AD ADP3156JR-15

a
FEATURES
Active Voltage Positioning with Gain and Offset
Adjustment
Optimal Compensation for Superior Load Transient
Response
Fixed 1.5 V, 1.8 V and 2.5 V Output Versions
Dual N-Channel Synchronous Driver
On-Board Linear Regulator Controller
Total Output Accuracy ⴞ1% Over Temperature
High Efficiency, Current-Mode Operation
Short Circuit Protection
Overvoltage Protection Crowbar Protects Loads with
No Additional External Components
Power Good Output
SO-16 Package
APPLICATIONS
Desktop Computer Supplies
ACPI-Compliant Power Systems
General Purpose DC-DC Converters
Dual Power Supply Controller
for Desktop Systems
ADP3156
FUNCTIONAL BLOCK DIAGRAM
AGND
VCC DRIVE1 DRIVE2 PGND
SENSE+ SENSE–
PWRGD
DELAY
NONOVERLAP
DRIVE
SD
VREF +15%
2R
CROWBAR
IN
OFF
VREF +5% VREF –5%
CMPI
Q
VT1
S
R
gm
VT2
CT
R
VREF
REFERENCE
VLDO
CMPT
1.20V
FB
VIN
OFF-TIME
CONTROL
ADP3156
SENSE–
GENERAL DESCRIPTION
The ADP3156 is a highly efficient synchronous buck switching
regulator controller optimized for converting the 3.3 V or 5 V
main supply into lower supply voltages required on the motherboards of Pentium® III and other high performance processor
systems. The ADP3156 uses a current mode, constant off-time
architecture to drive two external N-channel MOSFETs at a
programmable switching frequency that can be optimized for
size and efficiency. It also uses a unique supplemental regulation
technique called active voltage positioning to enhance load
transient performance. Active voltage positioning results in a
DC/DC converter that provides the best possible transient response using the minimum number of output capacitors and
smallest footprint. Unlike voltage-mode and standard currentmode architectures, active voltage positioning adjusts the output
voltage as a function of the load current so that it is always
optimally positioned for a system transient.
The ADP3156 provides accurate and reliable short circuit
protection and adjustable current limiting. It also includes an
integrated overvoltage crowbar function to protect the microprocessor from destruction in case the core supply exceeds the
nominal programmed voltage by more than 15%.
CMP
The ADP3156 contains a linear regulator controller that is
designed to drive an external N-channel MOSFET. This linear
regulator is used to generate the auxiliary voltages (AGP, GTL,
etc.) required in most motherboard designs, and has been designed to provide a high bandwidth load-transient response. A
pair of external feedback resistors sets the linear regulator output voltage.
VCC +12V
22mF
R1
VIN +5V
CIN
+
1mF
SD VCC
DRIVE1
VLDO
VO2
L
RSENSE
VO
ADP3156
35kV
+
SENSE+
1000mF
FB
CMP SENSE–
20kV
R2
CCOMP
200pF
1nF
CO
DRIVE2
CT
AGND
PGND
Figure 1. Typical Application
Pentium is a registered trademark of Intel Corporation.
All other trademarks are the property of their respective holders.
REV. 0
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 1999
ADP3156–SPECIFICATIONS (0ⴗC ⱕ T ⱕ +70ⴗC, V
A
Parameter
OUTPUT ACCURACY
ADP3156-1.5 V
ADP3156-1.8 V
ADP3156-2.5 V
Symbol
CC
= 12 V, VIN = 5 V, unless otherwise noted)1
Conditions
VO
∆VO
Min
Typ
Max
Units
1.480
1.777
2.475
1.500
1.800
2.500
1.520
1.823
2.525
V
V
V
ILOAD = 10 A (Figure 2)
VIN = 4.75 V to 5.25 V
0.05
IQ
VSD = 0.6 V
TA = +25°C, VSD = 2.0 V
4.1
140
5.5
250
mA
µA
CURRENT SENSE THRESHOLD
VOLTAGE
VSENSE(TH)
VSENSE– Forced to VOUT – 3%
145
165
mV
CT PIN DISCHARGE CURRENT
IT
TA = +25°C
VOUT in Regulation
VOUT = 0 V
65
2
10
µA
µA
2.45
3.2
µs
OUTPUT VOLTAGE LINE
REGULATION
INPUT DC SUPPLY CURRENT2
Normal Mode
Shutdown
125
OFF-TIME
tOFF
CT = 150 pF
DRIVER OUTPUT TRANSITION
TIME
t R , tF
CL = 7000 pF (DRIVE1, 2)
TA = +25°C
120
200
ns
POSITIVE POWER GOOD TRIP POINT3
VPWRGD
% Above Output Voltage
5
8
%
NEGATIVE POWER GOOD TRIP POINT3
VPWRGD
% Below Output Voltage
POWER GOOD RESPONSE TIME
tPWRGD
CROWBAR TRIP POINT
VCROWBAR
ERROR AMPLIFIER
OUTPUT IMPEDANCE
ROERR
275
kΩ
ERROR AMPLIFIER
TRANSCONDUCTANCE
gm(ERR)
2.2
mmho
ERROR AMPLIFIER MINIMUM
OUTPUT VOLTAGE
VCMPMIN
VSENSE– Forced to VOUT + 3%
0.8
V
ERROR AMPLIFIER MAXIMUM
OUTPUT VOLTAGE
VCMPMAX
VSENSE– Forced to VOUT – 3%
2.4
V
ERROR AMPLIFIER BANDWIDTH –3 dB
BWERR
CMP = Open
500
kHz
LINEAR REGULATOR FEEDBACK
CURRENT
IFB
LINEAR REGULATOR
OUTPUT VOLTAGE
VO2
SHUTDOWN (SD) PIN
Low Threshold
High Threshold
Input Current
SDL
SDH
SDIC
% Above Output Voltage
Figure 2, VLDOIN = 1.8 V
RPROG = 5 kΩ, R2 = 20 kΩ,
IO2 = 1 A
Part Active
Part in Shutdown
1.8
%
–8
9
1.47
–5
%
500
µs
15
24
%
0.35
1
µA
1.5
1.53
V
0.6
V
V
µA
2.0
10
NOTES
1
All limits at temperature extremes are guaranteed via correlation using standard Statistical Quality Control (SQC) methods. Specifications subject to change without
notice.
2
Dynamic supply current is higher due to the gate charge being delivered to the external MOSFETs.
3
The trip point is for the output voltage coming into regulation.
Specifications subject to change without notice.
–2–
REV. 0
ADP3156
PIN FUNCTION DESCRIPTIONS
Pin
Mnemonic
Function
1, 2, 15
NC
No Connect.
3
AGND
Analog Ground. All internal signals of the ADP3156 are referenced to this ground.
4
SD
Shutdown. A logic high will place the ADP3156 in shutdown and disable both outputs. This pin
is internally pulled down.
5
FB
Feedback connection for the linear controller. Connect this pin to the resistor divider network to
set the output voltage of the linear regulator.
6
VLDO
Gate Drive for the linear regulator N-channel MOSFET.
7
SENSE–
Connects to the internal resistor divider that senses the output voltage. This pin is also the reference input for the current comparator.
8
SENSE+
(+) input for the current comparator. The output current is sensed as a voltage at this pin with
respect to SENSE–.
9
CT
External Capacitor CT connection to ground sets the off-time of the device.
10
CMP
Error Amplifier output and compensation point. The voltage at this output programs the
output current control level between the SENSE pins.
11
PWRGD
Power Good. An open drain signal indicates the output voltage is within a ± 5% regulation band.
12
VCC
Supply Voltage to ADP3156.
13
DRIVE2
Gate Drive for the (bottom) Synchronous Rectifier N-channel MOSFET. The voltage at DRIVE2
swings from ground to VCC.
14
DRIVE1
Gate Drive for the buck switch N-channel MOSFET. The voltage at DRIVE1 swings from
ground to VCC.
16
PGND
Power Ground. The drivers turn off the buck and synchronous MOSFETs by discharging their
gate capacitances to this pin. PGND should have a low impedance path to the source of the synchronous MOSFET.
ABSOLUTE MAXIMUM RATINGS*
PIN CONFIGURATION
Input Supply Voltage (VCC) . . . . . . . . . . . . . . . –0.3 V to +16 V
Shutdown Input Voltage . . . . . . . . . . . . . . . . –0.3 V to +16 V
Operating Ambient Temperature Range . . . . . . 0°C to +70°C
Junction Temperature Range . . . . . . . . . . . . . . 0°C to +150°C
θJA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90°C/W
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature (Soldering, 10 sec) . . . . . . . . . . . +300°C
16-Lead SOIC
Model
ADP3156JR-1.5
ADP3156JR-1.8
ADP3156JR-2.5
1.5 V
1.8 V
2.5 V
R-16A/SO-16
R-16A/SO-16
R-16A/SO-16
PGND
15
NC
AGND 3
14
DRIVE1
13
VLDO 6
11
PWRGD
SENSE– 7
10
CMP
SENSE+ 8
9
CT
NC = NO CONNECT
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the ADP3156 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
REV. 0
ADP3156
DRIVE2
TOP VIEW
FB 5 (Not to Scale) 12 VCC
ORDERING GUIDE
Package
Option
16
NC 2
SD 4
*This is a stress rating only; operation beyond these limits can cause the device to
be permanently damaged.
Buck Converter
Output Voltage
NC 1
–3–
WARNING!
ESD SENSITIVE DEVICE
ADP3156
22V
12V
100kV
ESR = 34mV
2700mF 3 2
(10V)
22mF
L2
1.7mH
5V
1mF
5V RTN
1mF
12V RTN
ADP3156-1.8
mP
SYSTEM
IRL3103
1000mF
RTN
NC
PGND 16
2
NC
NC 15
3
AGND
DRIVE1 14
4
SD
DRIVE2 13
5
FB
VCC 12
6
VLDO
7
SENSE–
CMP 10
8
SENSE+
CT 9
2kV
47pF
VO2
+1.5V
4A
1
IRL3103
L1
3mH
RSENSE
12.9mV
IRL3103
ESR = 60mV
470mF 3 4
VO
1.8V
7A
10BQ015
RTN
R1
110kV
PWRGD 11
CCOMP
2nF
R2
16kV
CT
200pF
220V
R4
5kV
1nF
220V
R3
20kV
Figure 2. ADP3156 Typical VRM8.4 AGP and GTL Chipset DC/DC Converter Circuit
AGND
VCC DRIVE1 DRIVE2 PGND
PWRGD
SENSE+ SENSE–
DELAY
SD
NONOVERLAP
DRIVE
VREF +15%
2R
CROWBAR
IN
OFF
VREF +5% VREF –5%
CMPI
Q
VT1
S
R
gm
VT2
CT
VREF
R
REFERENCE
VLDO
CMPT
FB
OFF-TIME
CONTROL
VIN
ADP3156
SENSE–
CMP
Figure 3. Functional Block Diagram
–4–
REV. 0
Typical Performance Characteristics–ADP3156
VOUT = 2.5V
VOUT = 1.8V
90
85
VOUT = 1.5V
FREQUENCY – kHz
EFFICIENCY – %
95
450
45
400
40
350
35
SUPPLY CURRENT – mA
100
300
250
200
150
100
80
30
25
QGATE(TOTAL) = 100nC
20
15
10
5
50
SEE FIGURE 2
75
0.5
1.5
2.5
3.5
4.5
5.5
OUTPUT CURRENT – Amps
0
50
6.5
Figure 4. Efficiency vs. Output
Current
0
100 200 300 400 500 600 700 800
TIMING CAPACITOR – pF
Figure 5. Frequency vs. Timing
Capacitor
SEE FIGURE 2
45
58
83
134
OPERATING FREQUENCY – kHz
397
Figure 6. Supply Current vs.
Operating Frequency
SEE FIGURE 2
IOUT = 10A
PRIMARY
N-DRIVE
DRIVER OUTPUT
VCC = +12V
VIN = +5V
I OUT = 10A
1
SECONDARY
N-DRIVE
DRIVER OUTPUT
OUTPUT VOLTAGE
50mV/DIV
OUTPUT CURRENT
7A TO 1A
2
DRIVE 1 AND 2 = 5V/DIV
500ns/DIV
Figure 7. Gate Switching Waveforms
OUTPUT VOLTAGE
50mV/DIV
100ns/DIV
10ms/DIV
Figure 8. Driver Transition
Waveforms
Figure 9. Transient Response,
7 A–1 A of Figure 2 Circuit
VCC VOLTAGE
5V/DIV
3
OUTPUT CURRENT
1A TO 7A
10ms/DIV
Figure 10. Transient Response,
1 A–7 A of Figure 2 Circuit
REV. 0
REGULATOR
OUTPUT VOLTAGE
1V/DIV
4
10ms/DIV
Figure 11. Power-On Start-Up
Waveforms
–5–
ADP3156
monitors the voltage between the SENSE+ and SENSE– pins.
When the voltage level between the two pins reaches the threshold level VT1, the high side drive output is switched to ground,
which turns off the high side MOSFET. The timing capacitor
CT is then discharged at a rate determined by the off-time controller. While the timing capacitor is discharging, the low side
drive output goes high, turning on the low side MOSFET. When
the voltage level on the timing capacitor has discharged to the
threshold voltage level VT2, comparator CMPT resets the SR
flip-flop. The output of the flip-flop forces the low side drive
output to go low and the high side drive output to go high. As a
result, the low side switch is turned off and the high side switch
is turned on. The sequence is then repeated. As the load current
increases, the output voltage starts to decrease. This causes an
increase in the output of the voltage-error amplifier, which, in
turn, leads to an increase in the current comparator threshold
VT1, thus tracking the load current. To prevent cross conduction of the external MOSFETs, feedback is incorporated to
sense the state of the driver output pins. Before the low side
drive output can go high, the high side drive output must be
low. Likewise, the high side drive output is unable to go high
while the low side drive output is high.
12V
SD
ADP3156
VCC
1mF
0.1mF
DRIVE1
CMP
DRIVE2
1kV
CT
SENSE+
SENSE–
4700pF
AGND
PGND
VOUT
100kV
OP27
1.2V
0.1mF
Figure 12. Closed-Loop Test Circuit for Accuracy
THEORY OF OPERATION
The ADP3156 uses a current-mode, constant-off-time control
technique to switch a pair of external N-channel MOSFETs in a
synchronous buck topology. Constant off-time operation offers
several performance advantages, including that no slope compensation is required for stable operation. A unique feature of
the constant-off-time control technique is that since the off-time
is fixed, the converter’s switching frequency is a function of the
ratio of input voltage to output voltage. The fixed off-time is
programmed by the value of an external capacitor connected to
the CT pin. The on-time varies in such a way that a regulated
output voltage is maintained as described below in the cycle-bycycle operation. Under fixed operating conditions the on-time
does not vary, and it varies only slightly as a function of load.
This means that switching frequency is fairly constant in standard VRM applications. In order to maintain a ripple current in
the inductor, which is independent of the output voltage (which
also helps control losses and simplify the inductor design), the
off-time is made proportional to the value of the output voltage.
Normally, the output voltage is constant and therefore the offtime is constant as well.
Power Good
The ADP3156 has an internal monitor that senses the output
voltage and drives the PWRGD pin of the device. This pin is an
open drain output whose high level (when connected to a pullup resistor) indicates that the output voltage has been within a
± 5% regulation band of the targeted value for more than 500 µs.
The PWRGD pin will go low if the output is outside the regulation band for more than 500 µs.
Output Crowbar
An added feature of using an N-channel MOSFET as the synchronous switch is the ability to crowbar the output with the
same MOSFET. If the output voltage is 15% greater than the
targeted value, the ADP3156 will turn on the lower MOSFET,
which will current-limit the source power supply or blow its
fuse, pull down the output voltage, and thus save the microprocessor from destruction. The crowbar function releases at approximately 50% of the nominal output voltage. For example, if
the output is programmed to 2.0 V, but is pulled up to 2.3 V or
above, the crowbar will turn on the lower MOSFET. If in this
case the output is pulled down to less than 1.0 V, the crowbar
will release, allowing the output voltage to recover to 2.0 V if
the fault condition has been removed.
Active Voltage Positioning
The output voltage is sensed at the SENSE– pin. SENSE– is
connected to an internal voltage divider. The output of the
divider is then compared to the internal reference. A unique
supplemental regulation technique called active voltage positioning with optimal compensation adjusts the output voltage as
a function of the load current so that it is always optimally positioned for a load transient. Standard (passive) voltage positioning, sometimes recommended for use with other architectures,
has poor dynamic performance which renders it ineffective
under the stringent repetitive transient conditions specified in
Intel VRM documents. Consequently, such techniques do not
allow the minimum possible number of output capacitors to be
used. Optimally compensated active voltage positioning, as used
in the ADP3156, provides a bandwidth for transient response
that is limited only by parasitic output inductance. This yields
an optimal load transient response with the minimum number
of output capacitors.
Shutdown
The ADP3156 has a shutdown (SD) pin that is pulled down by
an internal resistor. In this condition the device functions normally. This pin should be pulled high to disable the output
drives.
APPLICATION INFORMATION
A number of power conversion requirements must be considered when designing an ACPI compliant system. In normal
operating mode, 12 V, 5 V and 3.3 V are available from the
main supply. These voltages need to be converted into the
appropriate supply voltages for the Northbridge core, the
Southbridge core and RAMBUS memory, as well as supplies for
GTL and I/O drivers, CMOS memory and clock and graphics
(AGP) circuits.
Cycle-by-Cycle Operation
During normal operation (when the output voltage is regulated),
the voltage-error amplifier and the current comparator (CMPI)
are the main control elements. (See the block diagram of Figure
3). During the on-time of the high side MOSFET, CMPI
–6–
REV. 0
ADP3156
During the standby operating state, the 12 V, 5 V and 3.3 V
power supply outputs are disabled, and only a low power 5 V
rail (5VSB) is available. The circuits that must remain active in
standby must be able to run from 5VSB. To accomplish this,
power routing is required to allow switching between normal
and standby supplies. Lack of a 12 V rail in standby makes control
of linear outputs difficult, and with up to 8 A demand from the
1.5 V and 1.8 V rails, an all-linear solution is inefficient.
Slew rate of load current change: di1/dt = di2 /dt >10 A/µs
The absence of an inductor on the 1.5 V linear regulated output
allows the output current to respond quickly and the linear
regulator MOSFET’s resistance to be modulated quickly. This,
and some small bypassing capacitors, essentially insulates the
1.5 V output from transient activity on the 1.8 V output. However, this same fast response characteristic means that any 1.5 V
transient activity will be passed straight through the linear regulator to the 1.8 V output. This means that the 1.8 V output filter
capacitor selection must consider both 1.8 V and 1.5 V load
transients.
Figure 13 shows a typical ACP-compliant Pentium III / chipset
power management system using the ADP3155 and ADP3156.
The ADP3155 provides VID switched output and two linear
regulators for standby operation. A charge-pump-doubled 5VSB is
ORed into the supply rail to supply the linear regulators during
standby operation. The VID output collapses when the main
5 V rail collapses, but the N-channel MOSFET linear regulators can continue to supply current from the ~9 V supply.
The ADP3156 provides 1.8 V via its main switching regulator,
and allows efficient linear regulation of 1.5 V rail by using the
1.8 V output as its source.
In this design example, worst case consideration requires that
the 1.8 V output be designed for transient current loading of
I1MAX + I2MAX = 7 A. Also, because a practical switching regulator design will have a current slew rate of <1 A/µs due to the
inductor, nearly the entire 7 A transient current must be absorbed by the output capacitors.
CT Selection for Operating Frequency
The ADP3156 uses a constant-off-time architecture with tOFF
determined by an external timing capacitor CT. Each time the
high side N-channel MOSFET switch turns on, the voltage
across CT is reset to approximately 3.3 V. During the off-time,
CT is discharged by a constant current of 65 µA. Once CT reaches
2.3 V, a new on-time cycle is initiated. The value of the off-time
is calculated using the continuous-mode operating frequency.
Assuming a nominal operating frequency of fNOM = 200 kHz at
an output voltage of 1.8 V, the corresponding off-time is:
The design parameters for an ACPI-compliant Pentium III
peripheral system depend on what peripherals are used
(e.g., AGP) and what their specifications are. The following is
an example where the higher of two low system voltages (1.8 V
and 1.5 V) is created directly with the main buck converter, and
also used to supply power for the lower output voltage using the
ADP3156’s linear regulator controller.
Input voltage (power source): VIN = 5 V

V  1
tOFF = 1 – O 
= 3.2 µs

VIN  f NOM
Auxiliary voltage: VCC = 12 V
Output voltages and tolerances: V1 = 1.8 V ± 5%, V2 = 1.5 V ±
5%
The timing capacitor can be calculated from the equation:
Maximum output currents: I1MAX = 3 A, I2MAX = 4 A
CT =
ATX
(OR NLX)
POWER
SUPPLY
12V
12V
5V
5V
3.3V
= 208 pF
1V
12V
POWER MANAGEMENT
STATE COMMAND
3.3V
5V_ALWAYS
5V_PM
ATX_PGOOD
ATX_POWERGOOD
ATX_SHUTDOWN
tOFF × 65 µA
PMSC
5V_PM
5V_PM
ATX_POWER GOOD
ATXPG
POWER
MANAGEMENT
FUNCTIONS
VCC
12V
ATX_SHUTDOWN
GND
DUAL
OUTPUT
SUPPLY
VCC
MAIN_
CTRLS
1.8V FOR
SB CORE,
MEM, ETC
OUT
1.5V VTT
FOR GTL
OUT
SWITCHER
1.5V OR 3.3V
VDDQ FOR AGP
VDDQ
TYPEDET# FOR
AGP SELECT
SELECT
IN
ADP3155
ADP3156
LIN_
CTRLS
LIN#2_
CTRLS
5V
LIN#1_
CTRLS
5V
CTRLS
LINEAR
VID
VID_4:0
MAIN_
CTRLS
IN
SWITCHER
5V_PM
IN
IN
LINEAR#1
CTRLS
5V_PM
3.3V
POWER ROUTING
IN
LINEAR#2
CTRLS
1.5V_IN
Figure 13. ACPI-Compliant Pentium III System Block Diagram
REV. 0
TRIPLE
OUTPUT
SUPPLY
CTRLS
CTRLS
3.3V_IN
VCC
–7–
OUT
CPU
VCORE @ VID
OUT
3.3V_PM
FOR POWER
MANAGEMENT
OUT
2.5V_PM
FOR CMOS,
CLOCK, MEMORY
ADP3156
The converter operates at the nominal operating frequency only
at the VOUT specified above, and at light load. At higher load
conditions, the operating frequency decreases due to the parasitic voltage drops across the power devices. The actual minimum frequency at VOUT = 1.8 V is calculated from Equation 1,
and is a function of the finite resistances of various components
in the power converter.
lowest cost core is made of powdered iron, for example the #52
material from Micrometals, Inc., but yields a larger size inductor.
COUT Selection—Determining the Capacitance
The minimum capacitance of the output capacitor is determined
from the requirement that the output be held up while the inductor current ramps up (or down) to the new value. The minimum capacitance should produce an initial dv/dt which is equal
(but opposite in sign) to the dv/dt obtained by multiplying the
di/dt in the inductor and the ESR of the capacitor.
COUT Selection—Determining the ESR
The required ESR and capacitance drive the selection of the
type and quantity of the output capacitors. The ESR must be
small enough that both the resistive voltage deviation due to a
step change in the load current and the output ripple voltage
stay below the values defined in the specification of the supplied
circuitry. The capacitance must be large enough that the output
is held up while the inductor current ramps up or down to the
value corresponding to the new load current.
C MIN =
C MIN =
(2 × 5% × 1.5 V) – (2 × 1% × 1.5 V) – (1% × 1.5 V) = 105 mV
This sets the maximum ESR at 105 mV/7 A = 15 mΩ. Four
parallel capacitors of 470 µF with a maximum ESR of 60 mΩ
will achieve the 15 mΩ maximum net ESR. Whether or not the
capacitance is sufficient must be determined after the inductor
is selected.
= 871 µF
RSENSE = (125 mV)/[1.2(IOMAX + IRPP/2)] = 12.9 mΩ
The minimum inductance gives a peak-to-peak ripple current of
2.14 A, or 35% of the maximum dc output current IOMAX. The
inductor peak current in normal operation is:
Once RSENSE has been chosen, the peak short-circuit current
ISC(PK) can be predicted from the following equation:
ILPEAK = IOMAX + IRPP/2 = 8.07 A
ISC(PK) = (145 mV)/RSENSE = (145 mV)/(12.9 mΩ)= 11.2 A
The inductor valley current is:
The actual short-circuit current is less than the above-calculated
ISC(PK) value because the off-time rapidly increases when the
output voltage drops below 1 V. The relationship between the
off-time and the output voltage is:
ILVALLEY = ILPEAK – IRPP /2 = 5.93 A
The inductor for this application should have an inductance of
not less than 2.24 µH at full load current and should not saturate at the worst-case overload or short circuit current at the
maximum specified ambient temperature. For this example, it is
assumed the inductance might drop as much as 33% due to
load current, so its initial value might be as high as 3.36 µH.
tOFF ≈
Tips for Selecting the Inductor Core
CT × 1 V
VO
+ 2 µA
360 kΩ
With a short circuit across the output, the off-time will be about
104 µs. During that time the inductor current gradually decays.
The amount of decay depends on the L/R time constant in the
output circuit. With an inductance of 2.24 µH and total resistance of 40 mΩ (the inductor’s series resistance plus the sense
resistor), the time constant will be 56 µs. This yields a valley
Ferrite designs have very low core loss, so the design should
focus on copper loss and on preventing saturation. Molypermalloy,
or MPP, is a low loss core material for toroids, and it yields the
smallest size inductor, but MPP cores are more expensive than
ferrite cores or the Kool Mµ® cores from Magnetics, Inc. The
tOFF
)
The current comparator threshold sets the peak of the inductor
current yielding a maximum output current IOMAX, which equals
the peak value less half of the peak-to-peak ripple current. Solving for RSENSE and allowing a 20% margin for overhead, and
using the minimum current sense threshold of 125 mV yields:
VOtOFF RE ( MAX ) 1.5 × 3.2 µs × 7 mΩ
=
= 2.24 µH
VRIPPLE p − p
15 mV
×
(
15 mΩ 1.8 V / 3.36 µH
The value of RSENSE is based on the required output current.
The current comparator of the ADP3156 has a threshold range
that extends from 0 mV to 125 mV (minimum). Note that the
full 125 mV range cannot be used for the maximum specified
nominal current, as headroom is needed for current ripple and
transients.
The minimum inductor value can be calculated from ESR, offtime, dc output voltage and allowed peak-to-peak ripple voltage
using the following equation:
1
7 A−0 A
RSENSE
Inductor Selection
f MIN =
RE (di / dt )
In the above equation the value of di/dt is calculated as the
smaller voltage across the inductor (i.e., the smaller of
VIN – VOUT and VOUT) divided by the maximum inductance
(3.36 µH) of the inductor. The four parallel-connected
470 µF capacitors have a total capacitance of 1880 µF, so the
minimum capacitance requirement is met with ample margin.
Taking into account the ±1% setpoint accuracy of the ADP3156,
and assuming a 1% (or 15␣ mV) peak-to-peak ripple, the allowed
static voltage deviation of the output voltage when the load
changes between the minimum and maximum values is:
L MIN1 =
IOMAX – IOMIN
VIN – I IN RIN – IOMAX ( RDS(ON )HSF + RSENSE + RL ) – VO
VIN – I IN RIN – IOMAX ( RDS(ON )HSF + RSENSE + RL – RDS(ON )LSF )
–8–
(1)
REV. 0
ADP3156
economical choice for both the high side and low side positions.
Those devices have an RDS(ON) of 14 mΩ at VGS = 10 V and at
+25°C. The low side FET is turned on with at least 10 V. The
high side FET, however, is turned on with only 12 V – 5 V =
7 V. Checking the typical output characteristics of the device in
the data sheet, shows that for an output current of 10 A, and at
a VGS of 7 V, the VDS is 0.15 V. This gives an RDS(ON) only
slightly above the one specified at a VGS of 10 V, so the resistance increase due to the reduced gate drive can be neglected.
The specified RDS(ON) at the expected highest FET junction
temperature of +140°C must be modified by an RDS(ON) multiplier, using the graph in the data sheet. In this case:
current of 1.7 A and an average short-circuit current of about
6.5 A—meaning that there is actually a small degree of shortcircuit current foldback. To safely carry the maximum current,
the sense resistor must have a power rating of at least (11.2 A –
1.07 A)2 × 12.9 mW = 1.3 W.
Current Transformer Option
An alternative to using a low value and high power current sense
resistor is to reduce the sensed current by using a low cost current transformer and a diode. The current can then be sensed
with a small size, low cost SMT resistor. Using a transformer
with one primary and 50 secondary turns reduces the worst-case
resistor dissipation to a few mW. Another advantage of using
this option is the separation of the current and voltage sensing,
which makes the voltage sensing more accurate.
RDS(ON)MULT = 1.7
Using this multiplier, the expected RDS(ON) at +140°C is
1.7 × 14 = 24 mΩ.
Power MOSFETs
Two external N-channel power MOSFETs must be selected for
use with the ADP3156, one for the main switch, and an identical one for the synchronous switch. The main selection parameters for the power MOSFETs are the threshold voltage VGS(TH)
and the on resistance RDS(ON). The minimum input voltage
dictates whether standard threshold or logic-level threshold
MOSFETs must be used. For VIN > 8 V, standard threshold
MOSFETs (VGS(TH) < 4 V) may be used. If VIN is expected to
drop below 8 V, logic-level threshold MOSFETs (VGS(TH) <
2.5 V) are strongly recommended. Only logic-level MOSFETs
with VGS ratings higher than the absolute maximum of VCC
should be used.
The high side FET dissipation is:
PDFETHS = IRMSHS2RDS(ON) + 0.5 VINILPEAKQGfMIN/IG ~ 2.54 W
where the second term represents the turn-off loss of the FET.
(In the second term, QG is the gate charge to be removed from
the gate for turn-off and IG is the gate current. From the data
sheet, QG is about 50 nC–70 nC and the gate drive current
provided by the ADP3156 is about 1 A.)
The low side FET dissipation is:
PDFETLS = Irmsls2RDS(ON) = 0.49 W
The maximum output current IOMAX determines the RDS(ON)
requirement for the two power MOSFETs. When the ADP3156
is operating in continuous mode, the simplifying assumption can
be made that one of the two MOSFETs is always conducting
the average load current. For VIN = 5 V and VOUT = 1.8 V, the
maximum duty ratio of the high side FET is:
DMAXHF = (1 – fMIN × tOFF) = (1 – 150 kHz × 3.2 µs) = 52%
(Note that there are no switching losses in the low side FET.)
To maintain an acceptable MOSFET junction temperature,
proper heat sinking should be used. The heat sink and airflow
are chosen based on how low the impedance must be reduced in
order to keep the MOSFET’s junction temperature at an acceptably low level, according to the formula:
θHA = [(TJMAXOP – TA)¸PDFET] – θJC – θCH
where θHA is the thermal resistance from the heat sink to ambient air (and depends on airflow), TJMAXOP is the user-determined maximum acceptable operating temperature of the
MOSFET, and the last two factors are the thermal resistance
from junction-to-case of the device, and case-to-heat sink. Typically, the junction-to-case thermal resistance is 2°C/W, and the
case-to-heat sink resistance is 0.5°C/W.
The duty ratio of the low side (synchronous rectifier) FET under the maximum load condition is:
DMAXLF = 1 – DMAXHF = 48%
The maximum rms current of the high side FET is:
IRMSHS = [DMAXHF (ILVALLEY2 + ILPEAK2 + ILVALLEYILPEAK)/3]0.5
= 7.32 A rms
CIN Selection and Input Current di/dt Reduction
In continuous-inductor-current mode, the source current of the
high side MOSFET is a square wave with a duty ratio of VO/VlN.
To keep the input ripple voltage at a low value, one or more
capacitors with low equivalent series resistance (ESR) and adequate ripple-current rating must be connected across the input
terminals. The maximum rms current of the input bypass capacitors is:
The maximum rms current of the low side FET is:
0.5
IRMSLS = [DMAXLF (ILVALLEY2 + ILPEAK2 + ILVALLEYILPEAK)/3]
= 7.03 A rms
The RDS(ON) for each FET can be derived from the allowable
dissipation. Allowing 8% of the maximum output power for
FET dissipation, the total dissipation will be:
PFETALL = 0.08 VOIOMAX = 1.0 W
ICINRMS = IOMAX [DMAX × (1–DMAX)]0.5 = 3.5 A
Allocating half of the total dissipation for the high side FET and
half for the low side FET, the required minimum FET resistances will be:
For an FA-type capacitor with 2700 mF capacitance and 10 V
voltage rating, the ESR is 34 mΩ and the allowed ripple current
at 100 kHz (and similar frequencies) is 1.94 A. At +105°C, two
such capacitors may be connected in parallel to handle the calculated ripple current.
RDS(ON)HSF(MIN) = 1 W × 52%/(7.32A)2 = 9.7 mΩ
RDS(ON)LSF(MIN) = 1 W × 48%/(7.03A)2 = 9.7 mΩ
To further reduce the effect of the ripple voltage on the system
supply voltage bus and to reduce the input-current di/dt to
below the recommended maximum of 0.1 A/µs, an additional
small inductor should be inserted between the converter and the
supply bus (see Figure 2).
Note that there is a trade-off between converter efficiency and
cost. Larger FETs reduce the conduction losses and allow
higher efficiency, but increase the system cost. If efficiency is
not a major concern, the International Rectifier IRL3103 is an
REV. 0
–9–
ADP3156
Feedback Loop Compensation Design for Active Voltage
Positioning
Optimized compensation of the ADP3156 allows the best possible containment of the peak-to-peak output voltage deviation.
Any practical switching power converter is inherently limited by
the inductor in its output current slew rate to a value much less
than the slew rate of the load. Therefore, any sudden change of
load current will initially flow through the output capacitors,
and this will produce an output voltage deviation equal to the
ESR of the output capacitor array times the load current change.
To correctly implement active voltage positioning, the low frequency output impedance (i.e., the output resistance) of the
converter should be made equal to the maximum ESR of the
output capacitor array. This can be achieved by having a single
pole roll-off of the voltage gain of the gm error amplifier, where
the pole frequency coincides with the ESR zero of the output
capacitor. A gain with single pole roll-off requires that the gm
amplifier output pin be terminated by the parallel combination
of a resistor and capacitor. The required resistor value can be
calculated from the equation:
RC =
275 kΩ × RtTOTAL
275 kΩ – RtTOTAL
where:
RtTOTAL =
16.4 kΩ × RCS × IOMAX
VHI –VLO
where the quantities 16.4 kΩ and 275 kΩ are characteristics of
the ADP3156, the value of the current sense resistor, RCS, has
already been determined as above, and where VHI and VLO are
the respective upper and lower limits allowed for regulation.
Although a single termination resistor equal to RC would yield
the proper voltage positioning gain, the dc biasing of that resistor would determine how the regulation band is centered (i.e.,
note that sometimes the specified regulation band is asymmetrical with respect to the nominal VID voltage.) With the ADP3156,
the offset is already considered as part of the design procedure—
no special provision is required. To accomplish the dc biasing, it
is simplest to use two resistors to terminate the gm output, with
the lower resistor tied to ground and the upper resistor to the
12 V supply of the IC. The values of these resistors can be calculated using:
RUPPER = RC ×
VDIV
VOS
calculated using Equation 2, where VOUT(OS) is the offset from
the nominal VID-programmed value to the center of the specified regulation window for the output voltage. (Note this may be
either positive or negative.) For clarification, that offset is given
by:
1
VOUT (OS ) = (VHI +VLO )–VID
2
Finally, the compensating capacitance is determined from the
equality of the pole frequency of the error amplifier gain and the
zero frequency of the impedance of the output capacitor:
CCOMP =
CO × ESR
RtTOTAL
Trade-Offs Between DC Load Regulation and AC Load
Regulation
Casual observation of the circuit operation—e.g., with a voltmeter—would make it appear that the dc load regulation appears to be rather poor compared to a conventional regulator.
This would be especially noticeable under very light or very
heavy loads where the voltage is “positioned” near one of the
extremes of the regulation window rather than near the nominal
center value. It must be noted and understood that this low gain
characteristic (i.e., loose dc load regulation) is inherently required to allow improved transient containment (i.e., to achieve
tighter ac load regulation). That is, the dc load regulation is
intentionally sacrificed (but kept within specification) in order
to minimize the number of capacitors required to contain the
load transients produced by the CPU.
Linear Regulator
The ADP3156 linear regulator provides a low cost, convenient
and versatile solution for generating a lower supply rail in addition to the main output. The maximum output load current is
determined by the size and thermal impedance of the external
N-channel power MOSFET that is controlled by the ADP3156.
The output voltage, VO2 in Figure 14, is sensed at the FB pin of
the ADP3156 and compared to an internal 1.2 V reference in a
negative feedback loop which keeps the output voltage in regulation. If the load is being reduced or increased, the FET drive
will also be reduced or increased by the ADP3156 to provide a
well regulated ± 1% accurate output voltage. The output voltage
is programmed by adjusting the value of the external resistor
RPROG, shown in Figure 14.
VIN = +1.8V
ADP3156
and:
RLOWER = RC ×
VO2 = +1.5V
IO2 = 4.0A
VOS
VDIV – VOS
VLDO
IRL3103
FB
1000mF/10V
where VDIV is the resistor divider supply voltage (e.g., the recommended 12 V), and VOS is the offset voltage required on the
amplifier to produce the desired offset at the output. VOS is
VOS =
RC
RtTOTAL
RPROG
5kV
20kV
Figure 14. Linear Regulator Configuration


 Rt

 Rt

× 0.8 V + VOUT (OS ) TOTAL  – 1.7 V  TOTAL  + 6 RCS IOMAX 
1.36 kΩ
 275 kΩ 


–10–
(2)
REV. 0
ADP3156
Efficiency of the Linear Regulator
LAYOUT AND COMPONENT PLACEMENT GUIDELINES
The efficiency and corresponding power dissipation of the linear
regulator are not determined by the ADP3156. Rather, these are
a function of input and output voltage and load current. Efficiency is approximated by the formula:
η = 100% × (VOUT ⫼ VIN)
The following guidelines are recommended for optimal performance of a switching regulator in a PC system:
The corresponding power dissipation in the MOSFET, together
with any resistance added in series from input to output is given
by:
PLDO = (VIN(LDO) – VOUT(LDO)) × IOUT(LDO)
Minimum power dissipation and maximum efficiency are accomplished by choosing the lowest available input voltage that
exceeds the desired output voltage. However, if the chosen
input source is itself generated by a linear regulator, its power
dissipation will be increased in proportion to the additional
current it must now provide. For most PC systems, the lowest
available input source for the linear regulators, which is not
itself generated by a linear regulator, is 3.3 V from the main
power supply. However, in this case, the main output of the
ADP3156 creates a lower voltage that may be used as the source
supply for the linear regulator. Assuming that a 1.8 V main
output is used to provide power for a 1.5 V linear regulator
output, the efficiency will nominally be 1.5 V ÷ 1.8 V = 83%.
If the 1.5 V output must supply a 4 A maximum load (a total of
6 W), the steady state dissipation in the MOSFET may be as
high as:
PLDO(MAX) = (VIN – VOUT)
= 1.2 W
×
1. For best results, a four-layer (minimum) PCB is recommended. This should allow the needed versatility for control
circuitry interconnections with optimal placement, a signal
ground plane, power planes for both power ground and the
input power (e.g., 5 V), and wide interconnection traces in
the rest of the power delivery current paths. Each square
unit of 1 ounce copper trace has a resistance of ~0.53 mΩ at
room temperature.
2. Whenever high currents must be routed between PCB layers
vias should be used liberally to create several parallel current
paths so that the resistance and inductance introduced by
these current paths is minimized and the via current rating is
not exceeded.
3. The power and ground planes should overlap each other as
little as possible. It is generally the easiest (although not
necessary) to have the power and signal ground planes on
the same PCB layer. The planes should be connected nearest to the first input capacitor where the input ground current flows from the converter back to the power source (e.g.,
5 V).
4. If critical signal lines (including the voltage and current
sense lines of the ADP3156) must cross through power
circuitry, it is best if a signal ground plane can be interposed
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.
IOUT(MAX) = (1.8 V – 1.5 V) × 4 A
The minimum acceptable on resistance of the MOSFET that
would deliver the 4 A load with only a 0.3 V difference between
input and output is:
RDS(ON, MAX) = (VOUT – VIN) ÷ IOUT(MAX) = (1.8 V – 1.5 V) ÷ 4 A
= 75 mΩ
There are many MOSFETs to choose from that can support the
maximum power dissipation without need for a heat sink and
without exceeding the calculated maximum on-resistance. For
simplicity it may be desirable to use the same MOSFET as is
used for the main power converter.
The output voltage may be programmed by the RPROG resistor
as follows:
 V

 1.5

RPROG =  O2 – 1 × 20 kΩ = 
− 1 × 20 kΩ = 5 kΩ
 1.2

 1.2 V

The output filter capacitor maximum allowed ESR is:
ESR~VTR2/IOMAX = 0.036/0.5 = 0.072 Ω
where VTR2 is the maximum allowed transient deviation on the
output. This requirement is met using a 1000 µF/10 V LXV
series capacitor from United Chemicon. For applications requiring higher output current, a heat sink and/or a larger MOSFET
should be used to reduce the MOSFET’s junction-to-ambient
thermal impedance.
REV. 0
General Recommendations
5. The PGND pin of the ADP3156 should connect first to a
ceramic bypass capacitor (on the VCC pin) and then into the
power ground plane using the shortest possible trace. However, the power ground plane should not extend under other
signal components, including the ADP3156 itself. If necessary, follow the preceding guideline to use the signal plane
as a shield between the power ground plane and the signal
circuitry.
6. The AGND pin of the ADP3156 should connect first to the
timing capacitor (on the CT pin), and then into the signal
ground plane. In cases where no signal ground plane can be
used, short interconnections to other signal ground circuitry
in the power converter should be used—the compensation
capacitor being the next most critical.
7. The output capacitors of the power converter should be
connected to the signal ground plan even though power
current flows in the ground of these capacitors. For this
reason, it is advised to avoid critical ground connections (e.g.,
the signal circuitry of the power converter) in the signal ground
plane in between the input and output capacitors. It is also
advised to keep the planar interconnection path short (i.e.,
have input and output capacitors close together).
8. The output capacitors should also be connected as closely as
possible to the load (or connector) which receives the power
(e.g., a microprocessor core). If the load is distributed, the
capacitors also should be distributed, and generally in proportion to where the load tends to be more dynamic.
–11–
9. Absolutely avoid crossing any signal lines over the switching
power path loop, described below.
15. For best EMI containment, the power ground plane should
extend fully under all the power components except the
output capacitors. These are: the input capacitors, the power
MOSFETs and Schottky diode, the inductor, the current
sense resistor, and any snubbing elements that might be
added to dampen ringing. Avoid extending the power ground
under any other circuitry or signal lines, including the voltage and current sense lines.
Power Circuitry
10. The switching power path should be routed on the PCB to
encompass the smallest possible area in order to minimize
radiated switching noise energy (i.e., EMI). Failure to take
proper precaution often results in EMI problems for the
entire PC system as well as 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, the two FETs, and the power Schottky
diode if used, including all interconnecting PCB traces and
planes. The use of 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 highenergy ringing, and it accommodates the high current demand with minimal voltage loss.
Signal Circuitry
11. A power Schottky diode (1~2 Adc rating) placed from the
lower FET’s source (anode) to drain (cathode) will help to
minimize switching power dissipation in the upper FET. In
the absence of an effective Schottky diode, this dissipation
occurs through the following sequence of switching events.
The lower FET turns off in advance of the upper FET turning on (necessary to prevent cross-conduction). The circulating current in the power converter, no longer finding a
path for current through the channel of the lower FET,
draws current through the inherent body-drain diode of the
FET. The upper FET turns on, and the reverse recovery
characteristic of the lower FET’s body-drain diode prevents
the drain voltage from being pulled high quickly. The upper
FET then conducts very large current while it momentarily
has a high voltage forced across it, which translates into
added power dissipation in the upper FET. The Schottky
diode minimizes this problem by carrying a majority of the
circulating current when the lower FET is turned off, and by
virtue of its essentially nonexistent reverse recovery time.
16. The output voltage is sensed and regulated between the
AGND pin (which connects to the signal ground plane) and
the SENSE– pin. The output current is sensed (as a voltage)
and regulated between the SENSE– pin and the SENSE+
pin. In order to avoid differential mode noise pickup in
those sensed signals, their loop areas should be small. Thus
the SENSE– trace should be routed atop the signal ground
plane, and the SENSE+ and SENSE– traces should be routed
as a closely coupled pair (SENSE+ should be over the signal
ground plane as well).
C3598–2–4/99
ADP3156
17. The SENSE+ and SENSE– traces should be Kelvin connected to the current sense resistor so that the additional
voltage drop due to current flow on the PCB at the current
sense resistor connections does not affect the sensed voltage.
It is desirable to both have the ADP3156 close to the output
capacitor bank and not in the output power path so that any
voltage drop between the output capacitors and the AGND
pin is minimized, and voltage regulation is not compromised.
OUTLINE DIMENSIONS
12. A small ferrite bead inductor placed in series with the drain
of the lower FET can also help to reduce this previously
described source of switching power loss.
Dimensions shown in inches and (mm).
16-Lead Standard Small Outline Package (SOIC)
(R-16A)
13. Whenever a power dissipating component (e.g., a power
MOSFET) is soldered to a PCB, the liberal use of vias both
directly on the mounting pad and immediately surrounding
it is recommended. Two important reasons for this are:
improved current rating through the vias (if it is a current
path), and improved thermal performance—especially if the
vias extended to the opposite side of the PCB where a plane
can more readily transfer the heat to the air.
0.1574 (4.00)
0.1497 (3.80)
PIN 1
14. The output power path, though not as critical as the switching power path, should also be routed to encompass a small
area. The output power path is formed by the current path
through the inductor, the current sensing resistor, the output capacitors, and back to the input capacitors.
16
9
1
8
0.050 (1.27)
BSC
0.0098 (0.25)
0.0040 (0.10)
–12–
0.2440 (6.20)
0.2284 (5.80)
0.0688 (1.75)
0.0532 (1.35)
0.0196 (0.50)
3 458
0.0099 (0.25)
88
0.0192 (0.49) SEATING 0.0099 (0.25) 08 0.0500 (1.27)
PLANE
0.0138 (0.35)
0.0160 (0.41)
0.0075 (0.19)
REV. 0
PRINTED IN U.S.A.
0.3937 (10.00)
0.3859 (9.80)