LINER LTC1703IG

LTC1703
Dual 550kHz Synchronous
2-Phase Switching Regulator
Controller with 5-Bit VID
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FEATURES
DESCRIPTIO
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The LTC®1703 is a dual switching regulator controller optimized for high efficiency with low input voltages. It includes
two complete, on-chip, independent switching regulator
controllers. Each is designed to drive a pair of external
N-channel MOSFET devices in a voltage mode feedback,
synchronous buck configuration. The LTC1703 includes
digital output voltage adjustment on side 1 that conforms to
the Intel Mobile VID specification. It uses a constantfrequency, true PWM design switching at 550kHz, minimizing external component size and cost and optimizing load
transient performance. The synchronous buck architecture
automatically shifts to discontinuous and then to Burst
Mode® operation as the output load decreases, ensuring
maximum efficiency over a wide range of load currents.
The LTC1703 features an onboard reference trimmed to 1%
and delivers better than 1.5% regulation at the converter
outputs. An optional latching FAULT mode protects the load
if the output rises 15% above the intended voltage. Each
channel can be enabled independently; with both channels
disabled, the LTC1703 shuts down and supply current drops
below 100µA.
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Side 1 Output Is Compliant with Intel Mobile
VID Specifications (Includes 5-Bit DAC)
0.9V to 2.0V Output Voltage with 25mV/50mV Steps
Two Sides Run Out-of-Phase to Minimize CIN
Precision Internal 0.8V ±1% Reference
Two Independent PWM Controllers in One Package
All N-Channel External MOSFET Architecture
No External Current Sense Resistor
550kHz Switching Frequency Minimizes External
Component Size
Very Fast Transient Response
Up to 25A Output Current per Channel
Low Shutdown Current: < 100µA
Small 28-Pin SSOP Package
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APPLICATIO S
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Mobile Pentium® III Processor Systems
Microprocessor Core and I/O Supplies
Multiple Logic Supply Generator
High Efficiency Power Conversion
, LTC and LT are registered trademarks of Linear Technology Corporation.
Burst Mode is a registered trademark of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
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TYPICAL APPLICATIO
Dual Output Mobile Pentium III Processor Supply
VOUT1
0.9V
TO 2V
15A
DCP1
MBR0520LT1
L1
1µH
1µF
+
DCP2
MBR0520LT1
QT2
L2
2.2µH
QT1
LTC1703
+
COUT1
180µF
4V
×6
QB1A
GND
CSS1
0.22µF
R21
100k
C31
220pF
1
2
QB1B
CCP1
1µF
3
4
5
RIMAX1,18.7k 6
7
8
9
10
C21
C11
11
15pF
220pF
12
13
R31, 10k
14
L1: MURATA LQT12535C1R5N12
L2: COILTRONICS UP2B-2R2
QT1, QB1A, QB1B: INTERNATIONAL RECTIFIER IRF7811
QT2, QB2: 1/2 FAIRCHILD NDS8926
VID0
VID1
VID2
VID3
VID4
28
PVCC
IMAX2
27
BOOST1
BOOST2
26
BG1
BG2
25
TG1
TG2
24
SW1
SW2
23
IMAX1
PGND
22
FCB
FAULT
21
RUN/SS1 RUN/SS2
20
COMP1
COMP2
19
SGND
FB2
18
FB1
VCC
17
VID4
SENSE
16
VID3
VID0
15
VID2
VID1
VIN
4.5V TO 5.5V
CCP2
1µF
+
QB2
RIMAX2
20k
COUT2
180µF
4V
RB2
11.5k
0.1%
R22, 100k
C22
15pF
CIN
150µF
10V
×2
VOUT2
1.5V
3A
C32
2200pF
R12
10.2k
0.1%
R32
1k
10Ω
GND
GND
C12
220pF
1703 TA01
1µF
CSS2
0.22µF
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LTC1703
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ABSOLUTE
RATI GS
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PACKAGE/ORDER I FOR ATIO
(Note 1)
Supply Voltage
VCC ........................................................................................... 7V
BOOSTn ............................................................... 15V
BOOSTn – SWn .................................................... 7V
Input Voltage
SWn .......................................................... – 1V to 8V
VIDn ....................................................... – 0.3V to 7V
All Other Inputs ......................... – 0.3V to VCC + 0.3V
Peak Output Current < 10µs
TGn, BGn ............................................................... 5A
Operating Temperature Range
LTC1703C .............................................. 0°C to 85°C
LTC1703I ........................................... – 40°C to 85°C
Storage Temperature Range ................. – 65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
ORDER PART
NUMBER
TOP VIEW
PVCC
1
28 IMAX2
BOOST1
2
27 BOOST2
BG1
3
26 BG2
TG1
4
25 TG2
SW1
5
24 SW2
IMAX1
6
23 PGND
FCB
7
22 FAULT
RUN/SS1
8
21 RUN/SS2
COMP1
9
20 COMP2
SGND 10
19 FB2
FB1 11
18 VCC
SENSE 12
17 VID4
VID0 13
16 VID3
VID1 14
15 VID2
LTC1703CG
LTC1703IG
G PACKAGE
28-LEAD PLASTIC SSOP
TJMAX = 125°C, θJA = 55°C/ W
Order Options Tape and Reel: Add #TR
Lead Free: Add #PBF Lead Free Tape and Reel: Add #TRPBF
Lead Free Part Marking: http://www.linear.com/leadfree/
Consult LTC Marketing for parts specified with wider operating temperature ranges.
ELECTRICAL CHARACTERISTICS
The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are TA = 25°C.
VCC = 5V unless otherwise specified. (Note 3)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Main Control Loop
●
VCC
VCC Supply Voltage
3
7
PVCC
PVCC Supply Voltage
(Note 2)
BVCC
BOOST Pin Voltage
VBOOST – VSW (Note 2)
●
3
7
V
●
2.7
7
V
ICC
VCC Supply Current
Test Circuit 1
RUN/SS1 = RUN/SS2 = 0V (Note 5)
●
●
2.2
30
8
100
mA
µA
IPVCC
PVCC Supply Current
Test Circuit 1 (Note 4)
RUN/SS1 = RUN/SS2 = 0V (Note 5)
●
●
2.2
6
6
100
mA
µA
IBOOST
BOOST Pin Current
Test Circuit 1 (Note 4)
RUN/SS1 = RUN/SS2 = 0V
●
●
1.3
0.1
3
10
mA
µA
VFB
Feedback Voltage
Test Circuit 1, LTC1703C
Test Circuit 1, LTC1703I
●
●
0.800
0.800
0.808
0.810
V
V
∆VFB
Feedback Voltage Line Regulation
VCC = 3V to 7V
●
±0.005
±0.05
%/V
IFB
Feedback Current
FB2 Only (Note 8)
●
±0.001
±1
µA
∆VOUT
Output Voltage Load Regulation
(Note 6)
●
0.1
±0.2
%
VFCB
FCB Threshold
0.8
0.85
∆VFCB
FCB Feedback Hysteresis
IFCB
FCB Pin Current
VRUN
RUN/SS Pin RUN Threshold
ISS
Soft Start Source Current
●
0.792
0.790
0.75
20
±0.001
●
●
RUN/SSn = 0V
V
V
mV
±1
µA
0.45
0.55
0.65
V
– 1.5
– 3.5
– 5.5
µA
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LTC1703
ELECTRICAL CHARACTERISTICS
The ● denotes specifications which apply over the full operating
temperature range, otherwise specifications are TA = 25°C. VCC = 5V unless otherwise specified. (Note 3)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Switching Characteristics
VOSC
Oscillator Amplitude
1
fOSC
Oscillator Frequency
Test Circuit 1
ΦOSC2
Controller 2 Oscillator Phase
Relative to Controller 1
DCMIN1
Minimum Duty Cycle
VFB < VMAX
●
7
DCMIN2
Minimum Duty Cycle
VFB > VMAX
●
0
●
87
●
475
550
VP-P
750
180
kHz
DEG
10
%
%
DCMAX
Maximum Duty Cycle
90
93
%
tNOV
Driver Nonoverlap
Test Circuit 1 (Note 9)
●
40
100
ns
t r, t f
Driver Rise/Fall Time
Test Circuit 1 (Note 9)
●
12
80
ns
Feedback Amplifier
●
74
85
dB
25
MHz
●
±3
±10
mA
815
840
mV
40
dB
AVFB
FB DC Gain
GBW
FB Gain Bandwidth
IERR
FB Sink/Source Current
VMIN
MIN Comparator Threshold
●
VMAX
MAX Comparator Threshold
●
COMPN Output
760
785
mV
Current Limit Loop
AVILIM
ILIM Gain
IIMAX
IMAX Source Current
IMAX = 0V, LTC1703C
IMAX = 0V, LTC1703I
●
●
–7
–7
+ 10
–10
–10
–13
–14
µA
µA
+ 15
+ 20
%
0.03
0.1
V
Status Outputs
VFAULT
FAULT Trip Point
VFB Relative to Regulated VOUT
●
VOLF
FAULT Output Low Voltage
IFAULT = 1mA
●
IFAULT
FAULT Output Current
VFAULT = 0V
tFAULT
FAULT Delay Time
VFB > VFAULT to FAULT
(Note 9)
– 10
µA
25
µs
10
kΩ
VID Inputs
R11
Resistance Between SENSE and FB1
VOUT Error % Output Voltage Accuracy (Side 1)
Programmed from 0.9V to 2V
RPULLUP
VID Input Pull-Up Resistance
VDIODE = 0.6V (Note 7)
VIDT
VID Input Voltage Threshold
VIL (2.7V ≤ VCC ≤ 5.5V)
VIH (2.7V ≤ VCC ≤ 5.5V)
●
– 1.5
1.5
40
VID Input Leakage Current
VCC < VID < 7V (Note 7)
0.01
VPULLUP
VID Pull-Up Voltage
VCC = 3.3V
VCC = 5V
2.8
4.5
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: PVCC and BVCC (VBOOST – VSW) must be greater than VGS(ON) of
the external MOSFETs used to ensure proper operation.
Note 3: All currents into device pins are positive; all currents out of device
pins are negative. All voltages are referenced to ground unless otherwise
specified.
Note 4: Supply current in normal operation is dominated by the current
needed to charge and discharge the external MOSFET gates. This current
will vary with supply voltage and the external MOSFETs used.
kΩ
0.4
V
V
±1
µA
1.6
IVID-LEAK
%
V
V
Note 5: Supply current in shutdown is dominated by external MOSFET
leakage and may be significantly higher than the quiescent current drawn
by the LTC1703, especially at elevated temperature.
Note 6: This parameter is guaranteed by correlation and is not tested
directly.
Note 7: Each built-in pull-up resistor attached to the VID inputs also has a
series diode connected to VCC to allow input voltages higher than the VCC
supply without damage or clamping. (See Block Diagram.)
Note 8: Feedback current at FB1 will be higher due to internal VID
resistors.
Note 9: Rise and fall times are measured using 10% and 90% levels. Delay
and nonoverlap times are measured using 50% levels.
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LTC1703
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TYPICAL PERFOR A CE CHARACTERISTICS
Efficiency vs Load Current
VIN = 5V
VOUT = 2.5V
90
35
VIN = 5V
VOUT = 1.8V
ILOAD = 0A-10A-0A
±2.2% MAX DEVIATION
VOUT = 3.3V
VOUT = 1.6V
20mV/
DIV
80
70
0
5
10
LOAD CURRENT (A)
20
15
10
5
0
1703 G02
10µs/DIV
15
TEST CIRCUIT 1
ONE DRIVER LOADED
30 MULTIPLY BY # OF ACTIVE
DRIVERS TO OBTAIN TOTAL
25 DRIVER SUPPLY CURRENT
DRIVER SUPPLY CURRENT (mA)
EFFICIENCY (%)
100
MOSFET Driver Supply Current
vs Gate Capacitance
Transient Response
2000
4000
6000
8000
GATE CAPACITANCE (pF)
0
1703 G01
1703 G03
Normalized Frequency
vs Temperature
Supply Current vs Temperature
2.5
NORMALIZED FREQUENCY (%)
2.2
VCC
2.0
1.8
1.6
1.4
BOOST1, BOOST2
1.2
1.0
– 50 – 25
0
50
75
25
TEMPERATURE (°C)
100
125
VCC = 5V
1.3
1.5
1.2
1.0
1.1
0.5
1.0
0
–0.5
0.7
0.6
–2.0
0.5
–2.5
–50 –25
0.4
–50 –25
50
25
0
75
TEMPERATURE (°C)
100
VCC = 5V
60
NONOVERLAP (ns)
4.0
3.5
3.0
50
25
0
75
TEMPERATURE (°C)
50
125
100
1703 G06
Nonoverlap Time vs Temperature
70
4.5
SOURCE CURRENT (µA)
125
1703 G05
RUN/SS Source Current
vs Temperature
Driver Rise/Fall vs Temperature
15
TEST CIRCUIT 1
CL = 2000pF
TEST CIRCUIT 1
CL = 2000pF
14
TG FALLING EDGE
BG RISING EDGE
40
30
BG FALLING EDGE
TG RISING EDGE
20
13
12
11
2.5
2.0
–50 –25
0.8
–1.5
1703 G04
5.0
VPVCC = 5V
VBOOST – VSW = 5V
0.9
–1.0
RISE/FALL TIME (ns)
SUPPLY CURRENT (mA)
2.0
PVCC
Driver RON vs Temperature
1.4
RON (Ω)
2.6
TEST CIRCUIT 1
2.4 CL = 0pF
10000
10
50
25
75
0
TEMPERATURE (°C)
100
125
1703 G07
0
–50 –25
50
25
75
0
TEMPERATURE (°C)
100
125
1703 G08
12
–50
–25
50
25
0
75
TEMPERATURE (°C)
100
125
1703 G09
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LTC1703
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PVCC (Pin 1): Driver Power Supply Input. PVCC provides
power to the two BGn output drivers. PVCC must be
connected to a voltage high enough to fully turn on the
external MOSFETs QB1 and QB2. PVCC should generally
be connected directly to VIN. PVCC requires at least a 1µF
bypass capacitor directly to PGND.
BOOST1 (Pin 2): Controller 1 Top Gate Driver Supply. The
BOOST1 pin supplies power to the floating TG1 driver.
BOOST1 should be bypassed to SW1 with a 1µF capacitor.
An additional Schottky diode from VIN to BOOST1 pin will
create a complete floating charge-pumped supply at
BOOST1. No other external supplies are required.
BG1 (Pin 3): Controller 1 Bottom Gate Drive. The BG1 pin
drives the gate of the bottom N-channel synchronous
switch MOSFET, QB1. BG1 is designed to drive up to
10,000pF of gate capacitance directly. If RUN/SS1 goes
low, BG1 will go low, turning off QB1. If FAULT mode is
tripped, BG1 will go high and stay high, keeping QB1 on
until the power is cycled.
TG1 (Pin 4): Controller 1 Top Gate Drive. The TG1 pin
drives the gate of the top N-channel MOSFET, QT1. The
TG1 driver draws power from the BOOST1 pin and returns
to the SW1 pin, providing true floating drive to QT1. TG1
is designed to drive up to 10,000pF of gate capacitance
directly. In shutdown or fault modes, TG1 will go low.
SW1 (Pin 5): Controller 1 Switching Node. SW1 should be
connected to the switching node of converter 1. The TG1
driver ground returns to SW1, providing floating gate
drive to the top N-channel MOSFET switch, QT1. The
voltage at SW1 is compared to IMAX1 by the current limit
comparator while the bottom MOSFET, QB1, is on.
IMAX1 (Pin 6): Controller 1 Current Limit Set. The IMAX1
pin sets the current limit comparator threshold for
controller 1. If the voltage drop across the bottom MOSFET,
QB1, exceeds the magnitude of the voltage at IMAX1,
controller 1 will go into current limit. The IMAX1 pin has an
internal 10µA current source pull-up, allowing the current
threshold to be set with a single external resistor to PGND.
This current setting resistor should be Kelvin connected to
the source of QB1. See the Current Limit Programming
section for more information on choosing RIMAX.
FCB (Pin 7): Force Continuous Bar. The FCB pin forces
both converters to maintain continuous synchronous
operation regardless of load when the voltage at FCB
drops below 0.8V. FCB is normally tied to VCC. To force
continuous operation, tie FCB to SGND. FCB can also be
connected to a feedback resistor divider from a secondary
winding on one converter’s inductor to generate a third
regulated output voltage. Do not leave FCB floating.
RUN/SS1 (Pin 8): Controller 1 Run/Soft-Start. Pulling
RUN/SS1 to SGND will disable controller 1 and turn off
both of its external MOSFET switches. Pulling both
RUN/SS pins down will shut down the entire LTC1703,
dropping the quiescent supply current below 100µA. A
capacitor from RUN/SS1 to SGND will control the turn-on
time and rate of rise of the controller 1 output voltage at
power-up. An internal 3.5µA current source pull-up at
RUN/SS1 pin sets the turn-on time at approximately
50ms/µF.
COMP1 (Pin 9): Controller 1 Loop Compensation. The
COMP1 pin is connected directly to the output of the first
controller’s error amplifier and the input to the PWM
comparator. An RC network is used at the COMP1 pin to
compensate the feedback loop for optimum transient
response.
SGND (Pin 10): Signal Ground. All internal low power
circuitry returns to the SGND pin. Connect to a low
impedance ground, separated from the PGND node. All
feedback, compensation and soft-start connections should
return to SGND. SGND and PGND should connect only at
a single point, near the PGND pin and the negative plate of
the CIN bypass capacitor.
FB1 (Pin 11): Controller 1 Feedback Input. The loop
compensation network for controller 1 should be connected to FB1. FB1 is connected internally to the VID
resistor network to set the output voltage at side 1.
SENSE (Pin 12): Output Sense. Connect to VOUT1.
VID0 to VID4 (Pins 13 to 17): VID Programming Inputs.
These are logic inputs that set the output voltage at side 1
to a preprogrammed value (see Table 1). VID4 is the MSB,
VID0 is the LSB. The codes selected by the VIDn inputs
correspond to the Intel Mobile VID specification. Each
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LTC1703
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VIDn pin includes an on-chip 40kΩ pull-up resistor in
series with a diode (see Block Diagram).
VCC (Pin 18): Power Supply Input. All internal circuits
except the output drivers are powered from this pin. VCC
should be connected to a low noise power supply voltage
between 3V and 7V and should be bypassed to SGND with
at least a 1µF capacitor in close proximity to the LTC1703.
FB2 (Pin 19): Controller 2 Feedback Input. FB2 should be
connected through a resistor divider network to VOUT2 to
set the ouput voltage. The loop compensation network for
controller 2 also connects to FB2.
COMP2 (Pin 20): Controller 2 Loop Compensation. See
COMP1.
RUN/SS2 (Pin 21): Controller 2 Run/Soft-Start. See RUN/
SS1.
FAULT (Pin 22): Output Overvoltage Fault (Latched). The
FAULT pin is an open-drain output with an internal 10µA
pull-up. If either regulated output voltage rises more than
15% above its programmed value for more than 25µs, the
FAULT output will go high and the entire LTC1703 will be
disabled. When FAULT is high, both BG pins will go high,
turning on the bottom MOSFET switches and pulling down
the high output voltage. The LTC1703 will remain latched
in this state until the power is cycled. When FAULT mode
is active, the FAULT pin will be pulled up with an internal
10µA current source. Tying FAULT directly to SGND will
disable latched FAULT mode and will allow the LTC1703 to
resume normal operation when the overvoltage fault is
removed.
PGND (Pin 23): Power Ground. The BGn drivers return to
this pin. Connect PGND to a high current ground node in
close proximity to the sources of external MOSFETs, QB1
and QB2, and the VIN and VOUT bypass capacitors.
SW2 (Pin 24): Controller 2 Switching Node. See SW1.
TG2 (Pin 25): Controller 2 Top Gate Drive. See TG1.
BG2 (Pin 26): Controller 2 Bottom Gate Drive. See BG1.
BOOST2 (Pin 27): Controller 2 Top Gate Driver Supply.
See BOOST1.
IMAX2 (Pin 28): Controller 2 Current Limit Set. See IMAX1.
TEST CIRCUIT
Test Circuit 1
5V
IBOOST1
0.1µF
ICC
VCC
IPVCC
2000pF
2000pF
TG2
BG1
BG2
SW1
SW2
IMAX1
IMAX2
2000pF
2000pF
LTC1703
NC
VID0:4
NC
RUN/SS1
COMP1
VFB1
100µF
BOOST2
TG1
FCB
2k
+
PVCC
BOOST1
fOSC
MEASURED
IBOOST2
VFAULT
FAULT
RUN/SS2
NC
2k
COMP2
FB1
FB2
VFB2
SENSE
GND
PGND
1703 TC
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LTC1703
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BLOCK DIAGRA
PVCC
FCB
VCC
BOOST1,2
BURST
LOGIC
TG1,2
DRIVE
LOGIC
SW1,2
BG1,2
PGND
90% DUTY CYCLE
OSC
550kHz
SGND
DIS
4µA
SOFT
START
RUN/SS1,2
10µA
FAULT
COMP1,2
0V
ILIM
10µA
+
FB
MIN
–
MAX
25µs
DELAY
FLT
FROM
OTHER
CONTROLLER
IMAX1,2
800mV
760mV
840mV
920mV
SHUTDOWN TO
THIS CONTROLLER
FB1,2
40k
VCC
SHUTDOWN TO
ENTIRE CHIP
500mV
VID0
40k
SENSE
VCC
R11
10k
VID1
FROM
OTHER
CONTROLLER
40k
VCC
VID2
40k
TO FB1
SWITCH
CONTROL
LOGIC
RB1
VCC
VID3
40k
VCC
VID4
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APPLICATIO S I FOR ATIO
OVERVIEW
The LTC1703 is a dual, step-down (buck), voltage mode
feedback switching regulator controller. It is designed to
be used in a synchronous switching architecture with two
external N-channel MOSFETs per channel. It is intended to
operate from a low voltage input supply (7V maximum)
and provide a high power, high efficiency, precisely regulated output voltage. Several features make it particularly
suited for microprocessor supply regulation. Output regulation is extremely tight, with DC line and load regulation
and initial accuracy better than 1.5%, and total regulation
including transient response inside of 3.5% with a prop-
erly designed circuit. The 550kHz switching frequency
allows the use of physically small, low value external
components without compromising performance. An
onboard DAC sets the output voltage at channel 1, consistent with the Intel mobile VID specification (Table 1).
The LTC1703’s internal feedback amplifier is a 25MHz
gain-bandwidth op amp, allowing the use of complex
multipole/zero compensation networks. This allows the
feedback loop to maintain acceptable phase margin at
higher frequencies than traditional switching regulator
controllers allow, improving stability and maximizing transient response. The 800mV internal reference allows
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APPLICATIO S I FOR ATIO
Table 1. VID Inputs and Corresponding Output Voltage for
Channel 1
CODE
VID4
VID3
VID2
VID1
VID0
VOUT1
00000
GND
GND
GND
00001
GND
GND
00010
GND
GND
CODE
VID4
VID3
VID2
VID1
VID0
VOUT1
GND
GND
2.00V
10000
Float
GND
GND
GND
GND
1.275V
GND
GND
Float
1.95V
10001
Float
GND
GND
GND
Float
1.250V
GND
Float
GND
1.90V
10010
Float
GND
GND
Float
GND
1.225V
00011
GND
GND
GND
Float
Float
1.85V
10011
Float
GND
GND
Float
Float
1.200V
00100
GND
GND
Float
GND
GND
1.80V
10100
Float
GND
Float
GND
GND
1.175V
00101
GND
GND
Float
GND
Float
1.75V
10101
Float
GND
Float
GND
Float
1.150V
00110
GND
GND
Float
Float
GND
1.70V
10110
Float
GND
Float
Float
GND
1.125V
00111
GND
GND
Float
Float
Float
1.65V
10111
Float
GND
Float
Float
Float
1.100V
01000
GND
Float
GND
GND
GND
1.60V
11000
Float
Float
GND
GND
GND
1.075V
01001
GND
Float
GND
GND
Float
1.55V
11001
Float
Float
GND
GND
Float
1.050V
01010
GND
Float
GND
Float
GND
1.50V
11010
Float
Float
GND
Float
GND
1.025V
01011
GND
Float
GND
Float
Float
1.45V
11011
Float
Float
GND
Float
Float
1.000V
01100
GND
Float
Float
GND
GND
1.40V
11100
Float
Float
Float
GND
GND
0.975V
01101
GND
Float
Float
GND
Float
1.35V
11101
Float
Float
Float
GND
Float
0.950V
01110
GND
Float
Float
Float
GND
1.30V
11110
Float
Float
Float
Float
GND
0.925V
01111*
GND
Float
Float
Float
Float
1.25V
11111*
Float
Float
Float
Float
Float
0.900V
* 01111 and 11111 are defined by Intel to signify “no CPU.” The LTC1703
will generate the output voltages shown when these codes are selected.
regulated output voltages as low as 800mV without external level shifting amplifiers.
circuit designs shift the current load to lower voltage
supplies.
The LTC1703’s synchronous switching logic transitions
automatically into Burst Mode operation, maximizing efficiency with light loads. An onboard overvoltage (OV) fault
flag indicates when an OV fault has occurred. The OV flag
can be set to latch the device off when an OV fault has
occurred, or to automatically resume operation when the
fault is removed.
Each regulator in a typical 2-step system maintains a
relatively low step-down ratio (5:1 or less), running at high
efficiency while maintaining a reasonable duty cycle. In
contrast, a regulator taking a single step from a high input
voltage to a 1.xV output must run at a very narrow duty
cycle, mandating trade-offs in external component values
while compromising efficiency and transient response.
The efficiency loss can exceed that of using a 2-step
solution (see the 2-Step Efficiency Calculation section and
Figure 10). Further complicating the calculation is the fact
that many systems draw a significant fraction of their total
power off the intermediate 5V supply, bypassing the low
voltage supply. 2-step solutions using the LTC1703 usually match or exceed the total system efficiency of singlestep solutions, and provide the additional benefits of
improved transient response, reduced PCB area and simplified power trace routing.
2-Step Conversion
“2-step” architectures use a primary regulator to convert
the input power source (batteries or AC line voltage) to an
intermediate supply voltage, often 5V. This intermediate
voltage is then converted to the low voltage, high current
supplies required by the system using a secondary regulator— the LTC1703. 2-step conversion eliminates the
need for a single converter that converts a high input
voltage to a very low output voltage, often an awkward
design challenge. It also fits naturally into systems that
continue to use the 5V supply to power portions of their
circuitry, or have excess 5V capacity available as newer
2-step regulation can buy advantages in thermal management as well. Power dissipation in the LTC1703 portion of
a 2-step circuit is lower than it would be in a typical 1-step
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converter, even in cases where the 1-step converter has
higher total efficiency than the 2-step system. In a typical
microprocessor core supply regulator, for example, the
regulator is usually located right next to the CPU. In a
1-step design, all of the power dissipated by the core
regulator is right there next to the hot CPU, aggravating
thermal management. In a 2-step LTC1703 design, a
significant percentage of the power lost in the core regulation system happens in the 5V supply, which is usually
located away from the CPU. The power lost to heat in the
LTC1703 section of the system is relatively low, minimizing the added heat near the CPU.
See the Optimizing Performance section for a detailed
explanation of how to calculate system efficiency.
2-Phase Operation
The LTC1703 dual switching regulator controller also
features the considerable benefits of 2-phase operation.
Notebook computers, handheld terminals and automotive
electronics all benefit from the lower input filtering
requirement, reduced electromagnetic interference (EMI)
and increased efficiency associated with 2-phase
operation.
Why the need for 2-phase operation? Up until the LTC1703,
constant-frequency dual switching regulators operated
both channels in phase (i.e., single-phase operation). This
means that both topside MOSFETs turned on at the same
time, causing current pulses of up to twice the amplitude
of those for one regulator to be drawn from the input
capacitor. These large amplitude current pulses increased
the total RMS current flowing from the input capacitor,
requiring the use of more expensive input capacitors and
increasing both EMI and losses in the input capacitor and
input power supply.
With 2-phase operation, the two channels of the LTC1703
are operated 180 degrees out of phase. This effectively
interleaves the current pulses coming from the switches,
greatly reducing the overlap time where they add together.
The result is a significant reduction in total RMS input
current, which in turn allows less expensive input capacitors to be used, reduces shielding requirements for EMI
and improves real world operating efficiency.
Figure 7 shows example waveforms for a single switching
regulator channel versus a 2-phase LTC1703 system with
both sides switching. A single-phase dual regulator with
both sides operating would exhibit double the single side
numbers. In this example, 2-phase operation reduced the
RMS input current from 9.3ARMS (2 × 4.66ARMS) to
4.8ARMS. While this is an impressive reduction in itself,
remember that the power losses are proportional to IRMS2,
meaning that the actual power wasted is reduced by a
factor of 3.75. The reduced input ripple voltage also means
less power is lost in the input power path, which could
include batteries, switches, trace/connector resistances
and protection circuitry. Improvements in both conducted
and radiated EMI also directly accrue as a result of the
reduced RMS input current and voltage.
Small Footprint
The LTC1703 operates at a 550kHz switching frequency,
allowing it to use low value inductors without generating
excessive ripple currents. Because the inductor stores
less energy per cycle, the physical size of the inductor can
be reduced without risking core saturation, saving PCB
board space. The high operating frequency also means
less energy is stored in the output capacitors between
cycles, minimizing their required value and size. The
remaining components, including the SSOP-28 LTC1703,
are tiny, allowing an entire dual-output LTC1703 circuit to
be constructed in 1.5in2 of PCB space. Further, this space
is generally located right next to the microprocessor or in
some similarly congested area, where PCB real estate is at
a premium. The fact that the LTC1703 runs off the 5V
supply, often available from a power plane, is an added
benefit in portable systems —it does not require a dedicated supply line running from the battery.
Fast Transient Response
The LTC1703 uses a fast 25MHz GBW op amp as an error
amplifier. This allows the compensation network to be
designed with several poles and zeros in a more flexible
configuration than with a typical gm feedback amplifier.
The high bandwidth of the amplifier, coupled with the high
switching frequency and the low values of the external
inductor and output capacitor, allow very high loop crossover frequencies. The low inductor value is the other half
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of the equation—with a typical value on the order of 1µH,
the inductor allows very fast di/dt slew rates. The result is
superior transient response compared with conventional
solutions.
High Efficiency
The LTC1703 uses a synchronous step-down (buck)
architecture, with two external N-channel MOSFETs per
output. A floating topside driver and a simple external
charge pump provide full gate drive to the upper MOSFET.
The voltage mode feedback loop and MOSFET VDS current
limit sensing remove the need for an external current
sense resistor, eliminating an external component and a
source of power loss in the high current path. Properly
designed circuits using low gate charge MOSFETs are
capable of efficiencies exceeding 90% over a wide range
of output voltages.
VID Programming
The LTC1703 includes an onboard feedback network that
programs the output voltage at side 1 in accordance with
the Intel Mobile VID specification (Table 1). The network
includes a 10k resistor (R11) connected from SENSE to
FB1, and a variable value resistor (RB1) from FB1 to SGND,
with the value set by the digital code present at the VID0:4
pins. SENSE should be connected to VOUT1 to allow the
network to monitor the output voltage. No additional
feedback components are required to set the output voltage at controller 1, although loop compensation components are still required. Each VIDn pin includes an internal
40k pull-up resistor, allowing it to float high if left unconnected. The pull-up resistors are connected to VCC through
diodes (see Block Diagram), allowing the VIDn pins to be
pulled above VCC without damage.
Note that codes 01111 and 11111, defined by Intel to
indicate “no CPU present,” do generate output voltages at
VOUT1 (1.25V and 0.9V, respectively). Note also that
controller 2 on the LTC1703 is not connected to the VID
circuitry, and works independently from controller 1.
chip and their corresponding external components act
independently of each other with the exception of the
common input bypass capacitor, the VID circuitry at side
1, and the FCB and FAULT pins, which affect both channels. In the following discussions, when a pin is referred
to without mentioning which side is involved, that discussion applies equally to both sides.
Switching Architecture
Each half of the LTC1703 is designed to operate as a
synchronous buck converter (Figure 1). Each channel
includes two high power MOSFET gate drivers to control
external N-channel MOSFETs QT and QB. These drivers
have 0.5Ω output impedances and can carry well over an
amp of continuous current with peak currents up to 5A to
slew large MOSFET gates quickly. The external MOSFETs
are connected with the drain of QT attached to the input
supply and the source of QT at the switching node SW. QB
is the synchronous rectifier with its drain at SW and its
source at PGND. SW is connected to one end of the
inductor, with the other end connected to VOUT. The output
capacitor is connected from VOUT to PGND.
When a switching cycle begins, QB is turned off and QT is
turned on. SW rises almost immediately to VIN and the
inductor current begins to increase. When the PWM pulse
finishes, QT turns off and one nonoverlap interval later, QB
turns on. Now SW drops to PGND and the inductor current
decreases. The cycle repeats with the next tick of the
master clock. The percentage of time spent in each mode
is controlled by the duty cycle of the PWM signal, which in
turn is controlled by the feedback amplifier. The master
clock runs at a 550kHz rate and turns QT once every 1.8µs.
In a typical application with a 5V input and a 1.5V output,
the duty cycle will be set at 1.5/5 × 100% or 30% by the
feedback loop. This will give roughly a 540ns on-time for
QT and a 1.26µs on-time for QB.
VIN
+
CIN
TG
QT
LTC1703 SW
ARCHITECTURE DETAILS
The LTC1703 dual switching regulator controller includes
two independent regulator channels. The two sides of the
PGND
BG
QB
LEXT
VOUT
+
COUT
1703 F01
Figure 1. Synchronous Buck Architecture
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This constant frequency operation brings with it a couple
of benefits. Inductor and capacitor values can be chosen
with a precise operating frequency in mind and the feedback loop components can be similarly tightly specified.
Noise generated by the circuit will always be in a known
frequency band with the 550kHz frequency designed to
leave the 455kHz IF band free of interference. Subharmonic
oscillation and slope compensation, common headaches
with constant frequency current mode switchers, are
absent in voltage mode designs like the LTC1703.
During the time that QT is on, its source (the SW pin) is at
VIN. VIN is also the power supply for the LTC1703. However, QT requires VIN + VGS(ON) at its gate to achieve
minimum RON. This presents a problem for the LTC1703—
it needs to generate a gate drive signal at TG higher than
its highest supply voltage. To accomplish this, the TG
driver runs from floating supplies, with its negative supply
attached to SW and its power supply at BOOST. This allows
it to slew up and down with the source of QT. In combination
with a simple external charge pump (Figure 2), this allows
the LTC1703 to completely enhance the gate of QT without
requiring an additional, higher supply voltage.
The two channels of the LTC1703 run from a common
clock, with the phasing chosen to be 180° from side 1 to
side 2. This has the effect of doubling the frequency of the
switching pulses seen by the input bypass capacitor,
significantly lowering the RMS current seen by the capacitor and reducing the value required (see the 2-Phase
section).
Feedback Amplifier
Each side of the LTC1703 senses the output voltage at
VOUT with an internal feedback op amp (see Block Diagram). This is a real op amp with a low impedance output,
85dB open-loop gain and 25MHz gain-bandwidth product.
The positive input is connected internally to an 800mV
reference, while the negative input is connected to the FB
pin. The output is connected to COMP, which is in turn
connected to the soft-start circuitry and from there to the
PWM generator.
Unlike many regulators that use a resistor divider connected to a high impedance feedback input, the LTC1703
is designed to use an inverting summing amplifier
VIN
PVCC
+
DCP
BOOST
CCP
1µF
TG
QT
CIN
LEXT
SW
VOUT
+
BG
LTC1703
QB
COUT
PGND
1703 F02
Figure 2. Floating TG Driver Supply
topology with the FB pin configured as a virtual ground.
This allows flexibility in choosing pole and zero locations
not available with simple gm configurations. In particular,
it allows the use of “type 3” compensation, which provides a phase boost at the LC pole frequency and significantly improves loop phase margin (see Figure 3). The
Feedback Loop/Compensation section contains a detailed explanation of type 3 feedback loops. Note that side
1 of the LTC1703 includes R1 and RB internally as part
of the VID DAC circuitry.
MIN/MAX COMPARATORS
Two additional feedback loops keep an eye on the primary
feedback amplifier and step in if the feedback node moves
±5% from its nominal 800mV value. The MAX comparator
(see Block Diagram) activates whenever FB rises more
than 5% above 800mV. It immediately turns the top
MOSFET (QT) off and the bottom MOSFET (QB) on and
keeps them that way until FB falls back within 5% of its
nominal value. This pulls the output down as fast as possible, preventing damage to the (often expensive) load. If
FB rises because the output is shorted to a higher supply,
QB will stay on until the short goes away, the higher supply
+
COMP
0.8V
FB
R1
FB
–
C3
R3
VOUT
RB
C2
R2
C1
1703 F03
Figure 3. “Type 3” Feedback Loop (Side 2 Shown)
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current limits or QB dies trying to save the load. This
behavior provides maximum protection against overvoltage faults at the output, while allowing the circuit to resume normal operation when the fault is removed. The
overvoltage protection circuit can optionally be set to latch
the output off permanently (see the Overvoltage Fault
section).
The MIN comparator (see Block Diagram) trips whenever
FB is more than 5% below 800mV and immediately forces
the switch duty cycle to 90% to bring the output voltage
back into range. It releases when FB is within the 5%
window. MIN is disabled when the soft-start or current
limit circuits are active—the only two times that the
output should legitimately be below its regulated value.
Notice that the FB pin is the virtual ground node of the
feedback amplifier. A typical compensation network does
not include local DC feedback around the amplifier, so that
the DC level at FB will be an accurate replica of the output
voltage, divided down by R1 and RB (Figure 3). However,
the compensation capacitors will tend to attenuate AC
signals at FB, especially with low bandwidth type 1 feedback loops. This creates a situation where the MIN and
MAX comparators do not respond immediately to shifts in
the output voltage, since they monitor the output at FB.
Maximizing feedback loop bandwidth will minimize these
delays and allow MIN and MAX to operate properly. See
the Feedback Loop/Compensation section.
SHUTDOWN/SOFT-START
Each half of the LTC1703 has a RUN/SS pin. The RUN/SS
pins perform two functions: when pulled to ground, each
shuts down its half of the LTC1703, and each acts as a
conventional soft-start pin, enforcing a maximum duty
cycle limit proportional to the voltage at RUN/SS. An
internal 3.5µA current source pull-up is connected to each
RUN/SS pin, allowing a soft-start ramp to be generated
with a single external capacitor to ground. The 3.5µA
current sources are active even when the LTC1703 is shut
down, ensuring the device will start when any external
pull-down at RUN/SS is released. Either side can be shut
down without affecting the operation of the other side. If
both sides are shut down at the same time, the LTC1703
goes into a micropower sleep mode, and quiescent current drops typically below 50µA. Entering sleep mode also
resets the FAULT latch, if it was set.
Each RUN/SS pin shuts down its half of the LTC1703 when
it falls below about 0.5V (Figure 4). Between 0.5V and
about 1V, that half is active, but the maximum duty cycle
VOUT
0V
5V
4.5V
2.5V
VRUN/SS
2.5V
1.0V
0.5V
0V
LTC1703 ENABLED
RUN/SS CONTROLS
DUTY CYCLE
RUN/SS CONTROLS
DUTY CYCLE
COMP CONTROLS DUTY CYCLE
MIN COMPARATOR ENABLED
START-UP
NORMAL OPERATION
CURRENT LIMIT
1703 F04
Figure 4. Soft-Start Operation in Start-Up and Current Limit
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is limited to 10%. The maximum duty cycle limit increases
linearly between 1V and 2.5V, reaching its final value of
90% when RUN/SS is above 2.5V. Somewhere before this
point, the feedback amplifier will assume control of the
loop and the output will come into regulation. When RUN/
SS rises to 0.5V below VCC, the MIN feedback comparator
is enabled, and the LTC1703 is in full operation.
CURRENT LIMIT
The LTC1703 includes an onboard current limit circuit that
limits the maximum output current to a user-programmed
level. It works by sensing the voltage drop across QB
during the time that QB is on and comparing that voltage
to a user-programmed voltage at IMAX. Since QB looks like
a low value resistor during its on-time, the voltage drop
across it is proportional to the current flowing in it. In a
buck converter, the average current in the inductor is equal
to the output current. This current also flows through QB
during its on-time. Thus, by watching the voltage across
QB, the LTC1703 can monitor the output current.
Any time QB is on and the current flowing to the output is
reasonably large, the SW node at the drain of QB will be
somewhat negative with respect to PGND. The LTC1703
senses this voltage and inverts it to allow it to compare the
sensed voltage with a positive voltage at the IMAX pin. The
IMAX pin includes a trimmed 10µA pull-up, enabling the
user to set the voltage at IMAX with a single resistor, RIMAX,
to ground. The LTC1703 compares the two inputs and
begins limiting the output current when the magnitude of
the negative voltage at the SW pin is greater than the
voltage at IMAX.
The current limit detector is connected to an internal gm
amplifier that pulls a current from the RUN/SS pin proportional to the difference in voltage magnitudes between the
SW and IMAX pins. This current begins to discharge the
soft-start capacitor at RUN/SS, reducing the duty cycle
and controlling the output voltage until the output current
drops below the limit. The soft-start capacitor needs to
move a fair amount before it has any effect on the duty
cycle, adding a delay until the current limit takes effect
(Figure 4). This allows the LTC1703 to experience brief
overload conditions without affecting the output voltage
regulation. The delay also acts as a pole in the current limit
loop to enhance loop stability. Larger overloads cause the
soft-start capacitor to pull down quickly, protecting the
output components from damage. The current limit gm
amplifier includes a clamp to prevent it from pulling RUN/
SS below 0.5V and shutting off the device.
Power MOSFET RDS(ON) varies from MOSFET to MOSFET,
limiting the accuracy obtainable from the LTC1703 current
limit loop. Additionally, ringing on the SW node due to
parasitics can add to the apparent current, causing the
loop to engage early. The LTC1703 current limit is
designed primarily as a disaster prevention, “no blow up”
circuit, and is not useful as a precision current regulator.
It should typically be set around 50% above the maximum
expected normal output current to prevent component
tolerances from encroaching on the normal current range.
See the Current Limit Programming section for advice on
choosing a value for RIMAX.
DISCONTINUOUS/Burst Mode OPERATION
Theory of operation
The LTC1703 switching logic has three modes of operation. Under heavy loads, it operates as a fully synchronous, continuous conduction switching regulator. In this
mode of operation (“continuous” mode), the current in the
inductor flows in the positive direction (toward the output)
during the entire switching cycle, constantly supplying
current to the load. In this mode, the synchronous switch
(QB) is on whenever QT is off, so the current always flows
through a low impedance switch, minimizing voltage drop
and power loss. This is the most efficient mode of operation at heavy loads, where the resistive losses in the power
devices are the dominant loss term.
Continuous mode works efficiently when the load current
is greater than half of the ripple current in the inductor. In
a buck converter like the LTC1703, the average current in
the inductor (averaged over one switching cycle) is equal
to the load current. The ripple current is the difference
between the maximum and the minimum current during a
switching cycle (see Figure 5a). The ripple current
depends on inductor value, clock frequency and output
voltage, but is constant regardless of load as long as the
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Discontinuous Mode
To minimize the efficiency loss due to reverse current flow
at light loads, the LTC1703 switches to a second mode of
operation: discontinuous mode (Figure 5b). In discontinuous mode, the LTC1703 detects when the inductor current
approaches zero and turns off QB for the remainder of the
switch cycle. During this time, the voltage at the SW pin
will float about VOUT, the voltage across the inductor will
be zero, and the inductor current remains zero until the
next switching cycle begins and QT turns on again. This
prevents current from flowing backwards in QB, eliminating that power loss term. It also reduces the ripple current
in the inductor as the output current approaches zero.
The LTC1703 detects that the inductor current has reached
zero by monitoring the voltage at the SW pin while QB is
on. Since QB acts like a resistor, SW should ideally be right
at 0V when the inductor current reaches zero. In reality, the
SW node will ring to some degree immediately after it is
switched to ground by QB, causing some uncertainty as to
the actual moment the average current in QB goes to zero.
The LTC1703 minimizes this effect by ignoring the SW
node for a fixed 50ns after QB turns on when the ringing
IRIPPLE
INDUCTOR CURRENT
As the output load current decreases in continuous mode,
the average current in the inductor will reach a point where
it drops below half the ripple current. At this point, the
current in the inductor will reverse during a portion of the
switching cycle, or begin to flow from the output back to
the input. This does not adversely affect regulation, but
does cause additional losses as a portion of the inductor
current flows back and forth through the resistive power
switches, giving away a little more power each time and
lowering the efficiency. There are some benefits to allowing this reverse current flow: the circuit will maintain
regulation even if the load current drops below zero (the
load supplies current to the LTC1703) and the output
ripple voltage and frequency remain constant at all loads,
easing filtering requirements. Circuits that take advantage
of this behavior can force the LTC1703 to operate in
continuous mode at all loads by tying the FCB (Force
Continuous Bar) pin to ground.
is most severe, and by including a few millivolts offset in
the comparator that monitors the SW node. Despite these
precautions, some combinations of inductor and layout
parasitics can cause the LTC1703 to enter discontinuous
mode erratically. In many cases, the time that QB turns off
will correspond to a peak in the ringing waveform at the
SW pin (Figure 6). This erratic operation isn’t pretty, but
retains much of the efficiency benefit of discontinuous
mode and maintains regulation at all times.
IAVERAGE
TIME
1703 F05a
Figure 5a. Continuous Mode
INDUCTOR CURRENT
LTC1703 remains in continuous mode. See the Inductor
Selection section for a detailed description of ripple
current.
IRIPPLE
IAVERAGE
TIME
1703 F05b
Figure 5b. Discontinuous Mode
DISCONTINUOUS
COMPARATOR
TURNS OFF BG
VSW
0V
TIME
50ns
BLANK
TIME
5V
VBG
0V
TIME
1703 F06
Figure 6. Ringing at SW Causes Discontinuous
Comparator to Trip Early
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Burst Mode Operation
Discontinuous mode removes a loss term due to resistive
drop in QB, but the LTC1703 is still switching QT and QB
on and off once a cycle. Each time an external MOSFET is
turned on, the internal driver must charge its gate to VCC.
Each time it is turned off, that charge is lost to ground. At
the high switching frequencies that the LTC1703 operates
at, the charge lost to the gates can add up to tens of
milliamps from VCC. As the load current continues to drop,
this quickly become the dominant power loss term, reducing efficiency once again.
Once again, the LTC1703 switches to a new mode to
minimize efficiency loss: Burst Mode operation. As the
circuit goes deeper and deeper into discontinuous mode,
the total time QT and QB are on reduces. However, the ratio
of the time that QT is on to the time that QB is on must
remain constant for the output to stay in regulation. An
internal timer circuit forces QT to stay on for at least 10%
of a normal switching cycle. When the load drops to the
point that the output requires less than 10% on-time at QT,
the output voltage will begin to rise. The LTC1703 senses
this rise and shuts both QT and QB off completely, skipping several switching cycles until the output falls back
into range. It then resumes switching in discontinuous
mode with QT at 10% duty cycle and the burst sequence
repeats. The total deviation from the regulated output is
within the 1.5% regulation tolerance of the LTC1703.
In Burst Mode operation, both resistive loss and switching
loss are minimized while keeping the output in regulation.
The ripple current will be set by the 10% QT on-time and
the input supply voltage and is the lowest of all three
operating modes. As the load current falls to zero in Burst
Mode operation, the most significant loss term becomes
the 3mA quiescent current drawn by each side of the
LTC1703—usually much less than the minimum load
current in a typical low voltage logic system. Burst Mode
operation maximizes efficiency at low load currents, but
can cause low frequency ripple in the output voltage as the
cycle-skipping circuitry switches on and off.
FCB Pin
In some circumstances, it is desirable to control or disable
discontinuous and Burst Mode operations. The FCB (Force
Continuous Bar) pin allows the user to do this. When the
FCB pin is high, the LTC1703 is allowed to enter discontinuous and Burst Mode operations at either side as
required. If FCB is taken low, discontinuous and Burst
Mode operations are disabled and both sides of the
LTC1703 run in continuous mode regardless of load. This
does not affect output regulation but does reduce efficiency at low output currents. The FCB pin threshold is
specified at 0.8V ±50mV, and includes 20mV of hysteresis, allowing it to be used as a precision small-signal
comparator.
Paralleling Outputs
Synchronous regulators (like the LTC1703) are known for
their bullheadedness when their outputs are paralleled
with other regulators. In particular, a synchronous regulator paralleled with another regulator whose output is
slightly higher (perhaps just by millivolts) will happily sink
amps of current attempting to pull its own output back
down to what it thinks is the right value.
The LTC1703 discontinuous mode allows it to be paralleled with another regulator without fighting. A typical
system might use the LTC1703 as a primary regulator and
a small LDO as a backup regulator to keep SRAM alive
when the main power is off. When the LTC1703 is shut
down (by pulling RUN/SS to ground), both QT and QB turn
off and the output goes into a high impedance state,
allowing the smaller regulator to support the output voltage. However, if the LTC1703 is powered back up in
continuous mode, it will begin a soft-start cycle with a low
duty cycle, pulling the output down and corrupting the
data stored in SRAM. The solution is to tie FCB high,
allowing the device to start in discontinuous mode. Any
reverse current flow in QB will trip the discontinuous mode
circuitry, preventing the LTC1703 from pulling down the
output.
OVERVOLTAGE FAULT
The LTC1703 includes a single overvoltage fault flag for
both channels: FAULT. FAULT is an open-drain output
with an internal 10µA pull-up. If either FB pin rises more
than 15% above the nominal 800mV value for more than
25µs, the overvoltage comparator will trip, setting an
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internal latch. This latch releases the pull-down at FAULT,
allowing the 10µA pull-up to take it high. When FAULT
goes high, the LTC1703 stops all switching, turns both QB
(bottom synchronous) MOSFETs on continuously and
remains in this state until both RUN/SS pins are pulled low
simultaneously, the power supply is recycled, or the
FAULT pin is pulled low externally. This behavior is
intended to protect a potentially expensive load from
overvoltage damage at all costs. Under some conditions,
this behavior can cause the output voltage to undershoot
below ground. If latched FAULT mode is used, a Schottky
diode should be added with its cathode at the output and
its anode at ground to clamp the negative voltage to a safe
level and prevent possible damage to the load and the
output capacitors.
Note that in overvoltage conditions, the MAX comparator
will kick in at just +5%, turning QB on continuously long
before the output reaches +15%. Under most fault conditions, this is adequate to bring the output back down
without firing the fault latch. Additionally, if MAX successfully keeps the output below +15%, the LTC1703 will
resume normal regulation as soon as the output overvoltage fault is resolved.
In some circuits, the OV latch can be a liability. Consider
a circuit where the output voltage at one channel may be
changed on the fly by changing the VID code or switching
in different feedback resistors. A downward adjustment of
greater than 15% will fire the fault latch, disabling both
sides of the LTC1703 until the power is recycled. In circuits
such as this, the fault latch can be disabled by grounding
the FAULT pin. The internal latch will still be set the first
time the output exceeds +15%, but the 10µA current
source pull-up will not be able to pull FAULT high, and the
LTC1703 will ignore the latch and continue normal operation. The MAX comparator will act as usual, turning on QB
until output is within range and then allowing the loop to
resume normal operation. FAULT can also be pulled down
with external open-collector logic to restart a fault-latched
LTC1703 as an alternative to recycling the power. Note
that this will not reset the internal latch; if the external pulldown is released, the LTC1703 will reenter FAULT mode.
To reset the latch, pull both RUN/SS pins low simultaneously or cycle the power.
VID Considerations
Some applications change the VID codes at channel 1 on
the fly. This is possible with the LTC1703, but care must be
taken to avoid tripping the overvoltage fault circuit. Stepping the voltage upwards abruptly is safe, but stepping
down quickly by more than 15% can leave the system in a
state where the output voltage is still at the old higher level,
but the feedback node is set to expect a new, substantially
lower voltage. If this condition persists for more than
25µs, the overvoltage fault circuitry will fire and latch off
the LTC1703.
The simplest solution is to disable the fault circuit by
grounding the FAULT pin. Systems that must keep the fault
circuit active should ensure that the output voltage is never
programmed to step down by more than 15% in any single
step. A safe strategy is to step the output down by 10% or
less at a time and wait for the output to settle to the new
value before taking subsequent steps. Regardless of the
state of the FAULT pin, the load is always protected against
overvoltage faults by the +5% MAX comparator.
EXTERNAL COMPONENT SELECTION
POWER MOSFETs
Getting peak efficiency out of the LTC1703 depends strongly
on the external MOSFETs used. The LTC1703 requires at
least two external MOSFETs per side—more if one or
more of the MOSFETs are paralleled to lower on-resistance. To work efficiently, these MOSFETs must exhibit
low RDS(ON) at 5V VGS (3.3V VGS if the PVCC input supply
is 3.3V) to minimize resistive power loss while they are
conducting current. They must also have low gate charge
to minimize transition losses during switching. On the
other hand, voltage breakdown requirements in a typical
LTC1703 circuit are pretty tame: the 7V maximum input
voltage limits the VDS and VGS the MOSFETs can see to
safe levels for most devices.
Low RDS(ON)
RDS(ON) calculations are pretty straightforward. RDS(ON) is
the resistance from the drain to the source of the MOSFET
when the gate is fully on. Many MOSFETs have RDS(ON)
specified at 4.5V gate drive—this is the right number to
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use in LTC1703 circuits running from a 5V supply. As
current flows through this resistance while the MOSFET is
on, it generates I2R watts of heat, where I is the current
flowing (usually equal to the output current) and R is the
MOSFET RDS(ON). This heat is only generated when the
MOSFET is on. When it is off, the current is zero and the
power lost is also zero (and the other MOSFET is busy
losing power).
This lost power does two things: it subtracts from the
power available at the output, costing efficiency, and it
makes the MOSFET hotter—both bad things. The effect is
worst at maximum load when the current in the MOSFETs
and thus the power lost are at a maximum. Lowering
RDS(ON) improves heavy load efficiency at the expense of
additional gate charge (usually) and more cost (usually).
Proper choice of MOSFET RDS(ON) becomes a trade-off
between tolerable efficiency loss, power dissipation and
cost. Note that while the lost power has a significant effect
on system efficiency, it only adds up to a watt or two in a
typical LTC1703 circuit, allowing the use of small, surface
mount MOSFETs without heat sinks.
Gate Charge
Gate charge is amount of charge (essentially, the number
of electrons) that the LTC1703 needs to put into the gate
of an external MOSFET to turn it on. The easiest way to
visualize gate charge is to think of it as a capacitance from
the gate pin of the MOSFET to SW (for QT) or to PGND (for
QB). This capacitance is composed of MOSFET channel
charge, actual parasitic drain-source capacitance and
Miller-multiplied gate-drain capacitance, but can be
approximated as a single capacitance from gate to source.
Regardless of where the charge is going, the fact remains
that it all has to come out of VCC to turn the MOSFET gate
on, and when the MOSFET is turned back off, that charge
all ends up at ground. In the meanwhile, it travels through
the LTC1703’s gate drivers, heating them up. More power
lost!
In this case, the power is lost in little bite-sized chunks, one
chunk per switch per cycle, with the size of the chunk set
by the gate charge of the MOSFET. Every time the MOSFET
switches, another chunk is lost. Clearly, the faster the
clock runs, the more important gate charge becomes as a
loss term. Old-fashioned switchers that ran at 20kHz could
pretty much ignore gate charge as a loss term; in the
550kHz LTC1703, gate charge loss can be a significant
efficiency penalty. Gate charge loss can be the dominant
loss term at medium load currents, especially with large
MOSFETs. Gate charge loss is also the primary cause of
power dissipation in the LTC1703 itself.
TG Charge Pump
There’s another nuance of MOSFET drive that the LTC1703
needs to get around. The LTC1703 is designed to use
N-channel MOSFETs for both QT and QB, primarily
because N-channel MOSFETs generally cost less and have
lower RDS(ON) than similar P-channel MOSFETs. Turning
QB on is no big deal since the source of QB is attached to
PGND; the LTC1703 just switches the BG pin between
PGND and VCC. Driving QT is another matter. The source
of QT is connected to SW which rises to VCC when QT is
on. To keep QT on, the LTC1703 must get TG one MOSFET
VGS(ON) above VCC. It does this by utilizing a floating driver
with the negative lead of the driver attached to SW (the
source of QT) and the VCC lead of the driver coming out
separately at BOOST. An external 1µF capacitor (CCP)
connected between SW and BOOST (Figure 2) supplies
power to BOOST when SW is high, and recharges itself
through DCP when SW is low. This simple charge pump
keeps the TG driver alive even as it swings well above VCC.
The value of the bootstrap capacitor CCP needs to be at
least 100 times that of the total input capacitance of the
topside MOSFET(s). For very large external MOSFETs (or
multiple MOSFETs in parallel), CCP may need to be
increased beyond the 1µF value.
INPUT SUPPLY
The BiCMOS process that allows the LTC1703 to include
large MOSFET drivers on-chip also limits the maximum
input voltage to 7V. This limits the practical maximum
input supply to a loosely regulated 5V or 6V rail. The
LTC1703 will operate properly with input supplies down to
about 3V, so a typical 3.3V supply can also be used if the
external MOSFETs are chosen appropriately (see the Power
MOSFETs section).
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At the same time, the input supply needs to supply several
amps of current without excessive voltage drop. The input
supply must have regulation adequate to prevent sudden
load changes from causing the LTC1703 input voltage to
dip. In most typical applications where the LTC1703 is
generating a secondary low voltage logic supply, all of
these input conditions are met by the main system logic
supply when fortified with an input bypass capacitor.
INPUT BYPASS CAPACITOR
A typical LTC1703 circuit running from a 5V logic supply
might provide 1.6V at 10A at one of its outputs. 5V to 1.6V
implies a duty cycle of 32%, which means QT is on 32%
of each switching cycle. During QT’s on-time, the current
drawn from the input equals the load current and during
the rest of the cycle, the current drawn from the input is
near zero. This 0A to 10A, 32% duty cycle pulse train adds
up to 4.7ARMS at the input. At 550kHz, switching cycles
last about 1.8µs—most system logic supplies have no
hope of regulating output current with that kind of speed.
A local input bypass capacitor is required to make up the
difference and prevent the input supply from dropping
drastically when QT kicks on. This capacitor is usually
chosen for RMS ripple current capability and ESR as well
as value.
The input bypass capacitor in an LTC1703 circuit is
common to both channels. Consider our 10A example
case with the other side of the LTC1703 disabled. The input
bypass capacitor gets exercised in three ways: its ESR
must be low enough to keep the initial drop as QT turns on
within reason (100mV or so); its RMS current capability
must be adequate to withstand the 4.7ARMS ripple current
at the input and the capacitance must be large enough to
maintain the input voltage until the input supply can make
up the difference. Generally, a capacitor that meets the
first two parameters will have far more capacitance than is
required to keep capacitance-based droop under control.
In our example, we need 0.01Ω ESR to keep the input drop
under 100mV with a 10A current step and 4.7ARMS ripple
current capacity to avoid overheating the capacitor. These
requirements can be met with multiple low ESR tantalum
or electrolytic capacitors in parallel, or with a large monolithic ceramic capacitor.
The two sides of the LTC1703 run off a single master clock
and are wired 180° out of phase with each other to
significantly reduce the total capacitance/ESR needed at
the input. Assuming 100mV of ripple and 10A output
current, we needed an ESR of 0.01Ω and 4.7A ripple
current capability for one side. Now, assume both sides
are running simultaneously with identical loading. If the
two sides switched in phase, all the loading conditions
would double and we’d need enough capacitance for
9.4ARMS and 0.005Ω ESR. With the two sides out of
phase, the input current is 4.8ARMS—barely larger than
the single case (Figure 7)! The peak current deltas are still
only 10A, requiring the same 0.01Ω ESR rating. As long as
the capacitor we chose for the single side application can
support the slightly higher 4.8ARMS current, we can add
the second channel without changing the input capacitor
at all. As a general rule, an input bypass capacitor capable
of supporting the larger output current channel can support both channels running simultaneously (see the
2-Phase Operation section for more information). Details
on how to calculate the maximum RMS input current can
be found in Application Note 77.
Tantalum capacitors are a popular choice as input capacitors for LTC1703 applications, but they deserve a special
caution here. Generic tantalum capacitors have a destructive failure mechanism when they are subjected to large
RMS currents (like those seen at the input of a LTC1703).
32%
10A
68%
QT CURRENT, SIDE 1 ONLY
(FOR 1-PHASE, 2 SIDES:
MULTIPLY CURRENT BY 2)
0
32%
6.8A
0
–3.2A
68%
CURRENT IN CIN, SIDE 1 ONLY
ICIN = 4.66ARMS, (1-PHASE,
2 SIDES: ICIN = 9.3ARMS)
32% 18% 32% 18%
10A
QT1 CURRENT
QT2 CURRENT
BOTH SIDES EQUAL LOAD
2-PHASE OPERATION
0
32% 18% 32% 18%
3.6A
0
CURRENT IN CIN,
BOTH SIDES EQUAL LOAD
ICIN = 4.8ARMS
1703 F07
–6.4A
Figure 7. Current Waveforms
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OUTPUT BYPASS CAPACITOR
The output bypass capacitor has quite different requirements from the input capacitor. The ripple current at the
output of a buck regulator like the LTC1703 is much lower
than at the input, due to the fact that the inductor current
is constantly flowing at the output whenever the LTC1703
is operating in continuous mode. The primary concern at
the output is capacitor ESR. Fast load current transitions
at the output will appear as voltage across the ESR of the
output bypass capacitor until the feedback loop in the
LTC1703 can change the inductor current to match the
new load current value. This ESR step at the output is often
the single largest budget item in the load regulation
calculation. As an example, our hypothetical 1.6V, 10A
switcher with a 0.01Ω ESR output capacitor would experience a 100mV step at the output with a 0 to 10A load
step—a 6.3% output change!
Usually the solution is to parallel several capacitors at the
output. For example, to keep the transient response inside
of 3% with the previous design, we’d need an output ESR
better than 0.0048Ω. This can be met with three 0.014Ω,
470µF tantalum capacitors in parallel.
INDUCTOR
The inductor in a typical LTC1703 circuit is chosen primarily for value and saturation current. The inductor value
sets the ripple current, which is commonly chosen at
around 40% of the anticipated full load current. Ripple
current is set by:
IRIPPLE =
tON(QB) (VOUT )
L
Calculating RMS Current in CIN
A buck regulator like the LTC1703 draws pulses of
current from the input capacitor during normal operation. The input capacitor sees this as AC current, and
dissipates power proportional to the RMS value of the
input current waveform. To properly specify the capacitor, we need to know the RMS value of the input current.
Calculating the approximate RMS value of a pulse train
with a fixed duty cycle is straightforward, but the LTC1703
complicates matters by running two sides simultaneously
and out of phase, creating a complex waveform at the
input.
To calculate the approximate RMS value of the input
current, we first need to calculate the average DC value
with both sides of the LTC1703 operating at maximum
load. Over a single period, the system will spend some
time with one top switch on and the other off, perhaps
some time with both switches on, and perhaps some
time with both switches off. During the time each top
switch is on, the current will equal that side’s full load
output current. When both switches are on, the total
current will be the sum of the two full load currents, and
when both are off, the current is effectively zero. Multiply
each current value by the percentage of the period that
the current condition lasts, and sum the results—this is
the average DC current value.
As an example, consider a circuit that takes a 5V input
and generates 3.3V at 3A at side 1 and 1.6V at 10A at
side 2. When a cycle starts, TG1 turns on and 3A flows
50%
16% 16% 18%
13
INPUT CURRENT (A)
At some random time after they are turned on, they can
blow up for no apparent reason. The capacitor manufacturers are aware of this and sell special “surge tested”
tantalum capacitors specifically designed for use with
switching regulators. When choosing a tantalum input
capacitor, make sure that it is rated to carry the RMS
current that the LTC1703 will draw. If the data sheet
doesn’t give an RMS current rating, chances are the
capacitor isn’t surge tested. Don’t use it!
10
IAVE
5.2
3
0
0
A
B
TIME
C
D
1703 SB1
Figure SB1. Average Current Calculation
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from CIN (time point A). 50% of the way through, TG2
turns on and the total current is 13A (time point B).
Shortly thereafter, TG1 turns off and the current drops to
10A (time point C). Finally, TG2 turns off and the current
spends a short time at 0 before TG1 turns on again (time
point D).
(
) (
)
(10A • 0.16) + (0A • 0.18) = 5.18A
IAVG = 3A • 0.5 + 13A • 0.16 +
Now we can calculate the RMS current. Using the same
waveform we used to calculate the average DC current,
subtract the average current from each of the DC values.
Square each current term and multiply the squares by the
same period percentages we used to calculate the average DC current. Sum the results and take the square root.
The result is the approximate RMS current as seen by the
input capacitor with both sides of the LTC1703 at full load.
Actual RMS current will differ due to inductor ripple
50%
(–2.18 • 0.5) + (7.82 • 0.16) +
(4.82 • 0.16) + (–5.18 • 0.18)
2
IRMS =
2
2
2
= 4.55ARMS
If the circuit is likely to spend time with one side operating
and the other side shut down, the RMS current will need
to be calculated for each possible case (side 1 on, side 2
off; side 1 off, side 2 on; both sides on). The capacitor
must be sized to withstand the largest RMS current of the
three—sometimes this occurs with one side shut down!
Side 1 only:
(
) (
)
IAVE1 = 3A • 0.67 + 0 A • 0.33 = 2.01A
IRMS1 =
(1 • 0.67) + (–2 • 0.33) = 1.42A
2
2
Side 2 only:
16% 16% 18%
(
7.8
AC INPUT CURRENT (A)
current and resistive losses, but this approximate value is
adequate for input capacitor calculation purposes.
) (
RMS
)
IAVE2 = 10 A • 0.32 + 0 A • 0.68 = 3.2A
4.8
IRMS2 =
(6.8 • 0.32) + (–3.2 • 0.68)
2
2
= 4.66 ARMS > 4.55ARMS
0
–2.2
– 5.2
0
A
B
TIME
C
D
1703 SB2
Figure SB2. AC Current Calculation
In our hypothetical 1.6V, 10A example, we'd set the ripple
current to 40% of 10A or 4A, and the inductor value would
be:
tON(QB) (VOUT ) (1.2µs)(1.6V )
=
= 0.64µH
IRIPPLE
3A
⎛ 1.6V ⎞
with tON(QB) = ⎜ 1 −
⎟ / 550kHz = 1.2µs
⎝
5V ⎠
Consider the case where both sides are operating at the
same load, with a 50% duty cycle at each side. The RMS
current with both sides running is near zero, while the
RMS current with one side active is 1/2 the total load
current of that side.
The inductor must not saturate at the expected peak
current. In this case, if the current limit was set to 15A, the
inductor should be rated to withstand 15A + 1/2 IRIPPLE,
or 17A without saturating.
L=
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FEEDBACK LOOP/COMPENSATION1
Feedback Loop Types
In a typical LTC1703 circuit, the feedback loop consists of
the modulator, the external inductor and output capacitor,
and the feedback amplifier and its compensation network.
All of these components affect loop behavior and need to
be accounted for in the loop compensation. The modulator
consists of the internal PWM generator, the output MOSFET
drivers and the external MOSFETs themselves. From a
feedback loop point of view, it looks like a linear voltage
transfer function from COMP to SW and has a gain roughly
equal to the input voltage. It has fairly benign AC behavior
at typical loop compensation frequencies with significant
phase shift appearing at half the switching frequency.
The external inductor/output capacitor combination makes
a more significant contribution to loop behavior. These
components cause a second order LC roll-off at the output,
with the attendant 180° phase shift. This roll-off is what
filters the PWM waveform, resulting in the desired DC
output voltage, but the phase shift complicates the loop
compensation if the gain is still higher than unity at the pole
frequency. Eventually (usually well above the LC pole
frequency), the reactance of the output capacitor will
approach its ESR, and the roll-off due to the capacitor will
stop, leaving 6dB/octave and 90° of phase shift (Figure 8).
chosen based on the regulation and load current requirements without considering the AC loop response. The
feedback amplifier, on the other hand, gives us a handle
with which to adjust the AC response. The goal is to have
180° phase shift at DC (so the loop regulates) and something less than 360° phase shift at the point that the loop
gain falls to 0dB. The simplest strategy is to set up the
feedback amplifier as an inverting integrator, with the 0dB
frequency lower than the LC pole (Figure 9). This “type 1”
configuration is stable but transient response will be less
than exceptional if the LC pole is at a low frequency.
C1
R1
–
IN
OUT
+
RB
VREF
1703 F09a
Figure 9a. Type 1 Amplifier Schematic Diagram
GAIN
(dB)
PHASE
(DEG)
GAIN
0
0
So far, the AC response of the loop is pretty well out of the
user’s control. The modulator is a fundamental piece of the
LTC1703 design, and the external L and C are usually
–6dB/OCT
–90
–180
GAIN
(dB)
AV
PHASE
(DEG)
PHASE
–270
1703 F09b
GAIN
–12dB/OCT
Figure 9b. Type 1 Amplifier Transfer Function
0
0
–90
PHASE
–180
–6dB/OCT
Figure 10 shows an improved “type 2” circuit that uses an
additional pole-zero pair to temporarily remove 90° of
phase shift. This allows the loop to remain stable with 90°
more phase shift in the LC section, provided the loop
reaches 0dB gain near the center of the phase “bump.”
Type 2 loops work well in systems where the ESR zero in
1703 F08
Figure 8. Transfer Function of Buck Modulator
1The information in this section is based on the paper “The K Factor: A New Mathematical Tool for
Stability Analysis and Synthesis” by H. Dean Venable, Venable Industries, Inc. For complete paper,
see “Reference Reading #4” at www.linear-tech.com.
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C2
C2
C3
R2
R1
C1
R2
R1
–
IN
+
RB
VREF
VREF
1703 F10a
Figure 10a. Type 2 Amplifier Schematic Diagram
PHASE
(DEG)
GAIN
(dB)
C1
–
IN
OUT
+
RB
R3
OUT
1703 F11a
Figure 11a. Type 3 Amplifier Schematic Diagram
GAIN
(dB)
PHASE
(DEG)
–6dB/OCT
–6dB/OCT
+6dB/OCT
GAIN
GAIN
0
0
–6dB/OCT
0
0
–6dB/OCT
–90
–90
–180
–180
PHASE
PHASE
–270
–270
1703 F11b
1703 F10b
Figure 10b. Type 2 Amplifier Transfer Function
Figure 11b. Type 3 Amplifier Transfer Function
the LC roll-off happens close to the LC pole, limiting the
total phase shift due to the LC. The additional phase
compensation in the feedback amplifier allows the 0dB
point to be at or above the LC pole frequency, improving
loop bandwidth substantially over a simple type 1 loop. It
has limited ability to compensate for LC combinations
where low capacitor ESR keeps the phase shift near 180°
for an extended frequency range. LTC1703 circuits using
conventional switching grade electrolytic output capacitors can often get acceptable phase margin with type 2
compensation.
need type 3 compensation to obtain acceptable phase
margin with a high bandwidth feedback loop.
“Type 3” loops (Figure 11) use two poles and two zeros to
obtain a 180° phase boost in the middle of the frequency
band. A properly designed type 3 circuit can maintain
acceptable loop stability even when low output capacitor
ESR causes the LC section to approach 180° phase shift
well above the initial LC roll-off. As with a type 2 circuit, the
loop should cross through 0dB in the middle of the phase
bump to maximize phase margin. Many LTC1703 circuits
using low ESR tantalum or OS-CON output capacitors
Feedback Component Selection
Selecting the R and C values for a typical type 2 or type 3
loop is a nontrivial task. The applications shown in this data
sheet show typical values, optimized for the power components shown. They should give acceptable performance
with similar power components, but can be way off if even
one major power component is changed significantly.
Applications that require optimized transient response will
need to recalculate the compensation values specifically
for the circuit in question. The underlying mathematics are
complex, but the component values can be calculated in a
straightforward manner if we know the gain and phase of
the modulator at the crossover frequency.
Modulator gain and phase can be measured directly from
a breadboard, or can be simulated if the appropriate
parasitic values are known. Measurement will give more
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accurate results, but simulation can often get close enough
to give a working system. To measure the modulator gain
and phase directly, wire up a breadboard with an LTC1703
and the actual MOSFETs, inductor, and input and output
capacitors that the final design will use. This breadboard
should use appropriate construction techniques for high
speed analog circuitry: bypass capacitors located close to
the LTC1703, no long wires connecting components,
appropriately sized ground returns, etc. Wire the feedback
amplifier as a simple type 1 loop, with a 10k resistor from
VOUT to FB and a 0.1µF feedback capacitor from COMP to
FB. Choose the bias resistor (RB) as required to set the
desired output voltage. Disconnect RB from ground and
connect it to a signal generator or to the source output of
a network analyzer (Figure 12) to inject a test signal into the
loop. Measure the gain and phase from the COMP pin to
the output node at the positive terminal of the output
capacitor. Make sure the analyzer’s input is AC coupled so
that the DC voltages present at both the COMP and VOUT
nodes don’t corrupt the measurements or damage the
analyzer.
5V
+
10Ω
CIN
MBR0530T
+
10µF
VCC
PVCC
BOOST2
VCOMP
TO
ANALYZER 0.1µF
NC
AC
SOURCE
FROM
ANALYZER
RB
10k
TG
1/2 LTC1703
COMP
SW
QT
FB
QB
RUN/SS
BG
1µF
LEXT
+
VOUT
TO
ANALYZER
COUT
FCB
FAULT
V(OUT) in degrees. Refer to your SPICE manual for details
of how to generate this plot.
*1703 modulator gain/phase
*©1999 Linear Technology
*this file written to run with PSpice 8.0
*may require modifications for other SPICE
simulators
*MOSFETs
rfet mod sw 0.02
;MOSFET rdson
*inductor
lext sw out1 1u
rl out1 out 0.005
;inductor value
;inductor series R
*output cap
cout out out2 1000u
resr out2 0 0.01
;capacitor value
;capacitor ESR
*1703 internals
emod mod 0 laplace {v(comp)} =
+ {5*exp(–s*909e–9)} ;5 -> 3.3 for 3.3 VCC
*emod mod 0 comp 0 5 ;use if above lines fail
vstim comp 0 0 ac 1 ;ac stimulus
.ac dec 100 1k 1meg
.probe
.end
With the gain/phase plot in hand, a loop crossover frequency can be chosen. Usually the curves look something
like Figure 8. Choose the crossover frequency in the rising
or flat parts of the phase curve, beyond the external LC
poles. Frequencies between 10kHz and 50kHz usually
work well. Note the gain (GAIN, in dB) and phase (PHASE,
in degrees) at this point. The desired feedback amplifier
gain will be – GAIN to make the loop gain 0dB at this
frequency. Now calculate the needed phase boost, assuming 60° as a target phase margin:
BOOST = – (PHASE + 30°)
SGND PGND
1703 F12
Figure 12. Modulator Gain/Phase Measurement Set-Up
If breadboard measurement is not practical, a SPICE
simulation can be used to generate approximate gain/
phase curves. Plug the expected capacitor, inductor and
MOSFET values into the following SPICE deck and generate an AC plot of V(VOUT)/V(COMP) in dB and phase of
If the required BOOST is less than 60°, a type 2 loop can
be used successfully, saving two external components.
BOOST values greater than 60° usually require type 3
loops for satisfactory performance.
Finally, choose a convenient resistor value for R1 (10k is
usually a good value). Note that channel 1 includes R1 and
RB internally as part of the VID DAC circuitry. R1 is fixed
at 10kΩ and RB varies depending on the VID code
selected.
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Now calculate the remaining values:
CURRENT LIMIT PROGRAMMING
(K is a constant used in the calculations)
Programming the current limit on the LTC1703 is straightforward. The IMAX pin sets the current limit by setting the
maximum allowable voltage drop across QB (the bottom
MOSFET) before the current limit circuit engages. The
voltage across QB is set by its on-resistance and the
current flowing in the inductor, which is the same as the
output current. The LTC1703 current limit circuit inverts
the voltage at IMAX before comparing it with the negative
voltage across QB, allowing the current limit to be set with
a positive voltage.
ƒ = chosen crossover frequency
G = 10(GAIN/20) (this converts GAIN in dB to G in absolute
gain)
Type 2 Loop:
⎞
⎛ BOOST
K = Tan⎜
+ 45°⎟
⎠
⎝ 2
1
C2 =
2πƒGKR1
( )
C1 = C2 K2 – 1
R2 =
RB =
K
2πƒC1
VREF R1
( )
VOUT – VREF
Type 3 Loop:
⎞
⎛ BOOST
K = Tan2 ⎜
+ 45°⎟
⎠
⎝ 4
1
2πƒGR1
C1 = C2 K – 1
C2 =
( )
R2 =
K
2πƒC1
R1
R3 =
(K – 1)
C3 =
1
RB =
2πƒ K R3
( )
VREF R1
VOUT – VREF
To set the current limit, calculate the expected voltage
drop across QB at the maximum desired current:
VPROG = (IILIM)(RDS(ON)) + CF
ILIM should be chosen to be quite a bit higher than the
expected operating current, to allow for MOSFET RDS(ON)
changes with temperature. Setting ILIM to 150% of the
maximum normal operating current is usually safe and will
adequately protect the power components if they are
chosen properly. The CF term is an approximate factor that
corrects for errors caused by ringing on the switch node
(illustrated in Figure 6). This correction factor will change
depending on the layout and the components used, but
100mV is usually a good starting point. However, to
provide adequate margin and to accommodate for offsets
and external variations, it is recommended that VPROG be
calculated with CF = 100 ± 50mV. VPROG is then programmed at the IMAX pin using the internal 10µA pull-up
and an external resistor:
RILIM = VPROG/10µA
The resulting value of RILIM should be checked in an actual
circuit to ensure that the ILIM circuit kicks in as expected.
MOSFET RDS(ON) specs are like horsepower ratings in
automobiles, and should be taken with a grain of salt.
Circuits that use very low values for RIMAX (< 20k) should
be checked carefully, since small changes in RIMAX can
cause large ILIM changes when the 100mV correction
factor makes up a large percentage of the total VPROG
value. If VPROG is set too low, the LTC1703 may fail to
start up.
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Accuracy Trade-Offs
The VDS sensing scheme used in the LTC1703 is not
particularly accurate, primarily due to uncertainty in the
RDS(ON) from MOSFET to MOSFET. A second error term
arises from the ringing present at the SW pin, which
causes the VDS to look larger than (ILOAD)(RDS(ON)) at the
beginning of QB’s on-time. These inaccuracies do not
prevent the LTC1703 current limit circuit from protecting
itself and the load from damaging overcurrent conditions,
but they do prevent the user from setting the current limit
to a tight tolerance if more than one copy of the circuit is
being built. The 50% factor in the current setting equation
above reflects the margin necessary to ensure that the
circuit will stay out of current limit at the maximum normal
load, even with a hot MOSFET that is running quite a bit
higher than its RDS(ON) spec.
FCB OPERATION/SECONDARY WINDINGS
The FCB pin can be used in conjunction with a secondary
winding on one side of the LTC1703 to generate a third
regulated voltage output. This output can be directly
regulated at the FCB pin. In theory, a fourth output could
be added, either unregulated or with additional external
circuitry at the FCB pin.
The extra auxiliary output is taken from a second winding
on the core of the inductor on one channel, converting it
into a transformer (Figure 13). The auxiliary output voltage
is set by the main output voltage and the turns ratio of the
extra winding to the primary winding. Load regulation at
the auxiliary output will be relatively good as long as the
main output is running in continuous mode. As the load on
the main channel drops and the LTC1703 switches to
discontinuous or Burst Mode operation, the auxiliary
output will not be able to maintain regulation, especially if
the load at the auxiliary output remains heavy.
To avoid this, the auxiliary output voltage is divided down
with a conventional feedback resistor string with the
divided auxiliary output voltage fed back to the FCB pin
(Figure 13). The FCB pin threshold is trimmed to 800mV
with 20mV of hysteresis, allowing fairly precise control of
the auxiliary voltage. If the LTC1703 is in discontinuous or
Burst Mode operation and the auxiliary output voltage
drops, the FCB pin will trip and the LTC1703 will resume
continuous operation regardless of the load on the main
output. The FCB pin removes the requirement that power
must be drawn from the inductor primary in order to
extract power from the auxiliary windings. With the loop in
continuous mode, the auxiliary outputs may be loaded
without regard to the primary load. Note that if the LTC1703
is already running in continuous mode and the auxiliary
output drops due to excessive loading, no additional
action can be taken by the LTC1703 to regulate the
auxiliary output.
VIN
VOUT(AUX)
+
+
CIN
TG
COUT(AUX)
QT
LTC1703
FCB BG
+
QB
VOUT
COUT
RFCB1
RFCB2
1703 F13
Figure 13. Regulating an Auxiliary Output with the FCB Pin
FAULT FLAG
The FAULT pin is an open-drain output that indicates if one
or both of the outputs has exceeded 15% of its programmed output voltage. FAULT includes an internal
10µA pull-up to VCC and does not require an external pullup to interface to standard logic. FAULT pulls low in
normal operation, and releases when a overvoltage fault is
detected.
When an overvoltage fault occurs, an internal latch sets
and FAULT goes high, disabling the LTC1703 until the
latch is cleared by recycling the power or pulling both
RUN/SS pins low simultaneously. Alternately, the FAULT
pin can be pulled back low externally with an opencollector/open-drain device or an N-channel MOSFET or
NPN, which will allow the LTC1703 to resume normal
operation, but will not reset the latch. If the pull-down is
later removed, the LTC1703 will latch off again unless the
latch is reset by cycling the power or RUN/SS pins.
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OPTIMIZING PERFORMANCE
2-Step Conversion
The LTC1703 is ideally suited for use in 2-step conversion
systems. 2-step systems use a primary regulator to convert the input power source (batteries or AC line voltage)
to an intermediate supply voltage, often 5V. The LTC1703
then converts the intermediate voltage to the low voltage,
high current supplies required by the system. Compared
to a 1-step converter that converts a high input voltage
directly to a very low output voltage, the 2-step converter
exhibits superior transient response, smaller component
size and equivalent efficiency. Thermal management and
layout complexity are also improved with a 2-step
approach.
A typical notebook computer supply might use a 4-cell
Li-Ion battery pack as an input supply with a 15V nominal
terminal voltage. The logic circuits require 5V/3A and
3.3V/5A to power system board logic, and 2.5V/0.5A,
1.5V/2A and 1.3V/10A to power the CPU. A typical 2-step
conversion system would use a step-down switcher (perhaps an LTC1628 or two LTC1625s) to convert 15V to 5V
and another to convert 15V to 3.3V (Figure 14). One
channel of the LTC1703 would generate the 1.3V supply
using the 3.3V supply as the input and the other channel
would generate 1.5V using the 5V supply as the input. The
corresponding 1-step system would use four similar stepdown switchers, each using 15V as the input supply and
generating one of the four output voltages. Since the 2.5V
supply represents a small fraction of the total output
power, either system can generate it from the 3.3V output
using an LDO linear regulator, without the 75% linear
efficiency making much of an impact on total system
efficiency.
VBAT
15V
5V/3A
LTC1628*
LTC1703
1.5V/2A
1.3V/10A
3.3V/5A
*OR TWO LTC1625s
LDO
2.5V/0.5A
1703 F14
Figure 14. 2-Step Conversion Block Diagram
Clearly, the 5V and 3.3V sections of the two schemes are
equivalent. The 2-step system draws additional power
from the 5V and 3.3V outputs, but the regulation techniques and trade-offs at these outputs are similar. The
difference lies in the way the 1.5V and 1.3V supplies are
generated. For example, the 2-step system converts 3.3V
to 1.3V with a 39% duty cycle. During the QT on-time, the
voltage across the inductor is 2V and during the QB
on-time, the voltage is 1.3V, giving roughly symmetrical
transient response to positive and negative load steps. The
2V maximum voltage across the inductor allows the use of
a small 0.47µH inductor while keeping ripple current
under 4A (40% of the 10A maximum load). By contrast,
the 1-step converter is converting 15V to 1.3V, requiring
just a 9% duty cycle. Inductor voltages are now 13.7V
when QT is on and 1.3V when QB is on, giving vastly
different di/dt values and correspondingly skewed transient response with positive and negative current steps.
The narrow 9% duty cycle usually requires a lower switching frequency, which in turn requires a higher value
inductor and larger output capacitor. Parasitic losses due
to the large voltage swing at the source of QT cost
efficiency, eliminating any advantage the 1-step conversion might have had.
Note that power dissipation in the LTC1703 portion of a
2-step circuit is lower than it would be in a typical 1-step
converter, even in cases where the 1-step converter has
higher total efficiency than the 2-step system. In a typical
microprocessor core supply regulator, for example, the
regulator is usually located right next to the CPU. In a
1-step design, all of the power dissipated by the core
regulator is right there next to the hot CPU, aggravating
thermal management. In a 2-step LTC1703 design, a
significant percentage of the power lost in the core regulation system happens in the 5V or 3.3V supply, which is
usually away from the CPU. The power lost to heat in the
LTC1703 section of the system is relatively low, minimizing the heat near the CPU.
2-Step Efficiency Calculation
Calculating the efficiency of a 2-step converter system
involves some subtleties. Simply multiplying the efficiency of the primary 5V or 3.3V supply by the efficiency
of the 1.5V or 1.3V supply underestimates the actual
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Efficiency =
TotalOutputPower
(100%)
TotalOutputPower + TotalPowerLost
In our example 2-step system, the total output power is:
Total output power =
15W + 16.5W + 1.25W + 3W + 13W = 48.75W
corresponding to 5V, 3.3V, 2.5V, 1.5V and 1.3V output
voltages.
Assuming the LTC1703 provides 90% efficiency at each
output, the additional load on the 5V and 3.3V supplies is:
1.3V: 13W/90% = 14.4W/3.3V = 4.4A from 3.3V
1.5V: 3W/90% = 3.3W/5V = 0.67A from 5V
2.5V: 1.25W/75% = 1.66W/3.3V = 0.5A from 3.3V
If the 5V and 3.3V supplies are each 94% efficient, the
power lost in each supply is:
1.3V: 14.4W – 13W = 1.4W
1.5V: 3.3W – 3W = 0.3W
2.5V: 1.66W – 1.25W = 0.4W
3.3V: 16.5W + 3.3V (4.4A + 0.5A) = 32.67W load
(32.67W/94%) – 32.67W = 2.09W lost
5V: 15W + 5V (0.67A) = 18.4W load
(18.4W/94%) – 18.4W = 1.17W lost
Total loss = 5.36W
Total system efficiency =
48.75W/(48.75W + 5.36W) = 90.1%
Maximizing High Load Current Efficiency
Efficiency at high load currents (when the LTC1703 is
operating in continuous mode) is primarily controlled by
the resistance of the components in the power path
(QT, QB, LEXT) and power lost in the gate drive circuits due
to MOSFET gate charge. Maximizing efficiency in this
region of operation is as simple as minimizing these
terms.
The behavior of the load over time affects the efficiency
strategy. Parasitic resistances in the MOSFETs and the
inductor set the maximum output current the circuit can
supply without burning up. A typical efficiency curve
(Figure 15) shows that peak efficiency occurs near 30% of
this maximum current. If the load current will vary around
the efficiency peak and will spend relatively little time at the
maximum load, choosing components so that the average
load is at the efficiency peak is a good idea. This puts the
maximum load well beyond the efficiency peak, but usually gives the greatest system efficiency over time, which
translates to the longest run time in a battery-powered
system. If the load is expected to be relatively constant at
the maximum level, the components should be chosen so
that this load lands at the peak efficiency point, well below
the maximum possible output of the converter.
100
EFFICIENCY (%)
efficiency, since a significant fraction of the total power is
drawn from the 3.3V and 5V rails in a typical system. The
correct way to calculate system efficiency is to calculate
the power lost in each stage of the converter, and divide
the total output power from all outputs by the sum of the
output power plus the power lost:
VIN = 5V
VOUT = 3.3V
VOUT = 2.5V
90
VOUT = 1.6V
80
70
0
5
10
LOAD CURRENT (A)
15
1703 G01
Figure 15. Typical LTC1703 Efficiency Curves
Maximizing Low Load Current Efficiency
Low load current efficiency depends strongly on proper
operation in discontinuous and Burst Mode operations. In
an ideally optimized system, discontinuous mode reduces
conduction losses but not switching losses, since each
power MOSFET still switches on and off once per cycle. In
a typical system, there is additional loss in discontinuous
mode due to a small amount of residual current left in the
inductor when QB turns off. This current gets dissipated
across the body diode of either QT or QB. Some LTC1703
systems lose as much to body diode conduction as they
save in MOSFET conduction. The real efficiency benefit of
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discontinuous mode happens when Burst Mode operation
is invoked. At typical power levels, when Burst Mode
operation is activated, gate drive is the dominant loss
term. Burst Mode operation turns off all output switching
for several clock cycles in a row, significantly cutting gate
drive losses. As the load current in Burst Mode operation
falls toward zero, the current drawn by the circuit falls to
the LTC1703’s background quiescent level—about 3mA
per channel.
To maximize low load efficiency, make sure the LTC1703
is allowed to enter discontinuous and Burst Mode operation as cleanly as possible. FCB must be above its 0.8V
threshold. Minimize ringing at the SW node so that the
discontinuous comparator leaves as little residual current
in the inductor as possible when QB turns off. It helps to
connect the SW pin of the LTC1703 as close to the drain
of QB as possible. An RC snubber network can also be
added from SW to PGND.
REGULATION OVER COMPONENT TOLERANCE/
TEMPERATURE
DC Regulation Accuracy
The LTC1703 initial DC output accuracy depends mainly
on internal reference accuracy, op amp offset and external
resistor accuracy (side 2 only). Two LTC1703 specs come
into play: feedback voltage and feedback voltage line
regulation. The feedback voltage spec is 800mV ± 8mV
over the full temperature range, and is specified at the FB
pin, which encompasses both reference accuracy and any
op amp offset. This accounts for 1% error at the output
with a 5V input supply. The feedback voltage line regulation spec adds an additional 0.05%/V term that accounts
for change in reference output with change in input supply
voltage. With a 5V supply, the errors contributed by the
LTC1703 itself add up to no more than 1.5% DC error at the
output.
At side 2, the output voltage setting resistors (R1 and RB
in Figure 3) are the other major contributor to DC error. At
a typical 1.xV output voltage, the resistors are of roughly
the same value, which tends to halve their error terms,
improving accuracy. Still, using 1% resistors for R1 and
RB will add 1% to the total output error budget, equal to
that of all errors due to the LTC1703 combined. Using 0.1%
resistors in just those two positions can nearly halve the DC
output error for very little additional cost. Side 1 uses the
internal VID network to set the output voltage, and is
specified to be within ±1.5% of the values shown in
Table 1.
Load Regulation
Load regulation is affected by feedback voltage, feedback
amplifier gain and external ground drops in the feedback
path. Feedback voltage is covered above and is within 1%
over temperature. A full-range load step might require a
10% duty cycle change to keep the output constant,
requiring the COMP pin to move about 100mV. With
amplifier gain at 85dB, this adds up to only a 10µV shift at
FB, negligible compared to the reference accuracy terms.
External ground drops aren’t so negligible. The LTC1703
can sense the positive end of the output voltage by
attaching the feedback resistor directly at the load, but it
cannot do the same with the ground lead. Just 0.001Ω of
resistance in the ground lead at 10A load will cause a 10mV
error in the output voltage—as much as all the other DC
errors put together. Proper layout becomes essential to
achieving optimum load regulation from the LTC1703. A
properly laid out LTC1703 circuit should move less than a
millivolt at the output from zero to full load.
TRANSIENT RESPONSE
Transient response is the other half of the regulation
equation. The LTC1703 can keep the DC output voltage
constant to within 1% when averaged over hundreds of
cycles. Over just a few cycles, however, the external
components conspire to limit the speed that the output
can move. Consider our typical 5V to 1.5V circuit, subjected to a 1A to 5A load transient. Initially, the loop is in
regulation and the DC current in the output capacitor is
zero. Suddenly, an extra 4A start flowing out of the output
capacitor while the inductor is still supplying only 1A. This
sudden change will generate a (4A)(CESR)voltage step at
the output; with a typical 0.015Ω output capacitor ESR,
this is a 60mV step at the output, or 4% (for a 1.5V output
voltage).
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Very quickly, the feedback loop will realize that something
has changed and will move at the bandwidth allowed by
the external compensation network towards a new duty
cycle. If the bandwidth is set to 50kHz, the COMP pin will
get to 60% of the way to 90% duty cycle in 3µs. Now the
inductor is seeing 3.5V across itself for a large portion of
the cycle, and its current will increase from 1A at a rate set
by di/dt = V/L. If the inductor value is 0.5µH, the di/dt will
be 3.5V/0.5µH or 7A/µs. Sometime in the next few microseconds after the switch cycle begins, the inductor current
will have risen to the 5A level of the load current and the
output capacitor will stop losing charge.
Note that the output voltage will stop dropping before the
inductor current reaches this new output current level.
Recall that any practical output capacitor looks like a pure
capacitance in series with some amount of ESR. When a
load transient hits, virtually all of the initial voltage drop at
the output is due to IR drop across the ESR. The output
capacitance begins to discharge at the same time and
continues until the inductor current rises to match the new
output current level.
The output voltage, however, will turn around and start
heading the right way before this happens. The next time
the top MOSFET turns on, the inductor current will begin
increasing linearly. This increasing current flows almost
entirely into the capacitor, going through the ESR as it
does so (Figure 16). Positive di/dt in the inductor causes
positive dv/dt in the ESR, regardless of what the “pure”
capacitance is doing. The output voltage will turn around
when the positive dv/dt across the ESR exceeds the
negative dv/dt across the pure capacitance. If the expected
load step (∆I) is known, an optimum inductor value can be
chosen:
(
)
L ≤ VIN – VOUT • C •
ESR
∆I
Making L smaller than this optimum value yields little or no
improvement in transient response. As the output voltage
recovers, the inductor current will briefly rise above the
level of the output current to replenish the charge lost from
the output capacitor. With a properly compensated loop,
the entire recovery time will be inside of 10µs.
Most loads care only about the maximum deviation from
ideal, which occurs somewhere in the first two cycles after
the load step hits. During this time, the output capacitor
does all the work until the inductor and control loop regain
control. The initial drop (or rise if the load steps down) is
entirely controlled by the ESR of the capacitor and amounts
to most of the total voltage drop. To minimize this drop,
reduce the ESR as much as possible by choosing low ESR
IL
IOUT
IL
IOUT
VESR
VESR
VCAP
VCAP
IL
VSW
L
COUT
VOUT
VOUT
+
VOUT
VOUT(NOMINAL)
VESR
–
+
IOUT
VCAP
–
1703 F16b
1703 F16a
Figure 16a. Capacitor Parasitics
Affecting Transient Recovery
TRANSIENT
HITS
VOUT
TURNS
AROUND
IL > IOUT
TIME
Figure 16b. Transient Recovery Curves
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capacitors and/or paralleling multiple capacitors at the
output. The capacitance value accounts for the rest of the
voltage drop until the inductor current rises. With most
output capacitors, several devices paralleled to get the
ESR down will have so much capacitance that this drop
term is negligible. Ceramic capacitors are an exception; a
small ceramic capacitor can have suitably low ESR with
relatively small values of capacitance, making this second
drop term significant.
Optimizing Loop Compensation
Loop compensation has a fundamental impact on transient recovery time, the time it takes the LTC1703 to
recover after the output voltage has dropped due to output
capacitor ESR. Optimizing loop compensation entails
maintaining the highest possible loop bandwidth while
ensuring loop stability. The Feedback Component Selection section describes in detail how to design an optimized
feedback loop, appropriate for most LTC1703 systems.
Voltage Positioning
If the load transients consist primarily of load steps from
near zero load to full load and back, the transient response
can be traded off against DC regulation performance by
using a technique known as “voltage positioning.” The
VIN
goal is to intentionally compromise the DC regulation loop
such that the output rides near the maximum allowable
value (often +5%) with no load and near the minimum
allowable value at maximum load. With the load at zero,
any transient that comes along will be a current increase
which will cause the output voltage to fall. Since the output
voltage is initially at a high value, it can fall further before
it goes out of spec. Similarly, at full load, the output current
can only decrease, causing a positive shift in the output
voltage; the initial low value allows it to rise further before
the spec is exceeded. The primary benefit of voltage
positioning is it increases the allowable ESR of the output
capacitors, saving cost. An additional bonus is that at
maximum load, the output voltage is near the minimum
allowable, decreasing the power dissipated in the load.
Implementing voltage positioning is as simple as creating
an intentional resistance in the output path to generate the
required voltage drop. This resistance can be a low value
resistor, a length of PCB trace, or even the parasitic
resistance of the inductor if an appropriate filter is used. If
the LTC1703 senses the output voltage upstream from the
resistance (Figure 17c), the output voltage will move with
load as I • RVP, where I is the load current and RVP is the
value of the voltage positioning resistor. If the feedback
network is then reset to regulate near the upper edge of the
MAXIMUM
ALLOWABLE
TRANSIENT
+5%
VOUT NOM
–5%
LTC1703
VOUT
MAX
FB
LOAD
CURRENT
0
1703 F17a
1703 F17b
Figure 17a. Standard Regulator
Figure 17b. Standard Regulator—Transient Response
VIN
+5%
VOUT NOM
–5%
RVP
LTC1703
MAXIMUM
ALLOWABLE
TRANSIENT
≈2× FIGURE 17b
VOUT
MAX
FB
LOAD
CURRENT
0
1703 F17c
1703 F17d
Figure 17c. Voltage Positioning Regulator
Figure 17d. Positioning Regulator—Transient Response
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specified tolerance, the output voltage will ride high when
ILOAD is low and will ride low when ILOAD is high. Compared
to a traditional regulator, a voltage positioning regulator
can theoretically stand as much as twice the ESR drop
across the output capacitor while maintaining output
voltage regulation. This means smaller, cheaper output
capacitors can be used while keeping the output voltage
within acceptable limits.
load which can dissipate 2.5W continuously or 50W if
pulsed with a 5% duty cycle, enough for most LTC1703
circuits. Solder the MOSFET and the resistor(s) as close to
the output of the LTC1703 circuit as possible and set up
the signal generator to pulse at a 100Hz rate with a 5% duty
cycle. This pulses the LTC1703 with 500µs transients
10ms apart, adequate for viewing the entire transient
recovery time for both positive and negative transitions
while keeping the load resistor cool.
Measurement Techniques
Measuring transient response presents a challenge in two
respects: obtaining an accurate measurement and generating a suitable transient to use to test the circuit. Output
measurements should be taken with a scope probe
directly across the output capacitor. Proper high frequency probing techniques should be used. In particular,
don’t use the 6" ground lead that comes with the probe!
Use an adapter that fits on the tip of the probe and has a
short ground clip to ensure that inductance in the ground
path doesn’t cause a bigger spike than the transient signal
being measured. Conveniently, the typical probe tip ground
clip is spaced just right to span the leads of a typical output
capacitor. Make sure the bandwidth limit on the scope is
turned off, since a significant portion of the transient
energy occurs above the 20MHz cutoff.
Now that we know how to measure the signal, we need to
have something to measure. The ideal situation is to use
the actual load for the test, and switch it on and off while
watching the output. If this isn’t convenient, a current step
generator is needed. This generator needs to be able to
turn on and off in nanoseconds to simulate a typical
switching logic load, so stray inductance and long clip
leads between the LTC1703 and the transient generator
must be minimized.
Figure 18 shows an example of a simple transient generator. Be sure to use a noninductive resistor as the load
element—many power resistors use an inductive spiral
pattern and are not suitable for use here. A simple solution
is to take ten 1/4W film resistors and wire them in parallel
to get the desired value. This gives a noninductive resistive
LTC1703
VOUT
RLOAD
PULSE
GENERATOR
IRFZ44 OR
EQUIVALENT
LOCATE CLOSE
TO THE OUTPUT
50Ω
1703 F18
0V TO 10V
100Hz, 5%
DUTY CYCLE
Figure 18. Transient Load Generator
Changing the Output Voltage on the Fly
The voltage at side 1 of the LTC1703 can be changed on the
fly by changing the VID code while the output is enabled,
but care must be taken to avoid tripping the overvoltage
fault circuit. Stepping the voltage upwards abruptly is safe,
but stepping down quickly by more than 15% can leave the
system in a state where the output voltage is still at the old
higher level, but the feedback node is set to expect a new,
substantially lower voltage. If this condition persists for
more than 10µs, the overvoltage fault circuitry will fire and
latch off the LTC1703.
The simplest solution is to disable the fault circuit by
grounding the FAULT pin. Systems that must keep the
fault circuit active should ensure that the output voltage is
never programmed to step down by more than 15% in any
single step. The safest strategy is to step the output down
by 10% or less at a time and wait for the output to settle
to the new value before taking subsequent steps.
1703fa
31
32
33k
330pF
330pF
56pF
0.1µF
33k
0.1µF
0.1µF
0.01µF
D1 TO D7: MOTOROLA
(800) 441-2447
Q1 TO Q5, QT1A/1B, QB1A/1B:
INTERNATIONAL RECTIFIER
(310) 22-3331
QT2, QB2: FAIRCHILD
(207) 775-4503
L1, L2, L3: PANASONIC
(201) 348-7522
L4, L5: COILTRONICS
(561) 241-7876
3.3VENABLE
STDBY5V
STDBY3.3V
STBYMD
5VENABLE
56pF
14
13
12
11
10
9
8
7
6
5
4
3
2
1
SENSE2+
SENSE2–
VOSENSE2
ITH2
3.3VOUT
SGND
ITH1
FCB
STBYMD
FREQSET
VOSENSE1
SENSE1–
SENSE1+
RUN/SS1
1000pF
RUNSS2
TG2
SW2
BOOST2
BG2
PGND
INTVCC
EXTVCC
BG1
VIN
BOOST1
SW1
TG1
FLTCPL
LTC1628
1000pF
1µF
15
16
17 0.1µF
18
19
0.1µF
D2 CMDSH-3
4.7µF
+
21
20
D1 CMDSH-3
22
23
24
25
26
27
28
0.1µF 10Ω
50V
Q5
IRF7807
Q4
IRF7807
Q3
IRF7805
0.22µF
Q1
IRF7805
Q2
IRF7805
L2
4.6µH
ETQP6F4R6H
D4
MBRS130T3
D3
MBRD835L
L1
2.9µH
ETQP6F2R9L
+
0.01Ω
180µF
4V
150µF
6V
×2
0.004Ω
+
Complete 2-Step Notebook Power Supply (Continued on the Next Page)
63.4k
1%
20.0k
1%
20.0k
1%
105k
1%
10µF
6.3V
22µF
50V
100pF
47pF 10µF
6.3V
47pF
100pF
0.1µF
50V
0.1µF
50V
1703 TA03
VOUT2
3.3V
5A
TO
POINT
A
VOUT1
5V
4A
VIN
7V TO
20V
LTC1703
TYPICAL APPLICATIO S
1703fa
U
1µF
VOUT4
0.9V TO 2V
12A
180µF, 4V
×6
D1 TO D7: MOTOROLA
(800) 441-2447
Q1 TO Q5, QT1A/1B, QB1A/1B:
INTERNATIONAL RECTIFIER
(310) 22-3331
QT2, QB2: FAIRCHILD
(207) 775-4503
L1, L2, L3: PANASONIC
(201) 348-7522
L4, L5: COILTRONICS
(561) 241-7876
COREVENABLE
1.5V ENABLE
FAULT
+
L3, 0.8µH
ETQP6F0R8L
0.22µF
220pF
100k
D5
MBRD- QB1A
IRF7811
835L
QT1A
IRF7811
10k
200pF
QB1B
IRF7811
QT1B
IRF7811
VID0
VID1
VID2
VID3
VID4
15pF
R18, 1M
18.7k, 1%
1µF
D6
MBR0520LT1
14
13
12
11
10
9
8
7
6
5
4
3
2
1
VID1
VID0
SENS
FB1
SGND
COMP1
FAULT
PGND
SW2
TG2
BG2
BOOST2
IMAX2
VID2
VID3
VID4
VCC
FB2
COMP2
15
16
17
18
19
20
21
22
23
24
25
26
27
28
24.9k, 1%
RUN/SS2
LTC1703
RUN/SS1
FCB
IMAX1
SW1
TG1
BG1
BOOST1
PVCC
1µF
0.1µF
1µF
100k
1µF
QB2
NDS8926
0.22µF
+
L4 2.2µF
DO3316P-222
15pF 220pF
QT2
NDS8926
D7
MBR0520LT1
Complete 2-Step Notebook Power Supply (Continued From the Previous Page)
1703 TA02
11.5k
1%
180µF
4V
+
10.2k
1%
2200pF
150µF
6V
×2
1k
10Ω
1µF
VOUT3
1.5V
3A
L5, 0.33µH
DO3316P-331HC
POINT A
LTC1703
TYPICAL APPLICATIO S
1703fa
33
U
LTC1703
U
TYPICAL APPLICATIO S
Single Output, 2-Phase, 25A VID Converter
(VIN = 5V, VOUT = 0.9V to 2.0V)
VIN
5V ±10%
10Ω
0.1µF
10Ω
0.003Ω
0.5W
0.003Ω
0.5W
0.1µF
10k
–
+
LT®1006
470µF*
10k
+
+
0.1µF
+
470µF*
+
10µF
MBR0530T
470µF*
MBR
0530T
MBR0530T
VCC
11k
BOOST1
FB1
120pF
220pF
330pF
0.1µF
TG1
RUN/SS1
SW1
RUN/SS2
BG1
10k
COMP2
SW2
IMAX1
BG2
IMAX2
FAULT
47k
22k
1Ω
Q2
1Ω
MBR
330T
Q3
VOUT
1.3V TO 3.5V
25A
+
TG2
120pF
220pF
Q1
LTC1703 BOOST2
FB2
20k
10k
L1
1µH
1µF
COMP1
47k
11k
PVCC
SENSE
330pF
VID4:0
1µF
Q4
FAULT
1Ω
VID4:0
Q5
Q6
470µF*
×2
L2
1µH
MBR
330T
1Ω
FCB
SGND
PGND
1703 TA04
*KEMET T510X477M006AS
Q1 TO Q6: FAIRCHILD FDS6670A
L1, L2: MURATA LQT12535C1R5N12
1703fa
34
LTC1703
U
PACKAGE DESCRIPTIO
G Package
28-Lead Plastic SSOP (0.209)
(LTC DWG # 05-08-1640)
9.90 – 10.50*
(.390 – .413)
28 27 26 25 24 23 22 21 20 19 18 17 16 15
1.25 ±0.12
7.8 – 8.2
5.3 – 5.7
7.40 – 8.20
(.291 – .323)
0.42 ±0.03
0.65 BSC
1
RECOMMENDED SOLDER PAD LAYOUT
2
3
4
5
6
7
8
9 10 11 12 13 14
2.0
(.079)
MAX
5.00 – 5.60**
(.197 – .221)
0° – 8°
0.09 – 0.25
(.0035 – .010)
0.55 – 0.95
(.022 – .037)
NOTE:
1. CONTROLLING DIMENSION: MILLIMETERS
MILLIMETERS
2. DIMENSIONS ARE IN
(INCHES)
0.65
(.0256)
BSC
0.22 – 0.38
(.009 – .015)
TYP
0.05
(.002)
MIN
G28 SSOP 0204
3. DRAWING NOT TO SCALE
*DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED .152mm (.006") PER SIDE
**DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED .254mm (.010") PER SIDE
1703fa
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
35
LTC1703
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTC1530
High Power Synchronous Step-Down Controller
SO-8 with Current Limit. No RSENSE Required
LTC1625
No RSENSETM Current Mode Synchronous Step-Down Controller
Above 95% Efficiency, Needs No RSENSE, 16-Lead SSOP Package
Fits SO-8 Footprint
LTC1628
Dual High Efficiency 2-Phase Synchronous Step-Down Controller
Constant Frequency, Standby 5V and 3.3V LDOs, 3.5V ≤ VIN ≤ 36V
LTC1702
Dual 550kHz Synchronous 2-Phase Switching Regulator Controller 550kHz, 25MHz GBW, No RSENSE, VIN ≤ 7V
LTC1706-81
VID Voltage Programmer
Adds 5-Bit VID to 0.8V Referenced Switching Regulators
for VOUT Range of 1.3V to 3.5V
LTC1709
2-Phase, 5-Bit Desktop VID Synchronous Step-Down Controller
Current Mode, VIN to 36V, IOUT Up to 42A
LTC1736
Synchronous Step-Down Controller with 5-Bit Mobile VID Control
Fault Protection, PowerGood, 3.5V to 36V Input, Current Mode
LTC1753
5-Bit Desktop VID Programmable Synchronous
Switching Regulator
1.3V to 3.5V Programmable Output Using Internal 5-Bit DAC
LTC1772
SOT-23 Step-Down Controller
550kHz, Up to 4A, 2.2V to 9.8V VIN, 100% Duty Cycle
LTC1873
Dual 550kHz Synchronous 2-Phase Switching Regulator
Controller with VRM 8.4 5-Bit VID
5-Bit VID for 1.3V ≤ VOUT ≤ 3.5V, VIN ≤ 7V
LTC1929
2-Phase, Synchronous High Efficiency Converter
Current Mode Ensures Accurate Current Sensing,
VIN Up to 36V, IOUT Up to 40A
No RSENSE is a trademark of Linear Technology Corporation.
1703fa
36
Linear Technology Corporation
LT 0306 REV A • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com
© LINEAR TECHNOLOGY CORPORATION 1999