AD ADP1850

Wide Range Input, Dual/Two-Phase, DC-to-DC
Synchronous Buck Controller
ADP1850
Wide range input: 2.75 V to 20 V
Power stage input voltage: 1 V to 20 V
Output voltage range: 0.6 V up to 90% VIN
Output current to more than 25 A per channel
Accurate current sharing between channels (interleaved)
Programmable frequency: 200 kHz to 1.5 MHz
180° phase shift between channels for reduced input
capacitance
±0.85% reference voltage accuracy from −40°C to +85°C
Integrated boost diodes
Power saving mode (PSM) at light loads
Accurate power good with internal pull-up resistor
Accurate voltage tracking capability
Independent channel precision enable
Overvoltage and overcurrent limit protection
Externally programmable soft start, slope compensation and
current sense gain
Synchronization input
Thermal overload protection
Input undervoltage lockout (UVLO)
Available in 32-lead 5 mm × 5 mm LFCSP
APPLICATIONS
The ADP1850 provides high speed, high peak current drive
capability with dead-time optimization to enable energy
efficient power conversion. For low load operation, the device
can be configured to operate in power saving mode (PSM) by
skipping pulses and reducing switching losses to improve the
energy efficiency at light load and standby conditions.
The accurate current limit (±6%) allows the power architect to
design within a narrower range of tolerances and can reduce
overall converter size and cost.
The ADP1850 provides a configurable architecture capable
of wide range input operation to provide the designer with
maximum re-use opportunities and improved time to market.
Additional flexibility is provided by external programmability
of loop compensation, soft start, frequency setting, power
saving mode, current limit and current sense gain can all be
programmed using external components.
The ADP1850 includes a high level of integration in a small size
package. The start-up linear regulator and the boot-strap diode
for the high side drive are included. Protection features include:
undervoltage lock-out, overvoltage, overcurrent/short-circuit
and over temperature. The ADP1850 is available in a compact
32-lead LFCSP 5 mm × 5 mm thermally enhanced package.
TYPICAL OPERATION CIRCUIT
High current single and dual output intermediate bus and
point of load converters requiring sequencing and
tracking capability, including converters for:
Point-of-load power supplies
Telecom base station and networking
Consumer
Industrial and instrumentation
Healthcare and medical
RAMP1
EN1
EN2
VDL
VCCO
TRK1
TRK2
HI
LO
M1
DH1
BST1
L1
SW1
ILIM1
FB1
R11
VOUT1
M2
DL1
R12
RCSG1
PGOOD1
PGOOD2
SYNC
PGND1
FREQ
RAMP2
RRAMP2
VIN
M3
COMP1
DH2
BST2
L2
SW2
ILIM2
FB2
R21
VOUT2
COMP2
The architecture enables accurate current sharing between
interleaved phases for high current outputs.
The ADP1850 is ideal in system applications requiring multiple
output voltages: the ADP1850 includes a synchronization feature to eliminate beat frequencies between switching devices;
provides accurate tracking capability between supplies and
includes precision enable for simple, robust sequencing.
VIN
ADP1850
GENERAL DESCRIPTION
The ADP1850 is a configurable dual output or two-phase, single
output dc-to-dc synchronous buck controller capable of running
from commonly used 3.3 V to 12 V (up to 20 V) voltage inputs.
The device operates in current mode for improved transient
response and uses valley current sensing for enhanced noise
immunity.
VIN
RRAMP1
SS1
SS2
AGND
M4
DL2
R22
RCSG2
PGND2
09440-001
FEATURES
Figure 1. Single Phase Circuit
Rev. 0
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2010 Analog Devices, Inc. All rights reserved.
ADP1850
TABLE OF CONTENTS
Features .............................................................................................. 1
Accurate Current Limit Sensing ............................................... 17
Applications ....................................................................................... 1
Setting the Slope Compensation .............................................. 17
General Description ......................................................................... 1
Setting the Current Sense Gain ................................................ 17
Typical Operation Circuit................................................................ 1
Input Capacitor Selection .......................................................... 18
Revision History ............................................................................... 2
Input Filter................................................................................... 18
Specifications..................................................................................... 3
Boost Capacitor Selection ......................................................... 18
Absolute Maximum Ratings ............................................................ 5
Inductor Selection ...................................................................... 18
ESD Caution .................................................................................. 5
Output Capacitor Selection....................................................... 19
Simplified Block Diagram ............................................................... 6
MOSFET Selection ..................................................................... 19
Pin Configuration and Function Descriptions ............................. 7
Loop Compensation (Single Phase Operation) ..................... 21
Typical Performance Characteristics ............................................. 9
Theory of Operation ...................................................................... 12
Configuration and Loop Compensation (Dual-Phase
Operation) ................................................................................... 22
Control Architecture .................................................................. 12
Switching Noise and Overshoot Reduction ............................ 22
Oscillator Frequency .................................................................. 12
Voltage Tracking ......................................................................... 23
Modes of Operation ................................................................... 13
Indepdendent Power Stage Input Voltage ............................... 24
Synchronization .......................................................................... 13
PCB Layout Guidelines .................................................................. 25
Synchronous Rectifier and Dead Time ................................... 14
MOSFETs, Input Bulk Capacitor, and Bypass Capacitor ...... 25
Input Undervoltage Lockout ..................................................... 14
High Current and Current Sense Paths ................................... 25
Internal Linear Regulator .......................................................... 14
Signal Paths ................................................................................. 25
Overvoltage Protection .............................................................. 14
PGND Plane ................................................................................ 25
Power Good ................................................................................. 14
Feedback and Current Limit Sense Paths ............................... 25
Short Circuit and Current Limit Protection ........................... 15
Switch Node ................................................................................ 26
Shutdown Control ...................................................................... 15
Gate Driver Paths ....................................................................... 26
Thermal Overload Protection................................................... 15
Output Capacitors ...................................................................... 26
Applications Information .............................................................. 16
Typical Operating Circuits ............................................................ 27
Setting the Output Voltage ........................................................ 16
Outline Dimensions ....................................................................... 31
Soft Start ...................................................................................... 16
Ordering Guide .......................................................................... 31
Setting the Current Limit .......................................................... 16
REVISION HISTORY
11/10—Revision 0: Initial Version
Rev. 0 | Page 2 of 32
ADP1850
SPECIFICATIONS
All limits at temperature extremes are guaranteed via correlation using standard statistical quality control (SQC). VIN = 12 V. The
specifications are valid for TJ = −40°C to +125°C, unless otherwise specified. Typical values are at TA = 25°C.
Table 1.
Parameter
POWER SUPPLY
Input Voltage
Undervoltage Lockout Threshold
Undervoltage Lockout Hysteresis
Quiescent Current
Shutdown Current
ERROR AMPLIFIER
FBx Input Bias Current
Transconductance
TRK1, TRK2 Input Bias Current
CURRENT SENSE AMPLIFIER GAIN
OUTPUT CHARACTERICTISTICS
Feedback Accuracy Voltage
Symbol
VIN
INUVLO
IIN
IIN_SD
IFB
Gm
ITRK
ACS
VFB
Line Regulation of PWM
Load Regulation of PWM
OSCILLATOR
Frequency
VFB/VIN
VFB/VCOMP
SYNC Input Frequency Range
SYNC Input Pulse Width
SYNC Pin Capacitance to GND
LINEAR REGULATOR
VCCO Output Voltage
VCCO Load Regulation
VCCO Line Regulation
VCCO Current Limit 1
VCCO Short-Circuit Current1
VIN to VCCO Dropout Voltage2
LOGIC INPUTS
EN1, EN2
EN1, EN2 Hysteresis
EN1, EN2 Input Leakage Current
SYNC Logic Input Low
SYNC Logic Input High
SYNC Input Pull-Down Resistance
fSYNC
tSYNCMIN
CSYNC
fSW
VDROPOUT
IEN
Conditions
Min
VIN rising
VIN falling
2.75
2.45
2.4
TJ = −40°C to +85°C, VFB = 0.6 V
TJ = −40°C to +125°C, VFB = 0.6 V
Unit
20
2.75
2.6
V
V
V
mA
2.8
100
200
mA
µA
−100
385
−100
2.4
+1
550
+1
3
+100
715
+100
3.6
nA
µS
nA
V/V
5.2
6
6.9
V/V
10.5
20.5
12
24
13.5
26.5
V/V
V/V
−0.85%
−1.5%
+0.6
+0.6
±0.015
±0.3
+0.85%
+1.5%
V
V
%/V
%
170
720
1275
235
475
400
100
200
800
1500
300
600
235
880
1725
345
690
3000
kHz
kHz
kHz
kHz
kHz
kHz
ns
pF
5.0
35
10
350
370
0.33
5.3
V
mV
mV
mA
mA
V
0.63
0.03
1
0.68
VCOMP range = 0.9 V to 2.2 V
RFREQ = 340 kΩ to AGND
RFREQ = 78.7 kΩ to AGND
RFREQ = 39.2 kΩ to AGND
FREQ to AGND
FREQ to VCCO
fSYNC = 2 × fSW
2.6
2.5
0.1
4.5
Max
5.8
EN1 = EN2 = VIN = 12 V, VFB = VCCO in PWM mode
(no switching)
EN1 = EN2 = VIN = 12 V, VFB = VCCO in PSM mode
EN1 = EN2 = GND, VIN = 5.5 V or 20 V
Sink or source 1 µA
0 V ≤ VTRK1/VTRK2 ≤ 5 V
Gain resistor connected to DLx,
RCSG = 47 kΩ ± 5%
Gain resistor connected to DLx,
RCSG = 22 kΩ ± 5%
Default setting, RCSG = open
Gain resistor connected to DLx,
RCSG = 100 kΩ ± 5%
Typ
5
IVCCO = 100 mA
IVCCO = 0 mA to 100 mA,
VIN = 5.5 V to 20 V, IVCCO = 20 mA
VCCO drops to 4 V from 5 V
VCCO < 0.5 V
IVCCO = 100 mA, VIN ≤ 5 V
4.7
EN1/EN2 rising
0.57
VIN = 2.75 V to 20 V
1.9
RSYNC
1
Rev. 0 | Page 3 of 32
400
200
1.3
V
V
nA
V
V
MΩ
ADP1850
Parameter
GATE DRIVERS
DHx Rise Time
DHx Fall Time
DLx Rise Time
DLx Fall Time
DHx to DLx Dead Time
DHx or DLx Driver RON, Sourcing
Current1
Symbol
Conditions
RON_SOURCE
CDH = 3 nF, VBST − VSW = 5 V
CDH = 3 nF, VBST − VSW = 5 V
CDL = 3 nF
CDL = 3 nF
External 3 nF is connected to DHx and DLx
Sourcing 2 A with a 100 ns pulse
16
14
16
14
25
2
ns
ns
ns
ns
ns
Ω
DHx or DLx Driver RON, Tempco
DHx or DLx Driver RON, Sinking
Current1
TCRON
RON_SINK
Sourcing 1 A with a 100 ns pulse, VIN = 3 V
VIN = 3 V or 12 V
Sinking 2 A with a 100 ns pulse
2.3
0.3
1.5
Ω
%/oC
Ω
2
Ω
%
%
ns
ns
ns
DHx Maximum Duty Cycle
DHx Maximum Duty Cycle
Minimum DHx On Time
Minimum DHx Off Time
Minimum DLx On Time
COMPx VOLTAGE RANGE
COMPx Pulse Skip Threshold
COMPx Clamp High Voltage
THERMAL SHUTDOWN
Thermal Shutdown Threshold
Thermal Shutdown Hysteresis
OVERVOLTAGE AND POWER GOOD
THRESHOLDS
FBx Overvoltage Threshold
FBx Overvoltage Hysteresis
FBx Undervoltage Threshold
FBx Undervoltage Hysteresis
TRKx INPUT VOLTAGE RANGE
FBx TO TRKx OFFSET VOLTAGE
SOFT START
SSx Output Current
SSx Pull-Down Resistor
FBx to SSx Offset
PGOODx
PGOODx Pull-up Resistor
PGOODx Delay
Over Voltage or Under Voltage
Sinking 1 A with a 100 ns pulse, VIN = 3 V
fSW = 300 kHz
fSW = 1500 kHz
fSW = 200 kHz to 1500 kHz
fSW = 200 kHz to 1500 kHz
fSW = 200 kHz to 1500 kHz
VCOMP,THRES
VCOMP,HIGH
VUV
VFB falling
0.525
TRKx = 0.1 V to 0.57 V, offset = VFB − VTRK
0
−10
During start-up
During a fault condition
VSS = 0.1 V to 0.6 V, offset = VFB − VSS
4.6
V
V
155
20
C
C
Relative to PGNDx
ILIMx = PGNDx
After DLx goes high, current limit is not sensed
during this period
At 20 mA forward current
−5
47
In pulse skip mode only, fSW = 600 kHz
0
Rev. 0 | Page 4 of 32
0
6.5
3
0.665
0.578
5
+10
8.4
+10
12.5
12
10
This is the minimum duration required to trip
the PGOOD signal
Guaranteed by design.
Connect VIN to VCCO when 2.75 V < VIN < 5.5 V.
0.65
30
0.55
30
−10
Internal pull-up resistor to VCCO
Unit
0.9
2.25
0.635
INTEGRATED RECTIFIER
(BOOST DIODE) RESISTANCE
ZERO CURRENT CROSS OFFSET
(SWx TO PGNDx)1
2
In pulse skip mode
VFB rising
RPGOOD
Max
135
335
285
VOV
ISS
Typ
90
50
TTMSD
Minimum Duration
ILIM1, ILIM2 Threshold Voltage1
ILIM1, ILIM2 Output Current
Current Sense Blanking Period
1
Min
0
50
100
μA
kΩ
mV
kΩ
μs
μs
+5
53
16
2
V
mV
V
mV
V
mV
mV
μA
ns
Ω
4
mV
ADP1850
ABSOLUTE MAXIMUM RATINGS
Table 2.
Parameter
VIN, EN1/EN2, RAMP1/RAMP2
FB1/FB2, COMP1/COMP2, SS1/SS2, TRK1/TRK2,
FREQ, SYNC, VCCO, VDL, PGOOD1/PGOOD2
ILIM1/ILIM2, SW1/SW2 to PGND1/PGND2
BST1/BST2, DH1/DH2 to PGND1/PGND2
DL1/DL2 to PGND1/PGND2
BST1/BST2 to SW1/SW2
BST1/BST2 to PGND1/PGND2
20 ns Transients
SW1/SW2 to PGND1/PGND2
20 ns Transients
DL1/DL2, SW1/SW2, ILIM1/ILIM2 to
PGND1/PGND2
20 ns Negative Transients
PGND1/PGND2 to AGND
PGND1/PGND2 to AGND 20 ns Transients
θJA on Multilayer PCB (Natural Convection)1, 2
Operating Junction Temperature Range3
Storage Temperature Range
Maximum Soldering Lead Temperature
Rating
21 V
−0.3 V to +6 V
−0.3 V to +21 V
−0.3 V to +28 V
−0.3V to VCCO + 0.3 V
−0.3 V to +6 V
32 V
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 GND.
25 V
−8 V
ESD CAUTION
−0.3 V to +0.3 V
−8 V to +4 V
32.6°C/W
−40°C to +125°C
−65°C to +150°C
260°C
1
Measured with exposed pad attached to PCB.
Junction-to-ambient thermal resistance (θJA) of the package was calculated
or simulated on multilayer PCB.
3
The junction temperature, TJ, of the device is dependent on the ambient
temperature, TA, the power dissipation of the device, PD, and the junction-toambient thermal resistance of the package, θJA. Maximum junction
temperature is calculated from the ambient temperature and power
dissipation using the formula: TJ = TA + PD × θJA.
2
Rev. 0 | Page 5 of 32
ADP1850
SIMPLIFIED BLOCK DIAGRAM
VCCO
VIN
THERMAL
SHUTDOWN
OV
0.6V
UV
REF
LDO
AGND
UVLO
0.6V
EN1_SW
EN2_SW
LOGIC
+
–
EN1
+
EN2
VCCO
–
OV1
LOGIC
SYNC
UV1
PH1
1MΩ
PGOOD1
FREQ
+
–
OV
FB1
0.6V
COMP1
FB1
TRK1
SS1
ERROR
AMPLIFIER
–
+
+ Gm
+
+
–
UV
VDL
BST1
SYNC
EN1_SW
VREF = 0.6V
6.5µA
5V
0.9V
FAULT
1kΩ
LOGIC
DH1
DRIVER LOGIC
CONTROL AND
STATE
MACHINE
OVER_LIM1
–
OV1
SW1
PULSE SKIP
+
OV1
–
EN1 OVER_LIM1
DCM
+
PWM
COMPARATOR
ZERO CROSS
DETECT
VDL
+
–
DL1
CS GAIN
SLOPE COMP AND
RAMP GENERATOR
PGND1
VCCO
–
AV = 3, 6, 12, 24
+
CURRENT SENSE
AMPLIFIER
50µA
+
CURRENT
LIMIT
OVER_LIM1 CONTROL
–
ILIM1
09440-003
RAMP1
12kΩ
DUPLICATE FOR
CHANNEL 2
PH2
OSCILLATOR
Figure 2.
Rev. 0 | Page 6 of 32
ADP1850
32
31
30
29
28
27
26
25
TRK1
FB1
COMP1
RAMP1
SS1
PGOOD1
ILIM1
BST1
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
1
2
3
4
5
6
7
8
ADP1850
TOP VIEW
(Not to Scale)
24
23
22
21
20
19
18
17
SW1
DH1
PGND1
DL1
DL2
PGND2
DH2
SW2
NOTES
1. CONNECT THE BOTTOM EXPOSED PAD OF THE
LFCSP PACKAGE TO SYSTEM AGND PLANE.
09440-004
TRK2
FB2
COMP2
RAMP2
SS2
PGOOD2
ILIM2
BST2
9
10
11
12
13
14
15
16
EN1
SYNC
VIN
VCCO
VDL
AGND
FREQ
EN2
Figure 3. Pin Configuration
Table 3. Pin Function Descriptions
Pin No.
1
Mnemonic
EN1
2
SYNC
3
VIN
4
VCCO
5
VDL
6
7
AGND
FREQ
8
EN2
9
10
11
TRK2
FB2
COMP2
12
RAMP2
13
SS2
14
PGOOD2
Description
Enable Input for Channel 1. Drive EN1 high to turn on the Channel 1 controller, and drive EN1 low to turn off the
Channel 1 controller. Tie EN1 to VIN for automatic startup. For a precision UVLO, put an appropriately sized
resistor divider from VIN to AGND and tie the midpoint to this pin.
Frequency Synchronization Input. Accepts an external signal between 1× and 2.3× of the internal oscillator
frequency, fSW, set by the FREQ pin. The controller operates in forced PWM when a signal is detected at SYNC or
when SYNC is high. The resulting switching frequency is ½ of the SYNC frequency. When SYNC is low or left
floating, the controller operates in pulse skip mode. For dual-phase operation, connect SYNC to a logic high or an
external clock.
Connect to Main Power Supply. Bypass with a 1 µF or larger ceramic capacitor connected as close to this pin as
possible and PGNDx.
Output of the Internal Low Dropout Regulator (LDO). Bypass VCCO to AGND with a 1 μF or larger ceramic
capacitor. The VCCO output remains active even when EN1 and EN2 are low. For operation with VIN below 5 V,
VIN may be shorted to VCCO. Do not use the LDO to power other auxiliary system loads.
Power Supply for the Low-Side Driver. Bypass VDL to PGNDx with a 1 µF or greater ceramic capacitor. Connect
VCCO to VDL.
Analog Ground.
Sets the desired operating frequency between 200 kHz and 1.5 MHz with one resistor between FREQ and AGND.
Connect FREQ to AGND for a preprogrammed 300 kHz or FREQ to VCCO for 600 kHz operating frequency.
Enable Input for Channel 2. Drive EN2 high to turn on the Channel 2 controller, and drive EN2 low to turn off the
Channel 2 controller. Tie EN2 to VIN for automatic startup. For a precision UVLO, put an appropriately sized
resistor divider from VIN to AGND, and tie the midpoint to this pin.
Tracking Input for Channel 2. Connect TRK2 to VCCO if tracking is not used.
Output Voltage Feedback for Channel 2. Connect to Output 2 via a resistor divider.
Compensation Node for Channel 2. Output of Channel 2 error amplifier. Connect a series resistor-capacitor
network from COMP2 to AGND to compensate the regulation control loop.
Connect a resistor from RAMP2 to VIN to set up a ramp current for slope compensation in Channel 2. The voltage
at RAMP2 is 0.2 V. This pin is high impedance when the channel is disabled.
Soft Start Input for Channel 2. Connect a capacitor from SS2 to AGND to set the soft start period. The node is
internally pulled up to 5 V with a 6.5 µA current source.
Power Good. Open-drain power-good indicator logic output with an internal 12 kΩ resistor connected between
PGOOD2 and VCCO. PGOOD2 is pulled to ground when the Channel 2 output is outside the regulation window.
An external pull-up resistor is not required.
Rev. 0 | Page 7 of 32
ADP1850
Pin No.
15
Mnemonic
ILIM2
16
BST2
17
SW2
18
DH2
19
PGND2
20
DL2
21
DL1
22
PGND1
23
DH1
24
SW1
25
BST1
26
ILIM1
27
PGOOD1
28
SS1
29
RAMP1
30
COMP1
31
32
33
(EPAD)
FB1
TRK1
Exposed Pad
(EPAD)
Description
Current Limit Sense Comparator Inverting Input for Channel 2. Connect a resistor between ILIM2 and SW2 to set
the current limit offset. For accurate current limit sensing, connect ILIM2 to a current sense resistor at the source
of the low-side MOSFET.
Boot-Strapped Upper Rail of High Side Internal Driver for Channel 2. Connect a multilayer ceramic capacitor
(0.1 µF to 0.22 µF) between BST2 and SW2. There is an internal boost rectifier connected between VDL and BST2.
Switch Node for Channel 2. Connect to source of the high-side N-channel MOSFET and the drain of the low-side
N-channel MOSFET of Channel 2.
High-Side Switch Gate Driver Output for Channel 2. Capable of driving MOSFETs with total input capacitance up
to 20 nF.
Power Ground for Channel 2. Ground for internal Channel 2 driver. Differential current is sensed between SW2
and PGND2. Use the Kelvin sensing connection technique between PGND2 and source of the low-side MOSFET.
Low-Side Synchronous Rectifier Gate Driver Output for Channel 2. To set the gain of the current sense amplifier,
connect a resistor between DL2 and PGND2. Capable of driving MOSFETs with a total input capacitance up to 20 nF.
Low-Side Synchronous Rectifier Gate Driver Output for Channel 1. To set the gain of the current sense amplifier,
connect a resistor between DL1 and PGND1. Capable of driving MOSFETs with a total input capacitance up to 20 nF.
Power Ground for Channel 1. Ground for internal Channel 1 driver. Differential current is sensed between SW1
and PGND1. Use the Kelvin sensing connection technique between PGND1 and source of the low-side MOSFET.
High-Side Switch Gate Driver Output for Channel 1. Capable of driving MOSFETs with a total input capacitance
up to 20 nF.
Power Switch Node for Channel 1. Connect to source of the high-side N-channel MOSFET and the drain of the
low-side N-channel MOSFET of Channel 1.
Boot-Strapped Upper Rail of High Side Internal Driver for Channel 1. Connect a multilayer ceramic capacitor
(0.1 µF to 0.22 µF) between BST1 and SW1. There is an internal boost diode or rectifier connected between VDL
and BST1.
Current Limit Sense Comparator Inverting Input for Channel 1. Connect a resistor between ILIM1 and SW1 to set
the current limit offset. For accurate current limit sensing, connect ILIM1 to a current sense resistor at the source
of the low-side MOSFET.
Power Good. Open-drain power-good indicator logic output with an internal 12 kΩ resistor connected between
PGOOD1 and VCCO. PGOOD1 is pulled to ground when the Channel 1 output is outside the regulation window.
An external pull-up resistor is not required.
Soft Start Input for Channel 1. Connect a capacitor from SS1 to AGND to set the soft start period. This node is
internally pulled up to 5 V with a 6.5 µA current source.
Connect a resistor from RAMP1 to VIN to set up a ramp current for slope compensation in Channel 1. The voltage
at RAMP2 is 0.2 V. This pin is high impedance when the channel is disabled.
Compensation Node for Channel 1. Output of Channel 1 error amplifier. Connect a series resistor-capacitor
network from COMP1 to AGND to compensate the regulation control loop.
Output Voltage Feedback for Channel 1. Connect to Output 1 via a resistor divider.
Tracking Input for Channel 1. Connect TRK1 to VCCO if tracking is not used.
Connect the bottom exposed pad of the LFCSP package to the system AGND plane.
Rev. 0 | Page 8 of 32
ADP1850
TYPICAL PERFORMANCE CHARACTERISTICS
100
5.10
90
5.05
VO = 3.3V, PSM
80
100mA LOAD ON LDO
70
4.95
60
VCCO (V)
VO = 3.3V, PWM
50
VO = 1.8V, PSM
40
4.90
4.85
4.80
30
VO = 1.8V, PWM
4.75
20
4.70
10
VIN = 12V, 600kHz
0.1
1
10
100
LOAD (A)
4.65
09440-005
0
0.01
5
7
9
11
13
15
17
5
6
VIN (V)
Figure 4. Efficiency Plot of Figure 44
09440-008
EFFICIENCY (%)
NO LOAD ON LDO
5.00
Figure 7. LDO Line Regulation
100
6
90
5
80
VO = 5V, PSM
4
60
VO = 1.8V, PSM
50
40
VCCO (V)
EFFICIENCY (%)
70
VO = 5V, PWM
3
2
30
20
VO = 1.8V, PWM
1
10
1
10
LOAD (A)
0
0
1
2
3
4
VIN (V)
Figure 5. Efficiency Plot of Figure 45
Figure 8. VCCO vs. VIN
0
SW1
1
–0.10
SW2
2
50mA LOAD
3
100mA LOAD
SYNC 600kHz
–0.20
–0.25
2.5
3.0
3.5
4.0
VIN (V)
4.5
5.0
Figure 6. LDO Load Regulation
CH1 10V
CH3 5V
CH2 10V
M1µs
A CH1
5.60V
Figure 9. An Example of Synchronization, fSYNC = 600 kHz
Rev. 0 | Page 9 of 32
09440-010
–0.15
09440-007
ΔVCCO (V)
–0.05
09440-009
0.1
09440-006
VIN = 12V, 750kHz
0
0.01
ADP1850
SW1
OUTPUT RESPONSE
1
1
PGOOD1
VCCO (CH3)
8A TO 13A STEP LOAD
2
VOUT, PRELOADED (CH4)
3
VIN = 12V
VOUT = 3.3V
B
W
M200µs
A CH4
11.5A
CH4 5A Ω
4
CH1 10V
CH2 2V
CH4 2V Ω
CH3 2V
Figure 10. Step Load Transient of Figure 44
M10ms
A CH2
09440-014
CH1 20mV
09440-011
4
3.76V
Figure 13. Thermal Shutdown Waveform
0.5
REFERENCED AT VIN = 2.75V
0
DH1
CHANGE IN fSW (%)
1
DL1
2
VOUT1
3
IL1
–0.5
600kHz
–1.0
300kHz
–1.5
4
VIN = 12V
VOUT = 1.8V
OUTPUT PRECHARGED TO 1V
A CH1
2.4V
3
5
7
9
11
13
15
17
21
09440-015
M1ms
–2.5
135
09440-016
CH2 5V
CH4 1A Ω
850kHz
09440-012
CH1 5V
CH3 1V
–2.0
19
VIN (V)
Figure 11. Soft Start into Precharged Output
Figure 14. Change in fSW vs. VIN
2.0
VIN = 12V; REFERENCED AT 25°C
1.5
1.0
1
CHANGE IN fSW (%)
SW
VOUT (CH3)
EN
M10ms
A CH2
1.52V
–1.0
–2.5
–40
09440-013
CH3 1V
CH2 2V
CH4 1V
–0.5
–2.0
CSS = 100nF
CH1 10V
0
–1.5
SS (CH4)
3
2
4
0.5
–15
10
35
60
85
TEMPERATURE (°C)
Figure 15. fSW vs. Temperature
Figure 12. Enable Start-Up Function
Rev. 0 | Page 10 of 32
110
ADP1850
45
350
TA = 25°C
OUTPUT IS LOADED
HS FET = BSC080N03LS
LS FET = BSC030N03LS
43
300
41
DH MINIMUM OFF TIME
39
DEAD TIME (ns)
200
150
37
35
33
31
DH MINIMUM ON TIME
29
100
27
DEAD TIME BETWEEN SW FALLING EDGE
AND DL RISING EDGE, INCLUDING DIODE RECOVERY TIME
5.0
7.5
10.0
12.5
15.0
17.5
20.0
VIN (V)
09440-017
25
50
2.5
0
5
10
15
20
VIN (V)
Figure 16. Typical DH Minimum On Time and Off Time
09440-020
TIME (ns)
250
Figure 19. Dead Time vs. VIN
600
4
DH MINIMUM OFF TIME
560
2
540
1
520
Gm (µS)
DH MINIMUM ON TIME
0
500
480
–1
460
–2
440
–3
–15
10
35
60
85
110
135
TEMPERATURE (°C)
400
–40
35
60
85
110
135
Figure 20. Gm of Error Amplifier vs. Temperature
35
4.5
VIN = 12V
34 OUTPUT IS LOADED
HS FET = BSC080N03LS
33 LS FET = BSC030N03LS
4.0
DRIVER RESISTANCE (Ω)
3.5
32
31
30
29
28
VIN = 2.75V, SOURCING
3.0
VIN = 12V, SOURCING
2.5
VIN = 2.75V, SINKING
2.0
1.5
VIN = 12V, SINKING
1.0
27
25
–40
–20
0
20
40
60
80
100
TEMPERATURE (°C)
120
140
Figure 18. Dead Time vs. Temperature
0
–40
–15
10
35
60
85
110
TEMPERATURE (°C)
Figure 21. Driver Resistance vs. Temperature
Rev. 0 | Page 11 of 32
135
09440-022
0.5
DEAD TIME BETWEEN SW FALLING EDGE
AND DL RISING EDGE, INCLUDING DIODE RECOVERY TIME
09440-019
DEAD TIME (ns)
10
TEMPERATURE (°C)
Figure 17. DH Minimum On Time and Off Time Over Temperature
26
–15
09440-021
420
–4
–40
09440-018
CHANGE IN MINIMUM ON/OFF TIME (%)
VIN = 2.75V TO 20V
580
3
ADP1850
THEORY OF OPERATION
The ADP1850 is a current mode, dual-channel, step-down
switching controller with integrated MOSFET drivers for external
N-channel synchronous power MOSFETs. The two outputs are
phase shifted 180°. This reduces the input RMS ripple current,
thus minimizing required input capacitance. In addition, the
two outputs can be combined for dual-phase PWM operation
that can deliver more than 50 A output current and the two
channels are optimized for current sharing.
The ADP1850 can be set to operate in pulse skip high efficiency
mode (power saving mode) under light load or in forced PWM.
The integrated boost diodes in the ADP1850 reduce the overall
system cost and component count. The ADP1850 includes
programmable soft start, output overvoltage protection, programmable current limit, power good, and tracking function. The
ADP1850 can be set to operate in any switching frequency
between 200 kHz and 1.5 MHz with one external resistor.
CONTROL ARCHITECTURE
The ADP1850 is based on a fixed frequency, current mode,
PWM control architecture. The inductor current is sensed
by the voltage drop measured across the external low-side
MOSFET, RDSON, during the off period of the switching cycle
(valley inductor current). The current sense signal is further
processed by the current sense amplifier. The output of the
current sense amplifier is held, and the emulated current ramp
is multiplexed and fed into the PWM comparator as shown in
Figure 22. The valley current information is captured at the end
of the off period, and the emulated current ramp is applied at
that point when the next on cycle begins. An error amplifier
integrates the error between the feedback voltage and the
generated error voltage from the COMPx pin (from error
amplifier in Figure 22).
VIN
OSC
VIN
S
Q
current signal is sampled at the end of the turn-off period,
which gives time for the switch node ringing to settle. Other
benefits of using current mode control scheme still apply, such
as simplicity of loop compensation. Control logic enforces
antishoot-through operation to limit cross conduction of the
internal drivers and external MOSFETs.
OSCILLATOR FREQUENCY
The internal oscillator frequency, which ranges from 200 kHz
to 1.5 MHz, is set by an external resistor, RFREQ, at the FREQ
pin. Some popular fSW values are shown in Table 4, and a graphical relationship is shown in Figure 23. For instance, a 78.7 kΩ
resistor sets the oscillator frequency to 800 kHz. Furthermore,
connecting FREQ to AGND or FREQ to VCCO sets the oscillator frequency to 300 kHz or 600 kHz, respectively. For other
frequencies that are not listed in Table 4, the values of RFREQ
and fSW can be obtained from Figure 23, or use the following
empirical formula to calculate these values:
R FEQ (kΩ) = 96568 × f SW (kHz) −1.065
Table 4. Setting the Oscillator Frequency
RFREQ
332 kΩ
78.7 kΩ
60.4 kΩ
51 kΩ
40.2 kΩ
FREQ to AGND
FREQ to VCCO
410
RFREQ (kΩ) = 96,568 fSW (kHz)–1.065
360
TO
DRIVERS
FF
RRAMP
R
310
Q
RFREQ (kΩ)
IRAMP
fSW (Typical)
200 kHz
800 kHz
1000 kHz
1200 kHz
1500 kHz
300 kHz
600 kHz
AR
260
210
160
CR
FROM
ERROR AMP
ACS
FROM
LOW-SIDE
MOSFET
Figure 22. Simplified Control Architecture
60
10
100
400
700
1000
1300
fSW (kHz)
As shown in Figure 22, the emulated current ramp is generated
inside the IC but offers programmability through the RAMPx
pin. Selecting an appropriate value resistor from VIN to the
RAMPx pin programs a desired slope compensation value and,
at the same time, provides a feed forward feature. The benefits
realized by deploying this type of control scheme are that there
is no need to worry about the turn-on current spike corrupting
the current ramp. Also, the current signal is stable because the
Rev. 0 | Page 12 of 32
Figure 23. RFREQ vs. fSW
1600
1900
09440-024
VCS
09440-023
110
ADP1850
MODES OF OPERATION
The SYNC pin is a multifunctional pin. PWM mode is enabled
when SYNC is connected to VCCO or a high logic. With SYNC
connected to ground or left floating, the pulse skip mode is
enabled. Switching SYNC from low to high or high to low on
the fly causes the controller to transition from forced PWM
to pulse skip mode or pulse skip mode to forced PWM, respectively, in two clock cycles.
DH1
1
DL1
2
Table 5. Mode of Operation Truth Table
Mode of Operation
Pulse skip mode
Forced PWM or two-phase operation
Pulse skip mode
Forced PWM or two-phase operation
The ADP1850 has a pulse skip sensing circuitry that allows the
controller to skip PWM pulses, thus, reducing the switching
frequency at light loads and, therefore, maintaining high
efficiency during a light load operation. The switching
frequency is a fraction of the natural oscillator frequency and
is automatically adjusted to regulate the output voltage. The
resulting output ripple is larger than that of the fixed frequency
forced PWM. Figure 24 shows that the ADP1850 operates in
PSM under a very light load. Pulse skip frequency under light
load is dependent on the inductor, output capacitance, output
load, and input and output voltages.
1
COMP1 (CH2)
VOUT RIPPLE
INDUCTOR
CURRENT
CH1 10V
CH3 20mV
CH2 200mV
CH4 2A Ω
M200µs
A CH1
7.8V
09440-025
4
2
INDUCTOR CURRENT
CH1 10V
CH3 20mV
CH2 5V
CH4 2A Ω
M1µs
A CH1
13.4V
Figure 25. Example of Discontinuous Conduction Mode (DCM) Waveform
In forced PWM, the ADP1850 always operates in CCM at any
load. The inductor current is always continuous, thus, efficiency
is poor at light loads.
SYNCHRONIZATION
The switching frequency of the ADP1850 can be synchronized
to an external clock by connecting SYNC to a clock signal. The
external clock should be between 1× and 2.3× of the internal
oscillator frequency, fSW. The resulting switching frequency is ½
of the external SYNC frequency because the SYNC input is
divided by 2, and the resulting phases are used to clock the two
channels alternately. In synchronization, the ADP1850 operates
in PWM.
When an external clock is detected at the first SYNC edge, the
internal oscillator is reset, and the clock control shifts to SYNC.
The SYNC edges then trigger subsequent clocking of the PWM
outputs. The DH1/DH2 rising edges appear approximately 100 ns
after the corresponding SYNC edge, and the frequency is locked
to the external signal. Depending on the start-up conditions of
Channel 1 and Channel 2, either Channel 1 or Channel 2 can be
the first channel synchronized to the rising edge of the SYNC
clock. If the external SYNC signal disappears during operation,
the ADP1850 reverts to its internal oscillator. When the SYNC
function is used, it is recommended to connect a pull-up resistor
from SYNC to VCCO so that when the SYNC signal is lost, the
ADP1850 continues to operate in PWM.
SW1
3
4
09440-026
SYNC Pin
Low
High
No Connect
Clock Signal
OUTPUT
RIPPLE
3
Figure 24. Example of Pulse Skip Mode Under Light Load
When the output load is greater than the pulse skip threshold
current, that is, VCOMP reaches the threshold of 0.9 V, the
ADP1850 exits the pulse skip mode of operation and enters
the fixed frequency discontinuous conduction mode (DCM),
as shown in Figure 25. When the load increases further, the
ADP1850 enters CCM.
Rev. 0 | Page 13 of 32
ADP1850
VIN = 2.75V TO 5.5V
SYNCHRONOUS RECTIFIER AND DEAD TIME
When the bias input voltage, VIN, is less than the undervoltage
lockout (UVLO) threshold, the switch drivers stay inactive.
When VIN exceeds the UVLO threshold, the switchers start
switching.
INTERNAL LINEAR REGULATOR
The internal linear regulator is low dropout (LDO) meaning it
can regulate its output voltage, VCCO. VCCO powers up the
internal control circuitry and provides power for the gate
drivers. It is guaranteed to have more than 200 mA of output
current capability, which is sufficient to handle the gate drive
requirements of typical logic threshold MOSFETs driven at up
to 1.5 MHz. VCCO is always active and cannot be shut down by
the EN1 and EN2 pins. Bypass VCCO to AGND with a 1 μF or
greater capacitor.
ADP1850
Figure 26. Configuration for VIN < 5.5 V
OVERVOLTAGE PROTECTION
The ADP1850 has a built-in circuit for detecting output overvoltage at the FB node. When the FB voltage, VFB, rises above
the overvoltage threshold, the low-side N-channel MOSFET
(NMOSFET) is immediately turned on, and the high-side
NMOSFET is turned off until the VFB drops below the
undervoltage threshold. This action is known as the crowbar overvoltage protection. If the overvoltage condition is
not removed, the controller maintains the feedback voltage
between the overvoltage and undervoltage thresholds, and the
output is regulated to within typically +8% and −8% of the
regulation voltage. During an overvoltage event, the SS node
discharges toward zero through an internal 3 kΩ pull-down
resistor. When the voltage at FBx drops below the undervoltage
threshold, the soft start sequence restarts. Figure 27 shows the
overvoltage protection scheme in action in PSM.
DH1
1
PGOOD1
2
VO1 = 1.8V SHORTED TO 2V SOURCE
Because the LDO supplies the gate drive current, the output of
VCCO is subject to sharp transient currents as the drivers
switch and the boost capacitors recharge during each switching
cycle. The LDO has been optimized to handle these transients
without overload faults. Due to the gate drive loading, using the
VCCO output for other external auxiliary system loads is not
recommended.
The LDO includes a current limit well above the expected
maximum gate drive load. This current limit also includes a
short-circuit fold back to further limit the VCCO current in the
event of a short-circuit fault.
The VDL pin provides power to the low-side driver. Connect
VDL to VCCO. Bypass VDL to PGNDx with a 1 μF (minimum)
ceramic capacitor, which must be placed close to the VDL pin.
For an input voltage less than 5.5 V, it is recommended to
bypass the LDO by connecting VIN to VCCO, as shown in
Figure 26, thus eliminating the dropout voltage. However, if
the input range is 4 V to 7 V, the LDO cannot be bypassed by
shorting VIN to VCCO because the 7 V input has exceeded the
maximum voltage rating of the VCCO pin. In this case, use the
LDO to drive the internal drivers, but keep in mind that there is
a dropout when VIN is less than 5 V.
VCCO
3
VIN
4
CH1 20.0V
CH3 1.00V
CH2 5.00V
CH4 10.0V
M100µs
A CH1
10.0V
09440-028
INPUT UNDERVOLTAGE LOCKOUT
VIN
09440-027
The synchronous rectifier (low-side MOSFET) improves efficiency
by replacing the Schottky diode that is normally used in an
asynchronous buck regulator. In the ADP1850, the antishootthrough circuit monitors the SW and DL nodes and adjusts the
low-side and high-side drivers to ensure break-before-make
switching which prevents cross-conduction or shoot-through
between the high-side and low-side MOSFETs. This breakbefore-make switching is known as dead time, which is not
fixed and depends on how fast the MOSFETs are turned on
and off. In a typical application circuit that uses medium sized
MOSFETs with input capacitance of approximately 3 nF, the
typical dead time is approximately 30 ns. When small and fast
MOSFETs with fast diode recovery time are used, the dead time
can be as low as 13 ns.
Figure 27. Overvoltage Protection in PSM
POWER GOOD
The PGOODx pin is an open-drain NMOSFET with an internal
12 kΩ pull-up resistor connected between PGOODx and VCCO.
PGOODx is internally pulled up to VCCO during normal
operation and is active low when tripped. When the feedback
voltage, VFB, rises above the overvoltage threshold or drops
below the undervoltage threshold, the PGOODx output is
pulled to ground after a delay of 12 μs. The overvoltage or
undervoltage condition must exist for more than 10 μs for
PGOODx to become active. The PGOODx output also
becomes active if a thermal overload condition is detected.
Rev. 0 | Page 14 of 32
ADP1850
SHUTDOWN CONTROL
When the output is shorted or the output current exceeds the
current limit set by the current limit setting resistor (between
ILIMx and SWx) for eight consecutive cycles, the ADP1850
shuts off both the high-side and low-side drivers and restarts
the soft start sequence every 10 ms, which is known as hiccup
mode. The SS node discharges to zero through an internal 1 kΩ
resistor during an overcurrent or short-circuit event. Figure 28
shows that the ADP1850 on a high current application circuit is
entering current limit hiccup mode when the output is shorted.
SW1
1
The EN1 and EN2 pins are used to enable or disable Channel 1
and Channel 2 of the ADP1850. The precision enable (minimum)
threshold for EN1/EN2 is 0.57 V. When the voltage at EN1/EN2
rises above the threshold voltage, the ADP1850 is enabled and
starts normal operation after the soft start period. And when
the voltage at EN1/EN2 drops typically 30 mV (hysteresis)
below the threshold voltage, the switchers and the internal
circuits in the ADP1850 are turned off. Note that EN1/EN2
cannot shut down the LDO at VCCO, which is always active.
For the purpose of start-up power sequencing, the startup of the
ADP1850 can be programmed by connecting an appropriate
resistor divider from the master power supply to the EN1/EN2
pin, as shown in Figure 29. For instance, if the desired start-up
voltage from the master power supply is 10 V, R1 and R2 can be
set to 156 kΩ and 10 kΩ, respectively.
MASTER
SUPPLY VOLTAGE
SS1
3
R1
R2
INDUCTOR CURRENT
VOUT1
ADP1850
EN1
OR
EN2
FB1
OR
FB2
RTOP
RBOT
CH1 10V
CH3 500mV
M2ms
A CH1
11.2V
CH4 10A Ω
Figure 28. Current Limit Hiccup Mode, 20 A Current Limit
09440-029
4
09440-030
SHORT CIRCUIT AND CURRENT LIMIT
PROTECTION
Figure 29. Optional Power-Up Sequencing Circuit
THERMAL OVERLOAD PROTECTION
The ADP1850 has an internal temperature sensor that senses
the junction temperature of the chip. When the junction
temperature of the ADP1850 reaches approximately 155°C, the
ADP1850 goes into thermal shutdown, the converter is turned
off, and SS discharges toward zero through an internal 1 kΩ
resistor. At the same time, VCCO discharges to zero. When the
junction temperature drops below 135°C, the ADP1850 resumes
normal operation after the soft start sequence.
Rev. 0 | Page 15 of 32
ADP1850
APPLICATIONS INFORMATION
SETTING THE OUTPUT VOLTAGE
The output voltage is set using a resistive voltage divider from
the output to FB. The voltage divider divides down the output
voltage to the 0.6 V FB regulation voltage to set the regulation
output voltage. The output voltage can be set to as low as 0.6 V
and as high as 90% of the power input voltage.
The maximum input bias current into FB is 100 nA. For a 0.15%
degradation in regulation voltage and with 100 nA bias current,
the low-side resistor, RBOT, must be less than 9 kΩ, which results
in 67 μA of divider current. For RBOT, use a 1 kΩ to 20 kΩ resistor.
A larger value resistor can be used but results in a reduction in
output voltage accuracy due to the input bias current at the FBx
pin, while lower values cause increased quiescent current
consumption. Choose RTOP to set the output voltage by using
the following equation:
RTOP
 V  V FB
 R BOT  OUT
V FB





The SSx pin reaches a final voltage equal to VCCO. If the output
voltage is precharged prior to turn-on, the ADP1850 prevents
reverse inductor current, which discharges the output capacitor.
Once the voltage at SSx exceeds the regulation voltage (typically
0.6 V), the reverse current is reenabled to allow the output
voltage regulation to be independent of load current.
Furthermore, in dual-phase operation, where SS1 is shorted to
SS2, the current source is doubled to 13 μA during the soft start
sequence.
When a controller is disabled, for instance, EN1/EN2 is pulled
low or experiences an overcurrent limit condition, the soft start
capacitor is discharged through an internal 3 kΩ pull-down
resistor.
SETTING THE CURRENT LIMIT
The current limit comparator measures the voltage across the
low-side MOSFET to determine the load current.
The current limit is set by an external current limit resistor,
RILIM, between ILIMx and SWx. The current sense pin, ILIMx,
sources nominally 50 μA to this external resistor. This creates an
offset voltage of RILIM multiplied by 50 μA. When the drop
across the low-side MOSFET, RDSON, is equal to or greater than
this offset voltage, the ADP1850 flags a current limit event.
where:
RTOP is the high-side voltage divider resistance.
RBOT is the low-side voltage divider resistance.
VOUT is the regulated output voltage.
VFB is the feedback regulation threshold, 0.6 V.
The minimum output voltage is dependent on fSW and minimum
DH on time. The maximum output voltage is dependent on fSW,
the minimum DH off time, and the IR drop across the high-side
NMOSFET and the DCR of the inductor. For example, with fSW of
600 kHz (or 1.67 μs) and a minimum on time of 130 ns, the
minimum duty cycle is approximately 7.8% (130 ns/1.67 μs). If
VIN is 12 V and the duty cycle is 7.8%, then the lowest output is
0.94 V. As an example for the maximum output voltage, if VIN is
5 V, fSW is 600 kHz, and the minimum DH off time is 395 ns
(335 ns DH off time plus approximately 60 ns total dead time),
then the maximum duty cycle is 76%. Therefore, the maximum
output is approximately 3.8 V. If the IR drop across the highside NMOSFET and the DCR of the inductor is 0.5 V, then the
absolute maximum output is 4.5 V (5 V − 0.5 V), independent of
fSW and duty cycle.
Because the ILIMx current and the MOSFET, RDSON, vary over
process and temperature, the minimum current limit should be
set to ensure that the system can handle the maximum desired
load current. To do this, use the peak current in the inductor,
which is the desired output current limit level plus ½ of the
ripple current, the maximum RDSON of the MOSFET at its
highest expected temperature, and the minimum ILIM current.
Keep in mind that the temperature coefficient of the MOSFET,
RDSON, is typically 0.4%/oC.
R ILIM 
The soft start period is set by an external capacitor between
SS1/SS2 and AGND. The soft start function limits the input
inrush current and prevents output overshoot.
When EN1/EN2 is enabled, a current source of 6.5 μA starts
charging the capacitor, and the regulation voltage is reached
when the voltage at SS1/SS2 reaches 0.6 V.
The soft start period is approximated by
0.6 V
6.5 μA
47 A
where:
ILPK is the peak inductor current.
SOFT START
t SS 
I LPK  R DSON _ MAX
C SS
Rev. 0 | Page 16 of 32
ADP1850
ACCURATE CURRENT LIMIT SENSING
VIN
RRAMP
RDSON of the MOSFET can vary by more than 50% over the
temperature range. Accurate current limit sensing is achieved
by adding a current sense resistor from the source of the lowside MOSFET to PGNDx. Make sure that the power rating of the
current sense resistor is adequate for the application. Apply the
previous equation and calculate RILIM by replacing RDSON_MAX
with RSENSE. Figure 30 illustrates the implementation of accurate
current limit sensing.
RAMP
ADP1850
DHx
SWx
RILIM
ILIMx
RCSG
VIN
Figure 31. Slope Compensation and CS Gain Connection
ADP1850
SETTING THE CURRENT SENSE GAIN
DHx
SWx
RILIM
ILIMx
RSENSE
09440-031
DLx
Figure 30. Accurate Current Limit Sensing
SETTING THE SLOPE COMPENSATION
In a current-mode control topology, slope compensation is
needed to prevent subharmonic oscillations in the inductor
current and to maintain a stable output. The external slope
compensation is implemented by summing the amplified sense
signal and a scaled voltage at the RAMPx pin. To implement the
slope compensation, connect a resistor between RAMPx and
the input voltage. The resistor, RRAMP, is calculated by
R RAMP =
7 × 10 9 L
ACS × R DSON _ MAX
where:
7 × 109 is an internal parameter.
L is the inductance (with units in H) of the inductor.
RDSON_MAX is the low-side MOSFET maximum on resistance.
ACS is the gain, either 3 V/V, 6 V/V, 12 V/V, or 24 V/V, of the
current sense amplifier (see the Setting the Current Sense Gain
section for more details).
RDSON is temperature dependent and can vary as much as
0.4%/oC. Choose RDSON at the maximum operating temperature.
The voltage at RAMPx is fixed at 0.2 V, and the current going
into RAMPx should be between 10 µA and 160 µA. Make sure
that the following condition is satisfied:
10 µA ≤
V IN − 0.2 V
R RAMP
09440-032
DLx
≤ 160 µA
For instance, with an input voltage of 12 V, RRAMP should not
exceed 1.1 MΩ. If the calculated RRAMP produces less than 10 µA,
then select an RRAMP value that produces between 10 µA and 15 µA.
Figure 31 illustrates the connection of the slope compensation
resistor, RRAMP, and the current sense gain resistor, RCSG.
The voltage drop across the external low-side MOSFET is
sensed by a current sense amplifier by multiplying the peak
inductor current and the RDSON of the MOSFET. The result is
then amplified by a gain factor of either 3 V/V, 6 V/V, 12 V/V,
or 24 V/V, which is programmable by an external resistor, RCSG,
connected to the DLx pin. This gain is sensed only during
power-up and not during normal operation. The amplified
voltage is summed with the slope compensation ramp voltage
and fed into the PWM controller for a stable regulation voltage.
The voltage range of the internal node, VCS, is between 0.4 V
and 2.2 V. Select the current sense gain such that the internal
minimum amplified voltage (VCSMIN) is above 0.4 V and the
maximum amplified voltage (VCSMAX) is 2.1 V. Note that VCSMIN
or VCSMAX is not the same as VCOMP, which has a range of 0.85 V
to 2.25 V. Make sure that the maximum VCOMP (VCOMPMAX) does
not exceed 2.2 V to account for temperature and part-to-part
variations. See the following equations for VCSMIN, VCSMAX, and
VCOMPMAX:
VCSMIN = 0.75 V −
1
I LPP × R DSON _ MIN × ACS
2
VCSMAX = 0.75 V + (I LOADMAX +
VCOMPMAX =
(VIN − 0.2 V)t ON
100 pF × R RAMP
1
I LPP ) × R DSON _ MAX × ACS
2
+ VCSMAX
where:
VCSMIN is the minimum amplified voltage of the internal current
sense amplifier at zero output current.
VCSMAX is the maximum amplified voltage of the internal current
sense amplifier at maximum output current.
RDSON_MIN is the low-side MOSFET minimum on resistance. The
zero-current level voltage of the current sense amplifier is 0.75 V.
ILPP is the peak-to-peak ripple current in the inductor.
ILOADMAX is the maximum output dc load current.
VCOMPMAX is the maximum voltage at the COMP pin.
100 pF is an internal parameter.
tON is the high-side driver (DH) on time.
Rev. 0 | Page 17 of 32
ADP1850
INPUT CAPACITOR SELECTION
INPUT FILTER
The input current to a buck converter is a pulse waveform. It is
zero when the high-side switch is off and approximately equal
to the load current when it is on. The input capacitor carries the
input ripple current, allowing the input power source to supply
only the direct current. The input capacitor needs sufficient
ripple current rating to handle the input ripple, as well as an
ESR that is low enough to mitigate input voltage ripple. For the
usual current ranges for these converters, it is good practice to
use two parallel capacitors placed close to the drains of the
high-side switch MOSFETs (one bulk capacitor of sufficiently
high current rating and a 10 μF ceramic decoupling capacitor,
typically).
Normally a 0.1 µF or greater value bypass capacitor from the
input pin (VIN) to AGND is sufficient for filtering out any
unwanted switching noise. However, depending on the PCB
layout, some switching noise can enter the ADP1850 internal
circuitry; therefore, it is recommended to have a low pass filter
at the VIN pin. Connecting a resistor, between 2 Ω and 5 Ω, in
series with VIN and a 1 µF ceramic capacitor between VIN and
AGND creates a low pass filter that effectively filters out any
unwanted glitches caused by the switching regulator. Keep in
mind that the input current could be larger than 100 mA when
driving large MOSFETs. A 100 mA across a 5 Ω resistor creates
a 0.5 V drop, which is the same voltage drop in VCCO. In this
case, a lower resistor value is desirable.
Select an input bulk capacitor based on its ripple current rating.
First, determine the duty cycle of the output.
VOUT
VIN
ADP1850
VIN
1µF
AGND
The input capacitor RMS ripple current is given by
Figure 32. Input Filter Configuration
I RMS = I O D(1 − D)
BOOST CAPACITOR SELECTION
where:
IO is the output current.
D is the duty cycle
The minimum input capacitance required for a particular load is
C IN , MIN =
2Ω TO 5Ω
I O × D(1 − D)
To lower system component count and cost, the ADP1850 has
an integrated rectifier (equivalent to the boost diode) between
VCCO and BSTx. Choose a boost ceramic capacitor with a
value between 0.1 µF and 0.22 µF; this capacitor provides the
current for the high-side driver during switching.
INDUCTOR SELECTION
(VPP − I O × DR ESR ) f SW
The output LC filter smoothes the switched voltage at SWx. For
most applications, choose an inductor value such that the
inductor ripple current is between 20% and 40% of the
maximum dc output load current. Generally, a larger inductor
current ripple generates more power loss in the inductor and
larger voltage ripples at the output. Check the inductor data
sheet to make sure that the saturation current of the inductor is
well above the peak inductor current of a particular design.
where:
VPP is the desired input ripple voltage.
RESR is the equivalent series resistance of the capacitor.
If an MLCC capacitor is used, the ESR is near 0, then the
equation is simplified to
C IN , MIN = I O ×
09440-033
D=
VIN
D(1 − D)
VPP × f SW
The capacitance of MLCC is voltage dependent. The actual
capacitance of the selected capacitor must be derated according to
the manufacturer’s specification. In addition, add more bulk
capacitance, such as by using electrolytic or polymer capacitors,
as necessary for large step load transients. Make sure the
current ripple rating of the bulk capacitor exceeds the
maximum input current ripple of a particular design.
Choose the inductor value by the following equation:
L=
V IN − VOUT VOUT
×
f SW × ∆I L
V IN
where:
L is the inductor value.
fSW is the switching frequency.
VOUT is the output voltage.
VIN is the input voltage.
∆IL is the peak-to-peak inductor ripple current.
Rev. 0 | Page 18 of 32
ADP1850
OUTPUT CAPACITOR SELECTION
Choose the output bulk capacitor to set the desired output voltage
ripple. The impedance of the output capacitor at the switching
frequency multiplied by the ripple current gives the output
voltage ripple. The impedance is made up of the capacitive
impedance plus the nonideal parasitic characteristics, the
equivalent series resistance (ESR), and the equivalent series
inductance (ESL). The output voltage ripple can be
approximated by


1
∆VOUT ≅ ∆I L  R ESR +
+ 4 f SW × L ESL 


8 f SW × COUT


ESR, required to satisfy the voltage droop requirement is
approximated by
COUT ≅
∆I STEP
∆VDROOP × f SW
where:
∆ISTEP is the step load.
∆VDROOP is the voltage droop at the output.
When a load is suddenly removed from the output, the energy
stored in the inductor rushes into the capacitor, causing the
output to overshoot. The output capacitance required to satisfy
the output overshoot requirement can be approximated by
where:
∆VOUT is the output ripple voltage.
∆IL is the inductor ripple current.
RESR is the equivalent series resistance of the output capacitor (or
the parallel combination of ESR of all output capacitors).
LESL is the equivalent series inductance of the output capacitor
(or the parallel combination of ESL of all capacitors).
where:
∆VOVERSHOOT is the overshoot voltage during the step load.
Solving COUT in the previous equation yields
MOSFET SELECTION
C OUT ≅
∆I L
1
×
8 f SW ∆VOUT − ∆I L R ESR − 4 ∆I L f SW × L ESL
Usually the capacitor impedance is dominated by ESR. The
maximum ESR rating of the capacitor, such as in electrolytic or
polymer capacitors, is provided in the manufacturer’s data
sheet; therefore, output ripple reduces to
∆VOUT ≅ ∆I L × RESR
Electrolytic capacitors also have significant ESL, on the order of
5 nH to 20 nH, depending on type, size, and geometry. PCB
traces contribute some ESR and ESL, as well. However, using
the maximum ESR rating from the capacitor data sheet usually
provides some margin such that measuring the ESL is not
usually required.
In the case of output capacitors where the impedance of the
ESR and ESL are small at the switching frequency, for instance,
where the output capacitor is a bank of parallel MLCC capacitors, the capacitive impedance dominates and the output
capacitance equation reduces to
COUT ≅
∆I L
8 ∆VOUT × f SW
C OUT ≅
(VOUT
∆I STEP 2 L
+ ∆VOVERSHOOT )2 − VOUT 2
Select the largest output capacitance given by any of the
previous three equations.
The choice of MOSFET directly affects the dc-to-dc converter
performance. A MOSFET with low on resistance reduces I2R
losses, and low gate charge reduces transition losses. The
MOSFET should have low thermal resistance to ensure that the
power dissipated in the MOSFET does not result in excessive
MOSFET die temperature.
The high-side MOSFET carries the load current during on time
and usually carries most of the transition losses of the converter.
Typically, the lower the on resistance of the MOSFET, the
higher the gate charge and vice versa. Therefore, it is important
to choose a high-side MOSFET that balances the two losses. The
conduction loss of the high-side MOSFET is determined by the
equation
V
PC ≅ (I LOAD )2 × R DSON  OUT
 VIN




where:
RDSON is the MOSFET on resistance.
The gate charging loss is approximated by the equation
PG ≅ VPV × QG × f SW
Make sure that the ripple current rating of the output capacitors
is greater than the maximum inductor ripple current.
During a load step transient on the output, for instance, when
the load is suddenly increased, the output capacitor supplies the
load until the control loop has a chance to ramp the inductor
current. This initial output voltage deviation results in a voltage
droop or undershoot. The output capacitance, assuming 0 Ω
where:
VPV is the gate driver supply voltage.
QG is the MOSFET total gate charge.
Note that the gate charging power loss is not dissipated in the
MOSFET but rather in the ADP1850 internal drivers. This
power loss should be taken into consideration when calculating
the overall power efficiency.
Rev. 0 | Page 19 of 32
ADP1850
The high-side MOSFET transition loss is approximated by the
equation
PT ≅
The total power dissipation of the high-side MOSFET is the
sum of conduction and transition losses:
VIN × I LOAD × (t R + t F ) × f SW
PHS ≅ PC + PT
2
The synchronous rectifier, or low-side MOSFET, carries the
inductor current when the high-side MOSFET is off. The lowside MOSFET transition loss is small and can be neglected in
the calculation. For high input voltage and low output voltage,
the low-side MOSFET carries the current most of the time.
Therefore, to achieve high efficiency, it is critical to optimize
the low-side MOSFET for low on resistance. In cases where the
power loss exceeds the MOSFET rating or lower resistance is
required than is available in a single MOSFET, connect multiple
low-side MOSFETs in parallel. The equation for low-side
MOSFET conduction power loss is
where:
PT is the high-side MOSFET switching loss power.
tR is the rise time in charging the high-side MOSFET.
tF is the fall time in discharging the high-side MOSFET.
tR and tF can be estimated by
tR ≅
Q GSW
I DRIVER _ RISE
tF ≅
Q GSW
I DRIVER _ FALL
where:
QGSW is the gate charge of the MOSFET during switching and is
given in the MOSFET data sheet.
IDRIVER_RISE and IDRIVER_FALL are the driver current put out by the
ADP1850 internal gate drivers.
If QGSW is not given in the data sheet, it can be approximated by
Q GSW ≅ Q GD +
Q GS
2
where:
QGD and QGS are the gate-to-drain and gate-to-source charges
given in the MOSFET data sheet.
IDRIVER_RISE and IDRIVER_FALL can be estimated by
I DRIVER _ RISE ≅
VDD − VSP
RON _ SOURCE + RGATE
I DRIVER _ FALL ≅
VSP
RON _ SINK + RGATE
 V

PCLS ≅ (I LOAD )2 × R DSON 1 − OUT 
VIN 

There is also additional power loss during the time, known as
dead time, between the turn-off of the high-side switch and the
turn-on of the low-side switch, when the body diode of the lowside MOSFET conducts the output current. The power loss in
the body diode is given by
PBODYDIODE = VF × t D × f SW × I O
where:
VF is the forward voltage drop of the body diode, typically 0.7 V.
tD is the dead time in the ADP1850, typically 30 ns when driving
some medium-size MOSFETs with input capacitance, Ciss, of
approximately 3 nF. The dead time is not fixed. Its effective
value varies with gate drive resistance and Ciss, so PBODYDIODE
increases in high load current designs and low voltage designs.
Then the power loss in the low-side MOSFET is
where:
VDD is the input supply voltage to the driver and is between 2.75 V
and 5 V, depending on the input voltage.
VSP is the switching point where the MOSFET fully conducts;
this voltage can be estimated by inspecting the gate charge
graph given in the MOSFET data sheet.
RON_SOURCE is the on resistance of the ADP1850 internal driver,
given in Table 1 when charging the MOSFET.
RON_SINK is the on resistance of the ADP1850 internal driver,
given in Table 1 when discharging the MOSFET.
RGATE is the on gate resistance of MOSFET given in the
MOSFET data sheet. If an external gate resistor is added, add
this external resistance to RGATE.
PLS = PCLS + PBODYDIODE
Note that MOSFET, RDSON, increases with increasing temperature with a typical temperature coefficient of 0.4%/oC. The
MOSFET junction temperature (TJ) rise over the ambient
temperature is
TJ = TA + θJA × PD
where:
θJA is the thermal resistance of the MOSFET package.
TA is the ambient temperature.
PD is the total power dissipated in the MOSFET.
Rev. 0 | Page 20 of 32
ADP1850
LOOP COMPENSATION (SINGLE PHASE
OPERATION)
As with most current mode step-down controller, a transconductance error amplifier is used to stabilize the external voltage
loop. Compensating the ADP1850 is fairly easy; an RC compensator is needed between COMPx and AGND. Figure 33 shows
the configuration of the compensation components: RCOMP,
CCOMP, and CC2. Because CC2 is very small compared to CCOMP,
to simplify calculation, CC2 is ignored for the stability
compensation analysis.
ADP1850
COMPx
Gm
At the crossover frequency, the open-loop transfer function is
unity or 0 dB, H (fCROSS) = 1. Combining Equation 1 and
Equation 3, ZCOMP at the crossover frequency can be written as
 2π × f CROSS
Z COMP ( f CROSS ) = 
 Gm × G
CS

CCOMP
f ZERO =
09440-034
The open loop gain transfer function at angular frequency, s, is
given by
VREF
× Z COMP (s) × Z FILTER (s)
VOUT
(2)
where:
ACS is the current sense gain of either 3 V/V, 6 V/V, 12 V/V, or
24 V/V set by the gain resistor between DLx and PGNDx.
RDSON_MIN is the low-side MOSFET minimum on resistance.
If a sense resistor, RS, is added in series with the low-side FET,
then GCS becomes
1
ACS × (R DSON _ MIN + RS )
Because the zero produced by the ESR of the output capacitor is
not needed to stabilize the control loop, assuming ESR is small
the ESR is ignored for analysis. Then ZFILTER is given by
1
(3)
sC OUT
1
sC COMP
=
1 + sRCOMP × CCOMP
sC COMP
f CROSS
f CROSS + f ZERO
2
2
 2π × f CROSS
×
 G ×G
CS
 m
  C OUT × VOUT
×
 
VREF
 

 (8)


Choose the crossover and zero frequencies as follows:
f CROSS =
f SW
12
f ZERO =
f CROSS f SW
=
4
48
(9)
(10)
  C OUT × VOUT
×
 
VREF
 

 (11)


where:
Gm is the transconductance of the error amplifier, 500 µS.
ACS is the current sense gain of 3 V/V, 6 V/V, 12 V/V, or 24 V/V.
RDSON is on resistance of the low-side MOSFET.
VREF = 0.6 V.
And combining Equation 6 and Equation 10 yields
C COMP =
2
πRCOMP × f CROSS
(12)
Note that the previous simplified compensation equations for
RCOMP and CCOMP yield reasonable results in fCROSS and phase
margin assuming that the compensation ramp current is ideal.
Varying the ramp current or deviating the ramp current from
ideal can affect fCROSS and phase margin.
And lastly, set CC2 to
Because CC2 is small relative to CCOMP, ZCOMP can be simplified to
Z COMP = RCOMP +
(7)
f CROSS
 2π × f CROSS
RCOMP = 0.97 × ACS × R DSON 
Gm

1
ACS × R DSON _ MIN
Z FILTER =
f CROSS 2 + f ZERO 2
Substituting Equation 2, Equation 9, and Equation 10 into
Equation 8 yields
GCS with units of A/V is given by
GCS =
RCOMP =
(1)
where:
Gm is the transconductance of the error amplifier, 500 µS.
GCS is the tranconductance of the power stage.
ZCOMP is the impedance of the compensation network.
ZFILTER is the impedance of the output filter.
VREF = 0.6 V.
GCS =
(6)
Combining Equations 5 and Equation 7 and solving for
RCOMP gives
Figure 33. Compensation Components
H (s) = Gm × GCS ×
1
2πRCOMP × C COMP
Z COMP ( f CROSS ) = RCOMP ×
0.6V
(5)
At the crossover frequency, Equation 4 can be shown as
FBx
AGND




The zero produced by RCOMP and CCOMP is
RCOMP
CC2
 C OUT × VOUT


VREF

(4)
Rev. 0 | Page 21 of 32
1
1
× C COMP ≤ C C 2 ≤ × C COMP
20
10
(13)
ADP1850
CONFIGURATION AND LOOP COMPENSATION
(DUAL-PHASE OPERATION)
SWITCHING NOISE AND OVERSHOOT REDUCTION
In dual-phase operation, the two outputs of the switching
regulators are shorted together and can source more than
50 A of output current depending on the selection of the
power components. Internal parameters in the ADP1850
are optimized and trimmed in the factory to minimize the
mismatch in output currents between the two channels. See
Figure 34 and Figure 47 for a configuration of a typical dualphase application circuit. Note that FB1 shorts to FB2, SS1 to
SS2, and COMP1 to COMP2, where the outputs of the two
error amplifiers are shared. Furthermore, the controller needs
to be placed in forced PWM operation by connecting SYNC
to VCCO or logic high.
The equations for calculating the loop compensation components are identical to the single-phase operation, but the
combined value of Gm of the error amplifiers, the modulator
gain and the effective fSW are all doubled.
In any high speed step-down regulator, high frequency noise
(generally in the range of 50 MHz to 100 MHz) and voltage
overshoot are always present at the gate, the switch node (SW),
and the drains of the external MOSFETs. The high frequency
noise and overshoot are caused by the parasitic capacitance,
CGD, of the external MOSFET and the parasitic inductance of
the gate trace and the packages of the MOSFETs. When the high
current is switched, electromagnetic interference (EMI) is
generated, which can affect the operation of the surrounding
circuits. To reduce voltage ringing and noise, it is recommended
to add an RC snubber between SWx and PGNDx for high current
applications, as illustrated in Figure 35.
In most applications, RSNUB is typically 2 Ω to 4 Ω, and CSNUB
typically 1.2 nF to 3 nF.
RSNUB can be estimated by
RRAMP1
L MOSFET
C OSS
RSNUB ≅ 2
VIN
And CSNUB can be estimated by
VIN
C SNUB ≅ COSS
ADP1850
EN1
EN2
VDL
HI
SW1
ILIM1
FB1
M2
DL1
VOUTx
RCSG1
RRAMP2
VIN
RAMP2
COMP1
COMP2
M3
PSNUB = V IN 2 × C SNUB × f SW
L2
DH2
BST2
SW2
ILIM2
FB2
R1
M4
DL2
R2
RCSG2
PGND2
Figure 34. Dual-Phase Circuit
09440-002
AGND
The size of the RC snubber components needs to be chosen
correctly to handle the power dissipation. The power dissipated
in RSNUB is
PGND1
FREQ
SS1
SS2
where:
LMOSFET is the total parasitic inductance of the high-side and
low-side MOSFETs, typically 3 nH, and is package dependent.
COSS is the total output capacitance of the high-side and lowside MOSFETs given in the MOSFET data sheet.
L1
DH1
BST1
VCCO
TRK1
TRK2
PGOOD1
PGOOD2
SYNC
LO
M1
In most applications, a component size 0805 for RSNUB is sufficient.
However, the use of an RC snubber reduces the overall efficiency,
generally by an amount in the range of 0.1% to 0.5%. The RC
snubber does not reduce the voltage overshoot. A resistor,
shown as RRISE in Figure 35, at the BSTx pin helps to reduce
overshoot and is generally between 2 Ω and 4 Ω. Adding a
resistor in series, typically between 2 Ω and 4 Ω, with the gate
driver also helps to reduce overshoot. If a gate resistor is added,
then RRISE is not needed.
VDL
ADP1850
(CHANNEL 1)
RRISE
VIN
BST1
M1
DH1
L
VOUTx
SW1
ILIM1
DL1
RSNUB
RILIM1
M2
COUT
CSNUB
PGND1
Figure 35. Application Circuit with a Snubber
Rev. 0 | Page 22 of 32
09440-035
RAMP1
ADP1850
VOLTAGE TRACKING
Two tracking configurations are possible with the ADP1850:
coincident and ratiometric trackings.
Coincident Tracking
The most common application is coincident tracking, used in
core vs. I/O voltage sequencing and similar applications.
Coincident tracking forces the slave output voltage’s ramp rate
to be the same as the master’s until the slave output reaches its
regulation. Connect the slave TRKx input to a resistor divider
from the master voltage that is the same as the divider used on
the slave FBx pin. This forces the slave voltage to be the same as
the master voltage. For coincident tracking, use RTRKT = RTOP
and RTRKB = RBOT, as shown in Figure 37.
VOUT _ MASTER
As the master voltage rises, the slave voltage rises identically.
Eventually, the slave voltage reaches its regulation voltage,
where the internal reference takes over the regulation while the
TRKx input continues to increase and thus removes itself from
influencing the output voltage.
To ensure that the output voltage accuracy is not compromised
by the TRKx pin being too close in voltage to the reference voltage
(VFB, typically 0.6 V), make sure that the final value of the TRKx
voltage of the slave channel is at least 30 mV above VFB.
Ratiometric Tracking
Ratiometric tracking limits the output voltage to a fraction of
the master voltage, as illustrated in Figure 38 and Figure 39. The
final TRKx voltage of the slave channel should be set to at least
30 mV below the FB voltage of the master channel. When the
TRKx voltage of the slave channel drops to a level that’s below
the minimum on-time condition, the slave channel operates in
pulse skip mode while keeping the output regulated and tracked
to the master channel. Also, when TRKx or FBx drops below
the PGOOD undervoltage threshold, the PGOOD signal gets
tripped and becomes active low.
SLAVE VOLTAGE
09440-036
TIME
Figure 38. Ratiometric Tracking
Figure 36. Coincident Tracking
EN1
EN2
ADP1850
TRK1
45.3kΩ
FB1
10kΩ
CSS1
100nF
SS1
FB2
EN2
45.3kΩ
ADP1850
RTRKT
20kΩ
1.1V
VCCO
0.6V
FB1
TRK1
10kΩ
RTRKB
10kΩ
CSS1
37nF
TRK2
SS2
RBOT
10kΩ
EN1
SS1
CSS2
20nF
SS2
RTOP
20kΩ
RBOT
10kΩ
VOUT2_SLAVE
0.55V
RTRKB
10kΩ
CSS2
20nF
RTOP
22.6kΩ
0.55V
1.8V
RTRKT
49.9kΩ
TRK2
FB2
09440-037
VCCO
3.3V
VOUT1_MASTER
EN
3.3V
VOUT1_MASTER
EN
SLAVE VOLTAGE
1.8V
VOUT2_SLAVE
09440-039
VOLTAGE (V)
MASTER VOLTAGE
TIME
MASTER VOLTAGE
09440-038
In all tracking configurations, the output can be set as low as 0.6 V
for a given operating condition. The soft start time setting of
the master voltage should be longer than the soft start of the
slave voltage. This forces the rise time of the master voltage to
be imposed on the slave voltage. If the soft start setting of the
slave voltage is longer, the slave comes up more slowly, and the
tracking relationship is not seen at the output.
VOUT _ SLAVE
VOLTAGE (V)
The ADP1850 includes a tracking feature that tracks a master
voltage. This feature is especially important when the ADP1850
is providing separate power supply voltages to a single integrated
circuit, such as the core and I/O voltages of a DSP, FPGA, or
microcontroller. In these cases, improper sequencing can cause
damage to the load IC.


R
1 + TOP 
 R

BOT 
= 
 RTRKT 
1 +


RTRKB 

Figure 39. Example of a Ratiometric Tracking Circuit
Figure 37. Example of a Coincident Tracking Circuit
The ratio of the slave output voltage to the master voltage is a
function of the two dividers.
Another ratiometric tracking configuration is having the slave
channel rise more quickly than the master channel, as shown in
Figure 40 and Figure 41. The tracking circuits in Figure 39 and
Figure 41 are virtually identical with the exception that RTRKB >
RTRKT as shown in Figure 41.
Rev. 0 | Page 23 of 32
ADP1850
high as 20 V. The user needs to make sure that the minimum
or the maximum duty cycle is not violated in this operating
condition. Furthermore, note that RRAMP is connected to VPIN.
VOLTAGE (V)
MASTER VOLTAGE
SLAVE VOLTAGE
09440-040
TIME
VIN
Figure 40. Ratiometric Tracking (Slave Channel Has a Faster Ramp Rate)
EN2
EN1
ADP1850
VCCO
45.3kΩ
RTRKT
5kΩ
2.2V
10kΩ
RTRKB
10kΩ
FB1
TRK1
RAMP1
ADP1850
VOUT1
DH1
3.3V
VOUT1_MASTER
EN
VPIN = 1V TO 20V
RRAMP1
VIN = 2.7V TO 20V
SW1
FB1
DL1
PGND1
RRAMP2
SS2
FB2
RBOT
10kΩ
RAMP2
TRK2
CSS2
20nF
DH2
VPIN = 1V TO 20V
VOUT2
SW2
RTOP
20kΩ
1.8V
VOUT2_SLAVE
FB2
Figure 41. Example of a Ratiometric Tracking Circuit (Slave Channel Has a
Faster Ramp Rate)
INDEPDENDENT POWER STAGE INPUT VOLTAGE
DL2
PGND2
09440-042
SS1
09440-041
CSS1
100nF
Figure 42. Independent Power Stage Input Voltage (Simplified Schematic)
In addition to the single power supply configuration, the power
stage input voltage of the dc-to-dc converter can come from a
different voltage supply, as illustrated in Figure 42. The range of
the power stage input voltage (VPIN) is 1 V to 20 V. For instance,
the bias input voltage (VIN) is 5 V, VPIN can be as low as 1 V or as
Rev. 0 | Page 24 of 32
ADP1850
PCB LAYOUT GUIDELINES
In any switching converter, there are some circuit paths that
carry high dI/dt, which can create spikes and noise. Some
circuit paths are sensitive to noise, while other circuits carry
high dc current and can produce significant IR voltage drops.
The key to proper PCB layout of a switching converter is to
identify these critical paths and arrange the components and
the copper area accordingly. When designing PCB layouts,
be sure to keep high current loops small. In addition, keep
compensation and feedback components away from the switch
nodes and their associated components.
VIN
ADP1850
Part of the ADP1850 architecture is sensing the current across
the low-side FET between the SWx and PGNDx pins. The
switching GND currents of one channel creates noise and
can be picked up by the other channel. It is essential to have
Kelvin sensing connection between SWx and the drain of the
respective low-side MOSFET, and between PGNDx and the
source of the respective low-side MOSFET, as illustrated in
Figure 43. Place these Kelvin connections very close to the
FETs to achieve accurate current sensing. Figure 43 illustrates
the proper connection technique for the SW1/SW2, PGND1/
PGND2, and PGND plane.
CDECOUPLE1
DL1 21
M2
VOUT1
CIN1
KELVIN
CONNECTIONS
DL2 20
CDECOUPLE2
PGND2 19
M4
SW2 17
DH2 18
COUT1
AGND
PLANE
PGND1 22
MOSFETS, INPUT BULK CAPACITOR, AND BYPASS
CAPACITOR
HIGH CURRENT AND CURRENT SENSE PATHS
L1
SW1 24
The following is a list of recommended layout practices for the
synchronous buck controller, arranged by decreasing order of
importance.
The current waveform in the top and bottom FETs is a pulse
with very high dI/dt; therefore, the path to, through, and from
each individual FET should be as short as possible, and the two
paths should be commoned as much as possible. In designs that
use a pair of D-Pak, or a pair of SO-8 FETs, on one side of the
PCB, it is best to counter-rotate the two so that the switch node
is on one side of the pair. This allows the high-side FET’s drain
to be bypassed to the low-side FET’s source with a suitable
ceramic bypass capacitor placed as close as possible to the FETs.
Close proximity of the bypass capacitor minimizes the
inductance around the loop through the FETs and capacitor.
The recommended bypass ceramic capacitor values range from
1 µF to 22 µF, depending on the output current. The ceramic
bypass capacitor is usually connected to a larger value bulk filter
capacitor and should be grounded to the PGNDx plane.
M1
PGND
PLANE
CIN2
COUT2
L2
VOUT2
M3
VIN
09440-043
DH1 23
Figure 43. Grounding Technique for Two Channels
SIGNAL PATHS
The negative terminals of VIN bypass, compensation
components, soft start capacitor, and the bottom end of the
output feedback divider resistors should be tied to a small
AGND plane. These connections should attach from their
respective pins to the AGND plane and should be as short as
possible. No high current or high dI/dt signals should be
connected to this AGND plane. The AGND area should be
connected through one wide trace to the negative terminal of
the output filter capacitors.
PGND PLANE
The PGNDx pin handles a high dI/dt gate drive current returning
from the source of the low side MOSFET. The voltage at this pin
also establishes the 0 V reference for the overcurrent limit
protection function and the ILIMx pin. A PGND plane should
connect the PGNDx pin and the VDL bypass capacitor, 1 µF,
through a wide and direct path to the source of the low side
MOSFET. The placement of CIN is critical for controlling
ground bounce. The negative terminal of CIN must be placed
very close to the source of the low-side MOSFET.
FEEDBACK AND CURRENT LIMIT SENSE PATHS
Avoid long traces or large copper areas at the FBx and ILIMx
pins, which are low-level signal inputs that are sensitive to
capacitive and inductive noise pickup. It is best to position
any series resistors and capacitors as close as possible to these
pins. Avoid running these traces close and/or parallel to high
dI/dt traces.
Rev. 0 | Page 25 of 32
ADP1850
SWITCH NODE
The switch node is the noisiest place in the switcher circuit with
large ac and dc voltages and currents. This node should be wide
to minimize resistive voltage drop. To minimize capacitively
coupled noise, the total area should be small. Place the FETs
and inductor close together on a small copper plane to minimize
series resistance and keep the copper area small.
GATE DRIVER PATHS
Gate drive traces (DH and DL) handle high dI/dt and tend to
produce noise and ringing. They should be as short and direct
as possible. If vias are needed, it is best to use two relatively
large ones in parallel to reduce the peak current density and the
current in each via. If the overall PCB layout is less than
optimal, slowing down the gate drive slightly can be helpful to
reduce noise and ringing. It is occasionally helpful to place
small value resistors, such as between 2 Ω and 4 Ω, on the DHx
and DLx pins. These can be populated with 0 Ω resistors if
resistance is not needed. Note that the added gate resistance
increases the switching rise and fall times, as well as increasing
switching power loss in the MOSFET.
OUTPUT CAPACITORS
The negative terminal of the output filter capacitors should be
tied close to the source of the low side FET. Doing this helps to
minimize voltage differences between AGND and PGNDx.
Rev. 0 | Page 26 of 32
ADP1850
TYPICAL OPERATING CIRCUITS
330pF
42.2kΩ
47pF
VIN = 10V TO 18V
M1
CIN
45.3kΩ
187kΩ
22pF
CIN1
100nF
VCCO
L1
2.1kΩ
2Ω
2
SYNC
3
VIN
4
VCCO
27
26
25
BST1
RAMP1
28
ILIM1
29
SS1
EN1
30
PGOOD1
1
31
FB1
TRK1
32
COMP1
10kΩ
0.1µF
COUT11
COUT12
VOUT1
3.3V
14A
M2
SW1 24
DH1 23
1µF
22kΩ
PGND1 22
1µF
DL1 21
1µF 2Ω
ADP1850
5
VDL
6
AGND
PGND2 19
7
FREQ
DH2
18
8
EN2
SW2 17
FB2
COMP2
RAMP2
SS2
PGOOD2
ILIM2
BST2
10
11
12
13
14
15
16
187kΩ
TRK2
DL2 20
9
VCCO
M3
CIN2
2.1kΩ
L2
M4 COUT21
0.1µF
COUT22
VOUT2
1.8V
14A
100nF
22pF
23.2kΩ
22kΩ
TO
VIN
47pF
10kΩ
20kΩ
fSW = 600kHz
CIN: 150µF/20V, OS-CON, 20SEP150M, SANYO
L1, L2: 1.2µH, WURTH ELEKTRONIK, 744325120
M1, M3: BSC080N03LS
M2, M4: BSC030N03LS
CIN1, CIN2: 10µF/X7R/25V/1210 × 2, GRM32DR71E106KA12, MURATA
COUT11, COUT21: 330µF/6.3V/POSCAP × 2, 6TPF330M9L, SANYO
COUT12, COUT22: 22µF/X5R/0805/6.3V × 3, GRM21BR60J226ME39, MURATA
Figure 44. Typical 14 A Operating Circuit
Rev. 0 | Page 27 of 32
09440-044
560pF
VIN
ADP1850
560pF
28kΩ
33pF
VIN = 10V TO 20V
M1A
73.2kΩ
150kΩ
CIN1
100nF
VCCO
L1
2.8kΩ
2Ω
VCCO
25
ILIM1
4
26
BST1
VIN
27
PGOOD1
3
28
SS1
SYNC
29
RAMP1
2
30
COMP1
EN1
31
FB1
1
32
TRK1
10kΩ
0.1µF
COUT1
VOUT1
5V
5A
M1B
SW1 24
DH1 23
1µF
22kΩ
PGND1 22
1µF
DL1 21
1µF 2Ω
ADP1850
5
VDL
6
AGND
PGND2 19
7
FREQ
DH2 18
8
EN2
SW2 17
VIN
DL2 20
M2A
CIN2
FB2
COMP2
RAMP2
SS2
PGOOD2
ILIM2
BST2
9
10
11
12
13
14
15
16
150kΩ
TRK2
84.5kΩ
VCCO
10kΩ
10kΩ
COUT2
100nF
22kΩ
TO
VIN
100pF
M2B
0.1µF
VOUT2
1.8V
5A
20kΩ
fSW = 750kHz, PULSE SKIP MODE
L1: 2µH, WURTH ELEKTRONIK, 744310200
L2: 1.15µH, WURTH ELEKTRONIK, 744310115
CIN1, CIN2: 10µF/X5R/16V/1206 × 2, GRM31CR61C106KA88, MURATA
M1, M2: SI944DY OR BSON03MD
COUT1, COUT2: 22µF/XR5/1210/6.3V × 3, GRM32DR60J226KA01, MURATA
Figure 45. Typical Low Current Operating Circuit
Rev. 0 | Page 28 of 32
09440-045
1.5nF
L2
2.8kΩ
ADP1850
1.8nF
5.34kΩ
33pF
VIN = 3V TO 5.5V
M1
7.5kΩ
20kΩ
CIN1
100nF
VCCO
L1
4.99kΩ
5Ω
3
VIN
4
VCCO
RAMP1
27
26
25
BST1
SYNC
28
ILIM1
2
29
SS1
EN1
30
PGOOD1
1
31
FB1
TRK1
32
COMP1
10kΩ
0.1µF
COUT1
VOUT1
1.05V
1.8A
M2
SW1 24
DH1 23
1µF
47kΩ
PGND1 22
1µF
DL1 21
1µF
ADP1850
5
VDL
6
AGND
PGND2 19
7
FREQ
DH2 18
8
EN2
SW2 17
VIN
DL2 20
M3
CIN2
FB2
COMP2
RAMP2
SS2
PGOOD2
ILIM2
BST2
9
10
11
12
13
14
15
16
8.66kΩ
10kΩ
fSW = 800kHz, PULSE SKIP MODE
L1, L2: 1µH, TOKO D62LCB1R0M
M1, M2, M3, M4: SI2302ADS, SOT23
M4
0.1µF
COUT2
VOUT2
1.8V
1.8A
100nF
47kΩ
TO
VIN
33pF
L2
4.99kΩ
20kΩ
CIN1, CIN2: 4.7µF/X5R/16V/0805 × 2, GRM219R60J475KE19, MURATA
COUT1, COUT2: 22µF/XR5/0805/6.3V, GRM21BR60J226ME39, MURATA
Figure 46. Typical Low Current Application with VIN < 5.5 V
Rev. 0 | Page 29 of 32
09440-046
VCCO
1nF
20kΩ
TRK2
78.7kΩ
ADP1850
3.3nF
8.87kΩ
VIN = 10V TO 14V
180pF
CIN
8.3kΩ
M1
CIN11
22pF
137kΩ
M2
CIN12
100nF
TO
VCCO
10kΩ
L1
2Ω
VCCO
BST1
4
25
ILIM1
VIN
26
PGOOD1
3
27
SS1
SYNC
28
RAMP1
2
29
COMP1
EN1
30
FB1
1
31
TRK1
1.74kΩ
32
0.1µF
COUT11
M3
COUT12
M4
SW1 24
DH1 23
22kΩ
1µF
PGND1 22
1µF
DL1 21
ADP1850
SW2 17
9
10
11
12
13
14
15
16
CIN21
TO
VCCO
TO
FB1
TO TO
VIN SS1
M5
M6
M7
M8
22pF
CIN22
L2
1.74kΩ
0.1µF
137kΩ
BST2
EN2
ILIM2
8
PGOOD2
DH2 18
SS2
FREQ
RAMP2
PGND2 19
COMP2
AGND
7
FB2
6
TRK2
VDL
VOUT1
1.09V
50A
VIN
DL2 20
5
COUT21
COUT22
22kΩ
TO
COMP1
fSW = 300kHz
CIN = 180µF/16V × 4, 16SEP180M, OS-CON, SANYO
M1, M2, M5, M6: BSC080N03IS
M3, M4, M7, M8: BSC030N03LS
L1, L2: SER1408-301, 300nH, COILCRAFT; OR 744355147, 0.4µH, WURTH ELECTRONIK
CIN11, CIN12, CIN21, CIN22: 10µF/X7R/25V/1210, MURATA
COUT11, COUT21, 2SEPC560MZ × 3, 560µF, OSCON, SANYO
COUT12, COUT22: GRM31CR60J476ME19 × 2, 47µV/1206/6.3V, MURATA
Figure 47. Dual-Phase Circuit, 50 A Output
Rev. 0 | Page 30 of 32
09440-047
2Ω
1µF
ADP1850
OUTLINE DIMENSIONS
0.30
0.25
0.18
32
25
0.50
BSC
0.80
0.75
0.70
0.50
0.40
0.30
8
16
0.05 MAX
0.02 NOM
COPLANARITY
0.08
0.20 REF
SEATING
PLANE
3.65
3.50 SQ
3.45
EXPOSED
PAD
17
TOP VIEW
PIN 1
INDICATOR
1
24
9
BOTTOM VIEW
0.25 MIN
FOR PROPER CONNECTION OF
THE EXPOSED PAD, REFER TO
THE PIN CONFIGURATION AND
FUNCTION DESCRIPTIONS
SECTION OF THIS DATA SHEET.
COMPLIANT TO JEDEC STANDARDS MO-220-WHHD.
112408-A
PIN 1
INDICATOR
5.10
5.00 SQ
4.90
Figure 48. 32-Lead Lead Frame Chip Scale Package [LFCSP_WQ]
5 mm × 5 mm Body, Very Very Thin Quad
(CP-32-11)
Dimensions shown in millimeters
ORDERING GUIDE
Model1
ADP1850ACPZ-R7
ADP1850SP-EVALZ
ADP1850DP-EVALZ
1
Temperature Range
−40°C to +85°C
Package Description
32-Lead Lead Frame Chip Scale Package [LFCSP_WQ]
Evaluation Board in Single-Phase Mode with 14 A Output
Evaluation Board in Dual-Phase Mode with 50 A Output
Z = RoHS Compliant Part.
Rev. 0 | Page 31 of 32
Package Option
CP-32-11
ADP1850
NOTES
©2010 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D09440-0-11/10(0)
Rev. 0 | Page 32 of 32