ONSEMI ADP3290

ADP3290
8-Bit, Programmable
2- to 4-Phase Synchronous
Buck Controller
The ADP3290 is a highly efficient, multi−phase, synchronous buck
switching regulator controller optimized for converting a 12 V main
supply voltage into the core supply voltage of high performance Intel
processors. It uses an internal 8−bit DAC to read a Voltage
Identification (VID) code directly from the processor, to set the output
voltage between 0.5 V and 1.6 V.
This device uses a multi−mode control architecture to drive the
logic−level PWM outputs. The switching frequency can be
programmed according to VR size and efficiency. The chip can
provide 2−, 3− or 4−phase operation, allowing for the construction of
up to four complementary buck switching stages.
The ADP3290 also includes programmable no load offset and load
line slope setting function that adjusts the output voltage as a function
of the load current, optimally positioning it for a system transient. The
ADP3290 also provides accurate and reliable short−circuit protection,
adjustable current limit, and a delayed power−good output that
accommodates On−The−Fly (OTF) output voltage changes requested
by the CPU.
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MARKING
DIAGRAM
Package Name
LFCSP40
CASE Number
932AC
ADP3290
#_YYYYYY
ZZZZZZZZ
CCCCC
ADP3290
#
YY
ZZ
CC
= Device Code
= Pb−Free Package
= Date Code
= Assembly Lot Number
= Country of Origin
Features
PIN ASSIGNMENT
•
•
•
Typical Applications
• Desktop PC Power Supplies for:
♦
♦
Next Generation Intel® Processors
VRM Modules
© Semiconductor Components Industries, LLC, 2009
July, 2009 − Rev. 2
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
ADP3290
TOP VIEW
PWM1
PWM2
PWM3
PWM4
ODN
SW1
SW2
SW3
SW4
IMON
11
12
13
14
15
16
17
18
19
20
•
•
•
PIN 1
INDICATOR
EN 1
PWRGD 2
FBRTN 3
FB 4
COMP 5
SS 6
DELAY 7
TRDET 8
VRHOT 9
TTSNS 10
ILIM
RT
RAMP
LLINE
CSREF
CSSUM
CSCOMP
GND
OD
IREF
•
Drivers
Fast−Enhanced PWM FlexModet for Excellent Load Transient
Performance
TRDET to Improve Load Release
Active Current Balancing Between All Output Phases
Built−In Power−Good/Crowbar Blanking Supports Dynamic
VID Code Changes
Digitally Programmable 0.5 V to 1.6 V Output Supports
VR11.1 Specification
Programmable Overcurrent Protection with Programmable
Latchoff Delay
This is a Pb−Free Device
PSI
VID0
VID1
VID2
VID3
VID4
VID5
VID6
VID7
VCC
• Selectable 2−, 3−, or 4−Phase Operation at Up to 1 MHz Per Phase
• ±7 mV Worse−Case Differential Sensing Error
• Logic−Level PWM Outputs for Interface to External High Power
ORDERING INFORMATION
Device
Package
Shipping†
ADP3290JCPZ−RL
LFCSP40
(Pb−Free)
2500/Tape & Reel
†For information on tape and reel specifications,
including part orientation and tape sizes, please
refer to our Tape and Reel Packaging Specifications
Brochure, BRD8011/D.
1
Publication Order Number:
ADP3290/D
ADP3290
VCC
RT
RAMP
31
12
13
SHUNT
REGULATOR
OSCILLATOR
UVLO
SHUTDOWN
+
GND 18
CMP
+
1
DAC
+ 150mV
PWRGD
VRHOT
CSREF
+
DAC
– 350mV
–
9
7
TRDET
8
+
CMP
–
+
CMP
–
30
PWM1
RESET
29
PWM2
28
PWM3
27
PWM4
RESET
2/3/4−PHASE
DRIVER LOGIC
RESET
CURRENT
LIMIT
CROWBAR
THERMAL
THROTTLING
CONTROL
ILIM 11
DELAY
–
DELAY
2
TTSNS 10
–
+
+
CMP
OD
CURRENT
MEASUREMENT
AND LIMIT
–
+
EN
–
CURRENT BALANCING
CIRCUIT
–
800mV
19
SET EN
RESET
TRDET
GENERATOR
26
ODN
40
PSI
25
SW1
24
SW2
23
SW3
22
SW4
17
CSCOMP
15
CSREF
16
CSSUM
21
IMON
4
FB
14
LLINE
6
SS
IREF 20
+
–
5
+
COMP
PRECISION
REFERENCE
–
FBRTN
3
BOOT
VOLTAGE
AND
SOFT START
CONTROL
VID DAC
ADP3290
32
33
34
35
36
37
38
39
VID7 VID6 VID5 VID4 VID3 VID2 VID1 VID0
Figure 1. Simplified Block Diagram
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2
3
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Figure 2. Application Schematic − 4−Phase Operation
C8 R3
1nF 1
1% C
TRDT
560pF
C7
1nF
RREF
100k
1%
C22
1F
D5
1N4148
C18
1F
D4
1N4148
18nF
C17
C21
18nF
Q9
Q7
Q5
Q15
Q13
Q11
IPD09N03LA
27nF
U5
C23
ADP3120A
1
8
BST DRVH
2
7
IN
SW
3
6
OD PGND
4
VCC DRVL
5
2.2
R7
27nF
U4
ADP3120A C19
1
8
BST DRVH
7
2
IN
SW
6
3
OD PGND
4
VCC DRVL
5
2.2
R6
27nF
U3
C15
ADP3120A
1
8
BST DRVH
2
7
IN
SW
6
3
OD PGND
4
VCC DRVL
5
L2
Q8
Q12
Q16
L5
CE1
102
C3
4.7F
102
C9
4.7F
102
C6
4.7F
RTH2
100k
5%
NTC
BSC100N03LS
220nH/0.57m
4.7F C2
C1 4.7F
L4
220nH/0.57m
BSC100N03LS
4.7F C8
C7 4.7F
L3
BSC100N03LS
220nH/0.57m
4.7F C5
C4 4.7F
IPD09N03LA
RT
113k
1%
RSW41
RSW31
RSW21
RSW11
RPH4
68.1k
35.7k 82.5k 68.1k RPH2
1%
1%
CCS2 RCS1 RCS2
RPH1
1%
RPH3
1.8nF
1.5nF
1%
68.1k
68.1k
5% NPO
CCS1
IRFE
OD
GND
CSCOMP
CSSUM
CSREF
LLINE
RAMP
RT
ILIM
RLIM
7.5k
1%
CIMON
0.1F
C14
1F
C13
18nF
Q4
220nH/0.57m
C3
4.7F
CIN3
680F
CE8
VSS(SENSE)
VCC(SENSE)
VCC(CORE) RTN
22Fx18
MLCC
IN SOCKET
560F/4V/4Vx8
SANYO SEPC SERIES V
CC(CORE)
5m Each
0.5V TO 1.6V
+
+
102
115A TDC, 130A PK
C2
4.7F
CIN2
680F
BSC100N03LS
IPD09N03LA
RTRDT2
RTRDT1 4.99k
69.8k 1%
PWM1
EN
PWM2
PWRGD
PWM3
FBRTN
U1
PWM4
FB
ODN
COMP ADP3290
SS
FROM CPU SW1
SW2
DELAY
SW3
TRDET
SW4
VRHOT
IMON
TTSNS
4.99
1%
RIMON
VID0
VID1
VID2
VID3
VID4
VID5
VID6
VID7
VCC
PSI#
CSS
120pF RA
28.0k
8.2nF
C6
CDLY
18nF
RTH1 0.1F
100k
5%
NTC
3.3pF
CA CFB
PROCHOT
1
40
C4
1F
R5
2.2
Q3
Q1
C1
4.7F
IPD09N03LA
RB
1.21k
CB
120pF
1. For a Description of Optional RSW Resistors,
See the Theory of Operation Section.
2. Connect Near Each Inductor.
IPD09N03LA
POWER GOOD
C5
1nF
C3
100F
(C3 OPTIONAL)
D3
1N4148
C10
1F
D2
1N4148
27nF
U2
C11
ADP3120A
8
1
BST DRVH
2
7
IN
SW
3
6
OD PGND
4
VCC DRVL
5
R4
2.2
CIN1
680F
IPD09N03LA
R1
10
D1
1N4148
2700F/16V/3.3 Ax2
SANYO MV−WX SERIES
+ +
C1
C2
C9
18nF
IPD09N03LA
VTT I/O
VIN
12V
VIN
RTN
L1
370nH
18A
ADP3290
IPD09N03LA
ADP3290
ABSOLUTE MAXIMUM RATINGS
Parameter
Symbol
Value
Unit
VCC
−0.3 to +6
V
VFBRTN
−0.3 to +0.3
V
−0.3 to VCC +0.3
V
SW1 to SW4
−5 to +25
V
SW1 to SW4 <200 ns
−10 to +25
V
−0.3 to VCC +0.3
V
Supply Voltage
FBRTN
PWM3 to PWM4, Rampadj
All other Inputs and Outputs
Storage Temperature Range
Tstg
−65 to +150
°C
Operating Ambient Temperature Range
TA
0 to 85
°C
Operating Junction Temperature
TJ
125
°C
Thermal Impedance
JA
100
°C/W
Lead Temperature
Soldering (10 sec)
Infrared (15 sec)
300
260
°C
Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the
Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect
device reliability.
NOTE: This device is ESD sensitive. Use standard ESD precautions when handling.
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4
ADP3290
PIN ASSIGNMENT
Pin No.
Mnemonic
Description
1
EN
Power Supply Enable Input. Pulling this pin to GND disables the PWM outputs and pulls the PWRGD output low.
2
PWRGD
Power−Good Output. Open−drain output that signals when the output voltage is outside of the proper operating range.
3
FBRTN
Feedback Return. VID DAC and error amplifier input for remote sensing of the output voltage.
4
FB
5
COMP
6
SS
7
DELAY
Delay Timer Setting Input. An external capacitor connected between this pin and GND sets the overcurrent
latchoff delay time, boot voltage hold time, EN delay time, and PWRGD delay time.
8
TRDET
Transient detection output. This pin is pulled low when a load release transient is detected.
9
VRHOT
VR Hot Output. Active high open−drain output that signals when the temperature of the temperature sensor
connected to TTSNS exceeds the programmed VRHOT temperature threshold.
10
TTSNS
VR Hot Thermal Throttling Sense Input. An NTC thermistor between this pin and GND is used to remotely sense
the temperature at the desired thermal monitoring point.
11
ILIM
12
RT
13
RAMP
PWM Ramp Slope Setting Input. An external resistor from the converter input voltage to this pin sets the slope
of the internal PWM ramp.
14
LLINE
Output Load Line Programming Input. This pin can be directly connected to CSCOMP, or it can be connected to
the center point of a resistor divider between CSCOMP and CSREF. Connecting LLINE to CSREF disables
positioning.
15
CSREF
Current Sense Reference Voltage Input. The voltage on this pin is used as the reference for the current sense
amplifier and the power−good and crowbar functions. This pin should be connected to the common point of the
output inductors.
16
CSSUM
Current Sense Summing Node. External resistors from each switch node to this pin sum the inductor currents
together to measure the total output current.
17
CSCOMP
18
GND
19
OD
20
IREF
Current Reference Input. An external resistor from this pin to ground sets the internal reference current used to
generate IFB, IDELAY, ISS, ICL, and ITTSNS.
21
IMON
IMON Total Current Output Pin. A resistor/capacitor from this pin to FBRTN/VSS Sense sets the IMON signal.
22 to 25
SW4 to
SW1
Current Balance Inputs. Inputs for measuring the current level in each phase. The SW pins of unused phases
should be left open.
26
ODN
27 to 30
PWM4 to
PMW1
31
VCC
32 to 39
VID7 to
VID0
40
PSI
NOTE:
Feedback Input. Error amplifier reference for remote sensing of the output voltage. An external resistor between
this pin and the output voltage sets the no−load offset point.
Error Amplifier Output and Compensation Point.
Soft−Start Delay Setting Input. An external capacitor connected between this pin and GND sets the soft−start
ramp−up time. After startup, pin used to control DVID slew−rate.
Current Sense and Limit Pin. Connecting a resistor from this pin to CSCOMP sets the internal current sensing
signal for current limit and IMON.
Frequency Setting Resistor Input. An external resistor connected between this pin and GND sets the PWM
oscillator frequency.
Current Sense Compensation Point. A resistor and capacitor from this pin to CSSUM determines the gain of the
current sense amplifier and the positioning loop response time.
Ground. All internal biasing and the logic output signals of the device are referenced to this ground.
Output Disable Logic Output for phase 1. This pin is actively pulled low when the EN input is low or when VCC is
below its UVLO threshold to signal to the Driver IC that the driver high−side and low−side outputs should go low.
Output Disable Logic output for PSI Operation. This pin is pulled low when PSI is low, otherwise it functions the
same as OD.
Logic−Level PWM Outputs. Each output is connected to the input of an external MOSFET driver such as the
ADP3121. Connecting the PWM4, and/or PWM3 output to VCC causes that phase to turn off, allowing the
ADP3290 to operate as a 2−, 3−, or 4−phase controller.
Supply Voltage for the Device. A 340 resistor should be placed between the 12 V system supply and the VCC
pin. The internal shunt regulator maintains VCC = 5.0 V.
Voltage Identification DAC Inputs. These eight pins are pulled down to GND, providing a Logic 0 if left open.
When in normal operation mode, the DAC output programs the FB regulation voltage from 0.5 V to 1.6 V.
Power State Indicator Input. Pulling this pin low places controller in lower power state operation.
True no connect. Printed circuit board traces are allowable.
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5
ADP3290
ELECTRICAL CHARACTERISTICS (VCC = 12 V, FBRTN = GND, TA = 0°C to 85°C unless otherwise noted) (Note 1)
Parameter
Symbol
Conditions
Min
Typ
Max
Unit
Reference Current
Reference Bias Voltage
VIREF
Reference Bias Current
IIREF
1.5
RIREF = 100 k
14.25
15
V
15.75
A
0
4.4
V
−8.0
−7.0
−0.5
+8.0
+7.0
+0.5
mV
mV
%
1.108
−78.3
V
mV
Error Amplifier
Output Voltage Range (Note 2)
Accuracy
Load Line Positioning Accuracy
VCOMP
VFB
VFB(BOOT)
Relative to nominal DAC output,
Referenced to FBRTN, LLINE = CSREF,
Temperature Range: 0 °C to 60 °C
DAC Code: 0.5 V to 0.99375 V
1.0 V to 1.39375 V
1.4 V to 1.6 V
In startup CSREF - LLINE = 80 mV,
Temperature Range: 0 °C to 60 °C,
DAC = 1.000 V
Differential Non−linearity
Input Bias Current
FBRTN Current
Output Current
Gain Bandwidth Product
1.092
−81.7
1.1
−80
−1.0
IFB
IFB = IIREF
13.5
IFBRTN
ICOMP
GBW(ERR)
Slew Rate
+1.0
LSB
15
16.5
A
125
200
A
FB forced to VOUT - 3%
500
A
COMP = FB
20
MHz
COMP = FB
25
V/s
LLINE Input Voltage Range
VLLINE
Relative to CSREF
−250
+250
mV
LLINE Input Bias Current
ILLINE
Temperature Range: 0 °C to 60 °C
−7.5
+7.5
nA
BOOT Voltage Hold Time
tBOOT
CDELAY = 10 nF
2.0
ms
VID Inputs
Input Low Voltage
VIL(VID)
VID(X)
Input High Voltage
VIH(VID)
VID(X)
Input Current
IIN(VID)
0.3
0.8
V
V
−1.0
A
VID Transition Delay Time (Note 3)
VID code change to FB change
400
ns
No CPU Detection Turn−Off Delay Time
(Note 2)
VID code change to PWM going low
5.0
s
PSI Input
Input Low Voltage
VIL(PSI)
Input High Voltage
VIH(PSI)
Input Current
IIN(PSI)
PSI = HIGH
Assertion time
tast(PSI)
Fsw= 400 kHz, 4−phase, measuring
from PSI falling edge to ODN falling
edge
1.0
3.0
s
tdeast(PSI)
Fsw= 400 kHz, 4−phase, measuring from
PSI falling edge to ODN falling edge
260
760
ns
VIL(TRDET)
ITRDET(sink) = −4 mA
300
mV
4.0
MHz
De−assertion time
0.3
0.8
V
V
1.0
A
TRDET Output
Low Voltage
150
Oscillator
Frequency Range
Frequency Variation
Output Voltage
fOSC
fPHASE
VRT
RAMP Output Voltage
VRAMP
RAMP Input Current Range
IRAMP
0.25
360
200
400
800
440
RT = 130 k to GND
1.9
2.0
2.1
V
RAMP - FB
−50
+50
mV
1.0
200
A
TA = 25 °C, RT = 277 k, 4−phase
TA = 25 °C, RT = 130 k, 4−phase
TA = 25 °C, RT = 57 k, 4−phase
1. All limits at temperature extremes are guaranteed via correction using standard quality control (SQC).
2. Guaranteed by characterization, not tested in production.
3. Guaranteed by design, not tested in production.
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6
kHz
ADP3290
ELECTRICAL CHARACTERISTICS (VCC = 12 V, FBRTN = GND, TA = 0°C to 85°C unless otherwise noted) (Note 1)
Parameter
Symbol
Conditions
Min
VOS(CSA)
CSSUM - CSREF, CSREF = 0.8V ~1.6V,
Temperature Range: 0 °C to 60 °C
−0.5
Temperature Range: 0 °C to 60 °C
−7.5
Typ
Max
Unit
+0.5
mV
Current Sense Amplifier
Offset Voltage
Input Bias Current
Gain Bandwidth Product
IBIAS(CSSUM)
GBW(CSA)
CSSUM = CSCOMP
Slew Rate
CCSCOMP = 10 pF
Input Common−Mode Range
CSSUM and CSREF
Output Voltage Range
Output Current
Current Limit Latchoff Delay Time
+7.5
10
10
0
tOC(DELAY)
CDELAY = 10 nF
V/s
3.5
0.05
ICSCOMP
nA
MHz
3.5
V
V
500
A
8.0
ms
Current Balance Amplifier
Common−Mode Range (Note 3)
VSW(X)CM
−600
+200
mV
Input Resistance
RSW(X)
SW(X) = 0 V
10
17
26
k
Input Current
ISW(X)
SW(X) = 0 V
8.0
12
20
A
ISW(X)
SW(X) = 0 V
−4.0
+4.0
%
1.0
1.15
V
Input Current Matching
IMON Output
Clamp Voltage
Current Gain
(IMONCURRENT) / (ILIMITCURRENT),
RILIM = RIMON = 8.0 k, PSI = High,
Temperature Range: 0 °C to 60 °C
9.5
10
Output Current
10.5
800
Offset
VCSREF − VILIMIT
1.2
A
mV
Current Limit Comparator
Current Limit Threshold Current
ICL
4/3 x IIREF, PSI = High
17.7
20
22.3
A
Delay Timer
Normal Mode Output Current
IDELAY
Output Current in Current Limit
IDELAY(CL)
Threshold Voltage
VDELAY(TH)
IDELAY = IIREF
12
15
18
A
IDELAY(CL) = 0.25 x IIREF
3.0
3.75
4.5
A
1.6
1.7
1.8
V
13.5
17.5
21.5
Soft−Start
Output Current
ISS
During startup
Soft Start slew rate
dv/dt
Css = 8.2 nF
2.0
mV/s
DVID slew rate
dv/dt
Css = 8.2 nF
10
mV/s
A
Enable Input
Input Low Voltage
VIL(EN)
Input High Voltage
VIH(EN)
Input Current
IIN(EN)
Delay Time
300
800
mV
mV
1.0
A
ms
tDELAY(EN)
EN > 800 mV, CDELAY = 10 nF
2.0
Output Low Voltage
VOL(OD)
VOL(ODN)
IOD(SINK) = −400 A
IODN(SINK) = −400 A
160
Output High Voltage
VOH(OD)
VOH(ODN)
IOD(SOURCE) = 400 A,
IODN (SOURCE) = 400 A
OD and ODN Output
4.0
OD Pulldown Resistor
500
mV
5.0
V
60
k
Thermal Throttling Control
TTSNS Voltage Range
Internally limited
TTSNS Bias Current
0
−133
1. All limits at temperature extremes are guaranteed via correction using standard quality control (SQC).
2. Guaranteed by characterization, not tested in production.
3. Guaranteed by design, not tested in production.
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7
−123
5.0
V
−113
A
ADP3290
ELECTRICAL CHARACTERISTICS (VCC = 12 V, FBRTN = GND, TA = 0°C to 85°C unless otherwise noted) (Note 1)
Parameter
Symbol
Conditions
Min
Typ
Max
Unit
715
760
805
mV
Thermal Throttling Control cont.
TTSNS VRHOT Threshold Voltage
TTSNS Hysteresis
50
VRHOT Output Low Voltage
VOL(VRHOT)
IVRHOT(SINK) = −4 mA, TTSNS = 5.0 V
mV
150
300
mV
Power−Good Comparator
Undervoltage Threshold
VPWRGD(UV)
Relative to nominal DAC output
−400
−350
−300
mV
Overvoltage Threshold
VPWRGD(OV)
Relative to nominal DAC output
100
150
200
mV
Output Low Voltage
VOL(PWRGD)
IPWRGD(SINK) = −4 mA
150
300
mV
CDELAY = 10 nF
2.0
Power−Good Delay Time During
Soft−Start
VID Code Changing
100
VID Code Static
Crowbar Trip Point
VCB(CSREF)
Crowbar Reset Threshold
Crowbar Delay Time VID Code
Changing
tCROWBAR
ms
250
s
200
ns
Relative to nominal DAC output
100
150
200
mV
Relative to FBRTN
305
360
415
mV
Overvoltage to PWM going low
100
250
s
400
ns
VID Code Static
PWM OUTPUTS Output Low Voltage
VOL(PWM)
IPWM(SINK) = −400 A
Output High Voltage
VOH(PWM)
IPWM(SOURCE) = 400 A
4.0
160
5.0
4.65
5.0
500
mV
V
Supply
VCC
VCC
VSYSTEM = 12 V, RSHUNT = 340 DC Supply Current
IVCC
VSYSTEM = 13.2 V, RSHUNT = 340 Shunt Turn−On Current
Shunt Turn−On Threshold Voltage
Shunt Turn−Off Voltage
VSYSTEM
5.55
V
25
mA
6.5
mA
VSYSTEM rising
6
V
VSYSTEM falling
4.1
V
1. All limits at temperature extremes are guaranteed via correction using standard quality control (SQC).
2. Guaranteed by characterization, not tested in production.
3. Guaranteed by design, not tested in production.
TYPICAL CHARACTERISTICS
5000
OSCILLATOR FREQUENCY (kHz)
5000
4500
4000
3500
3000
2500
2000
1500
1000
500
0
0
4500
4000
3500
3000
2500
2000
1500
1000
500
5.8
100 200 300 400 500 600 700 800 900 1000
6.0
6.2
6.4
6.6
RT (k)
SUPPLY CURRENT (A)
Figure 3. Oscillator Frequency vs. RT
Figure 4. Oscillator Frequency vs. Supply Current
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0
ADP3290
Theory of Operation
12V
SUPPLY
The ADP3290 combines a multi−mode, fixed frequency
PWM control with multiphase logic outputs for use in 2−, 3−,
or 4−phase synchronous buck CPU core supply power
converters. The internal VID DAC is designed to interface with
Intel 8−bit VRD/VRM 11.1 and compatible CPUs. Multiphase
operation is important for producing the high currents and low
voltages demanded by today’s microprocessors. Handling the
high currents in a single−phase converter places high thermal
demands on the components in the system, such as the
inductors and MOSFETs.
The multi−mode control of the ADP3290 ensures a stable,
high performance topology for the following:
• Balancing currents and thermals between phases for
both static and dynamic operation
• High speed response at the lowest possible switching
frequency and output decoupling
• FEPWM and TRDET functions for improved load step
and load release transient response
• Minimizing thermal switching losses by using lower
frequency operation
• Tight load line regulation and accuracy
• Reduced output ripple due to multiphase cancellation
• PC board layout noise immunity
• Ease of use and design due to independent component
selection
• Flexibility in operation for tailoring design to low cost
or high performance
VTT I/O
(ADP3290 EN)
UVLO
THRESHOLD
0.8V
VDELAY(TH)
(1.7V)
DELAY
1.0V
SS
VBOOT
(1.1V)
VVID
TD3
VCC_CORE
VBOOT
(1.1V)
TD1
VVID
TD4
TD2
VR READY
(ADP3290 PWRGD)
TD5
50ms
CPU
VID INPUTS
VID INVALID
VID VALID
Figure 5. System Startup Sequence
Phase Detection Sequence
During startup, the number of operational phases and their
phase relationship is determined by the internal circuitry
monitoring the PWM outputs. Normally, the ADP3290
operates as a 4−phase PWM controller. Connecting
PWM4 pin to VCC programs a 3−phase operation. For
2−phase operation, connect PWM4 and PWM3 pins to VCC.
Prior to soft−start, while EN is low, the PWM3 and PWM4
pins sink approximately 100 A. An internal comparator
checks the voltage of each pin versus a threshold of 3.15 V.
If the pin is tied to VCC, its voltage is above the threshold.
Otherwise, an internal current sink pulls the pin to GND,
which is below the threshold. PWM1 and PWM2 are low
during the phase detection interval that occurs during the
first four clock cycles of the internal oscillator. After this
time, if the remaining PWM outputs are not pulled to VCC,
the 100 A current sink is removed, and they function as
normal PWM outputs. If they are pulled to VCC, the 100 A
current source is removed, and the outputs are driven into a
high impedance state.
The PWM outputs are logic−level devices intended for
driving fast response external gate drivers such as the
ADP3121 and ADP3122. Because each phase is monitored
independently, operation approaching 100% duty cycle is
possible. In addition, more than one PWM output can be on
at the same time to allow overlapping phases.
Startup Sequence
The ADP3290 follows the VR11.1 startup sequence
shown in Figure 5. After both the EN and UVLO conditions
are met, the DELAY pin goes through one cycle (TD1).
After this cycle, the internal oscillator is enabled. The first
four clock cycles are blanked from the PWM outputs and
used for phase detection as explained in the Phase Detection
Sequence section. Then, the soft−start ramp is enabled
(TD2), and the output comes up to the boot voltage of 1.1 V.
The boot hold time is determined by the DELAY pin as
it goes through a third cycle (TD3). During TD3, the
processor VID pins settle to the required VID code. When
TD3 is over, the ADP3290 reads the VID inputs and
soft−starts either up or down to the final VID voltage
(TD4).When TD4 and the PWRGD masking time (equal to
VID OTF masking) is completed, a third ramp on the
DELAY pin sets the PWRGD blanking (TD5).
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ADP3290
Master Clock Frequency
be used to set the load line required by the microprocessor.
The current information is then given as CSREF − LLINE.
This difference signal is used internally to offset the
VID DAC for voltage positioning. The difference between
CSREF and CSCOMP is then used as a differential input for
the current limit comparator. This allows the load line to be
set independently of the current limit threshold. In the event
that the current limit threshold and load line are not
independent, the resistor divider between CSREF and
CSCOMP can be removed and the CSCOMP pin can be
directly connected to LLINE. To disable voltage positioning
entirely (that is, no load line) connect LLINE to CSREF.
To provide the best accuracy for sensing current, the CSA
is designed to have a low offset input voltage. Also, the
sensing gain is determined by external resistors to make it
extremely accurate.
The clock frequency of the ADP3290 is set with an
external resistor connected from the RT pin to ground. The
frequency follows the graph in Figure 3. To determine the
frequency per phase, the clock is divided by the number of
phases in use. If all phases are in use, divide by 4. If PWM4
is tied to VCC, divide by 3. If PWM4 and PWM3 are tied to
VCC, divide by 2.
NOTE: Single−Phase operation is also possible; contact
ON Semiconductor for more details.
Output Voltage Differential Sensing
The ADP3290 combines differential sensing with a high
accuracy VID DAC and reference, and a low offset error
amplifier. This maintains a worst−case specification of
±7.0 mV differential sensing error over its full operating
output voltage and with tighter accuracy over a 0 °C to 60 °C
temperature range. The output voltage is sensed between the
FB pin and FBRTN pin. FB is connected through a resistor
to the regulation point, usually the remote sense pin of the
microprocessor. FBRTN is connected directly to the remote
sense ground point. The internal VID DAC and precision
reference are referenced to FBRTN, which has a minimal
current of 125 A to allow accurate remote sensing. The
internal error amplifier compares the output of the DAC
to the FB pin to regulate the output voltage.
Active Impedance Control Mode
For controlling the dynamic output voltage droop as a
function of output current, a signal proportional to the total
output current at the LLINE pin can be scaled to equal the
regulator droop impedance multiplied by the output current.
This droop voltage is then used to set the input control
voltage to the system. The droop voltage is subtracted from
the DAC reference input voltage to tell the error amplifier
where the output voltage should be. This allows enhanced
feed−forward response.
Output Current Sensing
The ADP3290 provides a dedicated current sense
amplifier (CSA) to monitor the total output current for
proper voltage positioning versus load current, for the IMON
output, and for current limit detection. Sensing the load
current at the output gives the total real−time current being
delivered to the load, which is an inherently more accurate
method than peak current detection or sampling the current
across a sense element such as the low−side MOSFET. This
amplifier can be configured several ways, depending on
the objectives of the system, as follows:
• Output inductor DCR sensing without a thermistor for
lowest cost.
• Output inductor DCR sensing with a thermistor for
improved accuracy with tracking of inductor
temperature.
• Sense resistors for highest accuracy measurements.
The positive input of the CSA is connected to the
CSREF pin, which is connected to the average output
voltage. The inputs to the amplifier are summed together
through resistors from the sensing element, such as the
switch node side of the output inductors, to the inverting
input CSSUM. The feedback resistor between CSCOMP
and CSSUM sets the gain of the amplifier and a filter
capacitor is placed in parallel with this resistor. The gain of
the amplifier is programmable by adjusting the input
summing resistor.
An additional resistor divider connected between CSREF
and CSCOMP (with the midpoint connected to LLINE) can
Current Control Mode and Thermal Balance
The ADP3290 has individual inputs (SW1 to SW4) for
each phase that are used for monitoring the current of each
phase. This information is combined with an internal ramp
to create a current balancing feedback system that has been
optimized for initial current balance accuracy and dynamic
thermal balancing during operation. This current balance
information is independent of the average output current
information used for positioning as described in the Load
Line Setting section.
The magnitude of the internal ramp can be set to optimize
the transient response of the system. It also monitors the supply
voltage for feed−forward control for changes in the supply. A
resistor connected from the power input voltage to the
RAMP pin determines the slope of the internal PWM ramp.
External resistors can be placed in series with individual
phases to create an intentional current imbalance if desired,
such as when one phase has better cooling and can support
higher currents. Resistor RSW1 through RSW4 can be used
for adjusting thermal balance. It is best to have the ability to
add these resistors during the initial design, therefore, ensure
that placeholders are provided in the layout.
To increase the current in any given phase, enlarge RSW
for that phase (make RSW = 0 for the hottest phase and do not
change it during balancing). Increasing RSW by 1 k can
make an increase in phase current. Increase each RSW value
by small amounts to achieve balance, starting with the
coolest phase first.
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ADP3290
Voltage Control Mode
GND, and the capacitor is charged up to the 1.1 V boot
voltage by the SS amplifier, which has a limited output
current of 15 A. The voltage at the FB pin follows the
ramping voltage on the SS pin, limiting the inrush current
during startup. The soft−start time depends on the value of
the boot voltage and CSS.
Once the SS voltage is within 100 mV of the boot voltage,
the boot voltage delay time (TD3 in Figure 5) is started. The
end of the boot voltage delay time signals the beginning of the
second soft−start time (TD4 in Figure 5). The SS voltage now
changes from the boot voltage to the programmed VID DAC
voltage (either higher or lower) using the SS amplifier with
the limited 15 A output current. The voltage of the FB pin
follows the ramping voltage of the SS pin, limiting the inrush
current during the transition from the boot voltage to the final
DAC voltage. The second soft−start time depends on the boot
voltage, the programmed VID DAC voltage, and CSS.
Once TD5 has finished, the SS pin is then used to limit the
slew−rate of DVID steps. The current source is changed to
75 A and the DVID slew−rate becomes 5 X the soft−start
slew−rate. Typically, the SS slew−rate is 2 mV/S, so the
DVID becomes 10 mV/S.
If EN is taken low or if VCC drops below UVLO, DELAY
and SS are reset to ground to be ready for another soft−start
cycle. Figure 6 shows typical startup waveforms for the
ADP3290.
A high gain, bandwidth voltage mode error amplifier is
used for the voltage mode control loop. The control input
voltage to the positive input is set via the VID logic
according to the voltages listed.
This voltage is also offset by the droop voltage for active
positioning of the output voltage as a function of current,
commonly known as active voltage positioning. The output
of the amplifier is the COMP pin, which sets the termination
voltage for the internal PWM ramps.
The negative input (FB) is tied to the output sense location
with Resistor RB and is used for sensing and controlling the
output voltage at this point. A current source from the FB pin
flowing through RB is used for setting the no load offset
voltage from the VID voltage. The no load voltage is
negative with respect to the VID DAC. The main loop
compensation is incorporated into the feedback network
between FB and COMP.
Fast Enhanced Transient Modes
SINGLE−PHASE OPERATION
The ADP3290 incorporates enhanced transient response
for both load steps and load release. For load steps, it senses
the error amp to determine if a load step has occurred and
sequences the proper number of phases on to ramp up the
output current.
For load release, it also senses the error amp and uses the
load release information to trigger the TRDET pin, which is
then used to adjust the feedback for optimal positioning
especially during high frequency load steps.
Additional information is used during load transients to
ensure proper sequencing and balancing of phases during
high frequency load steps as well as minimizing stress on the
components such as the input filter and MOSFETs.
Delay Timer
4−PHASE OPERATION
The delay times for the startup timing sequence are set
with a capacitor from the DELAY pin to ground. In UVLO,
or when EN is logic low, the DELAY pin is held at ground.
After the UVLO and EN signals are asserted, the first delay
time (TD1 in Figure 5) is initiated. A 15 A current flows out
of the DELAY pin to charge CDLY. A comparator monitors
the DELAY voltage with a threshold of 1.7 V. The delay time
is therefore set by the 15 A charging a capacitor from 0 V
to 1.7 V. This DELAY pin is used for multiple delay timings
(TD1, TD3, and TD5) during the startup sequence. Also,
DELAY is used for timing the current limit latchoff, as
explained in the Current Limit, Short−Circuit, and Latchoff
Protection section.
Soft−Start
The soft−start times for the output voltage are set with a
capacitor from the SS pin to ground. After TD1 and the
phase detection cycle have been completed, the SS time
(TD2 in Figure 5) starts. The SS pin is disconnected from
Figure 6. Typical Startup Waveform
1-Vo, 2-EN, 3-SS, 4-DELAY, D0−D3-PWM1~4
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ADP3290
Current Limit, Short−Circuit, and Latchoff Protection
The ADP3290 compares a programmable current limit set
point to the voltage from the output of the current sense
amplifier. The level of current limit is set with the resistor
from the ILIM pin to CSCOMP. During operation, the
voltage on ILIM is equal to the voltage on CSREF. The
current through the external resistor connected between
ILIM and CSCOMP is then compared to the internal current
limit current Icl. If the current generated through this register
into the ILIM pin(ILIM) exceeds the internal current limit
threshold current (Icl), the internal current limit amplifier
controls the internal COMP voltage to maintain the average
output at the limit.
If the limit is reached and TD5 in Figure 5 has completed,
a latchoff delay time starts, and the controller shuts down if
the fault is not removed. The current limit delay time shares
the DELAY pin timing capacitor with the startup sequence
timing. However, during current limit, the DELAY pin
current is reduced to 3.75 A. A comparator monitors the
DELAY voltage and shuts off the controller when the
voltage reaches 1.7 V. Therefore, the current limit latchoff
delay time is set by the current of 3.75 A, charging the
delay capacitor from 0 V to 1.7 V. This delay is four times
longer than the delay time during the startup sequence.
The current limit delay time starts only after the TD5 is
complete. If there is a current limit during startup, the
ADP3290 goes through TD1 to TD5, and then starts the
latchoff time. Because the controller continues to cycle the
phases during the latchoff delay time, the controller returns
to normal operation and the DELAY capacitor is reset to
GND if the short is removed before the 1.7 V threshold is
reached.
The latchoff function can be reset by either removing and
reapplying the supply voltage to the ADP3290, or by
toggling the EN pin low for a short time. To disable the short
circuit latchoff function, an external resistor should be
placed in parallel with CDLY. This prevents the DELAY
capacitor from charging up to the 1.7 V threshold. The
addition of this resistor causes a slight increase in the delay
times.
During startup, when the output voltage is below 200 mV,
a secondary current limit is active. This is necessary because
the voltage swing of CSCOMP cannot go below ground.
This secondary current limit controls the internal COMP
voltage to the PWM comparators to 1.5 V. This limits the
voltage drop across the low−side MOSFETs through the
current balance circuitry. An inherent per−phase current
limit protects individual phases if one or more phases stop
functioning because of a faulty component. This limit is
based on the maximum normal mode COMP voltage.
Typical overcurrent latchoff waveforms are shown in
Figure 7.
Figure 7. Dynamic (Load Transient)
Overcurrent Latchoff Waveform
1-Vo, 2-Io(from VTT), 3-DELAY, D0~D3-PWM1~4
Output Current Monitor
The IMON pin is used to output an analog voltage
representing the total output current being delivered to the
load. It outputs an accurate current that is directly
proportional to the current set by the ILIM resistor. This
current is then run through a parallel RC connected from the
IMON pin to the FBRTN pin to generate an accurately scaled
and filtered voltage per the VR11.1 specification. The size
of the resistor is used to set the IMON scaling.
If the IMON and OCP are then desired to be changed based
on the TDC of the CPU, the ILIM resistor is the only
component that needs to be changed. If the IMON scaling is
the only desired change, then just changing the IMON resistor
accomplishes this.
The IMON pin also includes an active clamp to limit the
IMON voltage to 1.15 V MAX yet maintaining 900 mV MIN
full−scale accurate reporting.
Dynamic VID
The ADP3290 has the ability to dynamically change the
VID inputs while the controller is running. This allows the
output voltage to change while the supply is running and
supplying current to the load. This is commonly referred to
as dynamic VID (DVID). A DVID can occur under light or
heavy load conditions. The processor signals the controller
by changing the VID inputs in multiple steps from the start
code to the finish code. This change can be positive or
negative.
When a VID input changes state, the ADP3290 detects the
change and ignores the DAC inputs for a minimum of
400 ns. This time prevents a false code due to logic skew
while the eight VID inputs are changing. Additionally, the
first VID change initiates the PWRGD and crowbar
blanking functions for a minimum of 100 s to prevent a
false PWRGD or crowbar event. Each VID change resets the
internal timer.
If an OFF VID code is detected, the ADP3290 waits 5 S
to ensure this code is correct before initiating a shutdown of
the controller.
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ADP3290
providing full−power load transients immediately following
exit from a low−power state.
One additional feature of the ADP3290 is the internal
current limit threshold is changed when PSI is pulled low.
The current limit threshold is reduced by 1/N such that the
same per phase average current limit is maintained to protect
the components in the system.
PSI ASSERTION
The ADP3290 also adds the use of the SS pin to limit
DVID slew−rates. These can be encountered when the
system does a large single VID step for power state changes,
thus the DVID slew−rate needs to be limited to prevent large
in−rush currents. The SS pin uses a 75 A current source into
the SS capacitor to do this limiting and typical slew−rates of
10mV/S are set with the design.
PSI DE−ASSERTION
Figure 8. DVID Waveform (by VTT, 0.5 V-1.5V)
1-Vo D0~D2-PWM1~3
Power−Good Monitoring
The power−good comparator monitors the output voltage
via the CSREF pin. The PWRGD pin is an open−drain
output whose high level, when connected to a pullup
resistor, indicates that the output voltage is within the
nominal limits specified based on the VID voltage setting.
PWRGD goes low if the output voltage is outside of this
specified range, if the VID DAC inputs are in no CPU mode,
or if the EN pin is pulled low. PWRGD is blanked during a
DVID event for a period of 250 s to prevent false signals
during the time the output is changing.
The PWRGD circuitry also incorporates an initial turn−on
delay time (TD5), based on the DELAY timer. Prior to the
SS voltage reaching the programmed VID DAC voltage and
the PWRGD masking−time finishing, the PWRGD pin is
held low. Once the SS pin is within 100 mV of the
programmed DAC voltage, the capacitor on the DELAY pin
begins to charge. A comparator monitors the DELAY
voltage and enables PWRGD when the voltage reaches
1.7 V. The PWRGD delay time is, therefore, set by a current
of 15 A, charging a capacitor from 0 V to 1.7 V.
Figure 9. PSI Mode Transition Waveform (Io = 25A)
1-Vo, 2-PSI, 3-COMP, 4-TRDET, D0~D2-PWM1~3
Output Crowbar
To protect the load and output components of the supply,
the PWM outputs are driven low, which turns on the
low−side MOSFETs when the output voltage exceeds the
upper crowbar threshold. This crowbar action stops once the
output voltage falls below the release threshold of
approximately 375 mV.
Turning on the low−side MOSFETs pulls down the output
as the reverse current builds up in the inductors. If the output
overvoltage is due to a short in the high−side MOSFET, this
action current limits the input supply or blows its fuse,
protecting the microprocessor from being destroyed.
Power State Indicator
The PSI pin is used as an input to determine the operating
power state of the load. If this pin is pulled low, the controller
knows the load is in a low power state and it takes the ODN
signal low, which can be used to disable phases for increased
efficiency.
The sequencing into and out of low−power operation is
maintained to minimize output voltage deviations as well as
Output Enable and UVLO
For the ADP3290 to begin switching, the input supply
current to the controller must be higher than the UVLO
threshold and the EN pin must be higher than its 0.8 V
threshold. This initiates a system startup sequence. If either
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ADP3290
Thermal Monitoring
UVLO or EN is less than their respective thresholds, the
ADP3290 is disabled. This holds the PWM outputs at
ground, shorts the DELAY capacitor to ground, and the
forces PWRGD and OD signals low.
In the application circuit, the OD pin should be connected
to the OD input of the external driver for the phase that is
always on while the ODN pin should be connected to the OD
input on the external drivers of the phases that are shut off
during low−power operation. Grounding OD and ODN
disable the drivers such that both DRVH and DRVL are
grounded. This feature is important in preventing the
discharge of the output capacitors when the controller is shut
off. If the driver outputs are not disabled, a negative voltage
can be generated during output due to the high current
discharge of the output capacitors through the inductors.
The ADP3290 includes a thermal monitoring circuit to
detect when a point on the VR has exceeded a user−defined
temperature. The thermal monitoring circuit requires an
NTC thermistor to be placed between TTSNS and GND.
A fixed current of 120 A is sourced out of the TTSNS pin
and into the thermistor. The current source is internally
limited to 5.0 V. An internal circuit compares the TTSNS
voltage to a 0.81 V threshold, and outputs an open−drain
signal at the VRHOT output. Once the voltage on the
TTSNS pin drops below its threshold, the open−drain output
asserts high to signal the system that an overtemperature
event has occurred. Because the TTSNS voltage changes
slowly with respect to time, 55 mV of hysteresis is built into
this comparator. The thermal monitoring circuitry does not
depend on EN and is active when UVLO is above its
threshold. When UVLO is below its threshold, VRHOT is
forced low.
VR11.1 VID Codes
OUTPUT(V)
VID7
VID6
VID5
VID4
VID3
VID2
VID1
VID0
OFF
0
0
0
0
0
0
0
0
OFF
0
0
0
0
0
0
0
1
1.60000
0
0
0
0
0
0
1
0
1.59375
0
0
0
0
0
0
1
1
1.58750
0
0
0
0
0
1
0
0
1.58125
0
0
0
0
0
1
0
1
1.57500
0
0
0
0
0
1
1
0
1.56875
0
0
0
0
0
1
1
1
1.56250
0
0
0
0
1
0
0
0
1.55625
0
0
0
0
1
0
0
1
1.55000
0
0
0
0
1
0
1
0
1.54375
0
0
0
0
1
0
1
1
1.53750
0
0
0
0
1
1
0
0
1.53125
0
0
0
0
1
1
0
1
1.52500
0
0
0
0
1
1
1
0
1.51875
0
0
0
0
1
1
1
1
1.51250
0
0
0
1
0
0
0
0
1.50625
0
0
0
1
0
0
0
1
1.50000
0
0
0
1
0
0
1
0
1.49375
0
0
0
1
0
0
1
1
1.48750
0
0
0
1
0
1
0
0
1.48125
0
0
0
1
0
1
0
1
1.47500
0
0
0
1
0
1
1
0
1.46875
0
0
0
1
0
1
1
1
1.46250
0
0
0
1
1
0
0
0
1.45625
0
0
0
1
1
0
0
1
1.45000
0
0
0
1
1
0
1
0
1.44375
0
0
0
1
1
0
1
1
1.43750
0
0
0
1
1
1
0
0
1.43125
0
0
0
1
1
1
0
1
1.42500
0
0
0
1
1
1
1
0
1.41875
0
0
0
1
1
1
1
1
1.41250
0
0
1
0
0
0
0
0
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ADP3290
VR11.1 VID Codes
OUTPUT(V)
VID7
VID6
VID5
VID4
VID3
VID2
VID1
VID0
1.40625
0
0
1
0
0
0
0
1
1.40000
0
0
1
0
0
0
1
0
1.39375
0
0
1
0
0
0
1
1
1.38750
0
0
1
0
0
1
0
0
1.38125
0
0
1
0
0
1
0
1
1.37500
0
0
1
0
0
1
1
0
1.36875
0
0
1
0
0
1
1
1
1.36250
0
0
1
0
1
0
0
0
1.35625
0
0
1
0
1
0
0
1
1.35000
0
0
1
0
1
0
1
0
1.34375
0
0
1
0
1
0
1
1
1.33750
0
0
1
0
1
1
0
0
1.33125
0
0
1
0
1
1
0
1
1.32500
0
0
1
0
1
1
1
0
1.31875
0
0
1
0
1
1
1
1
1.31250
0
0
1
1
0
0
0
0
1.30625
0
0
1
1
0
0
0
1
1.30000
0
0
1
1
0
0
1
0
1.29375
0
0
1
1
0
0
1
1
1.28750
0
0
1
1
0
1
0
0
1.28125
0
0
1
1
0
1
0
1
1.27500
0
0
1
1
0
1
1
0
1.26875
0
0
1
1
0
1
1
1
1.26250
0
0
1
1
1
0
0
0
1.25625
0
0
1
1
1
0
0
1
1.25000
0
0
1
1
1
0
1
0
1.24375
0
0
1
1
1
0
1
1
1.23750
0
0
1
1
1
1
0
0
1.23125
0
0
1
1
1
1
0
1
1.22500
0
0
1
1
1
1
1
0
1.21875
0
0
1
1
1
1
1
1
1.21250
0
1
0
0
0
0
0
0
1.20625
0
1
0
0
0
0
0
1
1.20000
0
1
0
0
0
0
1
0
1.19375
0
1
0
0
0
0
1
1
1.18750
0
1
0
0
0
1
0
0
1.18125
0
1
0
0
0
1
0
1
1.17500
0
1
0
0
0
1
1
0
1.16875
0
1
0
0
0
1
1
1
1.16250
0
1
0
0
1
0
0
0
1.15625
0
1
0
0
1
0
0
1
1.15000
0
1
0
0
1
0
1
0
1.14375
0
1
0
0
1
0
1
1
1.13750
0
1
0
0
1
1
0
0
1.13125
0
1
0
0
1
1
0
1
1.12500
0
1
0
0
1
1
1
0
1.11875
0
1
0
0
1
1
1
1
1.11250
0
1
0
1
0
0
0
0
1.10625
0
1
0
1
0
0
0
1
1.10000
0
1
0
1
0
0
1
0
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15
ADP3290
VR11.1 VID Codes
OUTPUT(V)
VID7
VID6
VID5
VID4
VID3
VID2
VID1
VID0
1.09375
0
1
0
1
0
0
1
1
1.08750
0
1
0
1
0
1
0
0
1.08125
0
1
0
1
0
1
0
1
1.07500
0
1
0
1
0
1
1
0
1.06875
0
1
0
1
0
1
1
1
1.06250
0
1
0
1
1
0
0
0
1.05625
0
1
0
1
1
0
0
1
1.05000
0
1
0
1
1
0
1
0
1.04375
0
1
0
1
1
0
1
1
1.03750
0
1
0
1
1
1
0
0
1.03125
0
1
0
1
1
1
0
1
1.02500
0
1
0
1
1
1
1
0
1.01875
0
1
0
1
1
1
1
1
1.01250
0
1
1
0
0
0
0
0
1.00625
0
1
1
0
0
0
0
1
1.00000
0
1
1
0
0
0
1
0
0.99375
0
1
1
0
0
0
1
1
0.98750
0
1
1
0
0
1
0
0
0.98125
0
1
1
0
0
1
0
1
0.97500
0
1
1
0
0
1
1
0
0.96875
0
1
1
0
0
1
1
1
0.96250
0
1
1
0
1
0
0
0
0.95625
0
1
1
0
1
0
0
1
0.95000
0
1
1
0
1
0
1
0
0.94375
0
1
1
0
1
0
1
1
0.93750
0
1
1
0
1
1
0
0
0.93125
0
1
1
0
1
1
0
1
0.92500
0
1
1
0
1
1
1
0
0.91875
0
1
1
0
1
1
1
1
0.91250
0
1
1
1
0
0
0
0
0.90625
0
1
1
1
0
0
0
1
0.90000
0
1
1
1
0
0
1
0
0.89375
0
1
1
1
0
0
1
1
0.88750
0
1
1
1
0
1
0
0
0.88125
0
1
1
1
0
1
0
1
0.87500
0
1
1
1
0
1
1
0
0.86875
0
1
1
1
0
1
1
1
0.86250
0
1
1
1
1
0
0
0
0.85625
0
1
1
1
1
0
0
1
0.85000
0
1
1
1
1
0
1
0
0.84375
0
1
1
1
1
0
1
1
0.83750
0
1
1
1
1
1
0
0
0.83125
0
1
1
1
1
1
0
1
0.82500
0
1
1
1
1
1
1
0
0.81875
0
1
1
1
1
1
1
1
0.81250
1
0
0
0
0
0
0
0
0.80625
1
0
0
0
0
0
0
1
0.80000
1
0
0
0
0
0
1
0
0.79375
1
0
0
0
0
0
1
1
0.78750
1
0
0
0
0
1
0
0
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16
ADP3290
VR11.1 VID Codes
OUTPUT(V)
VID7
VID6
VID5
VID4
VID3
VID2
VID1
VID0
0.78125
1
0
0
0
0
1
0
1
0.77500
1
0
0
0
0
1
1
0
0.76875
1
0
0
0
0
1
1
1
0.76250
1
0
0
0
1
0
0
0
0.75625
1
0
0
0
1
0
0
1
0.75000
1
0
0
0
1
0
1
0
0.74375
1
0
0
0
1
0
1
1
0.73750
1
0
0
0
1
1
0
0
0.73125
1
0
0
0
1
1
0
1
0.72500
1
0
0
0
1
1
1
0
0.71875
1
0
0
0
1
1
1
1
0.71250
1
0
0
1
0
0
0
0
0.70625
1
0
0
1
0
0
0
1
0.70000
1
0
0
1
0
0
1
0
0.69375
1
0
0
1
0
0
1
1
0.68750
1
0
0
1
0
1
0
0
0.68125
1
0
0
1
0
1
0
1
0.67500
1
0
0
1
0
1
1
0
0.66875
1
0
0
1
0
1
1
1
0.66250
1
0
0
1
1
0
0
0
0.65625
1
0
0
1
1
0
0
1
0.65000
1
0
0
1
1
0
1
0
0.64375
1
0
0
1
1
0
1
1
0.63750
1
0
0
1
1
1
0
0
0.63125
1
0
0
1
1
1
0
1
0.62500
1
0
0
1
1
1
1
0
0.61875
1
0
0
1
1
1
1
1
0.61250
1
0
1
0
0
0
0
0
0.60625
1
0
1
0
0
0
0
1
0.60000
1
0
1
0
0
0
1
0
0.59375
1
0
1
0
0
0
1
1
0.58750
1
0
1
0
0
1
0
0
0.58125
1
0
1
0
0
1
0
1
0.57500
1
0
1
0
0
1
1
0
0.56875
1
0
1
0
0
1
1
1
0.56250
1
0
1
0
1
0
0
0
0.55625
1
0
1
0
1
0
0
1
0.55000
1
0
1
0
1
0
1
0
0.54375
1
0
1
0
1
0
1
1
0.53750
1
0
1
0
1
1
0
0
0.53125
1
0
1
0
1
1
0
1
0.52500
1
0
1
0
1
1
1
0
0.51875
1
0
1
0
1
1
1
1
0.51250
1
0
1
1
0
0
0
0
0.50625
1
0
1
1
0
0
0
1
0.50000
1
0
1
1
0
0
1
0
OFF
1
1
1
1
1
1
1
0
OFF
1
1
1
1
1
1
1
1
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17
ADP3290
Application Information
The design parameters for a typical Intel VRD 11.1
compliant CPU application are as follows:
• Input voltage (VIN) = 12 V
• VID setting voltage (VVID) = 1.400 V
• Duty cycle (D) = 0.117
• Nominal output voltage at no load (VONL) = 1.381 V
• Nominal output voltage at 115 A load
(VOFL) = 1.266 V
• Static output voltage drop based on a 1.0 m
load line (RO) from no load to full load
(VD) = VONL − VOFL = 1.381 V − 1.266 V = 115 mV
• Maximum output current (IO) = 130 A
• Maximum output current step (IO) = 95 A
• Maximum output current slew rate (SR) = 200 A/s
• Number of phases (n) = 4
• Switching frequency per phase (fSW) = 450 kHz
Current Limit Latchoff Delay Times
The startup and current limit delay times are determined
by the capacitor connected to the DELAY pin. The first step
is to set CDLY for the TD1, TD3, and TD5 delay times (see
Figure 5). The DELAY ramp (IDELAY) is generated using a
15 A internal current source.
The value for CDLY can be approximated using:
C DLY + I DELAY
The ADP3290 uses a fixed frequency control architecture.
The frequency is set by an external timing resistor (RT). The
clock frequency and the number of phases determine the
switching frequency per phase, which relates directly to
switching losses as well as the sizes of the inductors, the
input capacitors, and output capacitors. With n = 4 for four
phases, a clock frequency of 18 MHz sets the switching
frequency (fSW) of each phase to 450 kHz, which represents
a practical trade off between the switching losses and the
sizes of the output filter components. Figure 3 shows that to
achieve a 1.32 MHz oscillator frequency, the correct value
for RT is 130 k. Alternatively, the value for RT can be
calculated using:
n
f SW
1
4.3 pF
* 17 k
Inductor Selection
The choice of inductance for the inductor determines the
ripple current in the inductor. Less inductance leads to more
ripple current, which increases the output ripple voltage and
conduction losses in the MOSFETs. However, using smaller
inductors allows the converter to meet a specified
peak−to−peak transient deviation with less total output
capacitance. Conversely, a higher inductance means lower
ripple current and reduced conduction losses, but more
output capacitance is required to meet the same
peak−to−peak transient deviation.
In any multiphase converter, a practical value for the
peak−to−peak inductor ripple current is less than 50% of
the maximum dc current in the same inductor. Equation 4
shows the relationship between the inductance, oscillator
frequency, and peak−to−peak ripple current in the inductor.
(eq. 1)
where 4.3 pF is the internal IC component values. For good
initial accuracy and frequency stability, a 1% resistor is
recommended.
IR +
Soft−Start Delay Time
C SS + 15 A
V VID (1 * D)
f SW L
(eq. 4)
Equation 5 can be used to determine the minimum
inductance based on a given output ripple voltage.
The value of CSS sets the soft-start time. The ramp is
generated with a 15 A internal current source. The value for
CSS can be found using:
TD2
V BOOT
(eq. 3)
where TD(x) is the desired delay time for TD1, TD3, and
TD5. The DELAY threshold voltage (VDELAY(TH)) is given
as 1.7 V. In this example, 2 ms is chosen for all three delay
times, which meets Intel specifications. Solving for CDLY
gives a value of 17.6 nF. The closest standard value for CDLY
is 18 nF.
When the ADP3290 enters current limit, the internal
current source changes from 15 A to 3.75 A. This makes
the latchoff delay time four times longer than the startup
delay time. Longer latchoff delay times can be achieved by
placing a resistor in parallel with CDLY.
Setting the Clock Frequency
RT +
TD(x)
V DELAY(TH)
Lw
(eq. 2)
V VID
RO
f SW
(1 * (n
V RIPPLE
D))
(eq. 5)
Solving Equation 5 for an 8 mV p−p output ripple voltage
yields:
where TD2 is the desired soft−start time, and VBOOT is
internally set to 1.0 V.
Assuming a desired TD2 time of 2.5 ms, CSS is 37.5 nF.
The closest standard value for CSS is 39 nF. Although CSS
also controls the time delay for TD4 (determined by the final
VID voltage), the minimum specification for TD4 is 0 ns.
This means that as long as the TD2 time requirement is met,
TD4 is within the specification.
Lw
1.4 V
1.0 m (1 * 0.468)
+ 166 nH
450 kHz 10 mV
If the resulting ripple voltage is less than what is designed
for, the inductor can be made smaller until the ripple value
is met. This allows optimal transient response and minimum
output decoupling.
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18
ADP3290
increases. The specified voltage drop corresponds to a dc
output resistance (RO), also referred to as a load line. The
ADP3290 has the flexibility of adjusting RO, independent of
current limit or compensation components, and it can also
support CPUs that do not require a load line.
For designs requiring a load line, the impedance gain of
the CS amplifier (RCSA) must be to be greater than or equal
to the load line. All designs, whether they have a load line
or not, should keep RCSA ≥ 1 m.
The output current is measured by summing the voltage
across each inductor and passing the signal through a
low−pass filter. This summer filter is the CS amplifier
configured with resistors RPH(X) (summers), and RCS and
CCS (filter). The impedance gain of the regulator is set by the
following equations, where RL is the DCR of the output
inductors:
The smallest possible inductor should be used to minimize
the number of output capacitors. For this example, choosing
a 220 nH inductor is a good starting point and gives a
calculated ripple current of 12.5 A. The inductor should not
saturate at the peak current of 38.7 A and should be able to
handle the sum of the power dissipation caused by the
average current of 32.5 A in the winding and core loss.
Another important factor in the inductor design is the dc
resistance (DCR), which is used for measuring the phase
currents. A large DCR can cause excessive power losses,
though too small a value can lead to increased measurement
error. A good rule is to have the DCR (RL) be about 1 to 1.5
times the droop resistance (RO). This example uses an
inductor with a DCR of 0.57 m.
Designing an Inductor
Once the inductance and DCR are known, the next step is
to either design an inductor or to find a standard inductor that
comes as close as possible to meeting the overall design
goals. It is also important to have the inductance and DCR
tolerance specified to control the accuracy of the system.
Reasonable tolerances most manufacturers can meet are
15% inductance and 7% DCR at room temperature. The first
decision in designing the inductor is choosing the
core material. Several possibilities for providing low core
loss at high frequencies include the powder cores (from
Micrometals, Inc., for example, or Kool Mu® from
Magnetics®) and the gapped soft ferrite cores (for example,
3F3 or 3F4 from Philips®). Low frequency powdered iron
cores should be avoided due to their high core loss,
especially when the inductor value is relatively low and the
ripple current is high.
The best choice for a core geometry is a closed−loop type
such as a potentiometer core (PQ, U, or E core) or toroid. A
good compromise between price and performance is a core
with a toroidal shape.
Many useful magnetics design references are available for
quickly designing a power inductor, such as:
• Intusoft Magnetic Designer Software
• Designing Magnetic Components for High Frequency
DC to DC Converters, by William T. McLyman,
Kg Magnetics, Inc., ISBN 1883107008
R CSA +
C CS +
R CS
R PH(x)
RL
L
RL
R CS
(eq. 6)
(eq. 7)
The user has the flexibility to choose either RCS or RPH(X).
However, it is best to select RCS equal to 110 k, and then
solve for RPH(X) by rearranging Equation 6. Here,
RCSA = RO = 1 m because this is equal to the design load
line.
R PH(x) +
RL
R CSA
R PH(x) +
0.57 m
1.0 m
R CS
110 k + 63 k
Next, use Equation 7 to solve for CCS.
C CS +
220 nH
+ 35 nF
0.57 m 110 m
It is best to have a dual location for CCS in the layout so
that standard values can be used in parallel to get as close to
the desired value. For best accuracy, CCS should be a 5% or
10% NPO capacitor. This example uses a 5% combination
for CCS of one 1.8 nF capacitor and one 1.5nF capacitor in
parallel. Recalculating RCS and RPH(X) using this capacitor
combination yields 108.8 k and 62 k. The closest
standard 1% value for RPH(X) is 61.9 k.
When the inductor DCR is used as the sense element and
copper wire is used as the source of the DCR, the user needs
to compensate for temperature changes of the inductor’s
winding. Fortunately, copper has a well known temperature
coefficient (TC) of 0.39%/°C.
If RCS is designed to have an opposite and equal
percentage change in resistance to that of the wire, it cancels
the temperature variation of the inductor DCR. Due to the
nonlinear nature of NTC thermistors, Resistor RCS1 and
Resistor RCS2 are needed. See Figure 10 to linearize the
NTC and produce the desired temperature tracking.
Selecting a Standard Inductor
The following power inductor manufacturers can provide
design consultation and deliver power inductors optimized
for high power applications upon request.
• Coilcraft®
• Coiltronics®
• Sumida Corporation®
Current Sense Amplifier
Most designs require the regulator output voltage,
measured at the CPU pins, to drop when the output current
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19
ADP3290
PLACE AS CLOSE AS POSSIBLE
TO NEAREST INDUCTOR
OR LOW−SIDE MOSFET
5. Calculate values for RCS1 and RCS2 using
Equation 12 and 13.
R TH
R PH1
R PH2
R PH3
R PH4
ADP3290
CSCOMP
CSSUM
CSREF
R CS1
R CS2
KEEP THIS PATH
AS SHORT AS
POSSIBLE AND
WELL AWAY FROM
SWITCH NODE LINES
C CS2
16
15
Figure 10. Temperature Compensation Circuit Values
The following procedure and equations yield values to use
for RCS1, RCS2, and RTH (the thermistor value at 25°C) for
a given RCS value.
1. Select an NTC based on type and value. Because
the value is unknown, use a thermistor with a
value close to RCS. The NTC should also have an
initial tolerance of better than 5%.
2. Based on the type of NTC, find its relative
resistance value at two temperatures. The
temperatures that work well are 50°C and 90°C.
These resistance values are called
A (RTH(50°C))/RTH(25°C)) and B
(RTH(90°C))/RTH(25°C)). The relative value of the
NTC is always 1 at 25°C.
3. Find the relative value of RCS required for each of
these temperatures. This is based on the percentage
change needed, which in this example is initially
0.39%/°C. These temperatures are called
r1 (1/(1 + TC × (T1 − 25°C)))
and
r2 (1/(1 + TC × (T2 − 25°C))), where TC = 0.0039
for copper, T1 = 50°C, and T2 = 90°C. From this,
r1 = 0.9112 and r2 = 0.7978.
4. Compute the relative values for RCS1, RCS2, and
RTH using:
r TH +
1
1
* 1
1*r CS2 r CS1
CSCOMP
CSSUM
CSREF
k+
R TH(CALCULATED)
r CS2ǓǓ
(eq. 13)
17
16
15
R LL1
R LL2
OPTIONAL LOAD LINE
SELECT SWITCH
LLINE
14
Q LL
Figure 11. Load Line Setting Resistors
The two resistors RLL1 and RLL2 set up a divider between
the CSCOMP pin and CSREF pin. This resistor divider is
input into the LLSET pin to set the load line slope RO of the
VR according to the following equation:
RO +
(eq. 9)
R LL2
R LL1 ) R LL2
R CSA
(eq. 14)
The resistor values for RLL1 and RLL2 are limited by two
factors.
• The minimum value is based upon the loading of the
CSCOMP pin. This pin’s drive capability is 500 A and
the majority of this should be allocated to the CSA
feedback. If the current through RLL1 and RLL2 is
limited to 10% of this (50 A), the following limit can
be placed for the minimum value for RLL1 and RLL2:
(eq. 10)
Calculate RTH = rTH × RCS, then select the closest value
of thermistor available. Also, compute a scaling factor (k)
based on the ratio of the actual thermistor value used relative
to the computed one.
R TH(ACTUAL)
ǒ(1 * k) ) ǒk
ADP3290
(eq. 8)
1
A
*
1*r CS2 r 1*r CS2
R CS2 + R CS
(eq. 12)
For load line values greater than 1 m, RCSA can be set
equal to RO, and the LLSET pin can be directly connected
to the CSCOMP pin. When the load line value needs to be
less than 1 m, two additional resistors are required.
Figure 11 shows the placement of these resistors.
(A * B)xr 1xr 2 * A (1 * B)xr 2 ) B (1 * A) xr 1
A (1 * B)xr 1 * B (1 * A)xr 2 * (A * B)
r CS1 +
r CS1
Load Line Setting
r CS2 +
(1 * A)
k
In this example, RCS is calculated to be 114 k. Look for
an available 100 k thermistor, 0603 size. One such
thermistor is the Vishay NTHS0603N01N1003JR NTC
thermistor with A = 0.3602 and B = 0.09174. From these
values, rCS1 = 0.3795, rCS2 = 0.7195, and rTH = 1.075.
Solving for RTH yields 122.55 k, so 100 k is chosen,
making k = 0.816. Next, find RCS1 and RCS2 to be 35.3 k
and 87.9 k. Finally, choose the closest 1% resistor values,
which yield a choice of 35.7 k and 88.7 k.
17
C CS1
R CS1 + R CS
R LL1 ) R LL2 w
(eq. 11)
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20
I LIM
50
R CSA
10 *6
(eq. 15)
ADP3290
To determine the minimum amount of ceramic
capacitance required, start with a worst case load step
occurring right after a switching cycle has stopped. The
ceramic capacitance then delivers the charge to the load
while the load is ramping up and until the VR has responded
with the next switching cycle.
Equation 19 gives the designer a rough approximation for
determining the minimum ceramic capacitance. Due to the
complexity of the PCB parasitics and bulk capacitors, the
actual amount of ceramic capacitance required can vary.
Here, ILIM is the current limit current, which is the
maximum signal level that the CSA responds to.
It is best to select the resistor values to minimize their
values to reduce the noise and parasitic susceptibility of the
feedback path.
By combining Equation 14 with Equation 15 and selecting
minimum values for the resistors, the following equations result:
R LL2 +
I LIM R O
50 A
R LL1 +
ǒ
(eq. 16)
Ǔ
R CSA
*1
RO
R LL2
C Z(MIN) w 1
RO
(eq. 17)
Another useful feature for some VR applications is the
ability to select different load lines. Figure 11 shows an
optional MOSFET switch that allows this feature. Here,
design for RCSA = RO(MAX) (selected with QLL on) and then
use Equation 14 to set RO = RO(MIN) (selected with QLL off).
For this design, RCSA = RO = 1 m. As a result, connect
LLSET directly to CSCOMP; the RLL1 and RLL2 resistors
are not needed.
The Intel specification requires that at no load the nominal
output voltage of the regulator be offset to a value lower than
the nominal voltage corresponding to the VID code. The
offset is set by a constant current source flowing out of the
FB pin (IFB) and flowing through RB. The value of RB can
be found using Equation 18.
V VID * V ONL
I FB
1
f SW
ǒ1n * DǓ * 2SIO ƫ
(eq. 19)
R
The typical ceramic capacitors consist of multiple 10 F
or 22 F capacitors. For this example, Equation 19 yields
180.8 F, so eighteen, 22 F ceramic capacitors suffice.
Next, there is an upper limit imposed on the total amount
of bulk capacitance (CX) when the user considers the VID
OTF voltage stepping of the output (voltage step VV in time
tV with error of VERR).
A lower limit is based on meeting the capacitance for load
release for a given maximum load step (IO) and a
maximum allowable overshoot. The total amount of load
release voltage is given as VO = IO × RO + Vrl, where
Vrl is the maximum allowable overshoot voltage.
Output Offset
RB +
ƪ
C X(MAX) v
L
nK 2R 2O
(eq. 18)
VV
V VID
Ǹ
ȡ
ȧ
Ȣ
1 ) tV
VV
ǒ Ǔ
where : K + * 1n
1.4 V * 1.381 V
RB +
+ 1.27 k
15 A
ǒ
V VID
V ERR
VV
Ǔ ȣȧ
nKR O
L
2
* 1 * CZ
Ȥ
(eq. 20)
To meet the conditions of these equations and transient
response, the ESR of the bulk capacitor bank (RX) should be
less than two times the droop resistance (RO). If the CX(MIN)
is larger than CX(MAX), the system cannot meet the VID
OTF specification and can require the use of a smaller
inductor or more phases (and may have to increase the
switching frequency to keep the output ripple the same).
This example uses 18, 22 F 1206 MLC capacitors
(CZ = 396 F). The VID OTF step change is 1.1V in
233.75 s with a settling error of 5 mV. The maximum
allowable load release overshoot for this example is 50 mV,
therefore, solving for the bulk capacitance yields.
The closest standard 1% resistor value is 1.21 k.
The required output decoupling for the regulator is
typically recommended by Intel for various processors and
platforms. Use some simple design guidelines to determine
the requirements. These guidelines are based on having both
bulk capacitors and ceramic capacitors in the system.
First, select the total amount of ceramic capacitance. This
is based on the number and type of capacitor to be used. The
best location for ceramic capacitors is inside the socket, with
12 to 18, 1206 size being the physical limit. Other capacitors
can be placed along the outer edge of the socket as well.
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ADP3290
C X(MIN)
C X(MIN)
ȡ
wȧ
ȧn
Ȣ
ǒ
ȡ
wȧ
ȧ
Ȣ4
C X(MAX) v
L
IO
Ǔ
ǒ
4
V VID
95 A
50 mV
1.0 m )
95 A
220 nH
5.39 2
(eq. 21)
Z
V rl
RO )
IO
220 nH
ȣ
*C ȧ
ȧ
Ȥ
Ǔ
ȣ
* 396 Fȧ+ 2.08mF
ȧ
1.4 V
Ȥ
1.1 V
ǒ1.0 mǓ
2
1.4 V
Ǹ
ȡ
ȧ
Ȣ
1)
ǒ233.75 s
(eq. 22)
1.4 V
1.1 V
4 5.39
220 nH
1.0 m
Ǔ * 1ȣȧ
2
Ȥ
(eq. 23)
* 396 F + 41.5 mF
current divided by the total number of MOSFETs (nSF).
With conduction losses being dominant, Equation 25 shows
the total power that is dissipated in each synchronous
MOSFET in terms of the ripple current per phase (IR) and
average total output current (IO).
where K = 5.39.
Using 8, 560 F Al−Poly capacitors with a typical ESR of
5 m each yields CX = 4.48 mF with an RX = 0.6 m.
One last check should be made to ensure that the ESL of
the bulk capacitors (LX) is low enough to limit the high
frequency ringing during a load change.
This is tested using:
LX v CZ
R 2O
L Z v 396 F
Q2
ǒ1 mǓ
P SF + (1 * D)
(eq. 24)
2
ƪǒ
Ǔ
IO
n SF
2
) 1
12
ǒ Ǔƫ
nI R
n SF
2
R DS(SF)
(eq. 25)
4 + 528 pH
3
Knowing the maximum output current being designed for
and the maximum allowed power dissipation, the user can
find the required RDS(ON) for the MOSFET. For D−PAK
MOSFETs up to an ambient temperature of 50°C, a safe
limit for PSF is 1 W to 1.5 W at 120°C junction temperature.
Thus, for this example (115 A maximum), RDS(SF) (per
MOSFET) < 8.5 m. This RDS(SF) is also at a junction
temperature of about 120°C. As a result, users need to
account for this when making this selection. This example
uses two lower−side MOSFETs at 10.5 m, each at 120°C.
Another important factor for the synchronous MOSFET
is the input capacitance and feedback capacitance. The ratio
of the feedback to input needs to be small (less than 10% is
recommended) to prevent accidental turn−on of the
synchronous MOSFETs when the switch node goes high.
Also, the time to switch the synchronous MOSFETs off
should not exceed the non−overlap dead time of the
MOSFET driver (40 ns typical for the ADP3120A). The
output impedance of the driver is approximately 2 , and the
typical MOSFET input gate resistances are about 1 to 2 .
Therefore, a total gate capacitance of less than 6000 pF
should be adhered to. Because two MOSFETs are in parallel,
the input capacitance for each synchronous MOSFET
should be limited to 3000 pF.
The high−side (main) MOSFET has to be able to handle
two main power dissipation components: conduction and
switching losses. The switching loss is related to the amount
where Q2 is limited to 4/3 to ensure a critically damped
system.
In this example, LX is approximately 250 pH for the 8,
Al−Poly capacitors, which satisfies this limitation. If the LX
of the chosen bulk capacitor bank is too large, the number of
ceramic capacitors needs to be increased, or lower ESL
bulks need to be used if there is excessive undershoot during
a load transient.
For this multi−mode control technique, all ceramic
designs can be used providing the conditions of Equation 19
through Equation 24 are satisfied.
Power MOSFETs
For this example, the N−channel power MOSFETs have
been selected for one high−side switch and two low−side
switches per phase. The main selection parameters for the
power MOSFETs are VGS(TH), QG, CISS, CRSS, and
RDS(ON). The minimum gate drive voltage (the supply
voltage to the ADP3120A dictates whether standard
threshold or logic−level threshold MOSFETs must be used.
With VGATE ~10 V, logic−level threshold MOSFETs
(VGS(TH) < 2.5 V) are recommended.
The maximum output current (IO) determines the RDS(ON)
requirement for the low−side (synchronous) MOSFETs.
With the ADP3290, currents are balanced between phases,
thus, the current in each low−side MOSFET is the output
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22
ADP3290
dissipation limit. See the ADP3120A data sheet for more
details.
of time it takes for the main MOSFET to turn on and off, and
to the current and voltage that are being switched. Basing the
switching speed on the rise and fall time of the gate driver
impedance and MOSFET input capacitance, Equation 26
provides an approximate value for the switching loss per
main MOSFET, where nMF is the total number of main
MOSFETs.
P S(MF) + 2
f SW
V CC I O
n MF
RG
n MF
n
Ramp Resistor Selection
The ramp resistor (RR) is used for setting the size of the
internal PWM ramp. The value of this resistor is chosen to
provide the best combination of thermal balance, stability,
and transient response. Equation 29 is used for determining
the optimum value.
C ISS
(eq. 26)
RR +
where RG is the total gate resistance (2 for the ADP3120A
and about 1 for typical high speed switching MOSFETs,
making RG = 3 ), and CISS is the input capacitance of the
main MOSFET. Adding more main MOSFETs (nMF) does
not help the switching loss per MOSFET because the
additional gate capacitance slows switching. Use lower gate
capacitance devices to reduce switching loss.
The conduction loss of the main MOSFET is given by the
following, where RDS(MF) is the on resistance of the
MOSFET:
P C(MF) + D
ƪǒ
Ǔ
IO
n MF
2
) 1
12
ǒ
n
Ǔƫ
IR
n MF
RR +
3
AR L
A D R DS
3
0.5 220 nH
+ 367 k
5 4 m 5 pF
CR
where:
AR is the internal ramp amplifier gain.
AD is the current balancing amplifier gain.
RDS is the total low−side MOSFET on resistance.
CR is the internal ramp capacitor value.
Another requirement also needs to be satisfied:
IRAMP < ICLAMP (200A/3), thus:
2
R DS(MF)
RR w
AR
ǒVCC * VVIDǓ
I CLAMP
+
0.5
(12 * 1.4) V
+ 79 K
66.7 A
(eq. 27)
(eq. 30)
Typically, for main MOSFETs, the highest speed (low
CISS) device is preferred, but these usually have higher on
resistance. Select a device that meets the total power
dissipation (about 1.5 W for a single D−PAK) when
combining the switching and conduction losses.
For this example, an BSC100N03L is selected as the main
MOSFET (eight total; nMF = 4), with CISS = 1000 pF
(maximum) and RDS(MF) = 11 m (maximum at
TJ = 120°C). An IPD09N03L is selected as the synchronous
MOSFET (eight total; nSF = 8), with CISS = 1600 pF
(maximum) and RDS(SF) = 10.5 m (maximum at
TJ = 120°C). The synchronous MOSFET CISS is less than
3000 pF, satisfying this requirement.
Solving for the power dissipation per MOSFET at
IO = 115 A and IR = 7.5 A yields 1.9 W for each synchronous
MOSFET and 2.0 W for each main MOSFET.
Finally, consider the power dissipation in the driver for
each phase. This is best expressed as QG for the MOSFETs
and is given by Equation 28, where QGMF is the total gate
charge for each main MOSFET and QGSF is the total gate
charge for each synchronous MOSFET.
P DRV +
ƪ
f SW
2 n
ǒn MF
Q GMF ) n SF
ƫ
Q GSFǓ ) I CC
(eq. 29)
Since above RR value is bigger than 79 k, it keeps the
value of The internal ramp voltage magnitude can be calculated by
using:
VR +
A R (1 * D) V VID
R R C R f SW
(eq. 31)
0.5 (1 * 0.117) 1.4 V
VR +
+ 748 mV
367 k 5 pF 450 kHz
The size of the internal ramp can be made larger or
smaller. If it is made larger, stability and noise rejection
improves, but transient degrades. Likewise, if the ramp is
made smaller, transient response improves at the sacrifice of
noise rejection and stability.
The factor of 3 in the denominator of Equation 29 sets a
ramp size that gives an optimal balance for good stability,
transient response, and thermal balance.
Comp Pin Ramp
A ramp signal on the COMP pin is due to the droop voltage
and output voltage ramps. This ramp amplitude adds to the
internal ramp to produce the following overall ramp signal
at the PWM input:
V CC
V RT +
(eq. 28)
Also shown is the standby dissipation factor (ICC × VCC)
of the driver. For the ADP3120A, the maximum dissipation
should be less than 400 mW. In this example, with
ICC = 7 mA, QGMF = 13 nC, and QGSF = 15 nC, there is
200 mW in each driver, which is below the 400 mW
ǒ
VR
1*
Ǔ
2 ǒ1*n DǓ
n f SW C X R O
(eq. 32)
In this example, the overall ramp signal is 0.862 V. If the
ramp size is smaller than 0.5 V, increase the ramp size to be
at least 0.5 V by decreasing the ramp resistor for noise
immunity.
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23
ADP3290
Current Limit Setpoint
IMON Setpoint
To select the current limit setpoint, first find the resistor
value for RLIM. The current limit threshold for the ADP3290
is set with a constant current source (IILIM = 4/3*IREF)
flowing out of the ILIM pin, which sets up a voltage (VLIM)
across RLIM. Thus, increasing RLIM now increases the
current limit. RLIM can be found using:
R LIM +
I
R CS
V LIM
+ LIM
4
I ILIM
V REF
3
DCR
R REF
R PH
According to the function definition, IMON output voltage
should represent the load condition within the whole load
current range. The formula below will result RIMON in need:
R IMON +
I PHMAX +
V COMP(MAX) * V BIAS
V RT
D MAX
f SW
ǒV IN * V VIDǓ
L
Feedback Loop Compensation Design
Optimized compensation of the ADP3290 allows the best
possible response of the regulator output to a load change. The
basis for determining the optimum compensation is to make
the regulator and output decoupling appear as an output
impedance that is entirely resistive over the widest possible
frequency range, including dc, and equal to the droop
resistance (RO). With the resistive output impedance, the
output voltage droops in proportion to the load current at any
load current slew rate. This ensures optimal positioning and
minimizes the output decoupling.
Because of the multi−mode feedback structure of the
ADP3290, the feedback compensation must be set to make
the converter output impedance work in parallel with the
output decoupling to make the load look entirely resistive.
Compensation is needed for several poles and zeros created
by the output inductor and the decoupling capacitors (output
filter).
A type−three compensator on the voltage feedback is
adequate for proper compensation of the output filter.
Equation 38 to Equation42 are intended to yield an optimal
starting point for the design; some adjustments may be
necessary to account for PCB and component parasitic
effects (see the Tuning the ADP3290 section).
(eq. 34)
(eq. 35)
For the ADP3290, the maximum COMP voltage
(VCOMP(MAX)) is 4.4 V and the COMP pin bias voltage
(VBIAS) is 1.2 V. In this example, the maximum duty cycle
is 0.433 and the peak current is 46.4 A.
The limit of the peak per−phase current described earlier
during the secondary current limit is determined by:
I PHLIM +
V COMP(CLAMPED) * V BIAS
AD
R DS(MAX)
(eq. 37)
Here, IL is the total load current, M =10 is the current gain
for IMON. Since IMON output clamp voltage is around 1.1 V,
VIMON is selected as 0.8V when IL = IMAX (130A). While
RLIM = 7.5 k, RIMON is calculated as 5 k, for which
4.99 k is chosen as the nearest 1% value.
There is a capacitor (CIMON) in parallel with RIMON, in
order to filter output current ripple. The time constant of
RIMON * CIMON should be much bigger (> 10 x) than circuit
switching period. In this example, CIMON is selected as 0.1 F.
(eq. 33)
Here, ILIM is the peak average current limit for the supply
output. The peak average current is the dc current limit plus
the output ripple current. In this example, choose
ILIM_DC =150 A (130% * TDC ) and having a ripple current
of 10 A gives an ILIM of 160 A. RCS is selected as 110 k
in this example, RPH is 68.1 k, DCR is 0.57 m (Delta
THCBR1290−221−R). This results in an RLIM = 7.4 k, for
which 7.5 k is chosen as the nearest 1% value.
The per−phase initial duty cycle limit and peak current
during a load step are determined by:
D MAX + D
V IMON
V
R LIM
+ IMON
I IMON
M RO IL
(eq. 36)
For the ADP3290, the current balancing amplifier gain
(AD) is 5 and the clamped COMP pin voltage is 3.3 V. Using
an RDS(MAX) of 4.5 m (low−side on resistance at 150°C)
results in a per−phase peak current limit of 93.3 A. This
current level can be reached only with an absolute short at
the output, and the current limit latchoff function shuts down
the regulator before overheating can occur.
First, compute the time constants for all the poles and zeros in the system using Equation 38 to Equation 42.
RE + n
RO ) AD
RE + 4
1 m ) 5
TA + CX
R DS )
5.25 m )
ǒR O * R 1Ǔ ) L X
T B + ǒR X ) R 1 * R OǓ
R L V RT 2 L (1 * n D) V RT
)
V VID
n C X R O V VID
RO
220 nH (1 * 0.467) 0.862 V
+ 38.7 m
4 4.48 mF 1 m 1.4 V
0.57 m 0.862 V 2
)
1.4 V
RO * R1
+ 4.48 mF
RX
ǒ1 m * 0.5 mǓ ) 250 pH
1 m
C X + ǒ0.6 m ) 0.5 m * 1 mǓ
4.48 mf + 448 ns
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24
1 m * 0.5 m
+ 2.45 s
0.6 m
(eq. 38)
(eq. 39)
(eq. 40)
ADP3290
V RT
TC +
TD +
ǒ
Ǔ
AD RDS
2 f SW
L*
V VID
CX
CX
RE
CZ
0.862 V
+
R 2O
ǒR O * R 1Ǔ ) C Z
RO
ǒ220 nH * 52
1.4 V
+
38.7 m
4.48 mF
4.48 mF
5.25 m
450 kHz
396 F
Ǔ
+ 3.04 s
ǒ1 mǓ
(eq. 41)
2
ǒ1 m * 0.5 mǓ ) 396 F
1 m
+ 673 ns
(eq. 42)
where:
R’ is the PCB resistance from the bulk capacitors to the ceramics.
RDS is the total low−side MOSFET on resistance per phase.
In this example, AD is 5, VRT equals 0.862 V, R’ is approximately 0.5 m (assuming a 4−layer, 1 ounce motherboard), and
LX is 250 pH for the 8 Al−Poly capacitors.
The compensation values can then be solved using:
CA +
n
RO TA
4 1 m
+
RE RB
38.7 m
2.45 s
1.21 k
209 pF
(eq. 43)
RA +
TC
3.04 s
+
+ 14.5 k
CA
209 pF
(eq. 44)
CB +
TB
448 ns
+
+ 370 pF
RB
1.21 k
(eq. 45)
C FB +
TD
673 ns
+
+ 46.4 pF
RA
14.5 k
(eq. 46)
Figure 13. Typical Transient Response for Design
Example Load Release
1-Vo, 3-COMP, 4-TRDET, D0~D2-PWM1~3
These are the starting values prior to tuning the design that
account for layout and other parasitic effects (see the Tuning
the ADP3290 section). The final values selected after tuning
are:
CA = 120 pF
CIN Selection and Input Current di/dt Reduction
In continuous inductor current mode, the source current of
the high­side MOSFET is approximately a square wave with
a duty ratio equal to n × VOUT/VIN and an amplitude of
one­nth the maximum output current. To prevent large
voltage transients, a low ESR input capacitor, sized for the
maximum rms current, must be used. The maximum rms
capacitor current is given by:
RA = 28 k
CB = 120 pF
CFB = 3.3 pF
Figure 12 and Figure 13 show the typical transient
response using these compensation values.
I CRMS + D
I CRMS + 0.117
IO
115 A
ǸN 1 D * 1
Ǹ4
(eq. 47)
1
* 1 + 14.3 A
0.117
The capacitor manufacturer’s ripple−current ratings are
often based on only 2000 hours of life. As a result, it
advisable to further derate the capacitor or to choose a
capacitor rated at a higher temperature than required.
Several capacitors can be placed in parallel to meet size or
height requirements in the design. In this example, the input
capacitor bank is formed by three 680 F, 16 V aluminum
electrolytic capacitors and twelve 4.7 F ceramic capacitors.
To reduce the input current di/dt to a level below the
recommended maximum of 0.1 A/s, an additional small
inductor (L > 370 nH at 18 A) should be inserted between the
converter and the supply bus. This inductor also acts as a
filter between the converter and the primary power source.
Figure 12. Typical Transient Response for Design
Example Load Step
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25
ADP3290
Thermal Monitor Design
RTTSENSE values of 8.98 k for VRFAN and 6.58 k for
VRHOT.
These values correspond to a thermistor temperature of
~100°C and ~110°C when using the same type of 100 k
NTC thermistor used in the current sense amplifier.
An additional fixed resistor in parallel with the thermistor
allows tuning of the trip point temperatures to match the
hottest temperature in the VR, when the thermistor itself is
directly sensing a proportionately lower temperature.
Setting this resistor value is best accomplished with a
variable resistor during thermal validation and then fixing
this value for the final design.
Additionally, a 0.1 F capacitor should be used for
filtering noise.
The thermistor is used on the TTSENSE input of the
ADP3290 for monitoring the temperature of the VR. A
constant current of 123 A is sourced out of this pin and runs
through a thermistor network such as the one shown in
Figure 14.
ADP3290
9
VRHOT
10
TTSNS
OPTIONAL
TEMPERATURE
0.1mF
ADJUST
Shunt Resistor Design
RESISTOR
NEAR CLOSEST PHASE
The ADP3290 uses a shunt to generate 5.0 V from the
12 V supply range. A trade off can be made between the
power dissipated in the shunt resistor and the UVLO
threshold. Figure 15 shows the typical resistor value needed
to realize certain UVLO voltages. It also gives the maximum
power dissipated in the shunt resistor for these UVLO
voltages.
R TTSENSE
Figure 14. VR Thermal Monitor Circuit
A voltage is generated from this current through the
thermistor and sensed inside the IC. When the voltage reaches
1.105V, the VRFAN output gets set. When the voltage
reaches 0.81 V, the VRHOT gets set. This corresponds to
550
0.50
500
0.45
RSHUNT ()
450
400
0.40
PSHUNT
RSHUNT
0.35
350
0.30
300
0.25
250
0.20
200
0.15
150
7.0
8.0
7.5
9.0
8.5
10.0
9.5
10.5
PSHUNT (W)
PLACE THERMISTOR
0.10
11.0
VIN (UVLO)
Figure 15. Typical Shunt Resistor Value and Power Dissipation for Different UVLO Voltage
The maximum power dissipated is calculated using
Equation 48.
P MAX +
ǒVIN(MAX) * VCC(MIN)Ǔ
R SHUNT
The CECC standard specification for power rating in
surface mount resistors is: 0603 = 0.1 W, 0805 = 0.125 W,
1206 = 0.25 W.
2
(eq. 48)
Tuning the ADP3290
1. Build a circuit based on the compensation values
computed from the design spreadsheet.
2. Hook up the dc load to the circuit, turn it on, and
verify its operation. Also, check for jitter at no
load and full load.
where:
VIN(MAX) is the maximum voltage from the 12 V input
supply (if the 12 V input supply is 12 V ± 5%,
VIN(MAX) = 12.6 V; if the 12 V input supply is 12 V ± 10%,
VIN(MAX) = 13.2 V). VCC(MIN) is the minimum VCC voltage
of the ADP3290. This is specified as 4.75 V. RSHUNT is the
shunt resistor value.
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ADP3290
DC Load Line Setting
for each change, and then average to get the
overall load line slope (ROMEAS).
7. If ROMEAS is off from RO by more than 0.05 m,
use Equation 50 to adjust the RPH values.
3. Measure the output voltage at no load (VNL).
Verify that it is within tolerance.
4. Measure the output voltage at full load cold
(VFLCOLD). Let the board sit for ~10 minutes at
full load, and then measure the output (VFLHOT).
If there is a change of more than a few mV, adjust
RCS1 and RCS2 using Equation 49 and Equation 51.
R CS2(NEW) + R CS2(OLD)
V NL * V FLCOLD
V NL * V FLHOT
R CS2(NEW) + R CS2(OLD)
(eq. 49)
1
R CS1(OLD))R TH(25oC)
R CS1(OLD)
(eq. 50)
8. Repeat Step 6 and Step 7 to check the load line.
Repeat adjustments if necessary.
9. When the dc load line adjustment is complete, do
not change RPH, RCS1, RCS2, or RTH for the
remainder of the procedure.
10. Measure the output ripple at no load and full load
with a scope, and make sure it is within
specifications.
5. Repeat Step 4 until the cold and hot voltage
measurements remain the same.
6. Measure the output voltage from no load to full
load using 5 A steps. Compute the load line slope
R CS1(NEW) +
R OMEAS
RO
R TH(25oC))ǒR CS1(OLD)*R CS1(NEW)Ǔ
ǒRCS1(OLD)*RTH(25 C)Ǔ
*
o
AC Load Line Setting
1
R TH(25oC)
(eq. 51)
values are available. It is a good idea to have
locations for two capacitors in the layout for this.
11. Remove the dc load from the circuit and hook up
the dynamic load.
12. Hook up the scope to the output voltage and set it
to dc coupling with the time scale at 100 s/div.
13. Set the dynamic load for a transient step of about
40 A at 1 kHz with 50% duty cycle.
14. Measure the output waveform (use dc offset on
scope to see the waveform). Try to use a vertical
scale of 100 mV/div or finer. This waveform
should look similar to Figure 16.
R CS(NEW) + R CS(OLD)
V ACDRP
V DCDRP
(eq. 52)
17. Repeat Step 11 to Step 13 and repeat the
adjustments, if necessary. Once complete, do not
change CCS for the remainder of the procedure.
Set the dynamic load step to maximum step size.
Do not use a step size larger than needed. Verify
that the output waveform is square, which means
that VACDRP and VDCDRP are equal.
Initial Transient Setting
18. With the dynamic load still set at the maximum step
size, expand the scope time scale to either 2 s/div
or 5 s/div. The waveform can have two overshoots
and one minor undershoot (see Figure 17). Here,
VDROOP is the final desired value.
VACDRP
VDCDRP
VDROOP
Figure 16. AC Load Line Waveform
15. Use the horizontal cursors to measure VACDRP and
VDCDRP as shown in Figure 16. Do not measure
the undershoot or overshoot that happens
immediately after this step.
16. If VACDRP and VDCDRP are different by more than
a few millivolts, use Equation 51 to adjust CCS.
Users may need to parallel different values to get
the right one because limited standard capacitor
VTRAN1
VTRAN2
Figure 17. Transient Setting Waveform
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ADP3290
interconnection traces in the remainder of the power
delivery current paths. Keep in mind that each square unit of
1 ounce copper trace has a resistance of ~0.53 m at room
temperature.
Whenever high currents must be routed between PCB
layers, use vias liberally to create several parallel current
paths, so the resistance and inductance introduced by these
current paths is minimized and the via current rating is not
exceeded.
If critical signal lines (including the output voltage sense
lines of the ADP3290) must cross through power circuitry,
it is best to interpose a signal ground plane between those
signal lines and the traces of the power circuitry. This serves
as a shield to minimize noise injection into the signals at the
expense of making signal ground a bit noisier.
An analog ground plane should be used around and under
the ADP3290 as a reference for the components associated
with the controller. This plane should be tied to the nearest
output decoupling capacitor ground and should not be tied
to any other power circuitry to prevent power currents from
flowing into it.
The components around the ADP3290 should be located
close to the controller with short traces. The most important
traces to keep short and away from other traces are the FB
pin and CSSUM pin. The output capacitors should be
connected as close as possible to the load (or connector), for
example, a microprocessor core, that receives the power. If
the load is distributed, the capacitors should also be
distributed and generally be in proportion to where the load
tends to be more dynamic.
Avoid crossing any signal lines over the switching power
path loop described in the Power Circuitry Recommendations
sections.
19. If both overshoots are larger than desired, try
making the adjustments using the following
suggestions:
• Make the ramp resistor larger by 25% (RRAMP)
• For VTRAN1, increase CB or increase the switching
frequency
• For VTRAN2, increase RA and decrease CA by 25%
If these adjustments do not change the response, the
design is limited by the output decoupling. Check
the output response every time a change is made, and
check the switching nodes to ensure that the
response is still stable.
20. For load release (see Figure 18), if VTRANREL is
larger than the allowed overshoot, there is not
enough output capacitance. Either more
capacitance is needed, or the inductor values need
to be made smaller. When changing inductors,
start the design again using a spreadsheet and this
tuning procedure.
VTRANREL
VDROOP
Power Circuitry Recommendations
The switching power path should be routed on the PCB to
encompass the shortest possible length to minimize radiated
switching noise energy (EMI) and conduction losses in the
board. Failure to take proper precautions often results in
EMI problems for the entire PC system and noise−related
operational problems in the power converter control
circuitry. The switching power path is the loop formed by
the current path through the input capacitors and the power
MOSFETs, including all interconnecting PCB traces and
planes. Using short and wide interconnection traces is
especially critical in this path for two reasons: it minimizes
the inductance in the switching loop, which can cause high
energy ringing; and it accommodates the high current
demand with minimal voltage loss.
When a power dissipating component, for example, a
power MOSFET, is soldered to a PCB, it is recommended to
liberally use the vias, both directly on the mounting pad and
immediately surrounding it. Two important reasons for this
are improved current rating through the vias and improved
thermal performance from vias extended to the opposite side
of the PCB, where a plane can more readily transfer the heat
Figure 18. Transient Setting Waveform
Because the ADP3290 turns off all of the phases (switches
inductors to ground), no ripple voltage is present during load
release. Therefore, the user does not have to add headroom
for ripple. This allows load release VTRANREL to be larger
than VTRAN1 by the amount of ripple, and still meet
specifications.
If VTRAN1 and VTRANREL are less than the desired final
droop, this implies that capacitors can be removed. When
removing capacitors, also check the output ripple voltage to
make sure it is still within specifications.
Layout and Component Placement
The following guidelines are recommended for optimal
performance of a switching regulator in a PC system.
General Requirements
For good results, a PCB with at least four layers is
recommended. This provides the needed versatility for
control circuitry interconnections with optimal placement,
power planes for ground, input and output power, and wide
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ADP3290
Signal Circuitry Recommendations
to the air. Make a mirror image of any pad being used to
heatsink the MOSFETs on the opposite side of the PCB to
achieve the best thermal dissipation in the air around the
board. To further improve thermal performance, use the
largest possible pad area.
The output power path should also be routed to encompass
a short distance. The output power path is formed by the
current path through the inductor, the output capacitors, and
the load.
For best EMI containment, a solid power ground plane
should be used as one of the inner layers extending fully
under all the power components.
The output voltage is sensed and regulated between the
FB pin and the FBRTN pin, which connect to the signal
ground at the load. To avoid differential mode noise pickup
in the sensed signal, the loop area should be small. Thus, the
FB trace and FBRTN trace should be routed adjacent to each
other on top of the power ground plane back to the
controller.
The feedback traces from the switch nodes should be
connected as close as possible to the inductor. The CSREF
signal should be connected to the output voltage at the
nearest inductor to the controller.
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29
ADP3290
PACKAGE DIMENSIONS
LFCSP40 6x6, 0.5P
CASE 932AC−01
ISSUE A
D
NOTES:
1. DIMENSIONING AND TOLERANCING PER
ASME Y14.5M, 1994.
2. CONTROLLING DIMENSIONS: MILLIMETERS.
3. DIMENSION b APPLIES TO PLATED
TERMINAL AND IS MEASURED BETWEEN
0.15 AND 0.30mm FROM THE TERMINAL TIP.
4. COPLANARITY APPLIES TO THE EXPOSED
PAD AS WELL AS THE TERMINALS.
A
B
D1
PIN ONE
REFERENCE
E1
E
DIM
A
A1
A3
b
D
D1
D2
E
E1
E2
e
H
K
L
M
0.20 C
TOP VIEW
0.20 C
H
(A3)
0.10 C
A
NOTE 4
0.08 C
SIDE VIEW A1
C
4X
SEATING
PLANE
MILLIMETERS
MIN
MAX
0.80
1.00
0.00
0.05
0.20 REF
0.18
0.30
6.00 BSC
5.75 BSC
3.95
4.25
6.00 BSC
5.75 BSC
3.95
4.25
0.50 BSC
−−−
12 °
0.20
−−−
0.30
0.50
−−−
0.60
SOLDERING FOOTPRINT*
6.30
M
11
K
D2
4X
4.14
M
1
21
PIN 1
INDICATOR
40X
0.63
E2
4.14
40X
6.30
L
1
40
31
e
BOTTOM VIEW
40X
b
0.10 C A B
0.05 C
PACKAGE
OUTLINE
40X
0.50
PITCH
NOTE 3
0.28
DIMENSIONS: MILLIMETERS
*For additional information on our Pb−Free strategy and soldering
details, please download the ON Semiconductor Soldering and
Mounting Techniques Reference Manual, SOLDERRM/D.
FlexMode is a trademark of Analog Devices, Inc.
All brand names and product names appearing in this document are registered trademarks or trademarks of their respective holders.
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice
to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.
“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All
operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights
nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications
intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should
Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates,
and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death
associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal
Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.
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ADP3290/D