LINER LTC1430AIGN High power step-down switching regulator controller Datasheet

LTC1430A
High Power Step-Down
Switching Regulator Controller
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DESCRIPTIO
FEATURES
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The LTC ®1430A is a high power, high efficiency switching
regulator controller optimized for 5V to 1.xV-3.xV applications. It includes a precision internal reference and an
internal feedback system that can provide output regulation of ±1% over temperature, load current and line voltage
shifts. The LTC1430A uses a synchronous switching architecture with two N-channel output devices, eliminating the
need for a high power, high cost P-channel device. Additionally, it senses output current across the drain-source
resistance of the upper N-channel FET, providing an
adjustable current limit without an external low value sense
resistor.
High Power 5V to 1.xV-3.xV Switching Controller:
Can Exceed 10A Output
Maximum Duty Cycle > 90% Permits 3.3V to 2.xV
Conversion Using a Low Power 5V Supply
All N-Channel External MOSFETs
Fixed Frequency Operation—Small L
Excellent Output Regulation: ±1% Over Line, Load
and Temperature Variations
High Efficiency: Over 95% Possible
No Low Value Sense Resistor Needed
Outputs Can Drive External FETs with Up to
10,000pF Gate Capacitance
Quiescent Current: 350µA Typ, 1µA in Shutdown
Fast Transient Response
Adjustable or Fixed 3.3V Output
Available in 8-Lead SO and 16-Lead GN
and SO Packages
The LTC1430A includes a fixed frequency PWM oscillator
for low output ripple under virtually all operating conditions. The 200kHz free-running clock frequency can be
externally adjusted from 100kHz to above 500kHz. The
LTC1430A’s maximum duty cycle is typically 93.5% compared to 88% for the LTC1430. This permits 3.3V to 2.xV
conversion using a low power 5V supply. The LTC1430A
features low 350µA quiescent current, allowing greater
than 90% efficiency operation in converter designs from
1A to greater than 50A output current. Shutdown mode
drops the LTC1430A supply current to 1µA.
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APPLICATI
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Power Supply for Pentium® II and AMD-K6®
Microprocessors
High Power 5V to 3.xV Regulators
Local Regulation for Dual Voltage Logic Boards
Low Voltage, High Current Battery Regulation
, LTC and LT are registered trademarks of Linear Technology Corporation.
Pentium is a registered trademark of Intel Corporation.
AMD-K6 is a registered trademark of Advanced Micro Devices, Inc.
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TYPICAL APPLICATI
Efficiency
Typical 5V to 3.3V, 10A Application
100
5V
1µF
100Ω
PVCC2
+
4.7µF
0.1µF
NC
SHUTDOWN
RC
7.5k
CC
4700pF
0.1µF
0.1µF
IMAX
G2
SHDN
PGND
COMP
GND
2.7µH/15A
Q2
+
FB
COUT
330µF
×6
3.3V
10A
1430 TA01
NC
Q1A, Q1B, Q2: MOTOROLA MTD20N03HL
CIN: AVX-TPSE227M010R0100
COUT: AVX-TPSE337M006R0100
TA = 25°C
PVCC = 5V
VOUT = 3.3V
80
70
60
50
40
0.1
SENSE+
SENSE –
90
1k
LTC1430A IFB
FREQSET
CIN
220µF
×4
Q1A, Q1B
2 IN PARALLEL
G1
SS
0.01µF
16k
PVCC1
VCC
C1
220pF
+
MBR0530T1
EFFICIENCY (%)
+
1
LOAD CURRENT (A)
10
1430 TA02
1
LTC1430A
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ABSOLUTE
RATI GS
(Note 1)
Supply Voltage
VCC ....................................................................... 9V
PVCC1, 2 .............................................................. 13V
Input Voltage
IFB ......................................................... – 0.3V to 18V
All Other Inputs ...................... – 0.3V to (VCC + 0.3V)
Junction Temperature ........................................... 150°C
Operating Temperature Range
LTC1430AC ............................................. 0°C to 70°C
LTC1430AI ........................................ – 40°C to 85°C
Storage Temperature Range ................ – 65°C to 150°C
Lead Temperature (Soldering, 10 sec)................. 300°C
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PACKAGE/ORDER I FOR ATIO
ORDER
PART NUMBER
TOP VIEW
ORDER
PART NUMBER
TOP VIEW
LTC1430ACS8
G2
G1
1
16 G2
PVCC1
2
15 PVCC2
PGND
3
14 VCC
G1 1
8
PVCC1 2
7
VCC /PVCC2
GND
4
13 IFB
GND 3
6
COMP
SENSE –
5
12 IMAX
FB 4
5
SHDN
FB
6
11 FREQSET
SENSE+
7
10 COMP
SHDN
8
9
S8 PACKAGE
8-LEAD PLASTIC SO
TJMAX = 150°C, θJA = 150°C/W
S8 PART MARKING
1430A
GN PACKAGE
16-LEAD PLASTIC SSOP
LTC1430ACGN
LTC1430AIGN
LTC1430ACS
SS
S PACKAGE
16-LEAD PLASTIC SO
TJMAX = 150°C, θJA = 130°C/W (GN)
TJMAX = 150°C, θJA = 110°C/W (S)
Consult factory for Military grade parts.
ELECTRICAL CHARACTERISTICS
VCC = 5V, TA = 25°C (Note 2) unless otherwise noted.
LTC1430AC
MIN TYP MAX
PARAMETER
VCC
Supply Voltage
●
4
8
4
8
V
PVCC
PVCC1, PVCC2 Voltage
●
3
13
3
13
V
VOUT
Output Voltage
Figure 1
VFB
Feedback Voltage
SENSE + and SENSE – Floating ,
VCOMP = 2.5V
∆VOUT
Output Load Regulation
Output Line Regulation
Figure 1, IOUT = 0A to 10A
Figure 1, VCC = 4.75V to 5.25V
IVCC
Supply Current (VCC Only)
Figure 2, VSHDN = VCC
VSHDN = 0V
IPVCC
Supply Current (PVCC)
Figure 2, PVCC = 5V, VSHDN = VCC (Note 3)
VSHDN = 0V
fOSC
Internal Oscillator Frequency
FREQSET Floating
2
CONDITIONS
LTC1430AI
MIN TYP MAX
SYMBOL
●
3.30
3.30
V
1.25 1.265 1.28
1.23 1.265 1.29
V
5
1
5
1
350
1
●
700
10
350
1
1.5
0.1
●
UNITS
140
200
mV
mV
700
10
1.5
0.1
260
130
200
µA
µA
mA
µA
300
kHz
LTC1430A
ELECTRICAL CHARACTERISTICS
VCC = 5V, TA = 25°C (Note 2) unless otherwise noted.
CONDITIONS
LTC1430AC
MIN TYP MAX
LTC1430AI
MIN TYP MAX
2.4
2.4
SYMBOL
PARAMETER
VIH
SHDN Input High Voltage
●
VIL
SHDN Input Low Voltage
●
IIN
SHDN Input Current
●
gmV
Error Amplifier Transconductance
●
350
gmI
ILIM Amplifier Transconductance
(Note 4)
AV
Error Amplifier Open-Loop Gain
(Note 5)
●
40
48
IMAX
IMAX Sink Current
VI(MAX) = VCC
●
8
12
ISS
Soft Start Source Current
VSS = 0V
●
–8
tr, ts
Driver Rise/Fall Time
Figure 3, PVCC1 = PVCC2 = 5V
tNOV
Driver Non-Overlap Time
Figure 3, PVCC1 = PVCC2 = 5V
DCMAX
Maximum Duty Cycle
Figure 3, VCOMP = VCC,
VFB = 1.265V
The ● denotes specifications which apply over the full operating
temperature range.
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: 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 3: Supply current in normal operation is dominated by the current
needed to charge and discharge the external FET gates. This will vary with
±1
650
1100
300
2400
●
V
0.8
±0.1
UNITS
0.8
V
±0.1
±1
µA
650
1200
µmho
µmho
2400
40
48
dB
16
8
12
17
µA
– 12
– 16
–8
– 12
– 17
µA
80
250
80
250
ns
25
130
250
25
130
250
ns
90
93.5
89
93.5
%
the LTC1430A operating frequency, operating voltage and the external
FETs used.
Note 4: The ILIM amplifier can sink but cannot source current. Under
normal (not current limited) operation, the ILIM output current will be zero.
Note 5: The open-loop DC gain and transconductance from the FB pin
(SENSE + and SENSE – floating) to COMP pin will be AV and gmV
respectively.
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LTC1430A
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TYPICAL PERFOR A CE CHARACTERISTICS
IMAX Pin Sink Current
vs Temperature
240
VCC = 5V
13.0
12.5
12.0
11.5
11.0
10.5
– 40 –20
40
20
60
0
TEMPERATURE (°C)
80
100
VCC = 5V
FREQSET FLOATING
230
OSCILLATOR FREQUENCY (kHz)
IMAX CURRENT (µA)
13.5
Maximum Duty Cycle
vs Temperature
220
210
200
190
170
– 40 –20
40
20
60
0
TEMPERATURE (°C)
80
∆ICOMP
∆VFB
6
700
4
650
2
–4
–6
400
–8
– 20
20
0
60
40
TEMPERATURE (°C)
80
100
0
–2
450
–10
– 40 – 20
60
40
20
TEMPERATURE (°C)
80
0
–1.0
0
1000
SUPPLY CURRENT (mA)
3.0
2.5
2.0
RI(MAX) = 16k
1.5
1.0
2
3 4 5 6 7
LOAD CURRENT (A)
8
6
LOAD CURRENT (A)
10
12
TA = 25°C
VCC = 5V
FIGURE 4
IPVCC (LOADED
WITH 10,000pF,
PVCC = 12V)
100
IPVCC (NO LOAD,
PVCC = 12V)
10
1
1430 G07
IPVCC (NO LOAD,
PVCC = 5V)
0.1
0
8
9
10
1460 G06
IVCC
4
1
Supply Current
vs Oscillator Frequency
3.5
OUTPUT VOLTAGE (V)
100
1430 G05
4.0
4
– 0.4
– 0.8
Output Voltage vs Load Current
with Current Limit
TA = 25°C
0.5 V = 5V
CC
FIGURE 4
0
2
0
– 0.2
– 0.6
1430 G04
RI(MAX) = 10k
100
80
TA = 25°C
VOUT = 3.3V
VCC = 5V
FIGURE 4
0.2
0
500
350
– 40
20
0
60
40
TEMPERATURE (°C)
Load Regulation
0.4
∆VOUT (mV)
750
550
– 20
1430 G03
VCC = 5V
8
600
70
– 40
100
∆VFB vs Temperature
10
∆VFB (mV)
TRANSCONDUCTANCE (µmho)
gm =
80
1430 G02
Error Amplifier Transconductance
vs Temperature
800
85
75
1430 G01
850
90
180
100
VCOMP = VCC
VFB = 1.265V
95
DUTY CYCLE (%)
14.0
Oscillator Frequency
vs Temperature
100
200
300
400
OSCILLATOR FREQUENCY (kHz)
500
1430 G08
LTC1430A
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PI FU CTIO S
(16-Lead Package/8-Lead Package)
G1 (Pin 1/Pin 1): Driver Output 1. Connect this pin to the
gate of the upper N-channel MOSFET, Q1. This output will
swing from PVCC1 to PGND. It will always be low when G2
is high.
PVCC1 (Pin 2/Pin 2): Power VCC for Driver 1. This is the
power supply input for G1. G1 will swing from PGND to
PVCC1. PVCC1 must be connected to a potential of at least
PVCC + VGS(ON)(Q1). This potential can be generated using
an external supply or a simple charge pump connected to
the switching node between the upper MOSFET and the
lower MOSFET; see Applications Information for details.
PGND (Pin 3/Pin 3): Power Ground. Both drivers return to
this pin. It should be connected to a low impedance ground
in close proximity to the source of Q2. 8-lead parts have
PGND and GND tied together at Pin 3.
GND (Pin 4/Pin 3): Signal Ground. All low power internal
circuitry returns to this pin. To minimize regulation errors
due to ground currents, GND should be connected to
PGND right at the LTC1430A. 8-lead parts have PGND and
GND tied together internally at Pin 3.
SENSE –, FB, SENSE + (Pins 5, 6, 7/Pin 4): These three
pins connect to the internal resistor divider and to the
internal feedback node. To use the internal divider to set
the output voltage to 3.3V, connect SENSE + to the positive
terminal of the output capacitor and SENSE – to GND. FB
should be left floating in applications that use the internal
divider. To use an external resistor divider to set the output
voltage, float SENSE + and SENSE – and connect the external resistor divider to FB.
SHDN (Pin 8/Pin 5): Shutdown. A TTL compatible low
level at SHDN for longer than 50µs puts the LTC1430A into
shutdown mode. In shutdown, G1 and G2 go low, all
internal circuits are disabled and the quiescent current
drops to 10µA max. A TTL compatible high level at SHDN
allows the part to operate normally.
SS (Pin 9/NA): Soft Start. The SS pin allows an external
capacitor to be connected to implement a soft start function. An external capacitor from SS to ground controls the
start-up time and also compensates the current limit loop,
allowing the LTC1430A to enter and exit current limit
cleanly. See Applications Information for more details.
COMP (Pin 10/Pin 6): External Compensation. The COMP
pin is connected directly to the output of the error amplifier
and the input of the PWM. An RC network is used at this
node to compensate the feedback loop to provide optimum transient response. See Applications Information for
compensation details.
FREQSET (Pin 11/NA): Frequency Set. This pin is used to
set the free running frequency of the internal oscillator.
With the pin floating, the oscillator runs at about 200kHz.
A resistor from FREQSET to ground will speed up the
oscillator; a resistor to VCC will slow it down. See Applications Information for resistor selection details.
IMAX (Pin 12/NA): Current Limit Set. IMAX sets the threshold for the internal current limit comparator. If IFB drops
below IMAX with G1 on, the LTC1430A will go into current
limit. IMAX has a 12µA pull-down to GND. It can be adjusted
with an external resistor to PVCC or an external voltage
source.
IFB (Pin 13/NA): Current Limit Sense. Connect to the
switched node at the source of Q1 and the drain of Q2
through a 1k resistor. The 1k resistor is required to prevent
voltage transients from damaging IFB. This pin can be
taken up to 18V above GND without damage.
VCC (Pin 14/Pin 7): Power Supply. All low power internal
circuits draw their supply from this pin. Connect to a clean
power supply, separate from the main PVCC supply at the
drain of Q1. This pin requires a 4.7µF or greater bypass
capacitor. 8-lead parts have VCC and PVCC2 tied together
at Pin 7 and require at least a 10µF bypass to GND.
PVCC2 (Pin 15/Pin 7): Power VCC for Driver 2. This is the
power supply input for G2. G2 will swing from GND to
PVCC2. PVCC2 is usually connected to the main high power
supply. 8-lead parts have VCC and PVCC2 tied together at
Pin 7 and require at least a 10µF bypass to GND.
G2 (Pin 16/Pin 8): Driver Output 2. Connect this pin to the
gate of the lower N-channel MOSFET, Q2. This output will
swing from PVCC2 to PGND. It will always be low when G1
is high.
5
LTC1430A
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BLOCK DIAGRAM
DELAY
SHDN
INTERNAL
SHUTDOWN
50µs
FREQSET
PVCC1
G1
PWM
COMP
PVCC2
G2
VCC
PGND
12µA
SS
ILIM
–
FB
+
+
MIN
MAX
–
IMAX
IFB
12µA
FB
+
40mV
20k
40mV
SENSE +
12.4k
SENSE –
+
+
1430 BD
1.265V
TEST CIRCUITS
PVCC1 = 12V
+
1µF
PVCC2 = 5V
+
+
1µF
100Ω
PVCC2
+
4.7µF
PVCC1
0.1µF
SS
0.01µF
NC
SHUTDOWN
C1
220pF
RC
7.5k
CC
4700pF
LTC1430A IFB
G2
SHDN
PGND
COMP
GND
Q2
SENSE+
3.3V
COUT
330µF
×6
SENSE –
NC
1.61k
FB
1k
NC
SENSE+
SENSE –
FB
NC
Q1A, Q1B, Q2: MOTOROLA MTD20N03HL
CIN: AVX-TPSE227M010R0100
COUT: AVX-TPSE337M006R0100
Figure 1
6
+
VOUT
LTC1430A
2.7µH/15A
IMAX
FREQSET
FB MEASUREMENT
Q1A, Q1B
2 IN PARALLEL
G1
VCC
CIN
220µF
×4
1430 F01
LTC1430A
TEST CIRCUITS
5V
VSHDN VCC
PVCC
+
10µF
SHDN VCC PVCC2 PVCC1
NC
IMAX
VCC PVCC1 PVCC2
IFB
G1
NC
FREQSET
NC
COMP
NC
SS
LTC1430A
VCOMP
NC
G2
NC
FB
NC
COMP
G1
G1 RISE/FALL
10,000pF
LTC1430A
VFB
PGND SENSE – SENSE+
GND
FB
GND
G2
PGND
G2 RISE/FALL
10,000pF
1430 F02
1430 F03
Figure 2
Figure 3
VCC
VIN = 5V
+
1µF
PVCC2
+
PVCC1
0.1µF
SS
0.01µF
NC
SHUTDOWN
IMAX
CC
4700pF
1k
G2
SHDN
CIN
220µF
×4
Q1A, Q1B
2 IN PARALLEL
0.1µF
2.7µH/15A
LTC1430A IFB
FREQSET
Q2
+
PGND
COMP
RC
7.5k
0.1µF
16k
G1
VCC
C1
220pF
+
1N4148
100Ω
4.7µF
0.1µF
3.3V
COUT
330µF
×6
GND
SENSE+
SENSE –
FB
1430 F04
NC
Q1A, Q1B, Q2: MOTOROLA MTD20N03HL
CIN: AVX-TPSE227M010R0100
COUT: AVX-TPSE337M006R0100
Figure 4
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LTC1430A
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APPLICATIONS INFORMATION
OVERVIEW
The LTC1430A is a voltage feedback PWM switching
regulator controller (see Block Diagram) designed for use
in high power, low voltage step-down (buck) converters.
It includes an onboard PWM generator, a precision reference trimmed to ±0.5%, two high power MOSFET gate
drivers and all necessary feedback and control circuitry to
form a complete switching regulator circuit. The PWM
loop nominally runs at 200kHz.
The 16-lead versions of the LTC1430A include a current
limit sensing circuit that uses the upper external power
MOSFET as a current sensing element, eliminating the
need for an external sense resistor.
Also included in the 16-lead version is an internal soft start
feature that requires only a single external capacitor to
operate. In addition, 16-lead parts feature an adjustable
oscillator which can run at frequencies from 50kHz to
500kHz, allowing added flexibility in external component
selection. The 8-lead version does not include current
limit, internal soft start or frequency adjustability.
THEORY OF OPERATION
Primary Feedback Loop
The LTC1430A senses the output voltage of the circuit at
the output capacitor with the SENSE + and SENSE – pins
and feeds this voltage back to the internal transconductance amplifier FB. FB compares the resistor-divided output voltage to the internal 1.265V reference and outputs an
error signal to the PWM comparator. This is then compared to a fixed frequency sawtooth waveform generated
by the internal oscillator to generate a pulse width modulated signal. This PWM signal is fed back to the external
MOSFETs through G1 and G2, closing the loop. Loop
compensation is achieved with an external compensation
network at COMP, the output node of the FB transconductance amplifier.
MIN, MAX Feedback Loops
Two additional comparators in the feedback loop provide
high speed fault correction in situations where the FB
amplifier may not respond quickly enough. MIN compares
the feedback signal to a voltage 40mV (3%) below the
8
internal reference. At this point, the MIN comparator
overrides the FB amplifier and forces the loop to full duty
cycle, set by the internal oscillator at about 93.5%. Similarly, the MAX comparator monitors the output voltage at
3% above the internal reference and forces the output to
0% duty cycle when tripped. These two comparators
prevent extreme output perturbations with fast output
transients, while allowing the main feedback loop to be
optimally compensated for stability.
Current Limit Loop
The 16-lead LTC1430A devices include yet another feedback loop to control operation in current limit. The current
limit loop is disabled in the 8-lead device. The ILIM amplifier monitors the voltage drop across external MOSFET Q1
with the IFB pin during the portion of the cycle when G1 is
high. It compares this voltage to the voltage at the IMAX pin.
As the peak current rises, the drop across Q1 due to its
RDS(ON) increases. When IFB drops below IMAX, indicating
that Q1’s drain current has exceeded the maximum level,
ILIM starts to pull current out of the external soft start
capacitor, cutting the duty cycle and controlling the output
current level. At the same time, the ILIM comparator
generates a signal to disable the MIN comparator to
prevent it from conflicting with the current limit circuit. If
the internal feedback node drops below about 0.8V, indicating a severe output overload, the circuitry will force the
internal oscillator to slow down by a factor of as much as
100. If desired, the turn on time of the current limit loop
can be controlled by adjusting the size of the soft start
capacitor, allowing the LTC1430A to withstand short
overcurrent conditions without limiting.
By using the RDS(ON) of Q1 to measure the output current,
the current limit circuit eliminates the sense resistor that
would otherwise be required and minimizes the number of
components in the external high current path. Because
power MOSFET RDS(ON) is not tightly controlled and varies
with temperature, the LTC1430A current limit is not designed to be accurate; it is meant to prevent damage to the
power supply circuitry during fault conditions. The actual
current level where the limiting circuit begins to take effect
may vary from unit to unit, depending on the power
MOSFETs used. See Soft Start and Current Limit for more
details on current limit operation.
LTC1430A
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APPLICATIONS INFORMATION
MOSFET Gate Drive
VIN
Gate drive for the top N-channel MOSFET Q1 is supplied
from PVCC1. This supply must be above PVCC ( the main
power supply input) by at least one power MOSFET
VGS(ON) for efficient operation. An internal level shifter
allows PVCC1 to operate at voltages above VCC and PVCC,
up to 13V maximum. This higher voltage can be supplied
with a separate supply, or it can be generated using a
simple charge pump as shown in Figure 5. When using a
separate PVCC1 supply, the PVCC input may exhibit a large
inrush current if PVCC1 is present during power up. The
93.5% maximum duty cycle ensures that the charge pump
will always provide sufficient gate drive to Q1. Gate drive
for the bottom MOSFET Q2 is provided through PVCC2 for
16-lead devices or VCC/PVCC2 for the 8-lead device. PVCC2
can usually be driven directly from PVCC with 16-lead
parts, although it can also be charge pumped or connected
to an alternate supply if desired. 3.3V input applications
use 3.3V at PVCC and 5V at VCC and PVCC1. See 3.3V Input
Supply Operation for more details. The 8-lead part
requires an RC filter from PVCC to VCC to ensure proper
operation; see Input Supply Considerations.
PVCC
OPTIONAL
USE FOR PVCC ≥ 7V
DZ
12V
1N5242
MBR0530T1
PVCC2
PVCC1
G1
0.1µF
Q1
L1
VOUT
G2
+
Q2
LTC1430A
COUT
CONTROLLER
Q1
VOUT
D1
1430 F06a
Figure 6a. Classical Buck Architecture
VIN
Q1
CONTROLLER
VOUT
Q2
1430 F06b
Figure 6b. Synchronous Buck Architecture
much lower than the VF of the diode in the classical circuit.
This more than offsets the additional gate drive required
by the second MOSFET, allowing the LTC1430A to achieve
efficiencies in the mid-90% range for a wide range of load
currents.
Another feature of the synchronous architecture is that
unlike a diode, Q2 can conduct current in either direction.
This allows the output of a typical LTC1430A circuit to sink
current as well as sourcing it while remaining in regulation. The ability to sink current at the output allows the
LTC1430A to be used with reactive or other nonconventional
loads that may supply current to the regulator as well as
drawing current from it. An example is a high current logic
termination supply, such as the GTL terminator shown in
the Typical Applications section.
1430 F05
EXTERNAL COMPONENT SELECTION
Figure 5. Doubling Charge Pump
Synchronous Operation
The LTC1430A uses a synchronous switching architecture, with MOSFET Q2 taking the place of the diode in a
classical buck circuit (Figure 6). This improves efficiency
by reducing the voltage drop and the resultant power
dissipation across Q2 to VON = (I)(RDSON(Q2)), usually
Power MOSFETs
Two N-channel power MOSFETs are required for most
LTC1430A circuits. These should be selected based primarily on threshold and on-resistance considerations;
thermal dissipation is often a secondary concern in high
efficiency designs. Required MOSFET threshold should be
determined based on the available power supply voltages
and/or the complexity of the gate drive charge pump
9
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scheme. In 5V input designs where an auxiliary 12V supply
is available to power PVCC1 and PVCC2, standard MOSFETs
with RDS(ON) specified at VGS = 5V or 6V can be used with
good results. The current drawn from this supply varies
with the MOSFETs used and the LTC1430A’s operating
frequency, but is generally less than 50mA.
LTC1430A designs that use a doubler charge pump to
generate gate drive for Q1 and run from PVCC voltages
below 7V cannot provide enough gate drive voltage to fully
enhance standard power MOSFETs. When run from 5V, a
doubler circuit may work with standard MOSFETs, but the
MOSFET RON may be quite high, raising the dissipation in
the FETs and costing efficiency. Logic level FETs are a
better choice for 5V PVCC systems; they can be fully
enhanced with a doubler charge pump and will operate at
maximum efficiency. Doubler designs running from PVCC
voltages near 4V will begin to run into efficiency problems
even with logic level FETs; such designs should be built
with tripler charge pumps (see Figure 7) or with newer,
super low threshold MOSFETs. Note that doubler charge
pump designs running from more than 7V and all tripler
charge pump designs should include a zener clamp diode
DZ at PVCC1 to prevent transients from exceeding the
absolute maximum rating at that pin.
Once the threshold voltage has been selected, RON should
be chosen based on input and output voltage, allowable
power dissipation and maximum required output current.
In a typical LTC1430A buck converter circuit operating in
continuous mode, the average inductor current is equal to
DZ
12V
1N5242
10µF
1N5817
PVCC
1N5817
1N5817
PVCC2
PVCC1
G1
0.1µF
0.1µF
Q1
VOUT
+
Q2
LTC1430A
COUT
1430 • F07
Figure 7. Tripling Charge Pump
10
DC (Q1) =
VOUT
VIN
V
DC (Q2) = 1 – OUT
VIN
(V – VOUT)
= IN
VIN
The RON required for a given conduction loss can now be
calculated by rearranging the relation P = I2R:
RON (Q1) =
PMAX(Q1)
DC(Q1)(IMAX2)
V (P
)(Q1)
= IN MAX 2
VOUT(IMAX )
RON (Q2) =
=
PMAX(Q2)
DC(Q2)(IMAX2)
VIN(PMAX)(Q2)
(VIN – VOUT)(IMAX2)
PMAX should be calculated based primarily on required
efficiency. A typical high efficiency circuit designed for 5V
in, 3.3V at 10A out might require no more than 3%
efficiency loss at full load for each MOSFET. Assuming
roughly 90% efficiency at this current level, this gives a
PMAX value of (3.3V)(10A/0.9)(0.03) = 1.1W per FET and
a required RON of:
(5V)(1.1W)
= 0.017Ω
(3.3V)(10A2)
(5V)(1.1W)
RON (Q2) =
= 0.032Ω
(5V – 3.3V)(10A2)
RON (Q1) =
L1
G2
the output load current. This current is always flowing
through either Q1 or Q2 with the power dissipation split up
according to the duty cycle:
Note that the required RON for Q2 is roughly twice that of
Q1 in this example. This application might specify a single
0.03Ω device for Q2 and parallel two more of the same
devices to form Q1. Note also that while the required RON
values suggest large MOSFETs, the dissipation numbers
LTC1430A
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are only 1.1W per device or less — large TO-220 packages
and heat sinks are not necessarily required in high efficiency applications. Siliconix Si4410DY (in SO-8) and
Motorola MTD20N03HL (in DPAK) are two small, surface
mount devices with RON values of 0.03Ω or below with 5V
of gate drive; both work well in LTC1430A circuits with up
to 10A output current. A higher PMAX value will generally
decrease MOSFET cost and circuit efficiency and increase
MOSFET heat sink requirements.
Inductor
The inductor is often the largest component in an LTC1430A
design and should be chosen carefully. Inductor value and
type should be chosen based on output slew rate requirements and expected peak current. Inductor value is primarily controlled by the required current slew rate. The
maximum rate of rise of the current in the inductor is set
by its value, the input-to-output voltage differential and the
maximum duty cycle of the LTC1430A. In a typical 5V to
3.3V application, the maximum rise time will be:
90%
(VIN – VOUT) AMPS
1.53A I
=
µs L
L
SECOND
where L is the inductor value in µH. A 2µH inductor would
have a 0.76A/µs rise time in this application, resulting in a
6.5µs delay in responding to a 5A load current step. During
this 6.5µs, the difference between the inductor current and
the output current must be made up by the output capacitor, causing a temporary droop at the output. To minimize
this effect, the inductor value should usually be in the 1µH
to 5µH range for most typical 5V to 2.xV-3.xV LTC1430A
circuits. Different combinations of input and output voltages and expected loads may require different values.
Once the required value is known, the inductor core type
can be chosen based on peak current and efficiency
requirements. Peak current in the inductor will be equal to
the maximum output load current added to half the peakto- peak inductor ripple current. Ripple current is set by the
inductor value, the input and output voltage and the
operating frequency. If the efficiency is high and can be
approximately equal to 1, the ripple current is approximately equal to:
(VIN – VOUT)
DC
(fOSC)(L)
V
DC = OUT
VIN
∆I =
fOSC = LTC1430A oscillator frequency
L = inductor value
Solving this equation with our typical 5V to 3.3V application, we get:
(1.7)(0.66)
= 2.8AP–P
(200kHz)(2µH)
Peak inductor current at 10A load:
10A +
2.8A
= 11.4A
2
The inductor core must be adequate to withstand this peak
current without saturating, and the copper resistance in
the winding should be kept as low as possible to minimize
resistive power loss. Note that the current may rise above
this maximum level in circuits under current limit or under
fault conditions in unlimited circuits; the inductor should
be sized to withstand this additional current.
Input and Output Capacitors
A typical LTC1430A design puts significant demands on
both the input and output capacitors. Under normal steady
load operation, a buck converter like the LTC1430A draws
square waves of current from the input supply at the
switching frequency, with the peak value equal to the
output current and the minimum value near zero. Most of
this current must come from the input bypass capacitor,
since few raw supplies can provide the current slew rate to
feed such a load directly. The resulting RMS current flow
in the input capacitor will heat it up, causing premature
capacitor failure in extreme cases. Maximum RMS current
occurs with 50% PWM duty cycle, giving an RMS current
value equal to IOUT/2. A low ESR input capacitor with an
adequate ripple current rating must be used to ensure
reliable operation. Note that capacitor manufacturers’
ripple current ratings are often based on only 2000 hours
(3 months) lifetime; further derating of the input capacitor
ripple current beyond the manufacturer’s specification is
recommended to extend the useful life of the circuit.
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The output capacitor in a buck converter sees much less
ripple current under steady-state conditions than the input
capacitor. Peak-to-peak current is equal to that in the
inductor, usually a fraction of the total load current. Output
capacitor duty places a premium not on power dissipation
but on low ESR. During an output load transient, the
output capacitor must supply all of the additional load
current demanded by the load until the LTC1430A can
adjust the inductor current to the new value. ESR in the
output capacitor results in a step in the output voltage
equal to the ESR value multiplied by the change in load
current. A 5A load step with a 0.05Ω ESR output capacitor
will result in a 250mV output voltage shift; this is a 7.6%
output voltage shift for a 3.3V supply! Because of the
strong relationship between output capacitor ESR and
output load transient response, the output capacitor is
usually chosen for ESR, not for capacitance value; a
capacitor with suitable ESR will usually have a larger
capacitance value than is needed to control steady-state
output ripple.
Electrolytic capacitors rated for use in switching power
supplies with specified ripple current ratings and ESR can
be used effectively in LTC1430A applications. OS-CON
electrolytic capacitors from Sanyo give excellent performance and have a very high performance/size ratio for an
electrolytic capacitor. Surface mount applications can use
either electrolytic or dry tantalum capacitors. Tantalum
capacitors must be surge tested and specified for use in
switching power supplies; low cost, generic tantalums are
known to have very short lives followed by explosive
deaths in switching power supply applications. AVX TPS
series surface mount devices are popular tantalum capacitors that work well in LTC1430A applications. A common
way to lower ESR and raise ripple current capability is to
parallel several capacitors. A typical LTC1430A application might require an input capacitor with a 5A ripple
current capacity and 2% output shift with a 10A output
load step, which requires a 0.007Ω output capacitor ESR.
Sanyo OS-CON part number 10SA220M (220µF/10V)
capacitors feature 2.3A allowable ripple current at 85°C
and 0.035Ω ESR; three in parallel at the input and six at the
output will meet the above requirements.
Input Supply Considerations/Charge Pump
The 16-lead LTC1430A requires four supply voltages to
operate: PVCC for the main power input, PVCC1 and PVCC2
for MOSFET gate drive and a clean, low ripple VCC for the
LTC1430A internal circuitry (Figure 8). In many applications, PVCC and PVCC2 can be tied together and fed from a
common high power supply, provided that the supply
voltage is high enough to fully enhance the gate of external
MOSFET Q2. This can be the 5V system supply if a logic
level MOSFET is used for Q2. VCC can usually be filtered
with an RC from this same high power supply; the low
quiescent current (typically 350µA) allows the use of
relatively large filter resistors and correspondingly small
filter capacitors. 100Ω and 4.7µF usually provide adequate filtering for VCC.
The 8-lead version of the LTC1430A has the PVCC2 and VCC
pins tied together inside the package (Figure 9). This pin,
brought out as VCC /PVCC2, has the same low ripple requirements as the 16-lead part, but must also be able to
supply the gate drive current to Q2. This can be obtained
PVCC2
VCC
PVCC1
PVCC
G1
Q1
L1
INTERNAL
CIRCUITRY
VOUT
G2
+
Q2
COUT
LTC1430A (16-LEAD)
1430 F08
Figure 8. 16-Lead Power Supplies
PVCC
PVCC1
VCC /PVCC2
G1
Q1
L1
INTERNAL
CIRCUITRY
VOUT
G2
+
Q2
COUT
LTC1430A (8-LEAD)
1430 F09
Figure 9. 8-Lead Power Supplies
12
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by using a larger RC filter from the PVCC pin; 22Ω and 10µF
work well here. The 10µF capacitor must be VERY close to
the part (preferably right underneath the unit) or output
regulation may suffer.
PVCC. VCC can be driven from the same potential as PVCC2,
allowing the entire system to run from a single 3.3V
supply. Tripling charge pumps require the use of Schottky
diodes to minimize forward drop across the diodes at
start-up. The tripling charge pump circuit will tend to
rectify any ringing at the drain of Q2 and can provide well
more than 3PVCC at PVCC1; all tripling (or higher multiplying factor) circuits should include a 12V zener clamp diode
DZ to prevent overvoltage at PVCC1.
For both versions of the LTC1430A, PVCC1 must be higher
than PVCC by at least one external MOSFET VGS(ON) to fully
enhance the gate of Q1. This higher voltage can be
provided with a separate supply (typically 12V) which
should power up after PVCC, or it can be generated with a
simple charge pump (Figure 5). The charge pump consists
of a Schottky diode from PVCC to PVCC1 and a 0.1µF
capacitor from PVCC1 to the switching node at the drain of
Q2. This circuit provides 2PVCC – VF to PVCC1 while Q1 is
ON and PVCC – VF while Q1 is OFF where VF is the ON
voltage of the Schottky diode. Ringing at the drain of Q2
can cause transients above 2PVCC at PVCC1; if PVCC is
higher than 7V, a 12V zener diode should be included from
PVCC1 to PGND to prevent transients from damaging the
circuitry at PVCC2 or the gate of Q1.
3.3V Input Supply Operation
The LTC1430A can be used with input supply voltages
lower than 5V as long as a low power 5V supply is available
to power the LTC1430A itself and to provide gate drive to
the external MOSFETs. A typical 3.3V to 2.5V application
is shown in Figure 10. The circuit can supply up to 10A at
2.5V output, and draws this power from the 3.3V supply.
The 5V supply typically needs to supply about 20mA to
provide gate drive to the external MOSFETs and keep the
LTC1430A control circuits powered. For applications where
there is no 5V supply available, see the LTC1649 data
sheet.
More complex charge pumps can be constructed with the
16-lead versions of the LTC1430A to provide additional
voltages for use with standard threshold MOSFETs or very
low PVCC voltages. A tripling charge pump (Figure 7) can
provide 2PVCC and 3PVCC voltages. These can be connected to PVCC2 and PVCC1 respectively, allowing standard threshold MOSFETs to be used with 5V at PVCC or 5V
logic level threshold MOSFETs to be used with 3.3V at
Compensation and Transient Response
The LTC1430A voltage feedback loop is compensated at
the COMP pin; this is the output node of the internal gm
error amplifier. The loop can generally be compensated
3.3V
5V
+
1µF
100Ω
PVCC2
+
4.7µF
PVCC1
0.1µF
SS
0.01µF
NC
SHUTDOWN
IMAX
1k
1µF
G2
FREQSET
SHDN
CIN
220µF
×4
Q1A, Q1B
2 IN PARALLEL
2.7µH/15A
LTC1430A IFB
Q2
+
PGND
COMP
RC
7.5k
0.1µF
16k
G1
VCC
C1
220pF
+
MBR0530T1
COUT
330µF
×6
2.5V
10A
GND
SENSE+
SENSE –
CC
4700pF
NC
NC
976Ω
1%
FB
Q1A, Q1B, Q2: INTERNATIONAL RECTIFIER IRF7801
CIN: AVX-TPSE227M010R0100
COUT: AVX-TPSE337M006R0100
1k
1%
1430 F10
Figure 10. 3.3V to 2.5V, 10A Application
13
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properly with an RC network from COMP to GND and an
additional small C from COMP to GND (Figure 11). Loop
stability is affected by inductor and output capacitor
values and by other factors. Optimum loop response can
be obtained by using a network analyzer to find the loop
poles and zeros; nearly as effective and a lot easier is to
empirically tweak the RC values until the transient recovery
looks right with an output load step. Table 1 shows
recommended compensation components for 5V to 3.3V
applications based on the inductor and output capacitor
values. The values were calculated using multiple paralleled 330µF AVX TPS series surface mount tantalum
capacitors as the output capacitor.
Table 1. Recommended Compensation Network for 5V to 3.3V
Application Using Multiple 330µF AVX Output Capacitors
L1 (µH)
COUT (µF)
RC (kΩ)
CC (µF)
C1 (pF)
1
990
1.8
0.022
820
1
1980
3.6
0.01
470
1
4950
9.1
0.0047
150
1
9900
18
0.0022
82
2.7
990
3.6
0.01
470
2.7
1980
7.5
0.0047
220
2.7
4950
18
0.0022
82
2.7
9900
39
0.001
39
5.6
990
9.1
0.0047
150
5.6
1980
18
0.0022
82
5.6
4950
47
820pF
33
5.6
9900
91
470pF
15
10
990
18
0.0022
82
10
1980
39
0.001
39
10
4950
91
470pF
15
10
9900
180
220pF
10
Output transient response is set by three major factors: the
time constant of the inductor and the output capacitor, the
ESR of the output capacitor, and the loop compensation
components. The first two factors usually have much
more impact on overall transient recovery time than the
third; unless the loop compensation is way off, more
improvement can be had by optimizing the inductor and
the output capacitor than by fiddling with the loop compensation components. In general, a smaller value inductor will improve transient response at the expense of ripple
14
LTC1430A
COMP
RC
CC
GND
C1
SGND
1430 F11
Figure 11. Compensation Pin Hook-Up
and inductor core saturation rating. Minimizing output
capacitor ESR will also help optimize output transient
response. See Input and Output Capacitors for more
information.
Soft Start and Current Limit
The 16-lead versions of the LTC1430A include a soft start
circuit at the SS pin; this circuit is used both for initial startup and during current limit operation. The soft start and
current limit circuitry is disabled in the 8-lead version. SS
requires an external capacitor to GND with the value
determined by the required soft start time. An internal
12µA current source is included to charge the external
capacitor. Soft start functions by clamping the maximum
voltage that the COMP pin can swing to, thereby controlling the duty cycle (Figure 12). The LTC1430A will begin to
operate at low duty cycle as the SS pin rises to about 2V
below VCC. As SS continues to rise, the duty cycle will
increase until the error amplifier takes over and begins to
regulate the output. When SS reaches 1V below VCC the
LTC1430A
COMP
FB
VCC
12µA
SS
CSS
1430 F12
Figure 12. Soft Start Clamps COMP Pin
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LTC1430A will be in full operation. An internal switch
shorts the SS pin to GND during shutdown.
The LTC1430A detects the output current by watching the
voltage at IFB while Q1 is ON. The ILIM amplifier compares
this voltage to the voltage at IMAX (Figure 13). In the ON
state, Q1 has a known resistance; by calculating backwards, the voltage generated at IFB by the maximum
output current in Q1 can be determined. As IFB falls below
IMAX, ILIM will begin to sink current from the soft start pin,
causing the voltage at SS to fall. As SS falls, it will limit the
output duty cycle, limiting the current at the output.
Eventually the system will reach equilibrium, where the
pull-up current at the SS pin matches the pull-down
current in the ILIM amplifier; the LTC1430A will stay in this
state until the overcurrent condition disappears. At this
time IFB will rise, ILIM will stop sinking current and the
internal pull-up will recharge the soft start capacitor,
restoring normal operation. Note that the IFB pin requires
an external 1k series resistor to prevent voltage transients
at the drain of Q2 from damaging internal structures.
0.1µF
PVCC
RIMAX
Q1
IMAX
IFB
+
12µA
1k
–
Q2
ILIM
VCC
12µA
SS
CSS
LTC1430A
Longer overload conditions will allow the SS pin to reach
a steady level, and the output will remain at a reduced
voltage until the overload is removed. Serious overloads
will generate a larger overdrive at ILIM, allowing it to pull SS
down more quickly and preventing damage to the output
components.
The ILIM amplifier output is disabled when Q1 is OFF to
prevent the low IFB voltage in this condition from activating
the current limit. It is re-enabled a fixed 170ns after Q1
turns on; this allows for the IFB node to slew back high and
the ILIM amplifier to settle to the correct value. As the
LTC1430A goes deeper into current limit, it will reach a
point where the Q1 on-time needs to be cut to below 170ns
to control the output current. This conflicts with the
minimum settling time needed for proper operation of the
ILIM amplifier. At this point, a secondary current limit
circuit begins to reduce the internal oscillator frequency,
lengthening the off-time of Q1 while the on-time remains
constant at 170ns. This further reduces the duty cycle,
allowing the LTC1430A to maintain control over the output
current.
Under extreme output overloads or short circuits, the ILIM
amplifier will pull the SS pin more than 2V below VCC in a
single switching cycle, cutting the duty cycle to zero. At
this point all switching stops, the output current decays
through Q2 and the LTC1430A runs a partial soft start
cycle and restarts. If the short is still present the cycle will
repeat. Peak currents can be quite high in this condition,
but the average current is controlled and a properly
designed circuit can withstand short circuits indefinitely
with only moderate heat rise in the output FETs. In addition, the soft start cycle repeat frequency can drop into the
low kHz range, causing vibrations in the inductor which
provide an audible alarm that something is wrong.
1430 F13
Oscillator Frequency
Figure 13. Current Limit Operation
The ILIM amplifier pulls current out of SS in proportion to
the difference between IFB and IMAX. Under mild overload
conditions, the SS pin will fall gradually, creating a time
delay before current limit takes effect. Very short, mild
overloads may not trip the current limit circuit at all.
The LTC1430A includes an onboard current controlled
oscillator which will typically free-run at 200kHz. An
internal 20µA current is summed with any current in or out
of the FREQSET pin (Pin 11), setting the oscillator frequency to approximately 10kHz/µA. FREQSET is internally
servoed to the LTC1430A reference voltage (1.265V).
With FREQSET floating, the oscillator is biased from the
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internal 20µA source and runs at 200kHz. Connecting a
50k resistor from FREQSET to ground will sink an additional 25µA from FREQSET, causing the internal oscillator
to run at approximately 450kHz. Sourcing an external
10µA current into FREQSET will cut the internal frequency
to 100kHz. An internal clamp prevents the oscillator from
running slower than about 50kHz. Tying FREQSET to VCC
will cause it to run at this minimum speed.
Shutdown
The LTC1430A includes a low power shutdown mode,
controlled by the logic at the SHDN pin. A high at SHDN
allows the part to operate normally. A low level at SHDN
stops all internal switching, pulls COMP and SS to ground
internally and turns Q1 and Q2 off. In shutdown, the
LTC1430A itself will drop below 1µA quiescent current
typically, although off-state leakage in the external
MOSFETs may cause the total PVCC current to be somewhat higher, especially at elevated temperatures. When
SHDN rises again, the LTC1430A will rerun a soft start
cycle and resume normal operation. Holding the LTC1430A
in shutdown during PVCC power up removes any PVCC1
sequencing constraints.
External Clock Synchronization
The LTC1430A SHDN pin can double as an external clock
input for applications that require a synchronized clock or
a faster switching speed. The SHDN pin terminates the
internal sawtooth wave and resets the oscillator immediately when it goes low, but waits 50µs before shutting
down the rest of the internal circuitry. A clock signal
applied directly to the SHDN pin will force the LTC1430A
internal oscillator to lock to its frequency as long as the
external clock runs faster than the internal oscillator
frequency. The LTC1430A can be synchronized to frequencies between 250kHz and 350kHz with no additional
components.
The LTC1430A is synchronizable at frequencies from
200kHz to 500kHz. Frequencies above 300kHz can cause
a decrease in the maximum obtainable duty cycle as rise/
fall time and propagation delay take up a large fraction of
the switch cycle. Circuits using these frequencies should
16
be checked carefully in applications where operation near
dropout is important—like 3.3V to 2.5V converters. Frequencies above 500kHz can cause erratic current limit
operation and are not recommended.
LAYOUT CONSIDERATIONS
Grounding
Proper grounding is critical for the LTC1430A to obtain
specified output regulation. Extremely high peak currents
(as high as several amps) can flow between the bypass
capacitors and the PVCC1, PVCC2 and PGND pins. These
currents can generate significant voltage differences between two points that are nominally both “ground.” As a
general rule, GND and PGND should be totally separated
on the layout, and should be brought together at only one
point, right at the LTC1430A GND and PGND pins. This
helps minimize internal ground disturbances in the
LTC1430A by keeping PGND and GND at the same potential, while preventing excessive current flow from disrupting the operation of the circuits connected to GND. The
PGND node should be as compact and low impedance as
possible, with the negative terminals of the input and
output capacitors, the source of Q2, the LTC1430A PGND
node, the output return and the input supply return all
clustered at one point. Figure 14 is a modified schematic
showing the common connections in a proper layout. Note
that at 10A current levels or above, current density in the
PC board itself can become a concern; traces carrying high
currents should be as wide as possible.
Output Voltage Sensing
The 16-lead versions of the LTC1430A provide three pins
for sensing the output voltage: SENSE +, SENSE – and FB.
SENSE + and SENSE – connect to an internal resistor
divider which is connected to FB. To set the output of the
LTC1430A to 3.3V, connect SENSE + to the output as near
to the load as practical and connect SENSE – to the
common GND/PGND point. Note that SENSE – is not a true
differential input sense input; it is just the bottom of the
internal divider string. Connecting SENSE – to the ground
near the load will not improve load regulation. For any
other output voltage, the SENSE + and SENSE – pins should
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5V
100Ω
4.7µF
35V
1µF
+
0.1µF
PVCC2
VCC
PVCC1
GND
+
MBR0530T1
PGND
G1
NC
IMAX
NC
FREQSET
Q1B*
Q1A*
LTC1430A
TOTAL
880µF
(220µF
10V × 4)
0.1µF
2.7µH/15A
IFB
3.3V
SENSE+
C1
220pF
CC
4700pF
SHDN
G2
COMP
FB
+
NC
SENSE –
SS
RC
7.5k
Q2*
GND
PGND
CSS
0.01µF
TOTAL
1980µF
(330µF
6.3V × 6)
PGND
* MOTOROLA MTD20N03HL
GND
1430 F14
Figure 14. Typical Schematic Showing Layout Considerations
SENSE +
NC
LTC1430A
VOUT
R1
FB
R2
SENSE –
NC
1430 F15
Figure 15. Using External Resistors to Set Output Voltages
be floated and an external resistor string should be connected to FB (Figure 15). As before, connect the top
resistor (R1) to the output as close to the load as practical
and connect the bottom resistor (R2) to the common
GND/PGND point. In both cases, connecting the top of the
resistor divider (either SENSE + or R1) close to the load can
significantly improve load regulation by compensating for
any drops in PC traces or hookup wires between the
LTC1430A and the load.
Power Component Hook-Up/Heat Sinking
As current levels rise much above 1A, the power components supporting the LTC1430A start to become physically large (relative to the LTC1430A, at least) and can
require special mounting considerations. Input and output
capacitors need to carry high peak currents and must have
low ESR; this mandates that the leads be clipped as short
as possible and PC traces be kept wide and short. The
power inductor will generally be the most massive single
component on the board; it can require a mechanical holddown in addition to the solder on its leads, especially if it
is a surface mount type.
The power MOSFETs used require some care to ensure
proper operation and reliability. Depending on the current
levels and required efficiency, the MOSFETs chosen may
be as large as TO-220s or as small as SO-8s. High
efficiency circuits may be able to avoid heat sinking the
power devices, especially with TO-220 type MOSFETs. As
an example, a 90% efficient converter working at a steady
3.3V/10A output will dissipate only (33W/90%)10% =
3.7W. The power MOSFETs generally account for the
majority of the power lost in the converter; even assuming
that they consume 100% of the power used by the
converter, that’s only 3.7W spread over two or three
devices. A typical SO-8 MOSFET with a RON suitable to
provide 90% efficiency in this design can commonly
dissipate 2W when soldered to an appropriately sized
piece of copper trace on a PC board. Slightly less efficient
or higher output current designs can often get by with
standing a TO-220 MOSFET straight up in an area with
some airflow; such an arrangement can dissipate as much
as 3W without a heat sink. Designs which must work in
high ambient temperatures or which will be routinely
overloaded will generally fare best with a heat sink.
17
LTC1430A
U
W
U
UO
APPLICATI
S I FOR ATIO
Figure 17 is a synchronous buck regulator designed to
provide a low voltage, very high current output from a 5V
or lower input voltage. The circuit uses two 8-pin
LTC1430ACS8s, operated 180° out of phase from each
other. Each half of the circuit is good for 15A of output
current, giving 30A total. The LT®1006 amplifier forces the
two half circuits to share the load current equally. This
scheme trades a small amount of additional control circuit
complexity for radical reductions in the volume (hence
cost) of the capacitors and inductors required. Advantages of this approach include very low input and output
ripple voltages, higher ripple frequency and extremely fast
transient response.
By incorporating two regulators phased opposite one
another, both the input ripple currents and the output
ripple currents tend to cancel. This permits running much
higher ripple currents in the output inductors than would
be tolerable with a single channel. The overall output ripple
current in a two phase design is approximately 1/2 of a
single channel’s ripple current, allowing the inductor value
of each channel to be 1/2 that of what a single channel
system would require for equal output ripple. Since energy
storage varies as the square of inductor current, and
directly as the inductance, each inductor stores only 1/8th
the energy of a single inductor design. Since there are two
inductors, total energy storage, and therefore inductor
volume, is 1/4th that of a single phase system.
A similar analysis can be done for the input capacitor
requirements. In fact, a two-phase regulator will actually
require less input capacitance than a single channel design
at 1/2 the load current. Figure 16 shows how the ripple
currents tend to cancel one another.
Another significant advantage of the two-phase topology
is radically improved transient response. During a load
transient, each of the two channels runs to maximum (or
minimum) duty cycle. The two ripple current terms now
end up reinforcing one another rather than canceling. The
result is a very high di/dt, hence, very fast transient
recoveries. Once steady state conditions return, the ripple
currents begin to cancel again, providing very low output
ripple voltage.
18
A+B
CHANNEL A
CHANNEL B
2µs/DIV
1430A F16
Figure 16. Output Inductor Currents 5A/DIV, 30A Out
The clocking of the two channels is accomplished by the
CD4047, a low cost, CMOS mulitvibrator with a built-in
divide-by-two flip flop. The CD4047 oscillator is set to run
at 600kHz and the Q and Q outputs drive the LTC1430A
shutdown pins. Since the sync signals are derived from
the clock’s divide-by-two outputs, they are inherently
180° out of phase and at the desired 300kHz clock frequency. Q1, D1 and the two resistors connected to Q1’s
base are used to disable the synchronization at turn-on to
prevent start-up problems. As long as the input-output
differential voltage is large enough to turn on Q1, the sync
circuit is disabled and both LTC1430As will free run at
200kHz. Once the output rises above ≈ 1.5V, the regulators are allowed to lock to the clock.
One challenge with a voltage mode two-phase design is
current sharing. Unlike current mode control which offers
inherent current sharing, voltage mode control virtually
assures that one channel will try to hog a large percentage
of the load current. The circuit gets around this problem
with a current share amplifier. The LT1006 op amp compares the voltage across both sense resistors and adds or
subtracts a small current into the lower LTC1430A’s
feedback divider, forcing it to match the upper LTC1430A’s
current. The two PCB trace resistors are intentionally
chosen to have a very low value to minimize power losses.
The LT1006 features 80µV typical VOS, ensuring reasonably accurate current sharing.
There are three problems associated with this current
sharing approach that must be dealt with. The first is that
R31
1k
ISENSE1
C38
3300pF
R30
1k
+
R32
10Ω
ISENSE2
C26
22µF
25V
12V
R6
3.09k
1%
C6
100pF
NPO
5%
C28
0.1µF
5V
9
2
1
3
12
8
6
4
5
OSC
–T
R9
4.3k
R8
4.3k
C31
0.022µF
C37
3300pF
C29
1µF
13
11
10
3
2
SYNC2
CD4047
(POWER FROM
5V CLOCK)
RST
RX
CX
RCC
RET
+T
Q
Q
AST
AST
SYNC1
6
CURRENT
SHARE
AMPLIFIER
4
8
1
+
C3
22µF
25V
C30
0.022µF
LT1006
7
R4
1k
R3
1k
C22
1µF
+
R7
51k
C16
180pF
C13
180pF
C1
1µF
R1
51Ω
GND
COMP
G1
FB
GND
SHDN
COMP
LTC1430ACS8
G2
PVCC2 PVCC1
C24
1µF
FB
SHDN
C15
1500pF
R15
10k
6
5
8
7
G1
LTC1430ACS8
G2
PVCC2 PVCC1
C14
1500pF
R14
10k
6
5
8
7
C25
1µF
3
4
1
2
3
4
1
2
12V
R16
10Ω
R10
10Ω
R27
1Ω
R26
1Ω
R19
1Ω
R25
1Ω
R23
1Ω
R22
1Ω
R20
1Ω
R21
1Ω
D4
BAT54
D3
BAT54
Q8
Si4410DY
(OPTIONAL)
Q6
Si4410DY
5V
Q4
Si4410DY
(OPTIONAL)
Q2
Si4410DY
D2
BAT54
Q7
Si4410DY
L2
0.8µH
C5
1µF
Figure 17. Low Voltage 30A Power Supply
C20
6800pF
R29
1Ω
+
+
+
ISENSE2
C10
470µF
6.3V
C11
470µF
6.3V
C9
470µF
6.3V
+
R11
0.002Ω
TRACE
+
C18
1000pF
R12
10k
R2
9.76k
1%
C8
470µF
6.3V
D1
BAW56CT1
1430 F17
R18
10k
1%
VIN
C36
1µF
C35
1µF
+
C17
1000pF
C34
1µF
R24
39k
Q1
MMBT3906LT1
R17
10k
1%
SYNC2
SYNC1
R5
9.76k
1%
C33
470µF
6.3V
C7
470µF
6.3V
C32
470µF
6.3V
+
C12
470µF
6.3V
R13
0.002Ω
TRACE
ISENSE1
L1
0.8µH
+
+
C4
1µF
C19
6800pF
R28
1Ω
CHARGE PUMP
(OPTIONAL)
Q5
Si4410DY
Q3
Si4410DY
CHARGE PUMP
(OPTIONAL)
Q9
Si4410DY
C27
0.47µF
C23
0.47µF
C39
1500µF
6.3V
SANYO
+
VIN
VOUT
U
W
5V
NOTES:
1. L1 AND L2 ARE PANASONIC ETQP1F0R8LB
2. ALL RESISTORS ± 5% UNLESS OTHERWISE MARKED
3. INPUT AND OUTPUT CAPS ARE KEMET T510 SERIES
4. TRACE RESISTORS R11 AND R13 ARE 0.1" WIDE BY 0.675" LONG
C2
1µF
C21
47µF
10V
5V
12V
UO
S I FOR ATIO
C40
1500µF
6.3V
SANYO
OPTIONAL
U
2.0V
20k
16.9k
16.9k
62k
43k
16.9k
16.9k
62k
APPLICATI
+
–
SUBSTITUTION TABLE
VOUT
VIN
REF 3.3V 2.5V
R24
10k
NA
10k
NA
3.3V R17
R18
10k
NA
R7
51k
NA
R24
39k
36k
R17
10k
6.04k
5V
R18 6.04k 10k
R7
51k
36k
LTC1430A
19
LTC1430A
U
W
U
UO
APPLICATI
S I FOR ATIO
the sense resistors should be well matched. This is
accomplished by using trace resistors that are laid out
symmetrically. Since they are formed of the same material
and processed identically, they will inherently match very
well. Note that the absolute value of these resistors is not
important; only the match between them is of concern.
right direction. If there are any gain differences in the two
loops there will need to be a small correction in the current
share error voltage. This can occur over a relatively long
time period with no adverse effects. As such, the share
amplifier’s bandwidth is on the order of a few hundred Hz,
ensuring good noise immunity.
The second issue is related to the reference point for the
two sense voltages. In order to avoid the need to use a true
differential amplifier to measure input current, the circuit
is configured such that the input side of these resistors
must be at the exact same potential. If the layout is not
configured this way, the current sharing accuracy will
prove disappointing. With only 0.2Ω sense resistors, a
seemingly small error will produce a rather large current
mismatch between channels.
Figure 18 demonstrates the high efficiency achieved with
this two-phase converter. An efficiency > 90% is realized
from a few amperes up to 30A. In theory and in practice,
this multiphase approach can be extended to even higher
current and output power levels. Consult Linear Technology for further details.
20
95
90
EFFICIENCY (%)
The last issue is related to having a very noisy sense
voltage. The current waveshape at the input to a buck
regulator is trapezoidal. Therefore, the sense amplifier
must integrate the two current measurements in order that
the average input currents be compared. The two-stage
RC filter on the sense amplifier provides an adequately
clean signal for the share circuit to operate correctly. High
speed is not required in the current sense loop. In balanced
operation any offsets in the slave regulator are dialed out
by the sense amplifier. If a sudden load change should
occur, both regulators will respond immediately and in the
100
85
80
75
70
65
60
55
50
0
5
15
20
10
LOAD CURRENT (A)
25
30
1430 F18
Figure 18. Low Voltage 30A Power Supply Efficiency
LTC1430A
U
PACKAGE DESCRIPTIO
Dimensions in inches (millimeters) unless otherwise noted.
GN Package
16-Lead Plastic SSOP (Narrow 0.150)
(LTC DWG # 05-08-1641)
0.189 – 0.196*
(4.801 – 4.978)
16 15 14 13 12 11 10 9
0.229 – 0.244
(5.817 – 6.198)
0.150 – 0.157**
(3.810 – 3.988)
1
0.015 ± 0.004
× 45°
(0.38 ± 0.10)
0.007 – 0.0098
(0.178 – 0.249)
0.009
(0.229)
REF
0.053 – 0.068
(1.351 – 1.727)
2 3
4
5 6
7
8
0.004 – 0.0098
(0.102 – 0.249)
0° – 8° TYP
0.016 – 0.050
(0.406 – 1.270)
* DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
** DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
0.008 – 0.012
(0.203 – 0.305)
0.025
(0.635)
BSC
GN16 (SSOP) 0398
21
LTC1430A
U
PACKAGE DESCRIPTIO
Dimensions in inches (millimeters) unless otherwise noted.
S8 Package
8-Lead Plastic Small Outline (Narrow 0.150)
(LTC DWG # 05-08-1610)
0.189 – 0.197*
(4.801 – 5.004)
8
7
6
5
0.150 – 0.157**
(3.810 – 3.988)
0.228 – 0.244
(5.791 – 6.197)
1
0.010 – 0.020
× 45°
(0.254 – 0.508)
0.008 – 0.010
(0.203 – 0.254)
0.053 – 0.069
(1.346 – 1.752)
0°– 8° TYP
0.016 – 0.050
0.406 – 1.270
0.014 – 0.019
(0.355 – 0.483)
*DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
**DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
22
2
3
4
0.004 – 0.010
(0.101 – 0.254)
0.050
(1.270)
TYP
SO8 0996
LTC1430A
U
PACKAGE DESCRIPTIO
Dimensions in inches (millimeters) unless otherwise noted.
S Package
16-Lead Plastic Small Outline (Narrow 0.150)
(LTC DWG # 05-08-1610)
0.386 – 0.394*
(9.804 – 10.008)
16
15
14
13
12
11
10
9
0.150 – 0.157**
(3.810 – 3.988)
0.228 – 0.244
(5.791 – 6.197)
1
0.010 – 0.020
× 45°
(0.254 – 0.508)
0.008 – 0.010
(0.203 – 0.254)
2
3
4
5
6
0.053 – 0.069
(1.346 – 1.752)
0.014 – 0.019
(0.355 – 0.483)
8
0.004 – 0.010
(0.101 – 0.254)
0° – 8° TYP
0.016 – 0.050
0.406 – 1.270
7
0.050
(1.270)
TYP
S16 0695
*DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
**DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
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.
23
LTC1430A
UO
TYPICAL APPLICATI
GTL Terminator
D1
MBR0530T1
5V
+
C1
0.1µF
R4
51
R7
15k
C10
1µF
15
14
11
12
C7
0.1µF
8
10
9
R10
3.3k
C3
220pF
4
R8
130k
PVCC2
VCC
PVCC1
G1
2
1
Q1
Si4410
C8
22µF
35V
D1
MBRS340T3
13
R1
1k
L1
2.7µH
1.5V OUT
R3
3Ω
C6
0.01µF
C11
0.068µF
C5
330
6.3V
OSCON
C16
0.1µF
R2
3Ω
FSET
IFB
LTC1430A
16
G2
IMAX
3
SHDN
PGND
5
COMP
– SENSE
7
SS
+SENSE
6
SGND
FB
C4
+
330
6.3V
OSCON
C2
680pF
Q2
Si4410
D2
MBRS340T3
+
+
R5
16.5k
1%
C12
330
6.3V
OSCON
C13
330
R9
6.3V
88.7k OSCON
1%
+
+
330
6.3V
TANT
+
330
6.3V
TANT
ADDITIONAL
DECOUPLING
AT THE LOAD
1430 TA03
R6
10k
SHDN
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTC1142
Current Mode Dual Step-Down Switching Regulator Controller
Dual Version of LTC1148
LTC1148
Current Mode Step-Down Switching Regulator Controller
Synchronous, VIN ≤ 20V
LTC1149
Current Mode Step-Down Switching Regulator Controller
Synchronous, VIN ≤ 48V, For Standard Threshold FETs
LTC1159
Current Mode Step-Down Switching Regulator Controller
Synchronous, VIN ≤ 40V, For Logic Threshold FETs
LTC1266
Current Mode Step-Up/Down Switching Regulator Controller
Synchronous N- or P-Channel FETs, Comparator/
Low-Battery Detector
LTC1267
Current Mode Dual Step-Down Switching Regulator Controller
Dual Version of LTC1159
LTC1649
3.3V Input Synchronous Switching Regulator Controller
3.3V Input
24
Linear Technology Corporation
1430af, 1430afs LT/TP 0898 4K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com
 LINEAR TECHNOLOGY CORPORATION 1998
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