 V at VREG1.
In the ADP1071-2, to reduce power consumption in the LDO
for input voltages higher than approximately 30 V, an auxiliary
winding on the transformer of the active clamp forward
topology can be used to power VREG1. This auxiliary supply
voltage must be higher than the regulated output at VREG1 so
that the LDO shuts off during normal operation.
Connect a resistive divider between EN and VIN to set up the input
start-up voltage (see Figure 16). An internal current source at EN
allows the user to program the UVLO start-up voltage with a
desirable hysteresis. To calculate the start-up voltage with
hysteresis, use the superposition theorem or nodal analysis to
obtain the EN pin voltage, as follows:
In both the ADP1071-1 and ADP1071-2, the recommended
auxiliary voltage is from 8.5 V to 12.5 V because an internal
14 V Zener diode is connected at VREG1.
SECONDARY SIDE SUPPLY AND LDO
R2
R1 + R2
VEN =VIN
×
− IEN ×(R1 ||R2 + RH )
Two pins on the secondary side are supply pins: VDD2 and
VREG2.
where:
EN is the EN pin voltage.
EN is the current source at the EN pin (1 µA for turn on and
The secondary side is typically powered by the output rail of the
converter by connecting it to the VDD2 pin. The UVLO for the
secondary side is typically 3.55 V, at which the secondary side
starts up. For output voltages less than the secondary UVLO
voltage, a third winding is required to generate an auxiliary voltage
to power the secondary circuitry. The internal 5 V LDO regulator
at the VREG2 pin powers the MOSFET drivers, secondary side
iCouplers, and housekeeping circuits. When VDD2 is less than
5 V, the LDO regulator operates in dropout mode.
V
I
4 µA for turn off).
The user can adjust the R1, R2, and RH resistors such that
VEN ≥ 1.2 V and obtain the desired hysteresis.
An internal 1 µA pull-down current is always on, and the 3 µA
current is active only when the VEN is below the EN threshold
and becomes inactive when VEN is above the EN threshold.
For output voltages higher than 24 V, connecting the output
voltage directly to VDD2 can result in significant power
dissipation in the LDO. For instance, at 24 V and with the total
driver current at 10 mA, the power dissipated in the LDO is
0.19 W (10 mA × 19 V). It is recommended to power VDD2
with an auxiliary voltage in the 8 V to 12 V range.
In general, a higher input voltage requires a larger hysteresis. It
is recommended to keep a capacitor on the EN pin to AGND1
to provide a low impedance path that prevents any noise, which
toggles the EN pin when the input voltage hovers at the threshold.
VIN
ADP1071-1/ADP1071-2
VIN
EN
VREF
1.2V
8V LDO
R1
R2
LOGIC
R
H
1µA
3µA
HYSTERESIS
GENERATOR
Figure 16. Precision EN with Adjustable Hysteresis
When the EN pin is less than the threshold, the system enables
the soft stop procedure. SR takes up to a maximum of two
switching periods to terminate. See the Soft Start Procedure
section for more details.
Rev. A | Page 14 of 24
Data Sheet
ADP1071-1/ADP1071-2
After COMP transmission begins, the primary side receives the
signal and control is completely handed over to the secondary
side when either the received level of COMP on the primary
side is within 100 mV or up to 128 switching periods
(typically 8) have passed, starting from the first pulse being
transmitted to the primary side.
SOFT START PROCEDURE
The following procedure assumes that the VDD2 pin is
powered directly from the output voltage of the power supply.
To ensure a smooth output voltage ramp during startup, the soft
start sequence is controlled by two soft start control circuits,
one in the primary (for open-loop soft start using the GATE
pin) and the other in the secondary (for closed-loop soft start,
using the SS2 pin). Proper handshaking between the primary side
and the secondary side is needed prior to the secondary side
taking control.
Then, after the control is handed over to the secondary side, the
closed-loop soft start begins, where the SS2 capacitor is charged
at a nominal rate of 20 µA. The output voltage then rises to the
regulation voltage based on the SS2 pin voltage. The voltage on
the SS2 pin continues to rise to 1.2 V, that is, the steady state
voltage on the FB pin. At this stage, the power supply is in
regulation, and the output voltage is at its target value.
The open-loop soft start time is determined by the resistor on
the GATE pin prior to startup. The primary peak current is
increased gradually every switching period. The slew rate of the
increase in peak current is determined by selecting the GATE
resistor prior to startup. The current increases from a minimum
of 0 A to a maximum of 120 mV/RSENSE. This rate is the open-
loop soft start. Four speeds are available: 4 × 775, 16 × 775,
64 × 775, and 256 × 775 switching periods for resistors 100 kΩ,
10 kΩ, 22 kΩ, and 47 kΩ, respectively.
At the end of the soft start process, the voltage on the SS2 pin
continues to rise to approximately 1.4 V. In steady state, the
FB pin (that is, the reference voltage) is 1.2 V.
The SR1 and SR2 synchronous drivers begin to pulse after
VDD2 crosses the UVLO threshold.
If the voltage at the VDD2 pin is greater than the UVLO voltage,
such as a soft start from the precharged output, or if the VDD2 pin
is powered by an external supply, the secondary side assumes
control from the moment the EN pin is enabled, and only SS2 is
used for the soft start procedure.
During this time, the ADP1071-1/ADP1071-2 start firing the
PWM pulses and the output voltage continues to build up
slowly if the average current on the secondary side exceeds the
load current. Because the ADP1071-1/ADP1071-2 are current
mode controllers, the output capacitor starts charging only
when the primary current limit exceeds the load current
requirement.
When initiating a soft start from the precharged output, the
SS2 pin tracks the FB pin and then initiates a soft start. This
process eliminates any glitches in the output voltage.
The handshaking process is as follows.
When soft starting into a precharged output, the SR gate is
prevented from turning on until the SS2 voltage reaches the
precharged voltage at the FB pin. This soft start scheme prevents
the output from being discharged, and it prevents reverse current.
When VDD2 reaches the UVLO of approximately 3.5 V, the
internal circuitry on the secondary side is activated and the
ADP1071-1/ADP1071-2 initiate the following two processes:
Under abnormal situations, such as a shorted load or a transient
condition on the load during the soft start process, FB may not
be able to track SS2 accurately. If this condition occurs before the
VDD2 UVLO threshold is crossed, the open loop soft start is in
effect. If it occurs after the VDD2 UVLO threshold is crossed,
SS2 tracks the FB pin and then continues with the soft start
process until the regulation voltage is reached. In all conditions,
control is handed over to the secondary side if FB ≥ 1.2 V.
1. The ADP1071-1/ADP1071-2 make the voltage on the
SS2 pin equal to the value on the FB pin, with an SS2 pin
current, at 10 times the nominal current source of 20 µA
on the SS2 pin.
2. Simultaneously, the current limit on the primary side is
transferred over to the secondary side and the voltage on
the COMP pin is made equal to the instantaneous current
limit of 100 mV. There is a timeout for this process, which
is 1.5 ms after the VDD2 UVLO threshold is crossed.
When the secondary VDD2 is directly powered by the output of
the converter, the minimum output voltage required is higher
than the secondary UVLO voltage. For output voltages less than
the secondary UVLO voltage, a third winding is needed to generate
an auxiliary voltage to power the secondary side circuitry. Alter-
nately, in most cases, a diode resistor capacitor combination from
the switch node can provide the voltage to VDD2.
When this process is satisfied, the transmission of the COMP signal
occurs from the secondary to the primary side. The ADP1071-1/
ADP1071-2 transmit the COMP signal by continuously sampling
the analog signal at the COMP pin. The sampled value is then
transmitted using a proprietary scheme to the primary side
where the instantaneous value of the CS pin is compared to the
COMP level to determine the falling edge of the GATE pulse.
The COMP signal is, therefore, a representation of the primary
current limit.
Rev. A | Page 15 of 24
ADP1071-1/ADP1071-2
Data Sheet
OUTPUT VOLTAGE SENSING AND FEEDBACK
INPUT/OUTPUT CURRENT-LIMIT PROTECTION
The output voltage of the converter is set by a resistive divider
to the FB pin. The resistive divider must be set in a manner
such that the voltage at the FB pin is 1.2 V in steady state. The
output voltage must be differentially sensed using the FB pin
and the AGND2 pin.
There is no direct current-limit sensing circuit in the secondary
side, but the output current limit is indirectly set by sensing the
input primary peak current cycle by cycle. A leading edge
blanking time is added after the rising edge of the GATE signal
to avoid picking up any unwanted noise or ringing at the CS pin
at the start of the switching period.
LOOP COMPENSATION AND STEADY STATE
OPERATION
The input peak current limit is set by connecting a sense
resistor, RSENSE, from the source of the main MOSFET to
AGND1, and the sensed voltage appears at the CS pin. To
generate the slope-comp ramp, insert the slope compensation
The FB pin feeds into the negative terminal of a transconductance
amplifier (or gm amplifier) with a gain of approximately 250 µA / V.
The positive input terminal of the gm amplifier is connected to SS2,
which provides the reference setpoint voltage. The output of the
gm amplifier is connected to the COMP pin. The voltage on the
COMP pin is representative of the current peak limit required to
sustain regulation. This pin is continuously sampled, and the
signal is transmitted to the primary side, where it is compared
to the sensed primary current using a comparator. When the
comparator trips, it causes GATE to terminate.
resistor, RRAMP, between CS and RSENSE
.
The CS current limit, VCSLIM, is internally set to 120 m V.
Calculate the RSENSE value by
VCS _ LIM − RRAMP ×20 μA
RSENSE
=
IPKPRI
where:
CS_LIM is the CS current limit.
PKPRI is the primary peak current.
V
I
Typically, an RC network in series is connected between the
COMP pin and AGND2 for compensation. A high frequency
pole in the form of a capacitor can also be added in parallel to the
RC network.
When the sensed input peak current is above the CS limit
threshold, the controller operates in the cycle by cycle constant
current limit mode for 1.5 ms. Then, the controller immediately
shuts down the primary and secondary drivers. The controller
then enters hiccup mode for the next 40 ms and restarts the soft
start sequence after this timeout period.
The output of the gm amplifier is clamped to a minimum and max-
imum current of approximately +40 µA and −65 µA, respectively.
The COMP node is clamped to a lower and higher level of
approximately 0.7 V and 2.52 V, respectively. This is
representative of the CS range from 0 mV to 120 m V.
The slope ramp can affect the accuracy of the current-limit
threshold because the voltage drop across RRAMP contributes to
the inaccuracy of the peak current limit. For instance, if the
added slope ramp voltage is 20% of the current-limit threshold,
the actual input peak current limit can be off by as much as 20%
depending on where the peak current-limit threshold is tripped
during the on cycle. In the event of an output short circuit, the
controller treats this condition as an overcurrent event and
enters the 40 ms hiccup mode.
SLOPE COMPENSATION
For a peak current mode controller with a duty cycle higher than
50%, slope compensation is necessary for a stable operation. To
set up an external compensation in the ADP1071-1/ADP1071-2,
connect the external RRAMP resistor (see Figure 28) between CS
and the current sense resistor, RSENSE, to set up the slope voltage
ramp for the control signal. It is important to sense the signal
differentially. See the Layout Guidelines section for more details.
Under certain situations, the ADP1071-1/ADP1071-2 exit OCP
hiccup mode. In this condition, even though the COMP pin is
at the maximum clamp level, the device does not enter hiccup
mode. It is guaranteed that the PWMs are terminated whenever
the CS maximum threshold is reached. The conditions under
which this can occur are as follows.
An internal ramp current starts from 0 µA at the minimum
duty cycle (that is, the beginning of the switching period) and
increases linearly toward a maximum of 20 µA at the end of the
switching period. The slope of the voltage ramp is the ramp
current times RRAMP. RRAMP is sized using the following equation:
Under certain conditions, the ADP1071-1/ADP1071-2 exit
OCP hiccup mode. In these conditions, the COMP pin is at the
maximum clamp level, but the device does not enter hiccup
mode. However, it is guaranteed that the PWMs are terminated
whenever the CS maximum threshold is reached. The condition
under which the ADP1071-1/ADP1071-2 skip entering hiccup
mode is when VDD2 is powered through an auxiliary winding,
and an output short circuit occurs that results in the FB pin
having a voltage that is less than 300 mV. This event is more
prominent at high temperatures (>85°C) and can be exacerbated at
higher temperatures.
VOUT N2 RSENSE
RRAMP ≥ k
×
×
×tS
L
N1 20 μA
where:
k = 0.5 for nominal cases and k = 1 for deadbeat control.
OUT is the desired output voltage.
L is the output inductor.
N1 and N2 are the primary and secondary turns of the transformer.
V
tS is the switching period.
Rev. A | Page 16 of 24
Data Sheet
ADP1071-1/ADP1071-2
ALTERNATE OPTION
The root cause of the device exiting hiccup mode is due to the
effect that the OCP hiccup mode feature has on the SS2 pin.
During OCP recovery, the SS2 pin tracks the FB pin and
attempts a soft start from the precharge sequence. During this
time that SS2 tracks FB, the SS2 pin voltage can be less than the
FB pin voltage for a short interval, which causes the COMP pin
(output of the gm amplifier) to momentarily fall below the
maximum COMP pin clamp level. This event means that the
current limit required for the next few switching periods is less
than the maximum threshold and puts the device out of hiccup
mode because the ADP1071-1/ADP1071-2 fail to register
1.25 ms worth of consecutive overcurrent cycles and fails to
enter OCP hiccup mode.
VOUT
R4
D1
100Ω
VDD2
FROM AUXILIARY
WINDING
D1
~10V
VOUT
R3
500Ω
R4
100Ω
~6.3V
ZENER
AGND2
Figure 17. Recommended Circuit to Guarantee Hiccup Mode
TEMPERATURE SENSING
The ADP1071-1/ADP1071-2 have an internal temperature
sensor that shuts down the controller when the internal
temperature exceeds the OTP limit. At this time, the primary
and secondary MOSFET drivers (GATE and SR) are held low.
When the temperature drops below the OTP hysteresis level,
the ADP1071-1/ADP1071-2 restart with a soft start sequence.
The following scenarios guarantee OCP hiccup mode based on
the configuration of the VDD2 power supply:
•
When VDD2 is powered directly from the output voltage,
if a short circuit on the output terminals of the load occurs
after steady state regulation is achieved, the VDD2 pin
voltage is less than the UVLO threshold, and the device
enters hiccup mode for 200 ms, similar to the hiccup time
described in the Remote System Reset section.
FREQUENCY SETTING (RT PIN)
The switching frequency can be programmed in a range of
50 kHz to 600 kHz by connecting a resistor from RT to
AGND1. A small current flows out of the RT pin and the
voltage across it sets up the internal oscillator frequency. The
value of this pin is approximately 1.224 V in steady state. Use
the following equation to determine the resistor (in Ω) for a
particular switching frequency (in kHz):
•
When VDD2 is powered through auxiliary winding or
another configuration, when a short circuit occurs on the
output terminals, the auxiliary winding is not shorted and
maintains a positive voltage above the VDD2 UVLO
threshold. To enter hiccup mode, the following circuit is
recommended, as shown in Figure 17. The circuit operates
as follows: when the output voltage goes low due to a short
circuit, the D1 diode turns on, which pulls the base of the
bipolar junction transistor (BJT) low, shutting off VDD2.
The system then enters hiccup mode, as described in the
Remote System Reset section.
1
1
fS (kHz) =
×
41.67×10−12 × R 1000
where:
fS is the switching frequency.
R is the resistor on the RT pin.
MAXIMUM DUTY CYCLE
R3 is sized to bias the Zener diode and R4 is sized such that
(VZENER − 1)/R4 > IZENER, where VZENER is the voltage of the diode
and IZENER is the biasing current of the diode. This sizing ensures
that the impedance of the resistor is less than the impedance of
the diode, which causes the voltage of the diode to drop, and
allows VDD2 to enter UVLO.
To prevent the transformer core from saturating in the event of
high current or extreme load transient, a maximum duty cycle
clamp is internally set to 85%.
As an added protection feature to prevent open-loop conditions,
the maximum duty cycle is also applicable during soft start. If
the controller reaches the maximum duty cycle during soft start
for three consecutive switching periods, the 40 ms hiccup timer
is initiated.
If the output voltage is <5 V, the same procedure can be used to
size the R4 resistor. If a discrete LDO is not used, a simple
resistor and diode connector to the output voltage is sufficient.
In this case, the R4 resistor is sized to limit the current through
the D1 diode when the output voltage is 0 V during a short
circuit event. Because the bandwidth of the system is high, the
ADP1071-1/ADP1071-2 are able to maintain voltage regulation
at the proper voltage level, even if the auxiliary winding voltage
is higher than the output voltage. The soft start and soft start
from precharge conditions is met with the addition of this
circuit due to the bandwidth of the overall system.
FREQUENCY SYNCHRONIZATION
The switching frequency of the ADP1071-1/ADP1071-2 can be
synchronized to an external clock at the SYNC pin. When an
external clock rising edge is first detected, it takes approx-
imately seven to ten periods for the internal clock to lock in the
SYNC clock frequency. In between the time that the SYNC clock
is detected and the time that it is locked in, the controller
continues to operate with the internal oscillator frequency.
The SYNC frequency must be within 10% of the internal oscil-
lator frequency set by the RT pin. Otherwise, synchronization does
not take place.
Rev. A | Page 17 of 24
ADP1071-1/ADP1071-2
Data Sheet
A clock signal can be applied to SYNC on the fly or prior to the
soft start sequence. A dithered clock can also be applied to
SYNC to reduce the peak electromagnetic interference (EMI)
noise in the converter output and switch node. The internal
clock is able to lock onto the dithered clock cycle by cycle.
LIGHT LOAD MODE (LLM) AND CONTINUOUS
CONDUCTION MODE (CCM)
The ADP1071-1 has a power saving mode feature in which the
LLM threshold is programmable by connecting a resistor from
the MODE pin to AGND1. A current source flowing through
this resistor directly sets up the LLM threshold, which is compared
to the COMP voltage on the primary side. The SR driver is turned
off when the COMP voltage on the primary is below the LLM
threshold, and conduction current continues to flow through
the body diode of the SR MOSFET. However, the primary gate
driver continues to operate in full PWM mode. When the
COMP voltage moves above the LLM threshold, the controller
operates in forced CCM.
It is recommended to connect the SYNC pin to AGND1 if this
feature is not used.
SYNCHRONOUS RECTIFIER (SR) DRIVER
There is a synchronous rectifier driver on the secondary side for
driving the synchronous switch. VDD2 is the front end of the
LDO at VREG2. The 5 V internal LDO at VREG2 powers the
SR drivers and all internal circuits on the secondary side. The
recommended power supply range at VDD2 is from 6 V to 36 V.
However, at 36 V input to VDD2, the power dissipation in the
LDO can be significant. If VDD2 is less than 5 V, the LDO
operates in the dropout region, where VREG2 and the driver
output are less than 5 V. In this case, it is recommended to
supply VDD2 with an auxiliary power supply greater than 5 V.
When the COMP voltage rises above the LLM threshold (that
is, the MODE pin voltage), the SR PWMs gradually increase (or
phase in) from the duty cycle at light load to the steady state
duty cycle at the SR phase in rate. The SR phase in rate moves
the SR edges every 1.5 ns per μs. Without the phase in sequence,
a dip in the output voltage can occur if the SR PWMs transition
from zero to full duty cycle instantaneously.
VDD2 can be directly connected to the converter output or an
auxiliary power supply, by using a third winding of the main
transformer. For additional drive strength, SR can be fed into an
external MOSFET driver such as the ADP3624 or the ADP3654.
In a load dump situation, for example, when the load is stepped
from full load to light load, that is, from continuous conduction
mode (CCM) to discontinuous conduction mode (DCM) oper-
ation, the duty cycles of the SR PWMs gradually phase out at
the SR phase out rate, which has the same numerical value of
the SR phase in rate. The phase out sequence of the SR PWMs
prevents reverse current in the secondary side, and at the same
time, optimizes the dynamic performance of the output response.
Note that the level of COMP is still above the minimum COMP
clamp level at this point, and the ADP1071-1 outputs duty
cycles with minimum on time.
OUTPUT OVERVOLTAGE PROTECTION (OVP)
When the output voltage exceeds the OVP threshold of 1.36 V,
the controller immediately shuts off the drivers (GATE and SR)
on both the primary and secondary side. When the voltage at the
OVP drops below the OV hysteresis level, the controller resumes
switching in the next switching period with the primary drivers,
followed by the phasing in of SR. The OVP feature causes the
system to enter hiccup for 200 ms if the voltage on the OVP pin
exceeds 1.36 V for a sustained period of 200 μs.
If the load is further reduced and the COMP pin voltage becomes
equal to the minimum COMP clamp level, the ADP1071-1 enters
pulse skip mode.
SR DEAD TIME
To maximize efficiency and avoid cross conduction between the
primary and secondary sides, a fixed dead time between GATE
and SR is provided, as shown in Figure 18.
Note that when the system enters light load mode, the synchronous
rectifiers terminate at the falling edge of GATE, which prevents
termination at a negative current.
GATE
Use the following formula to set up the LLM threshold:
SR DEAD TIME
30ns FIXED
I
PEAK _ LLM CSGAIN 0.8
RMODE
SR DEAD TIME
50ns FIXED
SR
IMODE
Figure 18. Gate to SR Dead Time
where:
PEAK_LLM is the peak primary current at the particular no load
I
condition.
CSGAIN = 12.5.
I
MODE is the current flowing out of the MODE pin.
For full time CCM operation, connect MODE to AGND1.
The ADP1071-2 does not have an LLM and always operates in
forced CCM. Pulse skipping is not available in the ADP1071-2.
Rev. A | Page 18 of 24
Data Sheet
ADP1071-1/ADP1071-2
SOFT STOP
OUTPUT VOLTAGE TRACKING
The ADP1071-2 employs a soft stop feature that brings the output
voltage gradually down to zero by using the SS2 pin as a reference.
During the soft stop procedure, the SS2 pin is discharged to zero by
a current sink of approximately 1.5 times the value during closed-
loop soft start.
The ADP1071-1/ADP1071-2 offer a tracking feature. During
steady state, the FB pin is at 1.2 V. At this time, the SS2 pin
voltage is at 1.4 V. Using an external digital-to-analog converter
(DAC), the voltage on the SS2 pin can modulate the output
voltage. It is recommended that the SS2 pin voltage be changed
only after the VDD2 UVLO point is crossed, and control is
handed over to the secondary side, or else the handover process
does not occur smoothly, resulting in glitches in the output
voltage.
When the voltage at EN drops below the EN threshold, the
SR secondary driver shuts off immediately, and the primary
GATE pulse width gradually decreases the duty cycle from the last
known condition to the minimum pulse width and down to zero,
causing the output voltage to decrease. The soft stop feature
prevents any reverse current when the controller is shut down.
The SS2 voltage must be brought down from 1.4 V to 1.2 V, and
it must be brought down even further to effect any change in the
output voltage. The rate at which the output tracks the SS2 pin
is dependent upon the overall system bandwidth.
When the output voltage decreases below the VDD2 UVLO
threshold, there is no transmission of the COMP signal to the
primary side. Therefore, the output voltage continues to decrease at
the rate at which the load current discharges the output capacitor.
REMOTE SYSTEM RESET
For a remote (secondary side) system shutdown, an open-drain
general-purpose input/output (GPIO) of an external
microcontroller can be used to force the SS2 pin to 0 V.
When the load is at a minimum or at no load, the output voltage
does not discharge because any reduction in duty cycle or current
limit does not discharge the output voltage linearly.
This pull-down causes the ADP1071-1/ADP1071-2 to regulate
to 0 V, and the ADP1071-1/ADP1071-2 enter pulse skip mode
or output a minimum duty cycle because the SS2 pin offsets
because of the finite resistance of the GPIO.
OCP/FEEDBACK RECOVERY
During steady state, the FB pin is at 1.2 V. At this time, the SS2 pin
voltage is 1.4 V. Under abnormal situations, such as an overload
condition, the output voltage can dip severely. In such an event,
the current limit is at the maximum level, and the COMP pin
voltage is at its clamp level. If the two conditions of the COMP pin
voltage being clamped and VFB < (1.2 V − 100 mV) are satisfied,
the controller discharges the SS2 pin using a fast current sink
(200 µA) to make the SS2 pin equal to the FB pin. The controller
then attempts to perform a soft start from this precharged
condition, that is, from the last known value of the output
voltage. This process is how the OCP/feedback recovery feature
operates.
When the VDD2 is charged from the output bus, this setup is
equivalent to a system shutdown because when VDD2 < VDD2
UVLO, the ADP1071-1/ADP1071-2 enter a special hiccup
mode of 200 ms, (instead of the standard 40 ms hiccup).
When VDD2 is powered using auxiliary winding, the system
regulates to the voltage proportional to the voltage on the SS2 pin
and eventually enters the special hiccup mode previously
mentioned, after the auxiliary rail decays below the VDD2
UVLO threshold.
Therefore, the SS2 pin can achieve output tracking as well as a
secondary side shutdown, also known as remote system reset, as
shown in Figure 19.
However, if at any time the voltage on the COMP pin is above
the maximum clamp voltage for a period greater than 1.5 ms,
the system enters hiccup mode.
During the soft start from precharge, the output voltage rises at
the same rate as determined by the capacitor on the SS2 pin.
The SS2 pin voltage determines the current limit during this
period. If, however, there is a detrimental fault in the power
stage that prevents the rise of the output voltage, VFB does not
track SS2 and when SS2 > (VFB + 100 mV), the COMP pin
voltage increases to the clamp level and the system again enters
the OCP/feedback recovery mode.
Rev. A | Page 19 of 24
ADP1071-1/ADP1071-2
Data Sheet
VDD2
DEPENDS ON VDD2
CAPACITOR AND I
DD2
CONSUMPTION
(5mA TYPICAL)
VDD2 UVLO
(3.5V)
SS2 (1.4V)
V
(1.2V)
FB
DEPENDS ON SYSTEM
BANDWIDTH
SS2
CAPACITOR
SS1
CAPACITOR
TIME
HANDOVER TIME FROM
PRIMARY TO SECONDARY
(128 × tS
)
200ms HICCUP COUNTER
PWM SWITCHING
Figure 19. Remote Software Reset with 200 ms Hiccup
OCP COUNTER
VDD2
During overload conditions when the peak sensed currents
exceed the OCP threshold voltage of 120 mV on the CS pin, the
ADP1071-1/ADP1071-2 immediately terminate the remainder
of the PWM pulse. If the peak sense current continues to exceed
the threshold every switching period for 1.5 ms, the system
enters hiccup mode, by which it shuts down for approximately
40 ms and then soft starts. During an exceeded overcurrent
situation, such as a dead short, it is likely that the programmed
slope compensation is not enough, and therefore, the system
enters subharmonic oscillation. If this is the case, the system
cannot enter hiccup mode because the OCP threshold is crossed
every alternate switching period, and the 1.5 ms hiccup counter
resets.
VDD2_UVLO
3.1V
SS2 = 1.4V
V
= 1.2V
FB
DEPENDS ON
LOOP BANDWIDTH
DEPENDS ON
LOOP BANDWIDTH
TIME
To prevent this scenario, the ADP1071-1/ADP1071-2 latch the
last known state, whereby if an OCP condition registered as a 1
in one switching period and as a 0 in the next switching period,
it is still counted as a 1. In this manner, the system can enter
Figure 20. Tracking with SS2 Pin
Rev. A | Page 20 of 24
Data Sheet
ADP1071-1/ADP1071-2
FROM
hiccup mode even in subharmonic oscillation. Missing two
OCP thresholds consecutively resets the hiccup counter.
AUXILIARY
V
= 8V TO 13V
AUX
WINDING
VIN
VIN
ADP1071-1/ADP1071-2
VIN
EN
VREF
1.2V
ADP1071-1/
ADP1071-2
8V LDO
R1
<60mW
Q1
R1
R2
LOGIC
VIN
RH
LDO
D1
8.7V TO 11V
VREG1
R2
R3
1µA
3µA
14V
C1
2.2µF
EN
HYSTERESIS
GENERATOR
Figure 21. Precision EN with Adjustable Hysteresis
EXTERNAL START-UP CIRCUIT
Figure 23. Fast Start-Up Circuit
For input voltages higher than 36 V, in which the power
dissipation in the internal 8 V LDO can be significant, the use
of an external start-up circuit is recommended. (See Figure 22
for an example.) In this case, the VIN and VREG1 pins are
shorted together and connect to the output of the start-up
circuit. Because the input pre-enable bias current, the VIN and
VREG1 start-up current, is approximately 160 µA, the output of
the start-up circuit must be able to provide this level of current
in order to soft start. The auxiliary winding then provides the
bias voltage, shutting off the start-up circuit after soft start
completes.
INSULATION LIFETIME
All insulation structures eventually break down when subjected
to voltage stress over a sufficiently long period. The rate of insu-
lation degradation is dependent upon the characteristics of the
voltage waveform applied across the insulation. In addition to
the testing performed by the regulatory agencies, Analog
Devices carries out an extensive set of evaluations to determine
the lifetime of the insulation structure within the ADP1071-1/
ADP1071-2.
Analog Devices performs accelerated life testing using voltage
levels higher than the rated continuous working voltage.
Acceleration factors for several operating conditions are
determined. These factors allow calculation of the time to failure at
the actual working voltage.
VAUX1
VIN
ADP1071-1/ADP1071-2
VIN
VREG_UVLO
START-UP
CIRCUIT
8V LDO
The values shown in Table 6 summarize the peak voltage for
50 years of service life for a bipolar ac operating condition. In
many cases, the approved working voltage is higher than the
50-year service life voltage. Operation at these high working
voltages can lead to shortened insulation life in some cases.
VREG1
VREF
1.2V
R1
R2
LOGIC
EN
1µA
4µA
The ADP1071-1/ADP1071-2 insulation lifetime depends on the
voltage waveform type imposed across the isolation barrier. The
iCoupler insulation structure degrades at different rates
depending on whether the waveform is bipolar ac, unipolar ac, or
dc. Figure 24, Figure 25, and Figure 26 show these different
isolation voltage waveforms.
HYSTERESIS
GENERATOR
Figure 22. Precision EN Circuit Connection with an External Start-Up Circuit
A fast start-up circuit is shown in Figure 23. This circuit requires
two components: a Zener diode, which sets up the start-up
voltage at the VIN and VREG1 pin, and a negative positive
negative (NPN) transistor, which sets up a fast current path for
charging up the start-up capacitor, C1. The start-up current
through R1 must be more than 160 µA, which is the minimum
specified start-up current, and the start-up voltage at VREG1
and VIN must be approximately 8 V to 13 V. The auxiliary
winding then provides the bias voltage, shutting off the NPN
transistor after the soft start completes.
A bipolar ac voltage environment is the worst case for the iCoupler
products yet meets the 50-year operating lifetime recommended
by Analog Devices for maximum working voltage. In the case
of unipolar ac or dc voltage, the stress on the insulation is
significantly lower. The low stress allows operation at higher
working voltages while still achieving a 50-year service life. Treat
any cross insulation voltage waveform that does not conform to
Figure 25 or Figure 26 as a bipolar ac waveform, and limit its peak
voltage to the 50-year lifetime voltage value listed in Table 6.
Note that the voltage presented in Figure 25 is shown as
sinusoidal for illustration purposes only. It is meant to represent
any voltage waveform varying between 0 V and some limiting
Rev. A | Page 21 of 24
ADP1071-1/ADP1071-2
Data Sheet
value. The limiting value can be positive or negative, but the
voltage cannot cross 0 V.
3. Place a capacitor (33 pF to 470 pF typical) close to the
CS pin, connected to AGND1.
4. Place resistors (1 Ω to 5 Ω typical) in series with GATE and
the main power MOSFET. These resistors aid in eliminating
any ringing on the drive voltages. Use a 100 nF capacitor
on the MODE pin if LLM is used in noisy environments.
5. Ensure that RT pin resistor is Kelvin connected to AGND1
and not to a ground plane to avoid noise pickup.
RATED PEAK VOLTAGE
0V
Figure 24. Bipolar AC Waveform
RATED PEAK VOLTAGE
The layout guidelines for the secondary side are as follows:
0V
1. Ground all the capacitors to their respective grounds. For
example, ground the SS2 capacitor to AGND2.
Figure 25. Unipolar AC Waveform
RATED PEAK VOLTAGE
2. Place resistors (1 Ω to 5 Ω) in series with SRx and the
synchronous MOSFET. These resistors aid in eliminating
any ringing on the drive voltages.
0V
3. The ground plane on the secondary side must be
connected to AGND2. The negative terminal of the output
voltage must be Kelvin connected to the AGND2 pin.
4. Use the FB pin and the AGND2 pin to remotely differentially
sense the output voltage by connecting AGND2 to the
negative terminal of the output voltage using a 0 Ω resistor.
Figure 26. DC Waveform
LAYOUT GUIDELINES
The layout guidelines for the primary side are as follows:
1. Ground all the capacitors to their respective grounds. For
example, ground the VREG1 capacitor to AGND1.
2. Use the CS pin and the AGND1 pin to differentially sense
the primary current measurement through the sense
resistor. Do not cross the CS and AGND1 traces for current
sensing across any switch nodes.
Rev. A | Page 22 of 24
Data Sheet
ADP1071-1/ADP1071-2
APPLICATIONS INFORMATION
TYPICAL APPLICATION CIRCUITS
VIN
(385V DC)
AUXILIARY PS
VOUT
EMI FILTER
AND
RECTIFIER
90V TO 264V AC
R
STARTUP
R
RAMP
GATE
AGND1
VREG1
MODE
EN
SR
AGND2
VREG2
VDD2
OVP
ZENER
ADP1071-1
EXTERNAL
STARTUP CIRCUIT
CS
FB
RT
COMP
SS2
SYNC
Figure 27. ADP1071-1 Typical Application with External Start-Up Circuit and Auxiliary Power
VIN = 4.5V TO 60V
VOUT
R
STARTUP
R
RAMP
GATE
SR
AGND1
VREG1
VIN
AGND2
VREG2
VDD2
OVP
ADP1071-2
EN
CS
FB
RT
COMP
SS2
SYNC
Figure 28. ADP1071-2 Low Input Voltage Flyback Application Circuit
Rev. A | Page 23 of 24
ADP1071-1/ADP1071-2
OUTLINE DIMENSIONS
Data Sheet
10.50 (0.4134)
10.10 (0.3976)
16
1
9
8
7.60 (0.2992)
7.40 (0.2913)
10.65 (0.4193)
10.00 (0.3937)
0.75 (0.0295)
0.25 (0.0098)
1.27 (0.0500)
BSC
45°
2.65 (0.1043)
2.35 (0.0925)
0.30 (0.0118)
0.10 (0.0039)
8°
0°
COPLANARITY
0.10
SEATING
PLANE
0.51 (0.0201)
0.31 (0.0122)
1.27 (0.0500)
0.40 (0.0157)
0.33 (0.0130)
0.20 (0.0079)
COMPLIANT TO JEDEC STANDARDS MS-013-AA
CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS
(IN PARENTHESES) ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR
REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.
Figure 29. 16-Lead Standard Small Outline Package [SOIC_W]
Wide Body
(RW-16)
Dimensions shown in millimeters and (inches)
ORDERING GUIDE
Model1
Temperature Range
Package Description
Package Option
ADP1071-1ARWZ
ADP1071-1ARWZ-RL
ADP1071-1ARWZ-R7
ADP1071-2ARWZ
ADP1071-2ARWZ-RL
ADP1071-2ARWZ-R7
ADP1071-2EBZ12.1V
ADP1071-1EVALZ
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
16-Lead Standard Small Outline Package [SOIC_W]
16-Lead Standard Small Outline Package [SOIC_W]
16-Lead Standard Small Outline Package [SOIC_W]
16-Lead Standard Small Outline Package [SOIC_W]
16-Lead Standard Small Outline Package [SOIC_W]
16-Lead Standard Small Outline Package [SOIC_W]
ADP1071-2 Evaluation Board
RW-16
RW-16
RW-16
RW-16
RW-16
RW-16
ADP1071-1 Evaluation Board
1 Z = RoHS Compliant Part.
©2018 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D15626-0-11/18(A)
Rev. A | Page 24 of 24
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