AD ADP1883ARMZ-1.0-R7

Synchronous Current-Mode with
Constant On-Time, PWM Buck Controller
ADP1882/ADP1883
FEATURES
TYPICAL APPLICATIONS CIRCUIT
VIN = 2.75V TO 20V
VIN
CC
VOUT
RTOP
RC
CC2
ADP1882/
ADP1883
COMP/EN BST
CBST
FB
DRVH
Q1
L
VOUT
RBOT
VDD
COUT
Q2
SW
DRVL
PGND
RRES
VDD = 2.75V TO 5.5V
CVDD
LOAD
08901-001
GND
CVDD2
Figure 1.
100
95
90
85
APPLICATIONS
VDD = 5.5V, VIN = 13.0V
VDD = 5.5V, VIN = 16.5V
80
EFFICIENCY (%)
Telecom and networking systems
Mid to high end servers
Set-top boxes
DSP core power supplies
CIN
75
70
65
VDD = 5.5V, VIN = 5.5V (PSM)
VDD = 5.5V, VIN = 5.5V
VDD = 3.6V, VIN = 5.5V
60
55
TA = 25°C
VOUT = 1.8V
fSW = 300kHz
50
45
40
WURTH INDUCTOR:
744325120, L = 1.2µH, DCR = 1.8mΩ
INFINEON MOSFETs:
BSC042N03MS G (UPPER/LOWER)
35
30
25
100
1k
10k
LOAD CURRENT (mA)
100k
08901-002
Power input voltage as low as 2.75 V to 20 V
Bias supply voltage range: 2.75 V to 5.5 V
Minimum output voltage: 0.8 V
0.8 V reference voltage with ±1.0% accuracy
Supports all N-channel MOSFET power stages
Available in 300 kHz, 600 kHz, and 1.0 MHz options
No current-sense resistor required
Power saving mode (PSM) for light loads (ADP1883 only)
Resistor-programmable current-sense gain
Thermal overload protection
Short-circuit protection
Precision enable input
Integrated bootstrap diode for high-side drive
140 μA shutdown supply current
Starts into a precharged load
Small, 10-lead MSOP package
Figure 2. ADP1882/ADP1883 Efficiency vs. Load Current
(VOUT = 1.8 V, 300 kHz)
GENERAL DESCRIPTION
The ADP1882/ADP1883 are versatile current-mode, synchronous
step-down controllers that provide superior transient response,
optimal stability, and current-limit protection by using a constant
on-time, pseudo-fixed frequency with a programmable currentlimit, current-control scheme. In addition, these devices offer
optimum performance at low duty cycles by using valley currentmode control architecture. This allows the ADP1882/ADP1883
to drive all N-channel power stages to regulate output voltages
as low as 0.8 V.
The ADP1883 is the power saving mode (PSM) version of the
device and is capable of pulse skipping to maintain output
regulation while achieving improved system efficiency at light
loads (see the Power Saving Mode (PSM) Version (ADP1883)
section for more information).
Available in three frequency options (300 kHz, 600 kHz, and
1.0 MHz, plus the PSM option), the ADP1882/ADP1883 are
well suited for a wide range of applications. These ICs not only
operate from a 2.75 V to 5.5 V bias supply, but they also can
accept a power input as high as 20 V.
In addition, an internally fixed soft start period is included to limit
input in-rush current from the input supply during startup and
to provide reverse current protection during soft start for a precharged output. The low-side current-sense, current-gain scheme
and integration of a boost diode, along with the PSM/forced
pulse-width modulation (PWM) option, reduce the external
part count and improve efficiency.
The ADP1882/ADP1883 operate over the −40°C to +125°C
junction temperature range and are available in a 10-lead MSOP.
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.
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Fax: 781.461.3113
©2010 Analog Devices, Inc. All rights reserved.
ADP1882/ADP1883
TABLE OF CONTENTS
Features .............................................................................................. 1 Timer Operation ........................................................................ 22 Applications ....................................................................................... 1 Pseudo-Fixed Frequency ........................................................... 23 Typical Applications Circuit............................................................ 1 Applications Information .............................................................. 24 General Description ......................................................................... 1 Feedback Resistor Divider ........................................................ 24 Revision History ............................................................................... 2 Inductor Selection ...................................................................... 24 Specifications..................................................................................... 3 Output Ripple Voltage (ΔVRR) .................................................. 24 Absolute Maximum Ratings............................................................ 5 Output Capacitor Selection....................................................... 24 Thermal Resistance ...................................................................... 5 Compensation Network ............................................................ 25 Boundary Condition .................................................................... 5 Efficiency Considerations ......................................................... 26 ESD Caution .................................................................................. 5 Input Capacitor Selection .......................................................... 27 Pin Configuration and Function Descriptions ............................. 6 Thermal Considerations............................................................ 28 Typical Performance Characteristics ............................................. 7 Design Example .......................................................................... 28 ADP1882/ADP1883 Block Diagram............................................ 18 External Component Recommendations .................................... 31 Theory of Operation ...................................................................... 19 Layout Considerations ................................................................... 33 Startup .......................................................................................... 19 IC Section (Left Side of Evaluation Board) ............................. 36 Soft Start ...................................................................................... 19 Power Section ............................................................................. 36 Precision Enable Circuitry ........................................................ 19 Differential Sensing .................................................................... 36 Undervoltage Lockout ............................................................... 19 Typical Applications Circuits ........................................................ 37 Thermal Shutdown..................................................................... 19 Dual-Input, 300 kHz High Current Applications Circuit..... 37 Programming Resistor (RES) Detect Circuit .......................... 20 Single-Input, 600 kHz Applications Circuit ........................... 37 Valley Current-Limit Setting .................................................... 20 Dual-Input, 300 kHz High Current Applications Circuit..... 38 Hiccup Mode During Short Circuit ......................................... 21 Outline Dimensions ....................................................................... 39 Synchronous Rectifier ................................................................ 22 Ordering Guide .......................................................................... 39 Power Saving Mode (PSM) Version (ADP1883) .................... 22 REVISION HISTORY
4/10—Revision 0: Initial Version
Rev. 0 | Page 2 of 40
ADP1882/ADP1883
SPECIFICATIONS
All limits at temperature extremes are guaranteed via correlation using standard statistical quality control (SQC). VDD = 5 V, BST − SW = 5 V,
VIN = 13 V. The specifications are valid for TJ = −40°C to +125°C, unless otherwise specified.
Table 1.
Parameter
POWER SUPPLY CHARACTERISTICS
High Input Voltage Range
Low Input Voltage Range
Quiescent Current
Shutdown Current
Undervoltage Lockout
UVLO Hysteresis
SOFT START
Soft Start Period
ERROR AMPLIFIER
FB Regulation Voltage
Transconductance
FB Input Leakage Current
CURRENT-SENSE AMPLIFIER GAIN
Programming Resistor (RES)
Value from DRVL to PGND
SWITCHING FREQUENCY
ADP1882ARMZ-0.3/
ADP1883ARMZ-0.3 (300 kHz)
On Time
Minimum On Time
Minimum Off Time
ADP1882ARMZ-0.6/
ADP1883ARMZ-0.6 (600 kHz)
On Time
Minimum On Time
Minimum Off Time
ADP1882ARMZ-1.0/
ADP1883ARMZ-1.0 (1.0 MHz)
On Time
Minimum On Time
Minimum Off Time
Symbol
Conditions
Min
Typ
Max
Unit
VIN
ADP1882ARMZ-0.3/ADP1883ARMZ-0.3 (300 kHz)
ADP1882ARMZ-0.6/ADP1883ARMZ-0.6 (600 kHz)
ADP1882ARMZ-1.0/ADP1883ARMZ-1.0 (1.0 MHz)
CIN = 1 μF to PGND, CIN = 0.22 μF to GND
ADP1882ARMZ-0.3/ADP1883ARMZ-0.3 (300 kHz)
ADP1882ARMZ-0.6/ADP1883ARMZ-0.6 (600 kHz)
ADP1882ARMZ-1.0/ADP1883ARMZ-1.0 (1.0 MHz)
FB = 1.5 V, no switching
COMP/EN < 285 mV
Rising VDD (see Figure 35 for temperature variation)
Falling VDD from operational state
2.75
2.75
3.0
12
12
12
20
20
20
V
V
V
2.75
2.75
3.0
5
5
5
1.1
140
2.65
190
5.5
5.5
5.5
V
V
V
mA
μA
V
mV
VDD
IQ_DD + IQ_BST
IDD, SD + IBST, SD
UVLO
See Figure 58
VFB
GM
IFB, LEAK
TJ = 25°C
TJ = −40°C to +85°C
TJ = −40°C to +125°C
215
3.0
ms
795.3
792.8
300
800
800
800
520
1
805.5
808.0
730
50
mV
mV
mV
μs
nA
RES = 47 kΩ ± 1%
2.98
3.4
3.7
V/V
RES = 22 kΩ ± 1%
RES = none
RES = 100 kΩ ± 1%
Typical values measured at 50% time points with
0 nF at DRVH and DRVL; maximum values are
guaranteed by bench evaluation 1
6
24.1
12.1
6.6
26.7
13.4
7.4
29.3
14.7
V/V
V/V
V/V
FB = 0.8 V, COMP/EN = released
300
kHz
VIN = 5 V, VOUT = 2 V, TJ = 25°C
VIN = 20 V
84% duty cycle (maximum)
1115
1200
145
340
600
1285
190
400
ns
ns
ns
kHz
VIN = 5 V, VOUT = 2 V, TJ = 25°C
VIN = 20 V, VOUT = 0.8 V
65% duty cycle (maximum)
490
540
82
340
1.0
585
110
400
ns
ns
ns
MHz
VIN = 5 V, VOUT = 2 V, TJ = 25°C
VIN = 20 V
45% duty cycle (maximum)
280
312
60
340
340
85
400
ns
ns
ns
Rev. 0 | Page 3 of 40
ADP1882/ADP1883
Parameter
OUTPUT DRIVER CHARACTERISTICS
High-Side Driver
Output Source Resistance
Output Sink Resistance
Rise Time 2
Fall Time2
Low-Side Driver
Output Source Resistance
Output Sink Resistance
Rise Time2
Fall Time2
Propagation Delays
DRVL Fall to DRVH Rise2
DRVH Fall to DRVL Rise2
SW Leakage Current
Integrated Rectifier
Channel Impedance
PRECISION ENABLE THRESHOLD
Logic High Level
Enable Hysteresis
COMP VOLTAGE
COMP Clamp Low Voltage
Symbol
Conditions
COMP Clamp High Voltage
COMP Zero Current Threshold
THERMAL SHUTDOWN
Thermal Shutdown Threshold
Thermal Shutdown Hysteresis
Hiccup Current Limit Timing
VCOMP(HIGH)
VCOMP_ZCT
TTMSD
1
2
Typ
Max
Unit
2
0.8
25
11
3.5
2
tR, DRVH
tF, DRVH
ISOURCE = 1.5 A, 100 ns, positive pulse (0 V to 5 V)
ISINK = 1.5 A, 100 ns, negative pulse (5 V to 0 V)
BST − SW = 4.4 V, CIN = 4.3 nF (see Figure 60)
BST − SW = 4.4 V, CIN = 4.3 nF (see Figure 61)
Ω
Ω
ns
ns
1.7
0.75
18
16
3
2
tR, DRVL
tF, DRVL
ISOURCE = 1.5 A, 100 ns, positive pulse (0 V to 5 V)
ISINK = 1.5 A, 100 ns, negative pulse (5 V to 0 V)
VDD = 5.0 V, CIN = 4.3 nF (see Figure 61)
VDD = 5.0 V, CIN = 4.3 nF (see Figure 60)
Ω
Ω
ns
ns
tTPDH, DRVH
tTPDH, DRVL
ISW, LEAK
BST − SW = 4.4 V (see Figure 60)
BST − SW = 4.4 V (see Figure 61)
BST = 25 V, SW = 20 V, VDD = 5.5 V
22
24
ISINK = 10 mA
22
VCOMP(LOW)
Min
110
VIN = 2.75 V to 20 V, VDD = 2.75 V to 5.5 V
VIN = 2.75 V to 20 V, VDD = 2.75 V to 5.5 V
235
From disable state, release COMP/EN pin to enable
device; 2.75 V ≤ VDD ≤ 5.5 V
2.75 V ≤ VDD ≤ 5.5 V
2.75 V ≤ VDD ≤ 5.5 V
0.47
Rising temperature
285
35
ns
ns
μA
Ω
330
mV
mV
V
0.95
2.55
V
V
155
15
6
°C
°C
ms
The maximum specified values are with the closed loop measured at 10% to 90% time points (see Figure 60 and Figure 61), CGATE = 4.3 nF, and the upper-side and lower-side
MOSFETs specified as Infineon BSC042N030MSG.
Not automatic test equipment (ATE) tested.
Rev. 0 | Page 4 of 40
ADP1882/ADP1883
ABSOLUTE MAXIMUM RATINGS
THERMAL RESISTANCE
Table 2.
Parameter
VDD to GND
VIN to PGND
FB, COMP/EN to GND
DRVL to PGND
SW to PGND
BST to SW
BST to PGND
DRVH to SW
PGND to GND
θJA (10-Lead MSOP)
2-Layer Board
4-Layer Board
Operating Junction Temperature Range
Storage Temperature Range
Soldering Conditions
Maximum Soldering Lead Temperature
(10 sec)
Rating
−0.3 V to +6 V
−0.3 V to +28 V
−0.3 V to (VDD + 0.3 V)
−0.3 V to (VDD + 0.3 V)
−2.0 V to +28 V
−0.8 V to (VDD + 0.3 V)
−0.3 V to 28 V
−0.3 V to VDD
±0.3 V
θJA is specified for the worst-case conditions, that is, a device
soldered in a circuit board for surface-mount packages.
Table 3. Thermal Resistance
Package Type
θJA (10-Lead MSOP)
2-Layer Board
4-Layer Board
1
θJA1
Unit
213.1
171.7
°C/W
°C/W
θJA is specified for the worst-case conditions; that is, θJA is specified for device
soldered in a circuit board for surface-mount packages.
BOUNDARY CONDITION
213.1°C/W
171.7°C/W
−40°C to +125°C
−65°C to +150°C
JEDEC J-STD-020
300°C
In determining the values given in Table 2 and Table 3, natural
convection was used to transfer heat to a 4-layer evaluation board.
ESD CAUTION
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.
Absolute maximum ratings apply individually only, not in
combination. Unless otherwise specified, all other voltages are
referenced to PGND.
Rev. 0 | Page 5 of 40
ADP1882/ADP1883
VIN 1
FB 3
ADP1882/
ADP1883
GND 4
TOP VIEW
(Not to Scale)
COMP/EN 2
VDD 5
10
BST
9
SW
8
DRVH
7
PGND
6
DRVL
08901-003
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
Figure 3. Pin Configuration
Table 4. Pin Function Descriptions
Pin No.
1
2
3
4
Mnemonic
VIN
COMP/EN
FB
GND
5
VDD
6
DRVL
7
8
9
10
PGND
DRVH
SW
BST
Description
High Input Voltage. Connect VIN to the drain of the upper-side MOSFET.
Output of the Internal Error Amplifier/IC Enable. When this pin functions as EN, applying 0 V to this pin disables the IC.
Noninverting Input of the Internal Error Amplifier. This is the node where the feedback resistor is connected.
Analog Ground Reference Pin of the IC. All sensitive analog components should be connected to this ground
plane (see the Layout Considerations section).
Bias Voltage Supply for the ADP1882/ADP1883 Controller, Including the Output Gate Drivers. A bypass capacitor
of 1 μF directly from this pin to PGND and a 0.1 μF across VDD and GND are recommended.
Drive Output for the External Lower-Side N-Channel MOSFET. This pin also serves as the current-sense gain
setting pin (see Figure 69).
Power GND. Ground for the lower-side gate driver and lower-side N-channel MOSFET.
Drive Output for the External Upper-Side, N-Channel MOSFET.
Switch Node Connection.
Bootstrap for the Upper-Side MOSFET Gate Drive Circuitry. An internal boot rectifier (diode) is connected
between VDD and BST. A capacitor from BST to SW is required. An external Schottky diode can also be
connected between VDD and BST for increased gate drive capability.
Rev. 0 | Page 6 of 40
ADP1882/ADP1883
100
VDD = 5.5V, VIN = 5.5V (PSM)
VDD = 5.5V, VIN = 13V (PSM)
95
VDD = 5.5V, VIN = 5.5V
90
85
75
VDD = 3.6V,
VIN = 13V
(PSM)
VDD = 5.5V,
VIN = 13V
(PSM)
70
EFFICIENCY (%)
65
VDD = 5.5V, VIN = 16.5V (PSM)
60
55
VDD = 3.6V, VIN = 16.5V (PSM)
50
VDD = 3.6V, VIN = 5.5V (PSM)
45
40
30
100
1k
10k
100k
LOAD CURRENT (mA)
08901-004
WURTH IND: 744355147, L = 0.47 µH, DCR: 0.80MΩ
INFENION FETs: BSC042N03MS G (UPPER/LOWER)
TA = 25°C
35
LOAD CURRENT (mA)
Figure 4. Efficiency—300 kHz, VOUT = 0.8 V
100
100
VDD = 5.5V, VIN = 5.5V (PSM)
VDD = 5.5V, VIN = 5.5V
95
Figure 7. Efficiency—600 kHz, VOUT = 0.8 V
90
90
80
VDD = 5.5V, VIN = 13V (PSM)
75
EFFICIENCY (%)
VDD = 5.5V, VIN = 16.5V (PSM)
70
65
VDD = 3.6V, VIN = 5.5V
60
55
50
60
1k
10k
VDD = 5.5V, VIN = 16.5V
50
40
25
100
VDD = 5.5V, VIN = 13V (PSM)
55
45
30
VDD = 5.5V, VIN = 16.5V (PSM)
65
40
WURTH INDUCTOR: 7443252100, L = 1.0µH, DCR: 3.3mΩ
INFINEON MOSFETS: BSC042N03MS G (UPPER/LOWER)
RON: 5.4mΩ
TA = 25°C
VDD = 5.5V, VIN = 5.5V (PSM)
70
45
35
VDD = 3.6V, VIN = 5.5V
75
VDD = 5.5V, VIN = 13V
WURTH INDUCTOR: 744325072, L = 0.72µH, DCR: 1.65mΩ
INFINEON FETS: BSC042N03MS G (UPPER/LOWER)
RON: 5.4mΩ
TA = 25°C
35
30
100k
LOAD CURRENT (mA)
25
100
10k
Figure 8. Efficiency—600 kHz, VOUT = 1.8 V
100
VDD = 5.5V, VIN = 16.5V (PSM)
95
VDD = 5.5V/VIN = 13V (PSM)
95
90
85
60
55
VDD = 5.5V, VIN = 13V
VDD = 3.6V, VIN = 13V
VDD = 5.5V, VIN = 16.5V
VDD = 3.6V, VIN = 16.5V
50
40
35
1k
10k
LOAD CURRENT (mA)
100k
80
VDD = 5.5V/VIN = 16.5V
75
70
VDD = 5.5V/VIN = 13V
TA = 25°C
VOUT = 5V, VIN = 13V
FSW = 600kHz
65
TA = 25°C
VOUT = 1.8V
FSW = 300kHz
WURTH INDUCTOR:
744355200, L = 2µH, DCR: 2.5mΩ
INFINEON MOSFETS:
BSC042N03MS G (UPPER/LOWER)
45
30
100
EFFICIENCY (%)
65
85
VDD = 2.7V, VIN = 13V
60
WURTH INDUCTOR:
7443552100, L = 1.0µH, DCR: 3.3mΩ
INFINEON MOSFETS:
BSC042N03MS G (UPPER/LOWER)
55
08901-006
EFFICIENCY (%)
70
VDD = 3.6V/VIN = 13V
90
VDD = 2.7V, VIN = 16.5V (PSM)
80
75
100k
LOAD CURRENT (mA)
Figure 5. Efficiency—300 kHz, VOUT = 1.8 V
100
1k
08901-008
VDD = 5.5V,
VIN = 13V
08901-005
EFFICIENCY (%)
85
VDD = 5.5V, VIN = 16.5V
85
80
VDD = 5.5V, VIN = 5.5V
95
Figure 6. Efficiency—300 kHz, VOUT = 7 V
50
100
1k
10k
LOAD CURRENT (mA)
Figure 9. Efficiency—600 kHz, VOUT = 5 V
Rev. 0 | Page 7 of 40
100k
08901-009
EFFICIENCY (%)
80
100
VDD = 5.5V, VIN = 5.5V (PSM)
95 V = 5.5V,
DD
VDD = 5.5V, VIN = 5.5V
90 VIN = 13V (PSM)
85
80
75
70
VDD = 5.5V, VIN = 16.5V (PSM)
65
60
VDD = 5.5V, VIN = 13V
55
VDD = 5.5V, VIN = 16.5V
50
45
40
VDD = 3.6V, VIN = 5.5V
35
30
WURTH INDUCTOR: 744355072, L = 0.72µH, DCR: 1.65mΩ
INFINEON FETS: BSC042N03MS G (UPPER/LOWER)
25
RON: 5.4mΩ
20
TA = 25°C
15
100
1k
10k
100k
08901-007
TYPICAL PERFORMANCE CHARACTERISTICS
0.818
0.816
0.814
0.812
0.810
0.808
0.806
0.804
0.802
0.800
0.798
0.796
VIN = 5.5V
+125°C
+25°C
–40°C
0.794
0.792
VIN = 13V
+125°C
+25°C
–40°C
VIN = 16.5V
+125°C
+25°C
–40°C
0.790
0
2k
4k
6k
8k
10k
12k
14k
16k
LOAD CURRENT (mA)
Figure 10. Efficiency—1.0 MHz, VOUT = 0.8 V
08901-013
LOAD CURRENT (mA)
0.820
OUTPUT VOLTAGE (V)
100
VDD = 5.5V/VIN = 5.5V (PSM)
VDD = 3.6V/VIN = 3.6V
95
VDD = 5.5V/VIN = 5.5V
90
85
80
75
70
VDD = 3.6V/VIN = 13V
65
60
VDD = 5.5V/VIN = 16.5V
55
VDD = 5.5V/VIN = 13V
50
TA = 25°C
45
VOUT = 0.8V, VIN = 5.5V
40
FSW = 1MHz
35
WURTH INDUCTOR:
30
744303022, L = 0.22µH, DCR: 0.33mΩ
INFINEON MOSFETS:
25
BSC042N03MS G (UPPER/LOWER)
20
100
1k
10k
100k
08901-010
EFFICIENCY (%)
ADP1882/ADP1883
Figure 13. Output Voltage Accuracy—300 kHz, VOUT = 0.8 V
100
VDD = 5.5V/VIN = 5.5V (PSM)
95
1.809
VDD = 5.5V/VIN = 5.5V
VDD = 5.5V/VIN = 13V
VDD = 3.6V/VIN = 16.5V
70
VDD = 5.5V/VIN = 16.5V
65
VDD = 3.6V/VIN = 13V
60
55
50
45
TA = 25°C
VOUT = 1.8V, VIN = 5.5V
FSW = 1MHz
40
35
30
20
100
1k
10k
VIN = 5.5V
+125°C
+25°C
–40°C
0
VIN = 13V
+125°C
+25°C
–40°C
VIN = 16.5V
+125°C
+25°C
–40°C
1.5k
3.0k
4.5k
6.0k
7.5k
9.0k 10.5k 12.0k 13.5k 15.0k
LOAD CURRENT (mA)
Figure 11. Efficiency—1.0 MHz, VOUT = 1.8 V
Figure 14. Output Voltage Accuracy—300 kHz, VOUT = 1.8 V
100
6.970
6.960
85
6.955
OUTPUT VOLTAGE (V)
80
75
70
VDD = 5.5V/VIN = 16.5V
65
60
VDD = 5.5V/VIN = 13V
55
45
40
35
30
100
TA = 25°C
VOUT = 4V, VIN = 16.5V
FSW = 1MHz
1k
LOAD CURRENT (mA)
6.945
6.940
6.935
6.930
6.925
VDD = 5.5V,
VIN = 16.5V
+125°C
+25°C
–40°C
6.915
6.910
10k
Figure 12. Efficiency—1.0 MHz, VOUT = 4 V
VDD = 5.5V,
VIN = 13V
+125°C
+25°C
–40°C
6.950
6.920
WURTH INDUCTOR:
744318180, L = 1.4µH, DCR: 3.2mΩ
INFINEON MOSFETS:
BSC042N03MS G (UPPER/LOWER)
08901-012
50
VDD = 3.6V,
VIN = 16.5V
+125°C
+25°C
–40°C
6.965
VDD = 5.5V/VIN = 16.5V (PSM)
6.905
0
1k
2k
VDD = 3.6V,
VIN = 13V
+125°C
+25°C
–40°C
3k
4k
5k
6k
7k
8k
9k
10k
LOAD CURRENT (mA)
Figure 15. Output Voltage Accuracy—300 kHz, VOUT = 7 V
Rev. 0 | Page 8 of 40
08901-015
95
EFFICIENCY (%)
1.794
1.784
100k
LOAD CURRENT (mA)
90
1.799
1.789
WURTH INDUCTOR:
744303022, L = 0.22µH, DCR: 0.33mΩ
INFINEON MOSFETS:
BSC042N03MS G (UPPER/LOWER)
25
1.804
08901-011
EFFICIENCY (%)
75
OUTPUT VOLTAGE (V)
80
08901-014
90
85
0.829
0.827
0.825
0.823
0.821
0.819
0.817
0.815
0.813
0.811
0.809
0.807
0.805
0.803
0.801
0.799
0.797
0.795
VIN = 16.5V
+125°C
+25°C
–40°C
VIN = 16.5V
+125°C
+25°C
–40°C
0.820
VIN = 13V
+125°C
+25°C
–40°C
0.818
0.816
0.812
0.810
0.808
0.806
0.804
0.802
0.800
0.798
0.796
VIN = 5.5V
+125°C
+25°C
–40°C
0.794
0.792
0
2k
4k0
6k
8k
10k
12k
14k
LOAD CURRENT (mA)
VIN = 13V
+125°C
+25°C
–40°C
VIN = 16.5V
+125°C
+25°C
–40°C
0.790
0
2k
4k
6k
8k
10k
12k
LOAD CURRENT (mA)
08901-018
OUTPUT VOLTAGE (V)
0.814
08901-115
OUTPUT VOLTAGE (V)
ADP1882/ADP1883
Figure 19. Output Voltage Accuracy—1.0 MHz, VOUT = 0.8 V
Figure 16. Output Voltage Accuracy—600 kHz, VOUT = 0.8 V
1.808
1.806
1.806
1.804
1.802
1.800
1.800
1.798
1.796
1.794
1.792
1.790
VIN = 5.5V
+125°C
+25°C
–40°C
1.788
VIN = 13V
+125°C
+25°C
–40°C
3.0k
4.5k
6.0k
7.5k
1.794
1.792
1.790
1.788
VIN = 5.5V
+125°C
+25°C
–40°C
1.784
1.782
VIN = 13V
+125°C
+25°C
–40°C
VIN = 16.5V
+125°C
+25°C
–40°C
1.780
9.0k 10.5k 12.0k 13.5k 15.0k
LOAD CURRENT (mA)
0
08901-016
1.5k
1.796
1.786
VIN = 16V
+125°C
+25°C
–40°C
1.786
0
1.798
1.5k
3.0k
4.5k
6.0k
7.5k
9.0k 10.5k 12.0k 13.5k 15.0k
LOAD CURRENT (mA)
08901-019
OUTPUT VOLTAGE (V)
OUTPUT VOLTAGE (V)
1.804
1.802
Figure 20. Output Voltage Accuracy—1.0 MHz, VOUT = 1.8 V
Figure 17. Output Voltage Accuracy—600 kHz, VOUT = 1.8 V
4.060
5.015
4.055
5.010
4.050
OUTPUT VOLTAGE (V)
4.045
5.000
4.995
4.990
4.985
4.040
4.035
4.030
4.025
4.020
4.015
VDD = 5.5V, VIN = 13V
+125°C
+25°C
–40°C
4.975
VDD = 5.5V, VIN = 16.5V
+125°C
+25°C
–40°C
4.970
0
1k
2k
3k
4k
5k
6k
7k
8k
9k
LOAD CURRENT (mA)
10k
VIN = 13V
+125°C
+25°C
–40°C
4.010
4.005
VIN = 16.5V
+125°C
+25°C
–40°C
4.000
0
8.0k
1.6k
2.4k
3.2k
4.0k
4.8k
5.6k
6.4k
7.2k
LOAD CURRENT (mA)
Figure 21. Output Voltage Accuracy—1.0 MHz, VOUT = 4 V
Figure 18. Output Voltage Accuracy—600 kHz, VOUT = 5 V
Rev. 0 | Page 9 of 40
8.0k
08901-020
4.980
08901-017
OUTPUT VOLTAGE (V)
5.005
0.804
1000
0.803
950
900
0.801
0.800
0.799
0.798
800
750
700
650
0.797
0.796
–40.0
VDD = 2.7V, VIN = 2.7/3.6V
VDD = 3.6V, VIN = 3.6V TO 16.5V
VDD = 5.5V, VIN = 5.5/13V/16.5V
–7.5
25.0
57.5
600
90.0
122.5
TEMPERATURE (°C)
Figure 22. Feedback Voltage vs. Temperature
VIN (V)
355
340
325
305
310
FREQUENCY (kHz)
315
295
285
275
265
255
295
280
265
250
235
VDD = 5.5V
+125°C
+25°C
–40°C
225
10.8 11.0 11.2 11.4 11.6 11.8 12.0 12.2 12.4 12.6 12.8 13.0 13.2
VIN (V)
VIN = 5.5V
+125°C
+25°C
–40°C
220
205
VIN = 13V
+125°C
+25°C
–40°C
VIN = 16.5V
+125°C
+25°C
–40°C
190
0
2k
4k
6k
8k
10k
12k
14k
16k
LOAD CURRENT (mA)
08901-025
VDD = 3.6V
+125°C
+25°C
–40°C
08901-022
235
VIN = 5.5V
+125°C
+25°C
–40°C
Figure 25. Switching Frequency vs. High Input Voltage, 1.0 MHz, ±10% of 12 V
325
245
VIN = 3.6V
+125°C
+25°C
–40°C
550
10.8 11.0 11.2 11.4 11.6 11.8 12.0 12.2 12.4 12.6 12.8 13.0 13.2
335
FREQUENCY (kHz)
850
08901-024
FREQUENCY (kHz)
0.802
08901-021
FEEDBACK VOLTAGE (V)
ADP1882/ADP1883
Figure 26. Frequency vs. Load Current, 300 kHz, VOUT = 0.8 V
Figure 23. Switching Frequency vs. High Input Voltage, 300 kHz, ±10% of 12 V
380
650
VIN = 5.5V
+125°C
+25°C
–40°C
370
360
600
FREQUENCY (kHz)
FREQUENCY (kHz)
350
550
500
340
330
320
VIN = 13V
+125°C
+25°C
–40°C
310
300
290
VDD = 5.5V
+125°C
+25°C
–40°C
400
10.8 11.0 11.2 11.4 11.6 11.8 12.0 12.2 12.4 12.6 12.8 13.0 13.2
VIN (V)
VIN = 16.5V
+125°C
+25°C
–40°C
280
270
Figure 24. Switching Frequency vs. High Input Voltage, 600 kHz, VOUT = 1.8 V,
±10% of 12 V
Rev. 0 | Page 10 of 40
260
0
2k
4k
6k
8k
10k
12k
14k
16k
18k
20k
LOAD CURRENT (mA)
Figure 27. Frequency vs. Load Current, 300 kHz, VOUT = 1.8 V
08901-026
VOUT = 1.8V
+125°C
+25°C
–40°C
08901-023
450
750
358
354
350
346
342
338
334
330
326
322
318
314
310
306
302
298
294
290
742
734
726
FREQUENCY (kHz)
718
VIN = 16.5V
+125°C
+25°C
–40°C
0.8k 1.6k 2.4k 3.2k 4.0k 4.8k 5.6k 6.4k 7.2k 8.0k 8.8k 9.6k
LOAD CURRENT (mA)
694
686
678
670
654
VIN = 13V
+125°C
+25°C
–40°C
646
638
0
0.8k 1.6k 2.4k 3.2k 4.0k 4.8k 5.6k 6.4k 7.2k 8.0k 8.8k 9.6k
LOAD CURRENT (mA)
Figure 31. Frequency vs. Load Current, 600 kHz, VOUT =5 V
1300
700
670
640
610
580
550
520
490
460
430
400
370
340
310
280
250
220
190
VIN = 16.5V
+125°C
+25°C
–40°C
630
Figure 28. Frequency vs. Load Current, 300 kHz, VOUT = 7 V
VIN = 5.5V
+125°C
+25°C
–40°C
1225
1150
VIN = 13V
+125°C
+25°C
–40°C
VIN = 16.5V
+125°C
+25°C
–40°C
FREQUENCY (kHz)
1075
1000
925
850
775
700
625
0
2k
4k
VIN = 13V
+125°C
+25°C
–40°C
6k
8k
VIN = 16.5V
+125°C
+25°C
–40°C
10k
12k
14k
LOAD CURRENT (mA)
550
475
400
0
4k
6k
8k
10k
12k
LOAD CURRENT (mA)
Figure 32. Frequency vs. Load Current, VOUT = 1.0 MHz, 0.8 V
Figure 29. Frequency vs. Load Current, 600 kHz, VOUT = 0.8 V
835
815
795
775
755
735
715
695
675
655
635
615
595
575
555
535
515
495
2k
08901-031
VIN = 5.5V
+125°C
+25°C
–40°C
08901-028
1450
VIN = 5.5V
+125°C
+25°C
–40°C
1375
1300
FREQUENCY (kHz)
1225
VIN = 13V
+125°C
+25°C
–40°C
1150
1075
1000
925
850
775
VIN = 16.5V
+125°C
+25°C
–40°C
2k
4k
6k
8k
10k
625
12k
14k
16k
18k
LOAD CURRENT (mA)
08901-029
0
VIN = 5.5V
+125°C
+25°C
–40°C
700
Figure 30. Frequency vs. Load Current, 600 kHz, VOUT = 1.8 V
VIN = 13V
+125°C
+25°C
–40°C
VIN = 16.5V
+125°C
+25°C
–40°C
550
0
2k
4k
6k
8k
10k
12k
14k
16k
LOAD CURRENT (mA)
Figure 33. Frequency vs. Load Current, 1.0 MHz, VOUT = 1.8 V
Rev. 0 | Page 11 of 40
08901-032
FREQUENCY (kHz)
702
08901-030
0
FREQUENCY (kHz)
710
662
VIN = 13V
+125°C
+25°C
–40°C
08901-027
FREQUENCY (kHz)
ADP1882/ADP1883
ADP1882/ADP1883
MAXIMUM DUTY CYCLE (%)
1300
1200
1150
1100
1050
1000
VIN = 13V
+125°C
+25°C
–40°C
900
0.8k
1.6k
2.4k
3.2k
4.0k
4.8k
5.6k
6.4k
7.2k
8.0k
LOAD CURRENT (mA)
680
2.657
630
MINUMUM OFF TIME (ns)
2.655
UVLO (V)
8.4
9.6
10.8 12.0 13.2 14.4 15.6
VREG = 2.7V
VREG = 3.6V
VREG = 5.5V
580
2.656
2.654
2.653
2.652
530
480
430
380
330
2.651
280
2.650
230
0
20
40
60
80
100
120
180
–40
08901-034
–20
TEMPERATURE (°C)
–20
0
20
40
60
80
VDD = 2.7V
VDD = 3.6V
VDD = 5.5V
95
90
120
Figure 38. Minimum Off Time vs. Temperature
680
100
100
TEMPERATURE (°C)
Figure 35. UVLO vs. Temperature
+125°C
+25°C
–40°C
+125°C
+25°C
–40°C
630
580
MINUMUM OFF TIME (ns)
85
80
75
70
65
60
55
530
480
430
380
330
280
50
230
45
400
500
600
700
800
900
FREQUENCY (kHz)
1000
08901-035
MAXIMUM DUTY CYCLE (%)
7.2
Figure 37. Maximum Duty Cycle vs. High Voltage Input (VIN)
2.658
40
300
6.0
VIN (V)
Figure 34. Frequency vs. Load Current, 1.0 MHz, VOUT = 4 V
2.649
–40
4.8
+125°C
+25°C
–40°C
08901-037
0
VIN = 16.5V
+125°C
+25°C
–40°C
08901-033
950
VDD = 3.6V
VDD = 5.5V
180
2.7
3.1
3.5
3.9
4.3
4.7
5.1
VREG (V)
Figure 39. Minimum Off Time vs. VDD (Low Input Voltage)
Figure 36. Maximum Duty Cycle vs. Frequency
Rev. 0 | Page 12 of 40
5.5
08901-038
FREQUENCY (kHz)
1250
84
82
80
78
76
74
72
70
68
66
64
62
60
58
56
54
52
50
48
46
44
42
40
3.6
08297-036
1350
ADP1882/ADP1883
80
+125°C
+25°C
–40°C
RECTIFIER DROP (mV)
640
560
480
400
320
240
160
400
500
600
700
800
900
1000
FREQUENCY (kHz)
Figure 40. Internal Rectifier Drop vs. Frequency
1280
1200
1120
VIN = 5.5V
VIN = 13V
VIN = 16.5V
1MHz
300kHz
56
48
40
32
24
16
8
2.7
3.1
3.5
3.9
4.3
4.7
5.1
5.5
VREG (V)
Figure 43. Lower-Side MOSFET Body Conduction Time vs. VDD (Low Input Voltage)
TA = 25°C
OUTPUT VOLTAGE
1
1040
RECTIFIER DROP (mV)
+125°C
+25°C
–40°C
64
08901-039
80
300
300kHz
1MHz
72
08901-042
720
VREG = 2.7V
VREG = 3.6V
VREG = 5.5V
BODY DIODE CONDUCTION TIME (ns)
800
960
880
800
INDUCTOR CURRENT
720
2
640
560
SW NODE
480
400
3
320
240
LOW SIDE
160
3.1
3.5
3.9
4.3
4.7
5.1
5.5
VREG (V)
Figure 41. Internal Boost Rectifier Drop vs. VDD (Low Input Voltage)
over VIN Variation
720
640
300kHz
1MHz
CH1 50mV BW
CH3 10V BW
CH2 5A Ω
CH4 5V
M400ns
T 35.8%
A CH2
3.90A
08901-043
4
08901-040
80
2.7
Figure 44. Power Saving Mode (PSM) Operational Waveform, 100 mA
+125°C
+25°C
–40°C
OUTPUT VOLTAGE
INDUCTOR CURRENT
480
2
400
320
SW NODE
240
3
160
LOW SIDE
80
2.7
3.1
3.5
3.9
4.3
4.7
5.1
VREG (V)
5.5
Figure 42. Internal Boost Rectifier Drop vs. VDD
CH1 50mV BW
CH3 10V BW
CH2 5A Ω
CH4 5V
M4.0µs
T 35.8%
A CH2
3.90A
Figure 45. PSM Waveform at Light Load, 500 mA
Rev. 0 | Page 13 of 40
08901-044
4
08901-041
RECTIFIER DROP (mV)
1
560
ADP1882/ADP1883
OUTPUT VOLTAGE
2
4
OUTPUT VOLTAGE
INDUCTOR CURRENT
12A NEGATIVE STEP
1
SW NODE
1
3
SW NODE
LOW SIDE
3
CH4 100mV
B
W
M400ns
T 30.6%
A CH3
2.20V
CH1 10A Ω
CH3 20V
Figure 46. CCM Operation at Heavy Load, 18 A
(See Figure 92 for Applications Circuit)
CH2 200mV
CH4 5V
B
W M20µs
A CH1
3.40A
T 48.2%
08901-048
CH1 5A Ω
CH3 10V
08901-045
4
Figure 49. Negative Step During Heavy Load Transient Behavior—PSM Enabled,
20 A (See Figure 92 for Applications Circuit)
OUTPUT VOLTAGE
2
4
OUTPUT VOLTAGE
12A STEP
12A STEP
1
LOW SIDE
1
SW NODE
3
2
SW NODE
LOW SIDE
4
B
W
M2ms
T 75.6%
A CH1
3.40A
3
CH1 10A Ω
CH3 20V
Figure 47. Load Transient Step—PSM Enabled, 20 A
(See Figure 92 for Applications Circuit)
CH2 5V
CH4 200mV
B
W
M2ms
T 15.6%
A CH1
6.20A
08901-049
CH2 200mV
CH4 5V
08901-046
CH1 10A Ω
CH3 20V
Figure 50. Load Transient Step—Forced PWM at Light Load, 20 A
(See Figure 92 for Applications Circuit)
OUTPUT VOLTAGE
OUTPUT VOLTAGE
2
4
12A POSITIVE STEP
12A POSITIVE STEP
SW NODE
1
LOW SIDE
1
3
2
SW NODE
LOW SIDE
4
B
W M20µs
T 30.6%
A CH1
3.40A
CH1 10A Ω
CH3 20V
Figure 48. Positive Step During Heavy Load Transient Behavior—PSM Enabled,
20 A, VOUT = 1.8 V (See Figure 92 for Applications Circuit)
CH2 5V
CH4 200mV
M20µs
B
W T 43.8%
A CH1
6.20A
08901-050
CH2 200mV
CH4 5V
08901-047
3
CH1 10A Ω
CH3 20V
Figure 51. Positive Step During Heavy Load Transient Behavior—Forced PWM
at Light Load, 20 A, VOUT = 1.8 V (See Figure 92 for Applications Circuit)
Rev. 0 | Page 14 of 40
ADP1882/ADP1883
OUTPUT VOLTAGE
2
OUTPUT VOLTAGE
1
INDUCTOR CURRENT
12A NEGATIVE STEP
2
1
SW NODE
LOW SIDE
4
3
SW NODE
LOW
SIDE
CH2 200mV
CH4 5V
B
W M10µs
A CH1
5.60A
T 23.8%
CH1 2V BW CH2 5A Ω
CH3 10V
CH4 5V
M2ms
T 32.8%
A CH1
720mV
08901-054
CH1 10A Ω
CH3 20V
3
08901-051
4
Figure 55. Start-Up Behavior at Heavy Load, 18 A, 300 kHz
(See Figure 92 for Applications Circuit)
Figure 52. Negative Step During Heavy Load Transient Behavior—Forced PWM
at Light Load, 20 A (See Figure 92 for Applications Circuit)
OUTPUT VOLTAGE
OUTPUT VOLTAGE
1
1
INDUCTOR CURRENT
2
INDUCTOR CURRENT
LOW SIDE
2
LOW SIDE
4
4
SW NODE
SW NODE
3
M4ms
T 49.4%
A CH1
920mV
CH1 2V BW CH2 5A Ω
CH3 10V
CH4 5V
A CH1
720mV
Figure 56. Power-Down Waveform During Heavy Load
Figure 53. Output Short-Circuit Behavior Leading to Hiccup Mode
1
M4ms
T 41.6%
08901-055
CH1 2V BW CH2 5A Ω
CH3 10V
CH4 5V
08901-052
3
OUTPUT VOLTAGE
OUTPUT VOLTAGE
1
INDUCTOR CURRENT
INDUCTOR CURRENT
2
2
SW NODE
SW NODE
3
3
LOW SIDE
LOW SIDE
M10µs
T 36.2%
A CH2
8.20A
08901-053
CH1 5V BW CH2 10A Ω
CH3 10V
CH4 5V
CH1 50mV BW
CH3 10V BW
CH2 5A Ω
CH4 5V
M2µs
T 35.8%
A CH2
3.90A
08901-056
4
4
Figure 57. Output Voltage Ripple Waveform During PSM Operation
at Light Load, 2 A
Figure 54. Magnified Waveform During Hiccup Mode
Rev. 0 | Page 15 of 40
ADP1882/ADP1883
18ns (tr,DRVL )
LOW SIDE
OUTPUT VOLTAGE
1
4
24ns (tpdh,DRVL )
HIGH SIDE
LOW SIDE
4
HS MINUS
SW
11ns (tf,DRVH )
SW NODE
SW NODE
3
2
3
M
INDUCTOR CURRENT
CH2 5A Ω
CH4 2V
M1ms
T 63.2%
A CH1
1.56V
08901-057
CH1 1V BW
CH3 10V BW
CH2 5V
CH3 5V
CH4 2V
MATH 2V 20ns
A CH2
TA = 25°C
VREG = 5.5V
VREG = 3.6V
VREG = 2.7V
TRANSCONDUCTANCE (µS)
570
4
HIGH SIDE
SW NODE
3
2
550
530
510
490
470
HS MINUS
SW
M40ns
T 29.0%
A CH2
4.20V
430
–40
08901-058
CH3 5V
MATH 2V 40ns
CH2 5V
CH4 2V
20
40
60
80
100
120
Figure 62. Transconductance (GM) vs. Temperature
680
TA = 25°C
16ns (tf,DRVL )
0
TEMPERATURE (°C)
Figure 59. Output Drivers and SW Node Waveforms
LOW SIDE
–20
08901-061
450
M
+125°C
+25°C
–40°C
TRANSCONDUCTANCE (µS)
630
4
4.20V
Figure 61. Upper-Side Driver Falling and Lower-Side Rising Edge Waveforms
(CIN = 4.3 nF (Upper-Side/Lower-Side MOSFET),
QTOTAL = 27 nC (VGS = 4.4 V (Q1), VGS = 5 V (Q3))
Figure 58. Soft Start and RES Detect Waveform
LOW SIDE
M20ns
T 39.2%
08901-060
TA = 25°C
2
22ns (tpdhDRVH )
HIGH SIDE
25ns (tr,DRVH)
SW NODE
580
530
480
430
3
2
CH2 5V
CH3 5V
CH4 2V
MATH 2V 40ns
M40ns
T 29.0%
A CH2
4.20V
330
2.7
3.0
3.3
3.6
3.9
4.2
4.5
4.8
VREG (V)
Figure 60. Upper-Side Driver Rising and Lower-Side Falling Edge Waveforms
(CIN = 4.3 nF (Upper-Side/Lower-Side MOSFET),
QTOTAL = 27 nC (VGS = 4.4 V (Q1), VGS = 5 V (Q3))
Rev. 0 | Page 16 of 40
Figure 63. Transconductance (GM) vs. VDD
5.1
5.4
08901-062
380
HS MINUS
SW
08901-059
M
ADP1882/ADP1883
1.30
1.25
1.15
+125°C
1.10
1.05
+25°C
1.00
0.95
–40°C
0.90
0.85
0.80
0.75
0.70
2.7
3.1
3.5
3.9
4.3
4.7
5.1
VREG (V)
5.5
08901-063
QUIESCENT CURRENT (mA)
1.20
Figure 64. Quiescent Current vs. VDD (VIN = 13 V)
Rev. 0 | Page 17 of 40
ADP1882/ADP1883
ADP1882/ADP1883 BLOCK DIAGRAM
ADP1882/ADP1883
VDD
tON-TIMER
TO ENABLE
ALL BLOCKS
PRECISION
ENABLE BLOCK
VIN
C
VDD
BIAS BLOCK
AND REF
R (TRIMMED)
SW
INFORMATION
tON = 2RC (VOUT/VIN)
REF_ZERO
SW-FILTER
PFM
VDD
BST
ISS
SS
COMP
STATE
MACHINE
tON
CSS
BG_REF
SS_REF
PSM
DRVH
DH_LO
300kΩ
IN_SS
COMP/EN
LEVEL
SHIFT
DRVH
ERROR
AMP
SW
HS
8kΩ
SW
FB
PWM
IREV
VREG
LS
DRVL
DRVL
DL_LO
0.8V
PGND
PWM
IREV
COMP
CS
AMP
LOWER
COMP
CLAMP
REF_ZERO
CS GAIN SET
ADC
RES DETECT
AND
GAIN SET
800kΩ
08901-064
0.4V
GND
Figure 65. Block Diagram
Rev. 0 | Page 18 of 40
ADP1882/ADP1883
THEORY OF OPERATION
ADP1882/ADP1883, reducing the supply current of the devices
to approximately 140 μA. For more information, see Figure 67.
ADP1882/ADP1883
FB
VDD
SS
COMP/EN
STARTUP
ERROR
AMPLIFIER
CC
The ADP1882/ADP1883 have an input low voltage pin (VDD) for
biasing and supplying power for the integrated MOSFET drivers. A
bypass capacitor should be located directly across the VDD (Pin 5)
and PGND (Pin 7) pins. Included in the power-up sequence is
the biasing of the current-sense amplifier, the current-sense gain
circuit (see the Programming Resistor (RES) Detect Circuit
section), the soft start circuit, and the error amplifier.
RC
SOFT START
The ADP1882/ADP1883 have digital soft start circuitry, which
involves a counter that initiates an incremental increase in current,
by 1 μA, via a current source on every cycle through a fixed internal
capacitor. The output tracks the ramping voltage by producing
PWM output pulses to the upper-side MOSFET. The purpose is to
limit the in-rush current from the high voltage input supply (VIN)
to the output (VOUT).
PRECISION ENABLE CIRCUITRY
The ADP1882/ADP1883 employ precision enable circuitry. The
enable threshold is 285 mV typical with 35 mV of hysteresis.
The devices are enabled when the COMP/EN pin is released,
allowing the error amplifier output to rise above the enable
threshold (see Figure 66). Grounding this pin disables the
PRECISION
ENABLE
CC2
250mV
08901-065
TO ENABLE
ALL BLOCKS
Figure 66. Release COMP/EN Pin to Enable the ADP1882/ADP1883
COMP/EN
The current-sense blocks provide valley current information
(see the Programming Resistor (RES) Detect Circuit section)
and are a variable of the compensation equation for loop stability
(see the Compensation Network section). The valley current
information is extracted by forcing 0.4 V across the DRVL output
and the PGND pin, which generates a current depending on the
resistor across DRVL and PGND in a process performed by the
RES detect circuit. The current through the resistor is used to set
the current-sense amplifier gain. This process takes approximately
800 μs, after which the drive signal pulses appear at the DRVL
and DRVH pins synchronously and the output voltage begins to
rise in a controlled manner through the soft start sequence.
The rise time of the output voltage is determined by the soft
start and error amplifier blocks (see the Soft Start section).
At the beginning of a soft start, the error amplifier charges the
external compensation capacitor, causing the COMP/EN pin to
rise above the enable threshold of 285 mV, thus enabling the
ADP1882/ADP1883.
0.8V
>2.4V
2.4V
0.9V
HICCUP MODE INITIALIZED
MAXIMUM CURRENT (UPPER CLAMP)
ZERO CURRENT
USABLE RANGE ONLY AFTER SOFT START
PERIOD IF CONTUNUOUS CONDUCTION
MODE OF OPERATION IS SELECTED.
500mV
285mV
0V
LOWER CLAMP
PRECISION ENABLE THRESHOLD
35mV HYSTERESIS
08901-066
The ADP1882/ADP1883 are versatile current-mode, synchronous
step-down controllers that provide superior transient response,
optimal stability, and current limit protection by using a constant
on-time, pseudo-fixed frequency with a programmable currentsense gain, current-control scheme. In addition, these devices offer
optimum performance at low duty cycles by using valley currentmode control architecture. This allows the ADP1882/ADP1883
to drive all N-channel power stages to regulate output voltages
as low as 0.8 V.
Figure 67. COMP/EN Voltage Range
UNDERVOLTAGE LOCKOUT
The undervoltage lockout (UVLO) feature prevents the part
from operating both the upper-side and lower-side MOSFETs
at extremely low or undefined input voltage (VDD) ranges.
Operation at an undefined bias voltage may result in the
incorrect propagation of signals to the high-side power
switches. This, in turn, results in invalid output behavior that
can cause damage to the output devices, ultimately destroying
the device tied at the output. The UVLO level has been set at
2.65 V (nominal).
THERMAL SHUTDOWN
The thermal shutdown is a self-protection feature to prevent the
IC from damage due to a very high operating junction temperature.
If the junction temperature of the device exceeds 155°C, the part
enters the thermal shutdown state. In this state, the device shuts off
both the upper-side and lower-side MOSFETs and disables the
entire controller immediately, thus reducing the power consumption of the IC. The part resumes operation after the junction
temperature of the part cools to less than 140°C.
Rev. 0 | Page 19 of 40
ADP1882/ADP1883
PROGRAMMING RESISTOR (RES) DETECT CIRCUIT
VALLEY CURRENT-LIMIT SETTING
Upon startup, one of the first blocks to become active is the RES
detect circuit. This block powers up before a soft start begins. It
forces a 0.4 V reference value at the DRVL output (see Figure 68)
and is programmed to identify four possible resistor values:
47 kΩ, 22 kΩ, open, and 100 kΩ.
The architecture of the ADP1882/ADP1883 is based on valley
current-mode control. The current limit is determined by three
components: the RON of the lower-side MOSFET, the error amplifier output voltage swing (COMP), and the current-sense gain.
The COMP range is internally fixed at 1.5 V. The current-sense
gain is programmable via an external resistor at the DRVL pin
(see the Programming Resistor (RES) Detect Circuit section).
The RON of the lower-side MOSFET can vary over temperature
and usually has a positive TC (meaning that it increases with
temperature); therefore, it is recommended that the currentsense gain resistor be programmed based on the rated RON of
the MOSFET at 125°C.
ADP1882
Q1
DRVH
SW
Q2
RES
CS GAIN
PROGRAMMING
08901-067
DRVL
Because the ADP1882/ADP1883 are based on valley current
control, the relationship between ICLIM and ILOAD is as follows:
Figure 68. Programming Resistor Location
The RES detect circuit digitizes the value of the resistor at the
DRVL pin (Pin 6). An internal ADC outputs a 2-bit digital code
that is used to program four separate gain configurations in the
current-sense amplifier (see Figure 69). Each configuration
corresponds to a current-sense gain (ACS) of 3 V/V, 6 V/V, 12 V/V,
and 24 V/V, respectively (see Table 5 and Table 6). This variable
is used for the valley current-limit setting, which sets up the
appropriate current-sense signal gain for a given application
and sets the compensation necessary to achieve loop stability
(see the Valley Current-Limit Setting and Compensation
Network sections).
ICLIM = ILOAD × ⎛⎜1 − K I ⎞⎟
⎝
2 ⎠
where:
ICLIM is the desired valley current limit.
ILOAD is the current load.
KI is the ratio between the inductor ripple current and the
desired average load current (see Figure 10).
Establishing KI helps to determine the inductor value (see the
Inductor Selection section), but in most cases, KI = 0.33.
RIPPLE CURRENT =
SW
CS
AMP
ILOAD
3
LOAD CURRENT
CS GAIN SET
ADC
0.4V
VALLEY CURRENT LIMIT
08901-069
PGND
Figure 70. Valley Current Limit to Average Current Relation
RES
08901-068
DRVL
When the desired valley current limit (ICLIM) has been determined,
the current-sense gain can be calculated by using the following
expression:
ICLIM =
Figure 69. RES Detect Circuit for Current-Sense Gain Programming
Table 5. Current-Sense Gain Programming
Resistor (kΩ)
47
22
Open
100
ACS (V/V)
3.25
6.5
26
13
1.5 V
ACS × RON
where:
ACS is the current-sense gain multiplier (see Table 5 and Table 6).
RON is the channel impedance of the lower-side MOSFET.
Rev. 0 | Page 20 of 40
ADP1882/ADP1883
Although the ADP1882/ADP1883 have only four discrete currentsense gain settings for a given RON variable, Table 6 and Figure 71
outline several available options for the valley current setpoint
based on various RON values.
Table 6. Valley Current Limit Program1
RON
(mΩ)
1.5
2
2.5
3
3.5
4.5
5
5.5
10
15
18
Valley Current Level
22 kΩ
Open
100 kΩ
ACS = 3.4 V/V
ACS = 6.6 V/V
ACS = 26.7 V/V
ACS = 13.4 V/V
38.46
32.97
25.64
23.08
20.98
11.54
7.692
6.41
38.5
28.8
23.1
19.2
16.5
12.8
11.5
10.5
5.77
3.85
3.21
23.08
15.38
12.82
30.769
25.641
49A
MAXIMUM DC LOAD
CURRENT
39.5A
INDUCTOR
CURRENT
ΔI = 33%
OF 30A
ΔI = 65%
OF 37A
35A
37A
COMP
OUTPUT
ΔI = 45% 32.25A
OF 32.25A
30A
2.4V
VALLEY CURRENT-LIMIT
THRESHOLD (SET FOR 25A)
COMP
OUTPUT
SWING
39
37
35
33
31
29
27
25
23
21
19
17
15
13
11
9
7
5
3
0A
RES = 47kΩ
ACS = 6.6V/V
0.9V
08901-071
Refer to Figure 71 for more information and a graphical representation.
Figure 72. Valley Current-Limit Threshold in Relation to Inductor Ripple Current
HICCUP MODE DURING SHORT CIRCUIT
RES = 100kΩ
ACS = 13.4V/V
RES = 22kΩ
ACS = 3.4V/V
RES = OPEN
ACS = 26.7V/V
1
2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18
RON (mΩ)
08901-070
VALLEY CURRENT LIMIT (A)
Figure 71. Valley Current-Limit Value vs. RON of the Lower-Side MOSFET
for Each Programming Resistor (RES)
A current-limit violation occurs when the current across
the source and drain of the lower-side MOSFET exceeds the
current-limit setpoint. When 32 current-limit violations are
detected, the controller enters the idle mode and turns off the
MOSFETs for 6 ms, allowing the converter to cool down. Then,
the controller reestablishes soft start and begins to cause the
output to ramp up again (see Figure 73). While the output
ramps up, COMP is monitored to determine if the violation is
still present. If it is still present, the idle event occurs again,
followed by the full-chip power-down sequence. This cycle
continues until the violation no longer exists. If the violation
disappears, the converter is allowed to switch normally,
maintaining regulation.
REPEATED CURRENT-LIMIT
VIOLATION DETECTED
HS
CLIM
A PREDETERMINED NUMBER SOFT START IS
OF PULSES IS COUNTED TO REINITIALIZED TO
ALLOW THE CONVERTER MONITOR IF THE
TO COOL DOWN
VIOLATION
STILL EXISTS
08901-072
1
47 kΩ
The valley current limit is programmed as outlined in Table 6
and Figure 71. The inductor chosen must be rated to handle the
peak current, which is equal to the valley current from Table 6
plus the peak-to-peak inductor ripple current (see the Inductor
Selection section). In addition, the peak current value must be
used to compute the worst-case power dissipation in the
MOSFETs (see Figure 72).
ZERO
CURRENT
Figure 73. Idle Mode Entry Sequence Due to Current-Limit Violations
Rev. 0 | Page 21 of 40
ADP1882/ADP1883
SYNCHRONOUS RECTIFIER
The ADP1882/ADP1883 employ an internal lower-side MOSFET
driver to drive the external upper-side and lower-side MOSFETs.
The synchronous rectifier not only improves overall conduction
efficiency but also ensures proper charging to the bootstrap
capacitor located at the upper-side driver input. This is beneficial
during startup to provide a sufficient drive signal to the external
upper-side MOSFET and attain a fast turn on response, which is
essential for minimizing switching losses. The integrated upperside and lower-side MOSFET drivers operate in complementary
fashion with built-in anticross conduction circuitry to prevent
unwanted shoot-through current that may potentially damage the
MOSFETs or reduce efficiency as a result of excessive power loss.
As soon as the forward current through the lower-side
MOSFET decreases to a level where
10 mV = IQ2 × RON(Q2)
the zero-cross comparator (or IREV comparator) emits a signal to
turn off the lower-side MOSFET. From this point, the slope of the
inductor current ramping down becomes steeper (see Figure 76)
as the body diode of the lower-side MOSFET begins to conduct
current and continues conducting current until the remaining
energy stored in the inductor has been depleted.
ANOTHER tON EDGE IS
TRIGGERED WHEN VOUT
FALLS BELOW REGULATION
SW
tON
POWER SAVING MODE (PSM) VERSION (ADP1883)
HS AND LS
IN IDLE MODE
LS
ZERO-CROSS COMPARATOR
DETECTS 10mV OFFSET AND
TURNS OFF LS
ILOAD
0A
10mV = RON × ILOAD
HS
08901-075
The ADP1883 is the power saving mode version of the ADP1882.
The ADP1883 operates in the discontinuous conduction mode
(DCM) and pulse skips at light load to midload currents. It outputs
pulses, as necessary, to maintain output regulation. Unlike the
continuous conduction mode (CCM), DCM operation prevents
negative current, thus allowing improved system efficiency at
light loads. Current in the reverse direction through this pathway,
however, results in power dissipation and, therefore, a decrease
in efficiency.
Figure 76. 10 mV Offset to Ensure Prevention of Negative Inductor Current
tON
The system remains in idle mode until the output voltage drops
from within regulation. A PWM pulse is then produced, turning
on the upper-side MOSFET to maintain system regulation. The
ADP1883 does not have an internal clock; therefore, it switches
purely as a hysteretic controller as described in this section.
HS AND LS ARE OFF
OR IN IDLE MODE
LS
tOFF
TIMER OPERATION
AS THE INDUCTOR
CURRENT APPROACHES
ZERO CURRENT, THE STATE
MACHINE TURNS OFF THE
LOWER-SIDE MOSFET.
08901-073
ILOAD
0A
Figure 74. Discontinuous Mode of Operation (DCM)
To minimize the chance of negative inductor current buildup,
an on-board, zero-cross comparator turns off all upper-side and
lower-side switching activities when the inductor current
approaches the zero current line, causing the system to enter
idle mode, where the upper-side and lower-side MOSFETs are
turned off. To ensure idle mode entry, a 10 mV offset, connected
in series at the SW node, is implemented (see Figure 75).
ZERO-CROSS
COMPARATOR
The ADP1882/ADP1883 employ a constant on-time architecture
that provides a variety of benefits, including improved load and
line transient responses when compared with a constant (fixed)
frequency current-mode control loop of a comparable loop design.
The constant on-time timer, or tON timer, senses the high input
voltage (VIN) and the output voltage (VOUT) using SW waveform
information to produce an adjustable one-shot PWM pulse that
varies the on time of the upper-side MOSFET in response to
dynamic changes in input voltage, output voltage, and load current
conditions to maintain regulation. It then generates an on-time
(tON) pulse that is inversely proportional to VIN.
tON = K ×
where K is a constant that is trimmed using an RC timer product
for the 300 kHz, 600 kHz, and 1.0 MHz frequency options.
SW
IQ2
Q2
08901-074
10mV
LS
VOUT
VIN
Figure 75. Zero-Cross Comparator with 10 mV of Offset
Rev. 0 | Page 22 of 40
ADP1882/ADP1883
VREG
tON
VIN
To illustrate this feature more clearly, this section describes
one such load transient event—a positive load step—in detail.
During load transient events, the high-side driver output pulse
width stays relatively consistent from cycle to cycle; however,
the off time (DRVL on time) dynamically adjusts according to
the instantaneous changes in the external conditions mentioned.
C
I
R (TRIMMED)
08901-076
SW
INFORMATION
Figure 77. Constant On-Time Timer
The constant on time (tON) is not strictly constant because it
varies with VIN and VOUT. However, this variation occurs in such
a way as to keep the switching frequency virtually independent
of VIN and VOUT.
The tON timer uses a feedforward technique, applied to the constant
on-time control loop, making it pseudo-fixed frequency to a first
order. Second-order effects, such as dc losses in the external power
MOSFETs (see the Efficiency Consideration section), cause some
variation in frequency vs. load current and line voltage. These
effects are shown in Figure 23 to Figure 34. The variations in
frequency are much reduced, compared with the variations
generated when the feedforward technique is not used.
The feedforward technique establishes the following relationship:
fSW =
1
K
where fSW is the controller switching frequency (300 kHz,
600 kHz, and 1.0 MHz).
The tON timer senses VIN and VOUT to minimize frequency
variation with VIN and VOUT as previously explained. This
provides a pseudo fixed frequency that is explained in the
Pseudo-Fixed Frequency section. To allow headroom for VIN
and VOUT sensing, adhere to the following two equations:
VDD ≥ VIN/8 + 1.5
VDD ≥ VOUT/4
For typical applications where VDD = 5 V, these equations are
not relevant; however, for lower VDD inputs, care may be
required.
When a positive load step occurs, the error amplifier (out of
phase of the output, VOUT) produces new voltage information
at its output (COMP). In addition, the current-sense amplifier
senses new inductor current information during this positive
load transient event. The error amplifier’s output voltage
reaction is compared to the new inductor current information
that sets the start of the next switching cycle. Because current
information is produced from valley current sensing, it is
sensed at the down ramp of the inductor current, whereas the
voltage loop information is sensed through the counter action
upswing of the error amplifier’s output (COMP).
The result is a convergence of these two signals (see Figure 78),
which allows an instantaneous increase in switching frequency
during the positive load transient event. In summary, a positive
load step causes VOUT to transient down, which causes COMP to
transient up and, therefore, shortens the off time. This resultant
increase in frequency during a positive load transient helps to
quickly bring VOUT back up in value and within the regulation
window.
Similarly, a negative load step causes the off time to lengthen in
response to VOUT rising. This effectively increases the inductor
demagnetizing phase, helping to bring VOUT within regulation.
In this case, the switching frequency decreases, or experiences
a foldback, to help facilitate output voltage recovery.
Because the ADP1882/ADP1883 can respond rapidly to sudden
changes in load demand, the recovery period in which the output
voltage settles back to its original steady state operating point is
much quicker than it would be for a fixed-frequency equivalent.
Therefore, using a pseudo-fixed frequency results in significantly better load transient performance than using a fixed
frequency.
PSEUDO-FIXED FREQUENCY
Rev. 0 | Page 23 of 40
LOAD CURRENT
DEMAND
CS AMP
OUTPUT
ERROR AMP
OUTPUT
PWM OUTPUT
VALLEY
TRIP POINTS
fSW
>fSW
08901-077
The ADP1882/ADP1883 employ a constant on-time control
scheme. During steady state operation, the switching frequency
stays relatively constant, or pseudo-fixed. This is due to the oneshot tON timer, which produces a high-side PWM pulse with
a fixed duration, given that external conditions such as input
voltage, output voltage, and load current are also at steady state.
During load transients, the frequency momentarily changes for
the duration of the transient event so that the output comes back
within regulation more quickly than if the frequency were fixed
or if it were to remain unchanged. After the transient event is
complete, the frequency returns to a pseudo-fixed value to
a first-order.
Figure 78. Load Transient Response Operation
ADP1882/ADP1883
APPLICATIONS INFORMATION
FEEDBACK RESISTOR DIVIDER
Table 7. Recommended Inductors
The required resistor divider network can be determined for
a given VOUT value because the internal band gap reference (VREF)
is fixed at 0.8 V. Selecting values for RT and RB determines the
minimum output load current of the converter. Therefore, for
a given value of RB, the RT value can be determined using the
following expression:
L
(μH)
0.12
0.22
0.47
0.72
0.9
1.2
1.0
1.4
2.0
0.8
RT = RB ×
(VOUT − 0.8 V)
0 .8 V
INDUCTOR SELECTION
The inductor value is inversely proportional to the inductor
ripple current. The peak-to-peak ripple current is given by
ΔI L = K I × I LOAD
Dimensions
(mm)
10.2 × 7
10.2 × 7
14.2 × 12.8
10.5 × 10.2
13 × 12.8
10.5 × 10.2
10.5 × 10.2
14 × 12.8
13.2 × 12.8
Manufacturer
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Sumida
Model
Number
744303012
744303022
744355147
744325072
744355090
744325120
7443552100
744318180
7443551200
CEP125U-0R8
The output ripple voltage is the ac component of the dc output
voltage during steady state. For a ripple error of 1.0%, the output
capacitor value needed to achieve this tolerance can be determined using the following equation. Note that an accuracy of
1.0% is possible only during steady state conditions, not during
load transients.
The equation for the inductor value is given by
(V IN − VOUT ) VOUT
×
ΔI L × f SW
V IN
ΔVRR = (0.01) × VOUT
where:
VIN is the high voltage input.
VOUT is the desired output voltage.
fSW is the controller switching frequency (300 kHz, 600 kHz, and
1.0 MHz).
When selecting the inductor, choose an inductor saturation
rating that is above the peak current level, and then calculate
the inductor current ripple (see the Valley Current-Limit
Setting section and Figure 79).
52
50
48
46
44
42
40
38
36
34
32
30
28
26
24
22
20
18
16
14
12
10
8
ΔI = 50%
ΔI = 40%
OUTPUT CAPACITOR SELECTION
The primary objective of the output capacitor is to facilitate the
reduction of the output voltage ripple; however, the output
capacitor also assists in the output voltage recovery during load
transient events. For a given load current step, the output
voltage ripple generated during this step event is inversely
proportional to the value chosen for the output capacitor. The
speed at which the output voltage settles during this recovery
period depends on where the crossover frequency (loop
bandwidth) is set. This crossover frequency is determined by
the output capacitor, the equivalent series resistance (ESR) of
the capacitor, and the compensation network.
To calculate the small-signal voltage ripple (output ripple
voltage) at the steady state operating point, use the following
equation:
ΔI = 33%
⎛
⎞
1
⎟
COUT = ΔI L × ⎜⎜
⎟
[
]
8
F
V
(
I
ESR
)
×
×
Δ
−
Δ
×
RIPPLE
L
SW
⎝
⎠
where ESR is the equivalent series resistance of the output
capacitors.
6
8
10
12
14
16
18
20
22
VALLEY CURRENT LIMIT (A)
24
26
28
30
08901-078
PEAK INDUCTOR CURRENT (A)
ISAT
(A)
55
30
50
35
28
25
20
24
22
27.5
OUTPUT RIPPLE VOLTAGE (ΔVRR)
I
≈ LOAD
3
where KI is typically 0.33.
L=
DCR
(mΩ)
0.33
0.33
0.8
1.65
1.6
1.8
3.3
3.2
2.6
To calculate the output load step, use the following equation:
COUT = 2 ×
Figure 79. Peak Current vs. Valley Current Threshold for 33%, 40%, and 50%
of Inductor Ripple Current
f SW
ΔI LOAD
× (ΔVDROOP − (ΔI LOAD × ESR))
where ΔVDROOP is the amount that VOUT is allowed to deviate for
a given positive load current step (ΔILOAD).
Rev. 0 | Page 24 of 40
ADP1882/ADP1883
Ceramic capacitors are known to have low ESR. However, the
trade-off of using X5R technology is that up to 80% of its capacitance may be lost due to derating as the voltage applied across
the capacitor is increased (see Figure 80). Although X7R series
capacitors can also be used, the available selection is limited to
only up to 22 μF.
Error Amplifier Output Impedance (ZCOMP)
Assuming CC2 is significantly smaller than CCOMP, CC2 can be
omitted from the output impedance equation of the error
amplifier. The transfer function simplifies to
Z COMP =
R COMP ( f CROSS + f ZERO )
f CROSS
20
and
10
X7R (50V)
fCROSS =
–10
1
× f SW
12
–20
where fZERO, the zero frequency, is set to be 1/4 of the crossover
frequency for the ADP1882.
–30
–40
Error Amplifier Gain (GM)
–50
X5R (25V)
–60
The error amplifier gain (transconductance) is
–70
X5R (16V)
–80
GM = 500 μA/V
10µF TDK 25V, X7R, 1210 C3225X7R1E106M
22µF MURATA 25V, X7R, 1210 GRM32ER71E226KE15L
47µF MURATA 16V, X5R, 1210 GRM32ER61C476KE15L
–90
–100
0
5
10
15
20
25
DC VOLTAGE (VDC)
Current-Sense Loop Gain (GCS)
30
08901-079
CAPACITANCE CHARGE (%)
0
The current-sense loop gain is
G CS =
Figure 80. Capacitance vs. DC Voltage Characteristics for Ceramic Capacitors
Electrolytic capacitors satisfy the bulk capacitance requirements
for most high current applications. Because the ESR of electrolytic
capacitors is much higher than that of ceramic capacitors, when
using electrolytic capacitors, several MLCCs should be mounted
in parallel to reduce the overall series resistance.
1
(A/V)
ACS × RON
where:
ACS (V/V) is programmable for 3 V/V, 6 V/V, 12 V/V, and 24 V/V
(see the Programming Resistor (RES) Detect Circuit and Valley
Current-Limit Setting sections).
RON is the channel impedance of the lower-side MOSFET.
COMPENSATION NETWORK
Crossover Frequency
Due to its current-mode architecture, the ADP1882/ADP1883
require Type II compensation. To determine the component values
needed for compensation (resistance and capacitance values),
it is necessary to examine the overall loop gain (H) of the converter at the unity gain frequency (fSW/10) when H = 1 V/V,
as follows:
The crossover frequency is the frequency at which the overall
loop (system) gain is 0 dB (H = 1 V/V). For current-mode
converters such as the ADP1882, it is recommended that the
user set the crossover frequency between 1/10 and 1/15 of the
switching frequency.
H = 1 V/V = GM × ACS ×
fCROSS =
VOUT
× ZCOMP × ZFILT
VREF
Examining each variable at high frequency enables the unitygain transfer function to be simplified to provide expressions
for the RCOMP and CCOMP component values.
1
f SW
12
The relationship between CCOMP and fZERO (zero frequency) is as
follows:
f ZERO =
1
2 π × RCOMP × C COMP
)
Output Filter Impedance (ZFILT)
The zero frequency is set to 1/4 of the crossover frequency.
Examining the transfer function of the filter at high frequencies
simplifies to
Combining all of the above parameters results in
ZFILT =
RCOMP =
1
sC OUT
C COMP =
at the crossover frequency (s = 2πfCROSS).
Rev. 0 | Page 25 of 40
2πf CROSS C OUT VOUT
f CROSS
×
×
f CROSS + f ZERO
G M ACS
VREF
1
2 × π × RCOMP × f ZERO
ADP1882/ADP1883
EFFICIENCY CONSIDERATIONS
800
One of the important criteria to consider in constructing a dc-to-dc
converter is efficiency. By definition, efficiency is the ratio of the
output power to the input power. For high power applications at
load currents up to 20 A, the following are important MOSFET
parameters that aid in the selection process:
720
•
•
•
VGS (TH), the MOSFET support voltage applied between the
gate and the source
RDS (ON), the MOSFET on resistance during channel
conduction
QG, the total gate charge
CN1, the input capacitance of the upper-side switch
CN2, the input capacitance of the lower-side switch
The following are the losses experienced through the external
component during normal switching operation:
•
•
•
•
•
Channel conduction loss (both MOSFETs)
MOSFET driver loss
MOSFET switching loss
Body diode conduction loss (lower-side MOSFET)
Inductor loss (copper and core loss)
Channel Conduction Loss
During normal operation, the bulk of the loss in efficiency is
due to the power dissipated through MOSFET channel conduction. Power loss through the upper-side MOSFET is directly
proportional to the duty cycle (D) for each switching period,
and the power loss through the lower-side MOSFET is directly
proportional to 1 − D for each switching period. The selection
of MOSFETs is governed by the amount of maximum dc load
current that the converter is expected to deliver. In particular,
the selection of the lower-side MOSFET is dictated by the
maximum load current because a typical high current application
employs duty cycles of less than 50%. Therefore, the lower-side
MOSFET is in the on state for most of the switching period.
[
]
2
PN1,N2(CL) = D × R N1(ON) + (1 − D ) × R N2(ON) × I LOAD
480
400
320
240
+125°C
+25°C
–40°C
160
80
300
400
500
600
700
800
900
Figure 81. Internal Rectifier Voltage Drop vs. Switching Frequency
Switching Loss
The SW node transitions as a result of the switching activities
of the upper-side and lower-side MOSFETs. This causes removal
and replenishing of charge to and from the gate oxide layer of
the MOSFET, as well as to and from the parasitic capacitance that
is associated with the gate oxide edge overlap and the drain and
source terminals. The current that enters and exits these charge
paths presents additional loss during these transition times. This
loss can be approximately quantified by using the following equation, which represents the time in which charge enters and exits
these capacitive regions:
tSW-TRANS = RGATE × CTOTAL
where:
RGATE is the gate input resistance of the MOSFET.
CTOTAL is the CGD + CGS of the external MOSFET used.
The ratio of this time constant to the period of one switching cycle
is the multiplying factor to be used in the following expression:
PSW ( LOSS) =
t SW -TRANS
t SW
× I LOAD × V IN × 2
or
PSW(LOSS) = fSW × RGATE × CTOTAL × ILOAD × VIN × 2
Other dissipative elements are the MOSFET drivers. The contributing factors are the dc current flowing through the driver
during operation and the QGATE parameter of the external MOSFETs.
(
PDR ( LOSS ) = VDR × f SW C upperFET VDR + I BIAS
+ [VDD × ( f SW C lowerFET VDD + I BIAS )]
1000
SWITCHING FREQUENCY (kHz)
MOSFET Driver Loss
[
560
08901-080
•
640
RECTIFIER DROP (mV)
•
VDD = 2.7V
VDD = 3.6V
VDD = 5.5V
)]
where:
VDR is the driver bias voltage (that is, the low input voltage (VDD)
minus the rectifier drop (see Figure 81)).
CupperFET is the input gate capacitance of the upper-side MOSFET.
ClowerFET is the input gate capacitance of the lower-side MOSFET.
IBIAS is the dc current flowing into the upper and lower-side drivers.
VDD is the bias voltage.
Rev. 0 | Page 26 of 40
ADP1882/ADP1883
Diode Conduction Loss
The ADP1882/ADP1883 employ anticross conduction circuitry
that prevents the upper-side and lower-side MOSFETs from
conducting current simultaneously. This overlap control is
beneficial, avoiding large current flow that may lead to
irreparable damage to the external components of the power
stage. However, this blanking period comes with the trade-off of
a diode conduction loss occurring immediately after the
MOSFETs change states and continuing well into idle mode.
The amount of loss through the body diode of the lower-side
MOSFET during the antioverlap state is given by the following
expression:
PBODY ( LOSS) =
t BODY ( LOSS)
t SW
× I LOAD × VF × 2
where:
tBODY(LOSS) is the body conduction time (refer to Figure 82 for
dead time periods).
tSW is the period per switching cycle.
VF is the forward drop of the body diode during conduction
(refer to the selected external MOSFET data sheet for more
information about the VF parameter).
+125°C
+25°C
–40°C
1MHz
300kHz
72
PDCR(LOSS) = DCR × I2LOAD + Core Loss
INPUT CAPACITOR SELECTION
The goal in selecting an input capacitor is to reduce or minimize
input voltage ripple and to reduce the high frequency source
impedance, which is essential for achieving predictable loop
stability and transient performance.
The problem with using bulk capacitors, other than their
physical geometries, is their large equivalent series resistance
(ESR) and large equivalent series inductance (ESL). Aluminum
electrolytic capacitors have such high ESR that they cause
undesired input voltage ripple magnitudes and are generally not
effective at high switching frequencies.
If bulk capacitors are to be used, it is recommended that multilayered ceramic capacitors (MLCC) be used in parallel, due to
their low ESR values. This dramatically reduces the input voltage
ripple amplitude as long as the MLCCs are mounted directly across
the drain of the upper-side MOSFET and the source terminal of
the lower-side MOSFET (see the Layout Considerations section).
Improper placement and mounting of these MLCCs may cancel
their effectiveness due to stray inductance and an increase in
trace impedance.
64
I CIN , RMS = I LOAD, MAX ×
56
48
32
24
16
8
2.7
VOUT × (V IN − VOUT )
VOUT
The maximum input voltage ripple and maximum input capacitor
rms current occur at the end of the duration of 1 − D while the
upper-side MOSFET is in the off state. The input capacitor rms
current reaches its maximum at Time D. When calculating the
maximum input voltage ripple, account for the ESR of the input
capacitor as follows:
40
3.4
4.1
VDD (V)
4.8
5.5
08901-081
BODY DIODE CONDUCTION TIME (ns)
80
to achieve minimal loss and negligible electromagnetic
interference (EMI).
Figure 82. Body Diode Conduction Time vs. Low Voltage Input (VDD)
Inductor Loss
During normal conduction mode, further power loss is caused
by the conduction of current through the inductor windings,
which have dc resistance (DCR). Typically, larger sized inductors
have smaller DCR values.
The inductor core loss is a result of the eddy currents generated
within the core material. These eddy currents are induced by the
changing flux, which is produced by the current flowing through
the windings. The amount of inductor core loss depends on the
core material, the flux swing, the frequency, and the core volume.
Ferrite inductors have the lowest core losses, whereas powdered
iron inductors have higher core losses. It is recommended to use
shielded ferrite core material type inductors with the ADP1882/
ADP1883 for a high current, dc-to-dc switching application
VMAX,RIPPLE = VRIPP + (ILOAD,MAX × ESR)
where:
VRIPP is usually 1% of the minimum voltage input.
ILOAD,MAX is the maximum load current.
ESR is the equivalent series resistance rating of the input
capacitor used.
Inserting VMAX,RIPPLE into the charge balance equation to
calculate the minimum input capacitor requirement gives
C IN,min =
I LOAD, MAX
VMAX , RIPPLE
×
D(1 − D)
f SW
or
C IN,min =
I LOAD, MAX
4 f SW V MAX , RIPPLE
where D = 50%.
Rev. 0 | Page 27 of 40
ADP1882/ADP1883
THERMAL CONSIDERATIONS
The ADP1882/ADP1883 are used for dc-to-dc, step down, high
current applications that have an on-board controller and on-board
MOSFET drivers. Because applications may require up to 20 A
of load current delivery and be subjected to high ambient
temperature surroundings, the selection of external upper-side
and lower-side MOSFETs must be associated with careful thermal
consideration to not exceed the maximum allowable junction
temperature of 125°C. To avoid permanent or irreparable damage
if the junction temperature reaches or exceeds 155°C, the part
enters thermal shutdown, turning off both external MOSFETs,
and does not reenable until the junction temperature cools to
140°C (see the Thermal Shutdown section).
The maximum junction temperature allowed for the ADP1882/
ADP1883 ICs is 125°C. This means that the sum of the ambient
temperature (TA) and the rise in package temperature (TR), which
is caused by the thermal impedance of the package and the internal
power dissipation, should not exceed 125°C, as dictated by the
following expression:
TJ = TR × TA
For example, if the external MOSFET characteristics are θJA
(10-lead MSOP) = 171.2°C/W, fSW = 300 kHz, IBIAS = 2 mA,
CupperFET = 3.3 nF, ClowerFET = 3.3 nF, VDR = 5.12 V, and VDD = 5.5 V,
then the power loss is
PDR(LOSS) = [VDR × (fSWCupperFETVDR + IBIAS)]
+ [VDD × (fSWClowerFETVDD + IBIAS)]
= [5.12 × (300 × 103 × 3.3 × 10−9 × 5.12 + 0.002)]
+ [5.5 × (300 × 103 ×3.3 × 10−9 × 5.5 + 0.002)]
= 77.13 mW
The rise in package temperature is
TR = θJA × PDR(LOSS)
= 171.2°C × 77.13 mW
= 13.2°C
Assuming a maximum ambient temperature environment of 85°C,
the junction temperature is
TJ = TR × TA = 13.2°C + 85°C = 98.2°C
which is below the maximum junction temperature of 125°C.
DESIGN EXAMPLE
The ADP1882/ADP1883 are easy to use, requiring only a few
design criteria. For example, the example outlined in this section
uses only four design criteria: VOUT = 1.8 V, ILOAD = 15 A (pulsing),
VIN = 12 V (typical), and fSW = 300 kHz.
where:
TA is the ambient temperature.
TJ is the maximum junction temperature.
TR is the rise in package temperature due to the power
dissipated from within.
Input Capacitor
The rise in package temperature is directly proportional to its
thermal impedance characteristics. The following equation
represents this proportionality relationship:
The maximum input voltage ripple is usually 1% of the
minimum input voltage (11.8 V × 0.01 = 120 mV).
VRIPP = 120 mV
VMAX,RIPPLE = VRIPP − (ILOAD,MAX × ESR)
= 120 mV − (15 A × 0.001) = 45 mV
TR = θJA × PDR(LOSS)
where:
θJA is the thermal resistance of the package from the junction to
the outside surface of the die, where it meets the surrounding air.
PDR(LOSS) is the overall power dissipated by the IC.
The bulk of the power dissipated is due to the gate capacitance
of the external MOSFETs. The power loss equation of the MOSFET
drivers (see the MOSFET Driver Loss section in the Efficiency
Consideration section) is
C IN,min =
I LOAD, MAX
4 f SW V MAX , RIPPLE
=
15 A
4 × 300 × 10 3 × 105 mV
= 120 μF
Choose five 22 μF ceramic capacitors. The overall ESR of five
22 μF ceramic capacitors is less than 1 mΩ.
PDR(LOSS) = [VDR × (fSWCupperFETVDR + IBIAS)]
+ [VDD × (fSWClowerFETVDD + IBIAS)]
where:
CupperFET is the input gate capacitance of the upper-side MOSFET.
ClowerFET is the input gate capacitance of the lower-side MOSFET.
IBIAS is the dc current (2 mA) flowing into the upper-side and
lower-side drivers.
VDR is the driver bias voltage (that is, the low input voltage (VDD)
minus the rectifier drop (see Figure 81)).
VDD is the bias voltage
Rev. 0 | Page 28 of 40
IRMS = ILOAD/2 = 7.5 A
PCIN = (IRMS)2 × ESR = (7.5A)2 × 1 mΩ = 56.25 mW
ADP1882/ADP1883
Inductor
Assuming an overshoot of 45 mV, determine if the output
capacitor that was calculated previously is adequate.
Determine the inductor ripple current amplitude as follows:
ΔI L ≈
I LOAD
=5A
3
COUT =
=
then calculate for the inductor value
L=
=
(V IN , MAX − V OUT )
Δ I L × f SW
(13 . 2 V − 1 . 8 V )
5 V × 300 × 10 3
×
×
V OUT
V IN,MAX
((VOUT
1 × 10 − 6 × (15 A )2
(1.8 − 45 mV )2 − (1.8)2
= 1.4 mF
Choose five 270 μF polymer capacitors.
1 .8 V
The rms current through the output capacitor is
13 . 2 V
= 1.03 μH
I RMS =
The inductor peak current is approximately
=
15 A + (5 A × 0.5) = 17.5 A
Therefore, an appropriate inductor selection is 1.0 μH with
DCR = 3.3 mΩ (7443552100) from Table 8, with peak current
handling of 20 A.
1 1 (V IN , MAX − VOUT ) VOUT
×
×
2
L × f SW
V IN , MAX
3
1 1 (13.2 V − 1.8 V) 1.8 V
×
×
= 1.49 A
2
3 1 μF × 300 × 10 3 13.2 V
The power loss dissipated through the ESR of the output
capacitor is
PCOUT = (IRMS)2 × ESR = (1.5 A)2 × 1.4 mΩ = 3.15 mW
PDCR(LOSS) = DCR × I L2 = 0.003 × (15 A)2 = 675 mW
Feedback Resistor Network Setup
Current Limit Programming
It is recommended that RB = 15 kΩ be used. Calculate RT as
follows:
The valley current is approximately
15 A − (5 A × 0.5) = 12.5 A
Assuming a lower-side MOSFET RON of 4.5 mΩ, choosing 13 A
as the valley current limit from Table 7 and Figure 71 indicates
that a programming resistor (RES) of 100 kΩ corresponds to an
ACS of 24 V/V.
Choose a programmable resistor of RRES = 100 kΩ for a currentsense gain of 24 V/V.
Output Capacitor
Assume a load step of 15 A occurs at the output, and no more
than 5% is allowed for the output to deviate from the steady
state operating point. Because the frequency is pseudo-fixed,
the advantage of the ADP1882 is that the converter is able to
respond quickly because of the immediate, though temporary,
increase in switching frequency.
RT = 15 kΩ ×
(1.8 V − 0.6 V)
0. 6 V
= 30 kΩ
Compensation Network
To calculate RCOMP, CCOMP, and CPAR, the transconductance
parameter and the current-sense gain variable are required. The
transconductance parameter (GM) is 500 μA/V, and the currentsense loop gain is
GCS =
1
1
=
= 7.7 A/V
ACS RON 26 × 0.005
where ACS and RON are taken from setting up the current limit
(see the Programming Resistor (RES) Detect Circuit and Valley
Current-Limit Setting sections).
The crossover frequency is 1/12 of the switching frequency:
ΔVDROOP = 0.05 × 1.8 V = 90 mV
300 kHz/12 = 25 kHz
Assuming the overall ESR of the output capacitor ranges from
5 mΩ to 10 mΩ,
C OUT = 2 ×
(L × I 2 LOAD )
− ΔVOVSHT )2 − (VOUT )2 )
The zero frequency is 1/4 of the crossover frequency:
Δ I LOAD
25 kHz/4 = 6.25 kHz
RCOMP =
f SW × ( Δ V DROOP )
15 A
= 2×
300 × 10 3 × ( 90 mV )
f CROSS
f CROSS + f ZERO
×
2πf CROSSCOUT
G M ACS
×
VOUT
VREF
25 × 10
2 × 3.141 × 25 × 10 × 1.11 × 10 − 3
×
3
3
25 × 10 + 6.25 × 10
500 × 10 − 6 × 8.3
1.8
×
= 75 kΩ
0.8
3
=
= 1.11 mF
Therefore, an appropriate inductor selection is five 270 μF
polymer capacitors with a combined ESR of 3.5 mΩ.
C COMP =
=
1
2 × 3.14 × 75 ×10 3 × 6.25 ×10 3
= 340 pF
Rev. 0 | Page 29 of 40
1
2πRCOMP f ZERO
3
ADP1882/ADP1883
Loss Calculations
PSW(LOSS) = fSW × RGATE × CTOTAL × ILOAD × VIN × 2
= 300 × 103 × 1.5 Ω × 3.3 × 10 − 9 × 15 A × 12 × 2
= 534.6 mW
Duty cycle = 1.8/12 V = 0.15.
RON (N2) = 5.4 mΩ.
[
(
tBODY(LOSS) = 20 ns (body conduction time).
PDR ( LOSS ) = VDR × f SW C upperFET VDR + I BIAS
VF = 0.84 V (MOSFET forward voltage).
+
CIN = 3.3 nF (MOSFET gate input capacitance).
= (5.12 × (300 × 103 × 3.3 × 10−9 × 5.12 + 0.002))
+ (5.5 × (300 × 103 × 3.3 × 10−9 × 5.5 + 0.002))
= 77.13 mW
QN1,N2 = 17 nC (total MOSFET gate charge).
RGATE = 1.5 Ω (MOSFET gate input resistance).
[
t SW
×
(f
SW
CupperFETVDD +
I BIAS )]
2
PDCR(LOSS) = DCR × I LOAD
= 0.003 × (15 A)2 = 675 mW
= (0.15 × 0.0054 + 0.85 × 0.0054) × (15 A)2
= 1.215 W
t BODY ( LOSS )
DD
PCOUT = (IRMS)2 × ESR = (1.5 A)2 × 1.4 mΩ = 3.15 mW
]
2
PN1,N2(CL) = D × R N1(ON) + (1 − D ) × R N2(ON) × I LOAD
PBODY ( LOSS ) =
[V
)]
PCIN = (IRMS)2 × ESR = (7.5 A)2 × 1 mΩ = 56.25 mW
PLOSS = PN1,N2 + PBODY(LOSS) + PSW + PDCR + PDR + PCOUT + PCIN
= 1.215 W + 151.2 mW + 534.6 mW + 77.13 mW +
3.15 mW + 675 mW + 56.25 mW
= 2.62 W
× I LOAD × VF × 2
= 20 ns × 300 × 103 × 15 A × 0.84 × 2
= 151.2 mW
Rev. 0 | Page 30 of 40
ADP1882/ADP1883
EXTERNAL COMPONENT RECOMMENDATIONS
The configurations that are listed in Table 8 are with fCROSS = 1/12 × fSW, fZERO = ¼ × fCROSS, RRES = 100 kΩ, RBOT = 15 kΩ, RON = 5.4 mΩ
(BSC042N030MS G), VDD = 5 V, and a maximum load current of 14 A. The ADP1883 models that are listed in Table 8 are the PSM
versions of the device.
Table 8. External Component Values
Marking Code
SAP Model
ADP1882ARMZ-0.3-R7/
ADP1883ARMZ-0.3-R7
ADP1882ARMZ-0.6-R7/
ADP1883ARMZ-0.6-R7
ADP1882ARMZ-1.0-R7/
ADP1883ARMZ-1.0-R7
ADP1882
LGF
LGF
LGF
LGF
LGF
LGF
LGF
LGF
LGF
LGF
LGF
LGF
LGF
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGG
LGH
LGH
LGH
LGH
LGH
LGH
LGH
LGH
LGH
LGH
LGH
LGH
LGH
ADP1883
LGJ
LGJ
LGJ
LGJ
LGJ
LGJ
LGJ
LGJ
LGJ
LGJ
LGJ
LGJ
LGJ
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGK
LGL
LGL
LGL
LGL
LGL
LGL
LGL
LGL
LGL
LGL
LGL
LGL
LGL
VOUT
(V)
0.8
1.2
1.8
2.5
3.3
5
7
1.2
1.8
2.5
3.3
5
7
0.8
1.2
1.8
2.5
1.2
1.8
2.5
3.3
5
1.2
1.8
2.5
3.3
5
7
0.8
1.2
1.8
2.5
1.2
1.8
2.5
3.3
5
1.2
1.8
2.5
3.3
VIN
(V)
13
13
13
13
13
13
13
16.5
16.5
16.5
16.5
16.5
16.5
5.5
5.5
5.5
5.5
13
13
13
13
13
16.5
16.5
16.5
16.5
16.5
16.5
5.5
5.5
5.5
5.5
13
13
13
13
13
16.5
16.5
16.5
16.5
CIN
(μF)
5 × 225
5 × 225
5 × 225
5 × 225
5 × 225
4 × 225
4 × 225
5 × 225
4 × 225
4 × 225
4 × 225
3 × 225
3 × 225
5 × 225
5 × 225
5 × 225
5 × 225
5× 225
5 × 109
5 × 109
5 × 109
5 × 109
3 × 109
4 × 109
4 × 109
4 × 109
4 × 109
4 × 109
5 × 225
5 × 225
3 × 225
3 × 225
4 × 109
4 × 109
4 × 109
5 × 109
4 × 109
4 × 109
4 × 109
4 × 109
4 × 109
Rev. 0 | Page 31 of 40
COUT
(μF)
5 × 5602
4 × 5602
5 × 2703
3 × 2703
3 × 3304
3304
225+ (4 × 476)
4 × 5602
4 × 2703
4 × 2703
3 × 3304
2 × 1507
225+ 4 × 476
4 × 5602
4 × 2703
3 × 2703
3 × 1808
5 × 2703
3 × 3304
3 × 2703
2 × 2703
1507
4 × 2703
2 × 3304
3 × 2703
3304
4 × 476
3 × 476
4 × 2703
2 × 3304
3 × 1808
2703
3 × 3304
3 × 2703
2 x 2703
2703
3 × 476
4 × 2703
3 × 2703
3 × 1808
2703
L1
(μH)
0.47
1.0
1.2
1.53
2.0
3.27
3.44
1.0
1.0
1.67
2.00
3.84
4.44
0.22
0.47
0.47
0.47
0.47
0.72
0.90
1.00
1.76
0.47
0.72
0.90
1.0
2.0
2.0
0.22
0.22
0.22
0.22
0.22
0.47
0.47
0.72
1.0
0.47
0.47
0.72
0.72
RC
(kΩ)
38.3
38.3
38.3
38.3
38.3
27.4
27.4
38.3
38.3
38.3
38.3
27.4
27.4
38.3
38.3
38.3
38.3
38.3
38.3
38.3
38.3
27.4
38.3
38.3
38.3
38.3
27.4
27.4
38.3
38.3
38.3
38.3
38.3
38.3
38.3
38.3
27.4
38.3
38.3
38.3
38.3
CCOMP
(pF)
911
911
703
703
703
985
985
911
729
729
729
1020
1020
418
401
334
334
501
378
378
378
529
445
401
401
364
510
468
275
275
200
200
286
259
259
259
330
401
321
286
267
CPAR
(pF)
91
91
70
70
70
98
98
91
73
73
73
102
102
42
40
33
33
50
38
38
38
53
45
40
40
36
51
47
27
27
20
20
29
26
26
26
33
40
32
29
27
RTOP
(kΩ)
0.0
7.5
18.75
31.9
46.9
78.8
116.3
7.5
18.8
31.9
46.9
78.8
116.3
0.0
7.5
18.8
31.9
7.5
18.8
31.9
46.9
78.8
7.5
18.8
31.9
46.9
78.8
116.3
0.0
7.5
18.8
31.9
7.5
18.8
31.9
46.9
78.8
7.5
18.8
31.9
46.9
ADP1882/ADP1883
Marking Code
SAP Model
ADP1882
LGH
LGH
ADP1883
LGL
LGL
VOUT
(V)
5
7
VIN
(V)
16.5
16.5
CIN
(μF)
3 × 109
3 × 109
COUT
(μF)
3 × 476
225 + 476
L1
(μH)
1.4
1.4
RC
(kΩ)
27.4
27.4
CCOMP
(pF)
330
281
CPAR
(pF)
33
28
RTOP
(kΩ)
78.8
116.3
1
See the Inductor Selection section (see Table 9).
560 μF Panasonic (SP-series) 2 V, 7 mΩ, 3.7 A EEFUE0D561LR (4.3 mm × 7.3 mm × 4.2 mm).
3
270 μF Panasonic (SP-series) 4 V, 7 mΩ, 3.7 A EEFUE0G271LR (4.3 mm × 7.3 mm × 4.2 mm).
4
330 μF Panasonic (SP-series) 4 V, 12 mΩ, 3.3 A EEFUE0G331R (4.3 mm × 7.3 mm × 4.2 mm).
5
22 μF Murata 25 V, X7R, 1210 GRM32ER71E226KE15L (3.2 mm × 2.5 mm × 2.5 mm).
6
47 μF Murata 16 V, X5R, 1210 GRM32ER61C476KE15L (3.2 mm × 2.5 mm × 2.5 mm).
7
150 μF Panasonic (SP-series) 6.3 V, 10 mΩ, 3.5 A EEFUE0J151XR (4.3 mm × 7.3 mm × 4.2 mm).
8
180 μF Panasonic (SP-series) 4 V, 10 mΩ, 3.5 A EEFUE0G181XR (4.3 mm × 7.3 mm × 4.2 mm).
9
10 μF TDK 25 V, X7R, 1210 C3225X7R1E106M.
2
Table 9. Recommended Inductors
L (μH)
0.12
0.22
0.47
0.72
0.9
1.2
1.0
1.4
2.0
0.8
DCR (mΩ)
0.33
0.33
0.8
1.65
1.6
1.8
3.3
3.2
2.6
ISAT (A)
55
30
50
35
28
25
20
24
22
27.5
Dimension (mm)
10.2 × 7
10.2 × 7
14.2 × 12.8
10.5 × 10.2
13 × 12.8
10.5 × 10.2
10.5 × 10.2
14 × 12.8
13.2 × 12.8
Manufacturer
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Wurth Electronics
Sumida
Model Number
744303012
744303022
744355147
744325072
744355090
744325120
7443552100
744318180
7443551200
CEP125U-0R8
Manufacturer
Infineon
Infineon
Vishay
International Rectifier
Infineon
Infineon
Vishay
Model Number
BSC042N03MS G
BSC080N03MS G
Si4842DY
IRF7811
BSC042N030MS G
BSC080N030MS G
Si4842DY
Table 10. Recommended MOSFETs
VGS = 4.5 V
Upper-Side MOSFET (Q1/Q2)
Lower-Side MOSFET (Q3/Q4)
RON
(mΩ)
5.4
10.2
6.0
9
5.4
10.2
6.0
ID
(A)
47
53
19
14
47
82
19
VDS
(V)
30
30
30
30
30
30
30
CIN
(nF)
3.2
1.6
2.4
3.2
1.6
QTOTAL
(nC)
20
10
35
25
20
10
35
Rev. 0 | Page 32 of 40
Package
PG-TDSON8
PG-TDSON8
SO-8
SO-8
PG-TDSON8
PG-TDSON8
SO-8
ADP1882/ADP1883
LAYOUT CONSIDERATIONS
Figure 83 shows the schematic of a typical ADP1882/ADP1883
used for a high power application. Blue traces denote high current
pathways. VIN, PGND, and VOUT traces should be wide and
possibly replicated, descending down into the multiple layers.
Vias should populate, mainly around the positive and negative
terminals of the input and output capacitors, alongside the
source of Q1/Q2, the drain of Q3/Q4, and the inductor.
The performance of a dc-to-dc converter depends highly on how
the voltage and current paths are configured on the printed
circuit board (PCB). Optimizing the placement of sensitive
analog and power components are essential to minimize output
ripple, maintain tight regulation specifications, and reduce
PWM jitter and electromagnetic interference.
HIGH VOLTAGE INPUT
VIN = 12V
HIGH VOLTAGE INPUT
VDD = 5V
JP1
R1 18.75kΩ
VOUT
R2
15kΩ
C2
0.1µF
C1
1µF
ADP1882/
ADP1883
1
VIN
2
COMP/EN
BST 10
3
FB
DRVH 8
4
GND
PGND 7
5
VDD
DRVL 6
C12
100nF
C3
22µF
Q1
C4
22µF
C5
22µF
C6
22µF
1.0µH
Q3
C8
N/A
Q2
SW 9
R4
0Ω
C7
22µF
Q4
R6
2Ω
C13
1.5nF
VOUT = 1.8V, 15A
C20
270µF
+
C21
270µF
+
C22
270µF
+
C23
270µF
+
C24
270µF
+
+ C14 TO C19
N/A
R5
100kΩ
MURATA: (HIGH VOLTAGE INPUT CAPACITORS)
22µF, 25V, X7R, 1210 GRM32ER71E226KE15 L
PANASONIC: (OUTPUT CAPACITORS)
270µF SP-SERIES, 4V, 7mΩ EEFUE0G271LR
INFINEON MOSFETs (NO CONNECTION FOR Q2/Q4:
BSC042N03MS G (LOWER SIDE)
BSC080N03MS G (UPPER SIDE)
WURTH INDUCTORS:
1µH, 3.3mΩ, 20A 7443552100
Figure 83. ADP1882 High Current Evaluation Board Schematic (Blue Traces Indicate High Current Paths)
Rev. 0 | Page 33 of 40
08901-082
CF
70pF
CC
700pF
RC
38.1kΩ
ADP1882/ADP1883
SENSITIVE ANALOG
COMPONENTS
LOCATED FAR
FROM THE NOISY
POWER SECTION.
SEPARATE ANALOG GROUND
PLANE FOR THE ANALOG
COMPONENTS (THAT IS,
COMPENSATION AND
FEEDBACK RESISTORS).
OUTPUT CAPACITORS
ARE MOUNTED ON THE
RIGHTMOST AREA OF
THE EVB, WRAPPING
BACK AROUND TO THE
MAIN POWER GROUND
PLANE, WHERE IT MEETS
WITH THE NEGATIVE
TERMINALS OF THE
INPUT CAPACITORS.
BYPASS POWER CAPACITOR (C1)
FOR VDD BIAS DECOUPLING AND
HIGH FREQUENCY CAPACITOR
(C2) AS CLOSE AS POSSIBLE TO
THE IC.
08901-083
INPUT CAPACITORS
ARE MOUNTED CLOSE
TO DRAIN OF Q1/Q2
AND SOURCE OF Q3/Q4.
08901-084
Figure 84. Overall Layout of the ADP1882 High Current Evaluation Board
Figure 85. Layer 2 of Evaluation Board
Rev. 0 | Page 34 of 40
ADP1882/ADP1883
BOTTOM RESISTOR
TAP TO THE ANALOG
GROUND PLANE.
08901-085
VOUT SENSE TAP LINE
EXTENDING BACK TO THE TOP
RESISTOR IN THE FEEDBACK
DIVIDER NETWORK (SEE FIGURE 82).
THIS OVERLAPS WITH PGND SENSE
TAP LINE EXTENDING BACK TO THE
ANALOG PLANE (SEE FIGURE 86,
LAYER 4 FOR PGND TAP).
Figure 86. Layer 3 of Evaluation Board
BOTTOM RESISTOR
TAP TO THE ANALOG
GROUND PLANE.
08901-086
PGND SENSE TAP FROM
NEGATIVE TERMINALS OF
OUTPUT BULK CAPACITORS.
THIS TRACK PLACEMENT SHOULD
BE DIRECTLY BELOW THE VOUT
SENSE LINE FROM FIGURE 84.
Figure 87. Layer 4 (Bottom Layer) of Evaluation Board
Rev. 0 | Page 35 of 40
ADP1882/ADP1883
IC SECTION (LEFT SIDE OF EVALUATION BOARD)
A dedicated plane for the analog ground plane (GND) should
be separate from the main power ground plane (PGND). With
the shortest path possible, connect the analog ground plane to
the GND pin (Pin 4). This plane should be on only the top layer
of the evaluation board. To avoid crosstalk interference, there
should not be any other voltage or current pathway directly
below this plane on Layer 2, Layer 3, or Layer 4. Connect the
negative terminals of all sensitive analog components to the
analog ground plane. Examples of such sensitive analog components include the bottom resistor of the resistor divider, the
high frequency bypass capacitor for biasing (0.1 μF), and the
compensation network.
Mount a 1 μF bypass capacitor directly across VDD (Pin 5) and
PGND (Pin 7). In addition, a 0.1 μF should be tied across VDD
(Pin 5) and GND (Pin 4).
POWER SECTION
As shown in Figure 84, an appropriate configuration to localize
large current transfer from the high voltage input (VIN) to the output (VOUT), and then back to the power ground, puts the VIN
plane on the left, the output plane on the right, and the main power
ground plane in between the two. Current transfers from the
input capacitors to the output capacitors, through Q1/Q2, during
the on state (see Figure 88). The direction of this current (yellow
arrow) is maintained as Q1/Q2 turns off and Q3/Q4 turns on.
When Q3/Q4 turns on, the current direction continues to be
maintained (red arrow) as it circles from the power ground
terminal of the bulk capacitor to the output capacitors, through
the Q3/Q4. Arranging the power planes in this manner minimizes
the area in which changes in flux occur if the current through
Q1/Q2 stops abruptly. Sudden changes in flux, usually at the
source terminals of Q1/Q2 and the drain terminals of Q3/Q4,
cause large dV/dt’s at the SW node.
The SW node is near the top of the evaluation board. The SW
node should use the least amount of area possible and be kept
away from any sensitive analog circuitry and components because
this is where most sudden changes in flux density occur. When
possible, replicate this pad onto Layer 2 and Layer 3 for thermal
relief and eliminate any other voltage and current pathways directly
beneath the SW node plane. Populate the SW node plane with
vias, mainly around the exposed pad of the inductor terminal and
around the perimeter of the source of Q1/Q2 and the drain of
Q3/Q4. The output voltage power plane (VOUT) is at the rightmost end of the evaluation board. This plane should be replicated,
descending down to multiple layers with vias surrounding the
inductor terminal and the positive terminals of the output bulk
capacitors. Ensure that the negative terminals of the output
capacitors are placed close to the main power ground (PGND),
as previously mentioned. All of these points form a tight circle
(component geometry permitting) that minimizes the area of
flux change as the event switches between D and 1 − D.
DIFFERENTIAL SENSING
Because the ADP1882/ADP1883 operate in valley currentmode control, a differential voltage reading is taken across the
drain and source of the lower-side MOSFET. The drain of the
lower-side MOSFET should be connected as close as possible to
Pin 9 (SW) of the IC. Likewise, connect the source as close as
possible to Pin 7 (PGND) of the IC. When possible, both of
these track lines should be narrow and away from any other
active device or voltage/current paths.
SW
PGND
LAYER 1: SENSE LINE FOR SW
(DRAIN OF LOWER MOSFET)
VOUT
LAYER 1: SENSE LINE FOR PGND
(SOURCE OF LOWER MOSFET)
08901-088
SW
VIN
PGND
08901-087
Figure 89. Drain/Source Tracking Tapping of the Lower-Side MOSFET for
CS Amp Differential Sensing (Yellow Sense Line on Layer 2)
Figure 88. Primary Current Pathways During the On State of the Upper-Side
MOSFET (Left Arrow) and the On State of the Lower-Side MOSFET (Right Arrow)
Differential sensing should also be applied between the outermost
output capacitor to the feedback resistor divider (see Figure 86
and Figure 87). Connect the positive terminal of the output
capacitor to the top resistor (RT). Connect the negative terminal
of the output capacitor to the negative terminal of the bottom
resistor, which connects to the analog ground plane, as well.
Both of these track lines, as previously mentioned, should be
narrow and away from any other active device or voltage/
current paths.
Rev. 0 | Page 36 of 40
ADP1882/ADP1883
TYPICAL APPLICATIONS CIRCUITS
DUAL-INPUT, 300 kHz HIGH CURRENT APPLICATIONS CIRCUIT
HIGH VOLTAGE INPUT
VIN = 12V
HIGH VOLTAGE INPUT
VDD = 5V
JP1
CF
70pF
CC
700pF
RC
38.1kΩ
R1 18.75kΩ
VOUT
R2
15kΩ
C2
0.1µF
ADP1882/
ADP1883
1
VIN
2
COMP/EN
3
FB
BST 10
C3
22µF
C12
100nF
Q1
C4
22µF
GND
PGND 7
5
VDD
DRVL 6
C1
1µF
C6
22µF
1.0µH
R4
0Ω
Q3
C7
22µF
C8
N/A
Q2
SW 9
DRVH 8
4
C5
22µF
R6
2Ω
C13
1.5nF
Q4
VOUT = 1.8V, 15A
C20
270µF
+
C21
270µF
+
C22
270µF
+
C23
270µF
+
C24
270µF
+
+
C24
N/A
+
+ C14 TO C19
N/A
R5
100kΩ
08901-089
MURATA: (HIGH VOLTAGE INPUT CAPACITORS)
22µF, 25V, X7R, 1210 GRM32ER71E226KE15 L
PANASONIC: (OUTPUT CAPACITORS)
270µF SP-SERIES, 4V, 7mΩ EEFUE0G271LR
INFINEON MOSFETs (NO CONNECTION FOR Q2/Q4:
BSC042N03MS G (LOWER SIDE)
BSC080N03MS G (UPPER SIDE)
WURTH INDUCTORS:
1µH, 3.3mΩ, 20A 7443552100
Figure 90. Applications Circuit for 12 V Input, 1.8 V Output, 15 A, 300 kHz (Q2/Q4 No Connect)
SINGLE-INPUT, 600 kHz APPLICATIONS CIRCUIT
HIGH VOLTAGE INPUT
VIN = 5.5V
JP1
VOUT
ADP1882/
ADP1883
1
VIN
2
COMP/EN
3
FB
DRVH 8
4
GND
PGND 7
5
VDD
DRVL 6
R1 31.6kΩ
C2
0.1µF
R2
15kΩ
C1
1µF
BST 10
C12
100nF
C3
22µF
Q1
C4
22µF
C5
22µF
C6
22µF
0.47µH
Q3
C8
N/A
Q2
SW 9
R4
0Ω
C7
22µF
Q4
R6
2Ω
C13
1.5nF
VOUT = 1.8V, 15A
C20
180µF
+
C21
180µF
+
C22
180µF
+
C23
N/A
+ C14 TO C19
N/A
R5
OPEN
MURATA: (HIGH VOLTAGE INPUT CAPACITORS)
22µF, 25V, X7R, 1210 GRM32ER71E226KE15 L
PANASONIC: (OUTPUT CAPACITORS)
180µF SP-SERIES, 4V, 10mΩ EEFUE0G181XR
INFINEON MOSFETs (NO CONNECTION FOR Q2/Q4:
BSC042N03MS G (LOWER SIDE)
BSC080N03MS G (UPPER SIDE)
WURTH INDUCTORS:
0.47µH, 0.8mΩ, 50A 744355147
Figure 91. Applications Circuit for 5.5 V Input, 2.5 V Output, 15 A, 600 kHz (Q2/Q4 No Connect)
Rev. 0 | Page 37 of 40
08901-090
CF
34pF
CC
33.4pF
RC
38.3kΩ
ADP1882/ADP1883
DUAL-INPUT, 300 kHz HIGH CURRENT APPLICATIONS CIRCUIT
HIGH VOLTAGE INPUT
VIN = 13V
HIGH VOLTAGE INPUT
VDD = 5V
JP1
CF
70pF
VOUT
ADP1882/
ADP1883
1
VIN
2
COMP/EN
3
FB
DRVH 8
4
GND
PGND 7
5
VDD
DRVL 6
R1 7.5kΩ
C2
0.1µF
R2
15kΩ
C1
1µF
BST 10
C12
100nF
C3
22µF
Q1
C4
22µF
C5
22µF
C6
22µF
C8
22µF
Q2
SW 9
0.8µH
Q3
C7
22µF
Q4
R6
2Ω
C13
1.5nF
VOUT = 1.8V, 20A
C20
270µF
+
C21
270µF
+
C22
270µF
+
C23
270µF
+
C24
270µF
+
+ C14 TO C19
N/A
R5
100kΩ
MURATA: (HIGH VOLTAGE INPUT CAPACITORS)
22µF, 25V, X7R, 1210 GRM32ER71E226KE15 L
PANASONIC: (OUTPUT CAPACITORS)
270µF SP-SERIES, 4V, 7mΩ EEFUE0G271LR
INFINEON MOSFETs (NO CONNECTION FOR Q2/Q4:
BSC042N03MS G (LOWER SIDE)
BSC080N03MS G (UPPER SIDE)
WURTH INDUCTORS:
0.8µH, 27.5mΩ, SUMIDA CEP125U-0R8
Figure 92. Applications Circuit for 13 V Input, 1.8 V Output, 20 A, 300 kHz (Q2/Q4 No Connect)
Rev. 0 | Page 38 of 40
08901-091
CC
1000pF
RC
24.9kΩ
ADP1882/ADP1883
OUTLINE DIMENSIONS
3.10
3.00
2.90
10
3.10
3.00
2.90
5.15
4.90
4.65
6
1
5
PIN 1
IDENTIFIER
0.50 BSC
0.95
0.85
0.75
15° MAX
1.10 MAX
0.30
0.15
6°
0°
0.23
0.13
COMPLIANT TO JEDEC STANDARDS MO-187-BA
0.70
0.55
0.40
091709-A
0.15
0.05
COPLANARITY
0.10
Figure 93. 10-Lead Mini Small Outline Package [MSOP]
(RM-10)
Dimensions shown in millimeters
ORDERING GUIDE
Model 1
ADP1882ARMZ-0.3-R7
ADP1882ARMZ-0.6-R7
ADP1882ARMZ-1.0-R7
ADP1882ARMZ-0.3-EVALZ
ADP1882ARMZ-0.6-EVALZ
ADP1882ARMZ-1.0-EVALZ
ADP1883ARMZ-0.3-R7
ADP1883ARMZ-0.6-R7
ADP1883ARMZ-1.0-R7
ADP1883ARMZ-0.3-EVALZ
ADP1883ARMZ-0.6-EVALZ
ADP1883ARMZ-1.0-EVALZ
1
Temperature Range
−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
Package Description
10-Lead Mini Small Outline Package [MSOP]
10-Lead Mini Small Outline Package [MSOP]
10-Lead Mini Small Outline Package [MSOP]
Forced PWM, 300 kHz Evaluation Board
Forced PWM, 600 kHz Evaluation Board
Forced PWM, 1.0 MHz Evaluation Board
10-Lead Mini Small Outline Package [MSOP]
10-Lead Mini Small Outline Package [MSOP]
10-Lead Mini Small Outline Package [MSOP]
Power Saving Mode, 300 kHz Evaluation Board
Power Saving Mode, 600 kHz Evaluation Board
Power Saving Mode, 1.0 MHz Evaluation Board
Z = RoHS Compliant Part.
Rev. 0 | Page 39 of 40
Package
Option
RM-10
RM-10
RM-10
Branding
LGF
LGG
LGH
RM-10
RM-10
RM-10
LGJ
LGK
LGL
ADP1882/ADP1883
NOTES
©2010 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D08901-0-4/10(0)
Rev. 0 | Page 40 of 40