Datasheet LTC3832, LTC3832-1 Datasheet (LINEAR TECHNOLOGY)

FEATURES

LTC3832/LTC3832-1

High Power Step-Down

Synchronous DC/DC Controllers

for Low Voltage Operation

U

DESCRIPTIO

■

V

as Low as 0.6V

OUT

■

High Power Switching Regulator Controller
for 3.3V-5V to 0.6V-3.xV Step-Down Applications

■

No Current Sense Resistor Required

■

Low Input Supply Voltage Range: 3V to 8V

■

Maximum Duty Cycle >91% Over Temperature

■

All N-Channel External MOSFETs

■

Excellent Output Regulation: ±1% Over Line, Load
and Temperature Variations

■

High Efficiency: Over 95% Possible

■

Adjustable or Fixed 2.5V Output (LTC3832)

■

Programmable Fixed Frequency Operation: 100kHz to
500kHz

■

External Clock Synchronization

■

Soft-Start

■

Low Shutdown Current: <10µA

■

Overtemperature Protection

■

Available in SO-8 and SSOP-16 Packages

U

APPLICATIO S

■

CPU Power Supplies

■

Multiple Logic Supply Generator

■

Distributed Power Applications

■

High Efficiency Power Conversion

The LTC®3832/LTC3832-1 are high power, high effi­ciency switching regulator controllers optimized for

3.3V-5V to 0.6V-3.xV step-down applications. A preci­sion internal reference and feedback system provide
±1% output regulation over temperature, load current
and line voltage variations. The LTC3832/LTC3832-1 use
a synchronous switching architecture with N-channel
MOSFETs. Additionally, the chip senses output current
through the drain-source resistance of the upper
N-channel MOSFET, providing an adjustable current limit
without a current sense resistor.

The LTC3832/LTC3832-1 operate with an input supply
voltage as low as 3V and with a maximum duty cycle of
>91% over temperature. They include a fixed frequency
PWM oscillator for low output ripple operation. The 300kHz
free-running clock frequency can be externally adjusted or
synchronized with an external signal from 100kHz to 500kHz.
In shutdown mode, the LTC3832 supply current drops to
<10µA. The LTC3832-1 is the SO-8 version without current
limit, frequency adjustment and shutdown functions.

, LTC and LT are registered trademarks of Linear Technology Corporation.

TYPICAL APPLICATIO

4.7µF

5.1Ω

0.1µF

0.01µF

15k

6.49k

LTC3832-1

V

SS

/PV

CC

CC2

COMP

GND

FB

4.32k

680pF

G1

PV

CC1

G2

L1: SUMIDA CDEP105-3R2MC-88

: PANASONIC EEFUEOD271R

C

OUT

Figure 1. High Efficiency 3.3V to 1V Power Converter

U

V

IN

3V TO 7V

MBR0520T1

0.1µF

+

Si9426DY

Si9426DY

L1

3.2µH

Efficiency

100

V

= 2.5V

90

80

V

OUT

1V
9A

+

C

OUT

270µF
2V

3832 F01

70

EFFICIENCY (%)

60

50

VIN = 3.3V

40

2468

OUT

V

= 1V

OUT

LOAD CURRENT (A)

10103579

3832 F01b

sn3832 3832fs

1

LTC3832/LTC3832-1

WWWU

ABSOLUTE AXI U RATI GS

(Note 1)

Supply Voltage

VCC....................................................................... 9V

PV

................................................................ 14V

CC1,2

Input Voltage

IFB, I

............................................... –0.3V to 14V

MAX

SENSE+, SENSE–, FB,

SHDN, FREQSET ....................... –0.3V to VCC + 0.3V

UU

W

PACKAGE/ORDER I FOR ATIO

1

G1

2

PV

CC1

3

PGND

4

GND

–

SENSE

SENSE

5
6

FB

+

7
8

SHDN

16-LEAD PLASTIC SSOP

T

JMAX

TOP VIEW

16
15
14
13
12
11
10

9

GN PACKAGE

= 125°C, θJA = 130°C/W

G2
PV

CC2

V

CC

I

FB

I

MAX

FREQSET
COMP
SS

ORDER PART

NUMBER

LTC3832EGN

GN

PART MARKING

3832

Junction Temperature...........................................125°C

Operating Temperature Range (Note 9) .. –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

G1

1

PV

2

CC1

GND

3

FB

4

8-LEAD PLASTIC SO

T

= 125°C, θJA = 130°C/W

JMAX

S8 PACKAGE

8

G2

/PV

V

7

CC

CC2

COMP

6

SS

5

LTC3832-1ES8

S8

PART MARKING

38321

Consult LTC Marketing for parts specified with wider operating temperature ranges.

ELECTRICAL CHARACTERISTICS

range, otherwise specifications are at TA = 25°C. VCC, PV

The ● denotes specifications that apply over the full operating temperature

, PV

CC1

= 5V, unless otherwise noted. (Note 2)

CC2

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

V
PV
V
V

V

∆V

CC

CC

UVLO

FB

OUT

OUT

Supply Voltage ● 358 V
PV

, PV

CC1

Voltage (Note 7) ● 3 13.2 V

CC2

Undervoltage Lockout Voltage 2.4 2.9 V
Feedback Voltage V

Output Voltage V

Output Load Regulation I
Output Line Regulation V

= 1.25V 0.595 0.6 0.605 V

COMP

= 1.25V 2.462 2.5 2.538 V

COMP

= 0A to 10A (Note 6) 2 mV

OUT

= 4.75V to 5.25V 0.1 mV

CC

● 0.593 0.6 0.607 V

● 2.450 2.5 2.550 V

2

sn3832 3832fs

LTC3832/LTC3832-1

ELECTRICAL CHARACTERISTICS

range, otherwise specifications are at TA = 25°C. VCC, PV

The ● denotes specifications that apply over the full operating temperature

, PV

CC1

= 5V, unless otherwise noted. (Note 2)

CC2

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

I

VCC

I

PVCC

f

OSC

V

SAWL

V

SAWH

V

COMPMAX

∆f

OSC

A

V

g

m

I

COMP

I

MAX

V

IH

V

IL

I

IN

I

SS

I

SSIL

R

SENSE

R

SENSEFB

tr, t

f

t

NOV

DC

MAX

/∆I

FREQSET

Supply Current Figure 2, V

V

= 0V ● 110 µA

SHDN

PVCC Supply Current Figure 2, V

= 0V ● 0.1 10 µA

V

SHDN

= V

SHDN

CC

= VCC (Note 3) ● 20 30 mA

SHDN

● 0.7 1.6 mA

Internal Oscillator Frequency FREQSET Floating ● 230 300 360 kHz
V

at Minimum Duty Cycle 1.2 V

COMP

V

at Maximum Duty Cycle 2.2 V

COMP

Maximum V

COMP

VFB = 0V, PV

= 8V 2.85 V

CC1

Frequency Adjustment 10 kHz/µA
Error Amplifier Open-Loop DC Gain Measured from FB to COMP, ● 50 65 dB

Error Amplifier Transconductance Measured from FB to COMP, ● 1600 2000 2400 µmho

+

SENSE

and SENSE– Floating, (Note 4)

+

and SENSE– Floating, (Note 4)

SENSE

Error Amplifier Output Sink/Source Current 100 µA
I

Sink Current V

MAX

I

Sink Current Tempco V

MAX

= V

IMAX

CC

(Note 10)

= VCC (Note 6) 3300 ppm/°C

IMAX

81216 µA

● 41220 µA

SHDN Input High Voltage ● 2.4 V
SHDN Input Low Voltage ● 0.8 V
SHDN Input Current V
Soft-Start Source Current VSS = 0V, V
Maximum Soft-Start Sink Current V

In Current Limit V

= V

SHDN

CC

= 0V, V

IMAX

= VCC, V

IMAX

= VCC (Note 8), PV

SS

IFB

● 0.1 1 µA

IFB

= V

CC

● –8 –12 –18 µA

= 0V, 1.6 mA

= 8V

CC1

SENSE Input Resistance 23.7 kΩ
SENSE to FB Resistance 18 kΩ
Driver Rise/Fall Time Figure 2, PV
Driver Nonoverlap Time Figure 2, PV
Maximum G1 Duty Cycle Figure 2, VFB = 0V (Note 5), PV

CC1

CC1

= PV

= 5V (Note 5) ● 80 250 ns

CC2

= PV

= 5V (Note 5) ● 25 120 250 ns

CC2

= 8V ● 91 95 %

CC1

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
the LTC3832 operating frequency, operating voltage and the external FETs
used.

Note 4: The open-loop DC gain and transconductance from the SENSE

+

and SENSE– pins to COMP pin will be (AV)(0.6/2.5) and (gm)(0.6/2.5)
respectively.

Note 5: Rise and fall times are measured using 10% and 90% levels. Duty
cycle and nonoverlap times are measured using 50% levels.

Note 6: Guaranteed by design, not subject to test.

Note 7: PV

must be higher than VCC by at least 2.5V for G1 to operate

CC1

at 95% maximum duty cycle and for the current limit protection circuit to
be active.

Note 8: The current limiting amplifier can sink but cannot source current.
Under normal (not current limited) operation, the output current will be
zero.

Note 9: The LTC3832E/LTC3832-1E are guaranteed to meet performance
specifications from 0°C to 70°C. Specifications over the –40°C to 85°C
operating temperature range are assured by design, characterization and
correlation with statistical process controls.

Note 10: The minimum and maximum limits for I

over temperature

MAX

includes the intentional temperature coefficient of 3300ppm/°C. This
induced temperature coefficient counteracts the typical temperature
coefficient of the external power MOSFET on-resistance. This results in a
relatively flat current limit over temperature for the application.

sn3832 3832fs

3

LTC3832/LTC3832-1

EXTERNAL SYNC FREQUENCY (kHz)

100

0.5

V

SAWH

– V

SAWL

(V)

0.6

0.8

0.9

1.0

1.5

1.2

200

300

3832 G09

0.7

1.3

1.4

1.1

400

500

TA = 25°C

TEMPERATURE (°C)

–50

ERROR AMPLIFIER TRANSCONDUCTANCE (µmho)

2300

25

3832 G03

2000

1800

–25 0 50

1700

1600

2400

2200

2100

1900

75 100 125

TEMPERATURE (°C)

–50

50

ERROR AMPLIFIER OPEN-LOOP GIAN (dB)

55

60

65

70

–25 0 25 50

3832 G06

75 100 125

UW

TYPICAL PERFOR A CE CHARACTERISTICS

Load Regulation Line Regulation

2.54
TA = 25°C

REFER TO FIGURE 12

2.53

2.52

2.51

(V)

2.50

OUT

V

2.49

2.48

2.47

2.46

–15

–10 –5 5

OUTPUT CURRENT (A)

0

10

3832 G01

0.605
TA = 25°C

0.604

0.603

0.602

0.601

(V)

0.600

FB

V

0.599

0.598

0.597

0.596

0.595

15

4

3

SUPPLY VOLTAGE (V)

6

5

7

3832 G02

Error Amplifier Transconductance
vs Temperature

5
4
3
2

∆V

1

FB

(mV)

0
–1
–2
–3
–4
–5

8

Output Voltage Temperature Drift

2.55
REFER TO FIGURE 12

2.54

OUTPUT = NO LOAD

2.53

2.52

2.51

(V)

2.50

OUT

V

2.49

2.48

2.47

2.46

2.45

–50

–25

0

TEMPERATURE (°C)

Oscillator Frequency
vs Temperature

360

FREQSET FLOATING

350
340
330
320

310
300
290

280

270

OSCILLATOR FREQUENCY (kHz)

260

250

240

–50

4

–25

0

TEMPERATURE (°C)

50

25

50

25

Error Amplifier Sink/Source
Current vs Temperature

50
40
30
20
10
0
–10
–20
–30
–40
–50

100

125

3832 G04

75

∆V

OUT

(mV)

200

180

160

140

120

100

80

60

40

ERROR AMPLIFIER SINK/SOURCE CURRENT (µA)

–25 0 50

–50

25

TEMPERATURE (°C)

75 100 125

3830 G05

Oscillator Frequency
vs FREQSET Input Current

700

TA = 25°C

600

500

400

300

200

OSCILLATOR FREQUENCY (kHz)

100

100

125

3832 G07

75

0

–30

–20 –10

FREQSET INPUT CURRENT (µA)

10 30

020

3832 G08

Error Amplifier Open-Loop Gain
vs Temperature

Oscillator (V

SAWH

– V

SAWL

)

vs External Sync Frequency

sn3832 3832fs

UW

OUTPUT CURRENT (A)

0

OUTPUT VOLTAGE (V)

1.0

2.0

3.0

0.5

1.5

2.5

4 8 12 16

3832 G12

2020 6 10 14 18

TA = 25°C
REFER TO FIGURE 12

TYPICAL PERFOR A CE CHARACTERISTICS

LTC3832/LTC3832-1

Maximum G1 Duty Cycle
vs Temperature

100

VFB = 0V
REFER TO FIGURE 3

99

98

97

96

95

94

93

MAXIMUM G1 DUTY CYCLE (%)

92

91

–50

0

–25

TEMPERATURE (°C)

25 125

50

Output Current Limit Threshold
vs Temperature

20

REFER TO FIGURE 12 AND NOTE 10 OF

19

THE ELECTRICAL CHARACTERISTICS

18
17
16
15
14
13

OUTPUT CURRENT LIMIT (A)

12
11
10

–50

–25

0

TEMPERATURE (°C)

50

25

75 100

75

100

3832 G10

3832 G13

125

I

Sink Current

MAX

vs Temperature Output Overcurrent Protection

20

18

16

14

12

10

SINK CURRENT (µA)

MAX

8

I

6

4

–25 0 50

–50

25

TEMPERATURE (°C)

Soft-Start Source Current
vs Temperature

–8

–9

–10

–11

–12

–13

–14

–15

SOFT-START SOURCE CURRENT (µA)

–16

–25 0 50

–50

25

TEMPERATURE (°C)

75 100 125

3832 G11

75 100 125

3830 G14

Soft-Start Sink Current
vs (V

– V

IFB

2.00
TA = 25°C

1.75

1.50

1.25

1.00

0.75

0.50

SOFT-START SINK CURRENT (mA)

0.25

0

–125 –100 –50

–150

IMAX

V

IFB

– V

)

–75

IMAX

(mV)

–25

0

3832 G15

3.0

2.9

2.8

2.7

2.6

2.5

2.4

2.3

2.2

2.1

2.0
–50

UNDERVOLTAGE LOCKOUT THRESHOLD VOLTAGE (V)

Undervoltage Lockout Threshold
Voltage vs Temperature

50

25

–25

0

TEMPERATURE (°C)

75

100

3832 G16

125

VCC Operating Supply Current
vs Temperature

1.6
FREQSET FLOATING

1.5

1.4

1.3

1.2

1.1

1.0

0.9

0.8

0.7

0.6

OPERATING SUPPLY CURRENT (mA)

CC

0.5

V

0.4
–50

0

–25

TEMPERATURE (°C)

50

25

PVCC Supply Current
vs Oscillator Frequency

90

TA = 25°C

80

70

60

50

G1 AND G2

40

WITH 1000pF,

PV

30

SUPPLY CURRENT (mA)

CC

20

PV

10

100

125

3832 G17

75

0

0

G1 AND G2 LOADED

WITH 6800pF,

= 12V

PV

CC1,2

G1 AND G2

LOADED

= 5V

CC1,2

100 300

200

OSCILLATOR FREQUENCY (kHz)

LOADED

WITH 6800pF,

PV

CC1,2

sn3832 3832fs

400

= 5V

500

3832 G18

5

LTC3832/LTC3832-1

UW

TYPICAL PERFOR A CE CHARACTERISTICS

PVCC Supply Current
vs Gate Capacitance

80

TA = 25°C

70

60

50

40

30

SUPPLY CURRENT (mA)

CC

20

PV

10

0

0

PV

= 12V

CC1,2

246 107135 9

GATE CAPACITANCE AT G1 AND G2 (nF)

U

PI FU CTIO S

PV

= 5V

CC1,2

8

3832 G19

UU

(LTC3832/LTC3832-1)

G1 Rise/Fall Time
vs Gate Capacitance Transient Response

200

TA = 25°C

180
160
140
120
100

80
60

G1 RISE/FALL TIME (ns)

40
20

0

0

tf AT PV

AT PV

t

r

CC1,2

21

GATE CAPACITANCE AT G1 AND G2 (nF)

G1 (Pin 1/Pin 1): Top Gate Driver Output. Connect this pin
to the gate of the upper N-channel MOSFET, Q1. This
output swings from PGND to PV

. It remains low if G2

CC1

is high or during shutdown mode.

PV

(Pin 2/Pin 2): Power Supply Input for G1. Connect

CC1

this pin to a potential of at least VIN + V

GS(ON)(Q1)

. This
potential can be generated using an external supply or
charge pump.

PGND (Pin 3/Pin 3): Power Ground. Both drivers return to
this pin. Connect this pin to a low impedance ground in
close proximity to the source of Q2. Refer to the Layout
Consideration section for more details on PCB layout
techniques. The LTC3832-1 has PGND and GND tied
together internally 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, connect GND to PGND right at the
LTC3832.

SENSE–, FB, SENSE+ (Pins 5, 6, 7/Pin 4): These three
pins connect to the internal resistor divider and input of the
error amplifier. To use the internal divider to set the output
voltage to 2.5V, connect SENSE+ to the positive terminal
of the output capacitor and SENSE– to the negative termi­nal. FB should be left floating. To use an external resistor

V

OUT

50mV/DIV

= 5V

CC1,2

= 5V

t

AT PV

r

43

5

tf AT PV

67 9

CC1,2

CC1,2

= 12V

= 12V

8

10

3832 G20

I

LOAD

2AV/DIV

50µs/DIV

divider to set the output voltage, float SENSE+ and SENSE
and connect the external resistor divider to FB. The internal
resistor divider is not included in the LTC3832-1.

SHDN (Pin 8/NA): Shutdown. A TTL compatible low level
at SHDN for longer than 100µs puts the LTC3832 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. This pin also doubles
as an external clock input to synchronize the internal
oscillator with an external clock. The shutdown function is
disabled in the LTC3832-1.

SS (Pin 9/Pin 5): Soft-Start. Connect this pin to an external
capacitor, CSS, to implement a soft-start function. If the
LTC3832 goes into current limit, CSS is discharged to
reduce the duty cycle. CSS must be selected such that
during power-up, the current through Q1 will not exceed
the current limit level.

COMP (Pin 10/Pin 6): External Compensation. This pin
internally connects to the output of the error amplifier and
input of the PWM comparator. Use a RC + C network at this
pin to compensate the feedback loop to provide optimum
transient response.

sn3832 3832fs

3832 G21

–

6

LTC3832/LTC3832-1

U

UU

PI FU CTIO S

FREQSET (Pin 11/NA): Frequency Set. Use this pin to
adjust the free-running frequency of the internal oscillator.
With the pin floating, the oscillator runs at about 300kHz.
A resistor from FREQSET to ground speeds up the oscil­lator; a resistor to VCC slows it down.

I

(Pin 12/NA): Current Limit Threshold Set. I

MAX

the threshold for the internal current limit comparator. If
IFB drops below I
current limit. I

MAX

Connect this pin to the main V

with G1 on, the LTC3832 goes into

MAX

has an internal 12µA pull-down to GND.

supply at the drain of Q1,

IN

through an external resistor to set the current limit thresh­old. Connect a 0.1µF decoupling capacitor across this
resistor to filter switching noise.

IFB (Pin 13/NA): Current Limit Sense. Connect this pin to
the switching 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 is used for
sensing the voltage drop across the upper N-channel
MOSFET, Q1.

MAX

sets

VCC (Pin 14/Pin 7): Power Supply Input. All low power
internal circuits draw their supply from this pin. Connect
this pin to a clean power supply, separate from the main
VIN supply at the drain of Q1. This pin requires a 4.7µF
bypass capacitor. The LTC3832-1has VCC and PV

CC2

tied

together at Pin 7 and requires a 10µF bypass capacitor to
GND.

PV

(Pin 15/Pin 7): Power Supply Input for G2. Connect

CC2

this pin to the main high power supply.
G2 (Pin 16/Pin 8): Bottom Gate Driver Output. Connect

this pin to the gate of the lower N-channel MOSFET, Q2.
This output swings from PGND to PV

. It remains low

CC2

when G1 is high or during shutdown mode. To prevent
output undershoot during a soft-start cycle, G2 is held low
until G1 first goes high (FFBG in the Block Diagram).

BLOCK DIAGRA

SHDN

FREQSET

COMP

SS

QC

W

(LTC3832)

100µs DELAY

INTERNAL

OSCILLATOR

12µA

2.2V

1.2V

QSS

THERMAL SHUTDOWN

ERR

+

V

REF

CC

DISABLE
I

LIM

–

–

+

LOGIC AND

–

PWM

+

V

POWER DOWN

I

FB

I

MAX

12µA

+

–

–

V

+ 10%

REF

PV

CC1

VCC + 2.5V

DISABLE GATE DRIVE

MAX

+

S

R

FFBG

S

RPOR

V

REF

Q

Q

Q

+ 10%

PV

CC1

G1

PV

CC2

G2

ENABLE
G2

18k

5.7k

V

REF

BG

3832 BD

PGND

V

CC

GND

FB

SENSE

SENSE

+

–

sn3832 3832fs

7

LTC3832/LTC3832-1

COMP

FB

V

COMP

V

FB

G1

G2

I

FBVCCPVCC1

5V

PV

CC2

6800pF

0.1µF

10µF

6800pF

G1 RISE/FALL

G2 RISE/FALL

3832 F03

I

MAX

GND PGND

LTC3832

+

W

BLOCK DIAGRA

(LTC3832-1)

COMP

SS

QC

TEST CIRCUITS

INTERNAL

OSCILLATOR

12µA

2.2V

1.2V

QSS

ERR

+

V

REF

THERMAL SHUTDOWN

POWER DOWN

–

PWM

+

–

+

V

–

–

V

+ 10%

REF

PV

CC1

VCC + 2.5V

DISABLE GATE DRIVE

MAX

+

S

R

FFG2

S

RPOR

PV

CC1

3832 BD2

G1

V

CC

G2

PGND

FB

/PV

CC2

Q

Q

ENABLE

Q

G2

V

REF

V

+ 10%

REF

BG

PV

PV

CC2PVCC1

–

CC

I

FB

SENSE

G1

G2

+

3832 F02

6800pF

6800pF

NC
NC
NC
NC

V

SHDNVCC

SHDN V
FB
SS
FREQSET
COMP
I

MAX

CC

LTC3832

GND PGND SENSE

Figure 2 Figure 3

WUUU

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OVERVIEW

The LTC3832/LTC3832-1 are voltage mode feedback,
synchronous switching regulator controllers (see Block
Diagram) designed for use in high power, low voltage
step-down (buck) converters. They include an onboard
PWM generator, a precision reference trimmed to ±0.8%,
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
300kHz.

The LTC3832 includes a current limit sensing circuit that
uses the topside external N-channel power MOSFET as a
current sensing element, eliminating the need for an
external sense resistor.

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8

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LTC3832/LTC3832-1

Also included in the LTC3832 is an internal soft-start
feature that requires only a single external capacitor to
operate. In addition, the LTC3832 features an adjustable
oscillator that can free run or synchronize to external
signal with frequencies from 100kHz to 500kHz, allowing
added flexibility in external component selection. The
LTC3832-1 does not include current limit, frequency
adjustability, external synchronization and the shutdown
function.

THEORY OF OPERATION

Primary Feedback Loop

The LTC3832/LTC3832-1 sense the output voltage of the
circuit at the output capacitor and feeds this voltage back
to the internal transconductance error amplifier, ERR,
through a resistor divider network. The error amplifier
compares the resistor-divided output voltage to the inter­nal 0.6V reference and outputs an error signal to the PWM
comparator. This error signal is compared with a fixed
frequency ramp waveform, from the internal oscillator, to
generate a pulse width modulated signal. This PWM signal
drives the external MOSFETs through the G1 and G2 pins.
The resulting chopped waveform is filtered by LO and C
which closes the loop. Loop compensation is achieved
with an external compensation network at the COMP pin,
the output node of the error amplifier.

MAX Feedback Loop

An additional comparator in the feedback loop provides
high speed output voltage correction in situations where
the error amplifier may not respond quickly enough. MAX
compares the feedback signal to a voltage 60mV above the
internal reference. If the signal is above the comparator
threshold, the MAX comparator overrides the error ampli­fier and forces the loop to minimum duty cycle, 0%. To
prevent this comparator from triggering due to noise, the
MAX comparator’s response time is deliberately delayed
by two to three microseconds. This comparator helps
prevent extreme output perturbations with fast output
load current transients, while allowing the main feedback
loop to be optimally compensated for stability.

OUT

Thermal Shutdown

The LTC3832/LTC3832-1 have a thermal protection cir­cuit that disables both gate drivers if activated. If the chip
junction temperature reaches 150°C, both G1 and G2 are
pulled low. G1 and G2 remain low until the junction
temperature drops below 125°C, after which, the chip
resumes normal operation.

Soft-Start and Current Limit

The LTC3832 includes a soft-start circuit that is used for
start-up and current limit operation. The LTC3832-1 only
has the soft-start function; the current limit function is
disabled. The SS pin requires an external capacitor, CSS,
to GND with the value determined by the required soft­start time. An internal 12µA current source is included to
charge CSS. During power-up, the COMP pin is clamped to
a diode drop (B-E junction of QSS in the Block Diagram)
above the voltage at the SS pin. This prevents the error
amplifier from forcing the loop to maximum duty cycle.
The LTC3832/LTC3832-1 operate at low duty cycle as the
SS pin rises above 0.6V (V
to rise, QSS turns off and the error amplifier takes over to
regulate the output.

The LTC3832 includes yet another feedback loop to con­trol operation in current limit. Just before every falling
edge of G1, the current comparator, CC, samples and
holds the voltage drop measured across the external
upper MOSFET, Q1, at the IFB pin. CC compares the voltage
at IFB to the voltage at the I
rises, the measured voltage across Q1 increases due to the
drop across the R
drops below I
exceeded the maximum level, CC starts to pull current out
of CSS, cutting the duty cycle and controlling the output
current level. The CC comparator pulls current out of the
SS pin in proportion to the voltage difference between I
and I
falls gradually, creating a time delay before current limit
takes effect. Very short, mild overloads may not affect the
output voltage at all. More significant overload conditions
allow the SS pin to reach a steady state, and the output

. Under minor overload conditions, the SS pin

MAX

DS(ON)

, indicating that Q1’s drain current has

MAX

≈ 1.2V). As SS continues

COMP

pin. As the peak current

MAX

of Q1. When the voltage at I

FB

FB

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LTC3832/LTC3832-1

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APPLICATIO S I FOR ATIO

remains at a reduced voltage until the overload is re­moved. Serious overloads generate a large overdrive at
CC, allowing it to pull SS down quickly and preventing
damage to the output components. By using the R

DS(ON)

of Q1 to measure the output current, the current limiting
circuit eliminates an expensive discrete sense resistor that
would otherwise be required. This helps minimize the
number of components in the high current path.

The current limit threshold can be set by connecting an
external resistor R
supply at the drain of Q1. The value of R

IMAX

from the I

pin to the main V

MAX

is determined

IMAX

IN

by:

R

IMAX

= (I

LMAX

)(R

DS(ON)Q1

)/I

IMAX

where:

I

= I

LMAX

I

= Maximum load current

LOAD

I

RIPPLE

f

= LTC3832 oscillator frequency = 300kHz

OSC

LOAD

+ (I

RIPPLE

/2)

= Inductor ripple current

VV V

–

()()

IN OUT OUT

=

fLV

()()

()

OSC O IN

LO = Inductor value
R
I

IMAX

The R

DS(ON)Q1

DS(ON)

= On-resistance of Q1 at I

= Internal 12µA sink current at I

LMAX

MAX

of Q1 usually increases with temperature. To

keep the current limit threshold constant, the internal
12µA sink current at I

is designed with a positive

MAX

temperature coefficient to provide first order correction
for the temperature coefficient of R

DS(ON)Q1

.

In order for the current limit circuit to operate properly and
to obtain a reasonably accurate current limit threshold, the
I

IMAX

and I

pins must be Kelvin sensed at Q1’s drain and

FB

source pins. In addition, connect a 0.1µF decoupling
capacitor across R

to filter switching noise. Other-

IMAX

wise, noise spikes or ringing at Q1’s source can cause the
actual maximum current to be greater than the desired
current limit set point. Due to switching noise and varia­tion of R

, the actual current limit trip point is not

DS(ON)

highly accurate. The current limiting circuitry is primarily

meant to prevent damage to the power supply circuitry
during fault conditions. The exact current level where the
limiting circuit begins to take effect will vary from unit to
unit as the R

of Q1 varies. Typically, R

DS(ON)

DS(ON)

varies

as much as ±40%, and with ±33% variation on the
LTC3832’s I

current, this can give a ±73% variation on

MAX

the current limit threshold.
The R

low. This occurs during power up when PV
up. To prevent the high R

is high if the VGS applied to the MOSFET is

DS(ON)

CC1

from activating the current

DS(ON)

is ramping

limit, the LTC3832 will disable the current limit circuit if
PV

is less than 2.5V above VCC. To ensure proper

CC1

operation of the current limit circuit, PV
least 2.5V above VCC when G1 is high. PV

must be at

CC1

can go low

CC1

when G1 is low, allowing the use of the external charge
pump to power PV

LTC3832

+

CC

–

Figure 4. Current Limit Setting

12µA

CC1

.

V

IN

R

I

12

MAX

I

FB

13

IMAX

0.1µF

G1

1k

G2

Q1

Q2

+

C

IN

L

O

V

OUT

+

C

OUT

3832 F04

Oscillator Frequency

The LTC3832 includes an onboard current controlled
oscillator that typically free-runs at 300kHz. The oscillator
frequency can be adjusted by forcing current into or out of
the FREQSET pin. With the pin floating, the oscillator runs
at about 300kHz. Every additional 1µA of current into/out
of the FREQSET pin decreases/increases the frequency by
10kHz. The pin is internally servoed to 1.265V. The
frequency can be estimated as:

f kHz

=+

300

where R

is a frequency programming resistor con-

FSET

VV

1 265 10

.–

R

EXT

FSET

kHz

•
A

µ

1

nected between FREQSET and the external voltage source
V

.

EXT

10

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LTC3832/LTC3832-1

Connecting a 82k resistor from FREQSET to ground
forces 15µA out of the pin, causing the internal oscillator
to run at approximately 450kHz. Forcing an external 20µA
current into FREQSET cuts the internal frequency to
100kHz. An internal clamp prevents the oscillator from
running slower than about 50kHz. Tying FREQSET to V

CC

forces the chip to run at this minimum speed. The
LTC3832-1 does not have this frequency adjustment
function.

Shutdown

The LTC3832 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 for
more than 100µs forces the LTC3832 into shutdown
mode. In this mode, all internal switching stops, the COMP
and SS pins pull to ground and Q1 and Q2 turn off. The
LTC3832 supply current drops to <10µA, although off-
state leakage in the external MOSFETs may cause the total
VIN current to be some what higher, especially at elevated
temperatures. If SHDN returns high, the LTC3832 reruns
a soft-start cycle and resumes normal operation. The
LTC3832-1 does not have this shutdown function.

Figure 5 describes the operation of the conventional
synchronization function. A negative transition at the
SHDN pin forces the internal ramp signal low to restart a
new PWM cycle. Notice that the ramp amplitude is lowered
as the external clock frequency goes higher. The effect of
this decrease in ramp amplitude increases the open-loop
gain of the controller feedback loop. As a result, the loop
crossover frequency increases and it may cause the feed­back loop to be unstable if the phase margin is insufficient.

To overcome this problem, the LTC3832 monitors the
peak voltage of the ramp signal and adjusts the oscillator
charging current to maintain a constant ramp peak.

SHDN

TRADITIONAL

SYNC METHOD

WITH EARLY

RAMP

TERMINATION

300kHz

FREE RUNNING

RAMP SIGNAL

RAMP SIGNAL

WITH EXT SYNC

External Clock Synchronization

The LTC3832 SHDN pin doubles as an external clock
input for applications that require a synchronized clock.
An internal circuit forces the LTC3832 into external
synchronization mode if a negative transition at the SHDN
pin is detected. In this mode, every negative transition on
the SHDN pin resets the internal oscillator and pulls the
ramp signal low, this forces the LTC3832 internal oscil­lator to lock to the external clock frequency. The LTC3832-1
does not have this external synchronization function.

The LTC3832 internal oscillator can be externally synchro­nized from 100kHz 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
larger percentage of the switch cycle. Circuits using these
frequencies should be checked carefully in applications
where operation near dropout is important—like 3.3V to

2.5V converters. The low period of this clock signal must
not be >100µs, or else the LTC3832 enters shutdown
mode.

RAMP AMPLITUDE

ADJUSTED

LTC3832

KEEPS RAMP

AMPLITUDE

CONSTANT

UNDER SYNC

3832 F05

Figure 5. External Synchronization Operation

Input Supply Considerations/Charge Pump

The LTC3832 requires four supply voltages to operate: V
for the main power input, PV

CC1

and PV

for MOSFET

CC2

IN

gate drive and a clean, low ripple VCC for the LTC3832
internal circuitry (Figure 6). The LTC3832-1 has the PV

CC2

and VCC pins tied together inside the package (Figure 7).
This pin, brought out as VCC/PV

, has the same low

CC2

ripple requirements as the LTC3832, but must also be able
to supply the gate drive current to Q2.

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11

LTC3832/LTC3832-1

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INTERNAL

CIRCUITRY

LTC3832

V

CC

PV

CC2

PV

CC1

V

IN

G1

Q1

L

O

G2

Q2

V

OUT

+

C

OUT

3832 F6

Figure 6. LTC3832 Power Supplies

VCC/PV

INTERNAL

CIRCUITRY

LTC3832-1

CC2

PV

CC1

V

IN

G1

Q1

L

O

G2

Q2

V

OUT

+

C

OUT

3832 F7

Figure 7. LTC3832-1 Power Supplies

In many applications, V

can be powered from V

CC

IN

through an RC filter. This supply can be as low as 3V. The
low quiescent current (typically 800µA) allows the use of
relatively large filter resistors and correspondingly small
filter capacitors. 100Ω and 4.7µF usually provide ad-
equate filtering for VCC. For best performance, connect the

4.7µF bypass capacitor as close to the LTC3832 VCC pin as
possible.

Figure 8 shows a tripling charge pump circuit that can be
used to provide 2VIN and 3VIN gate drive for the external
top and bottom MOSFETs respectively. These should fully
enhance MOSFETs with 5V logic level thresholds. This
circuit provides 3VIN – 3VF to PV
2VIN – 2VF to PV

where VF is the forward voltage of the

CC2

while Q1 is ON and

CC1

Schottky diodes. The circuit requires the use of Schottky
diodes to minimize forward drop across the diodes at
start-up. The tripling charge pump circuit can rectify any
ringing at the drain of Q2 and provide more than 3VIN at
PV

; a 12V zener diode should be included from PV

CC1

CC1

to PGND to prevent transients from damaging the circuitry
at PV

The charge pump capacitors for PV

or the gate of Q1.

CC1

refresh when the

CC1

G2 pin goes high and the switch node is pulled low by Q2.
The G2 on-time becomes narrow when LTC3832/
LTC3832-1 operates at a maximum duty cycle (95%
typical), which can occur if the input supply rises more
slowly than the soft-start capacitor or if the input voltage
droops during load transients. If the G2 on-time gets so
narrow that the switch node fails to pull completely to
ground, the charge pump voltage may collapse or fail to
start, causing excessive dissipation in external MOSFET,
Q1. This condition is most likely with low VCC voltages and
high switching frequencies, coupled with large external
MOSFETs which slow the G2 and switch node slew rates.

The LTC3832/LTC3832-1 overcome this problem by sens­ing the PV

voltage when G1 is high. If PV

CC1

is less than

CC1

2.5V above VCC, the maximum G1 duty cycle is reduced to
70% by clamping the COMP pin at 1.8V (QC in the Block

Gate drive for the top N-channel MOSFET Q1 is supplied
from PV
power supply input) by at least one power MOSFET V
for efficient operation. An internal level shifter allows PV
to operate at voltages above V

. This supply must be above VIN (the main

CC1

and VIN, up to 14V maxi-

CC

GS(ON)

CC1

mum. This higher voltage can be supplied with a separate
supply, or it can be generated using a charge pump.

Gate drive for the bottom MOSFET Q2 is provided through
PV

for the LTC3832 or VCC/PV

CC2

for the LTC3832-1.

CC2

This supply only needs to be above the power MOSFET
V
from the same supply/charge pump for the PV

for efficient operation. PV

GS(ON)

can also be driven

CC2

, or it can

CC1

be connected to a lower supply to improve efficiency.

12

D

Z

12V
1N5242

10µF

LTC3832

1N5817

1N5817

CC2

PV

CC1

G1

G2

PV

1N5817

0.1µF

0.1µF

Figure 8. Tripling Charge Pump

V

IN

Q1

L

O

Q2 C

+

OUT

3832 F08

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OUT

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APPLICATIO S I FOR ATIO

LTC3832/LTC3832-1

Diagram). This increases the G2 on-time and allows the
charge pump capacitors to be refreshed.

For applications using an external supply to PV

CC1

, this
supply must also be higher than VCC by at least 2.5V to
ensure normal operation.

For applications with a 5V or higher VIN supply, PV
be tied to VIN if a logic level MOSFET is used. PV

CC1

can

CC2

can be
supplied using a doubling charge pump as shown in
Figure␣ 9. This circuit provides 2VIN – VF to PV

while Q1

CC1

is ON.

V

IN

OPTIONAL

USE FOR V

D

Z

12V
1N5242

IN

≥ 7V

PV

LTC3832

CC2

PV

CC1

G1

G2

MBR0530T1

0.1µF

Q1

L

O

Q2 C

+

3832 F09

OUT

V

OUT

enhance standard power MOSFETs. Under this condition,
the effective MOSFET R

may be quite high, raising

DS(ON)

the dissipation in the FETs and reducing efficiency. Logic
level FETs are the recommended choice for 5V or lower
voltage systems. Logic level FETs can be fully enhanced
with a doubler/tripling charge pump and will operate at
maximum efficiency.

After the MOSFET threshold voltage is selected, choose the
R

based on the input voltage, the output voltage,

DS(ON)

allowable power dissipation and maximum output current.
In a typical LTC3832 circuit, operating in continuous mode,
the average inductor current is equal to the output load
current. This current flows through either Q1 or Q2 with the
power dissipation split up according to the duty cycle:

V

DC Q

DC Q

The R

()

() –

DS(ON)

OUT

1

=

V

IN

V

21

==

OUT

V

IN

VV

–

IN OUT

V

IN

required for a given conduction loss can now

be calculated by rearranging the relation P = I2R.

Figure 9. Doubling Charge Pump

Power MOSFETs

Two N-channel power MOSFETs are required for most
LTC3832 circuits. These should be selected based
primarily on threshold voltage and on-resistance consid­erations. Thermal dissipation is often a secondary con­cern in high efficiency designs. The required MOSFET
threshold should be determined based on the available
power supply voltages and/or the complexity of the gate
drive charge pump scheme. In 3.3V input designs where
an auxiliary 12V supply is available to power PV
PV

, standard MOSFETs with R

CC2

DS(ON)

specified at V

CC1

and

GS

= 5V or 6V can be used with good results. The current
drawn from this supply varies with the MOSFETs used
and the LTC3832’s operating frequency, but is generally
less than 50mA.

LTC3832 applications that use 5V or lower VIN voltage and
a doubling/tripling charge pump to generate PV
PV

, do not provide enough gate drive voltage to fully

CC2

CC1

and

P

MAX Q

() ()

R

DS ON Q

()

==

1

DC Q I

()•( )

P

R

DS ON Q

P

MAX

()

==

2

DC Q I

()•( )•(– )•( )

should be calculated based primarily on required

1

1

LOAD

MAX Q

() ()

2

2

LOAD

VP

•

IN MAX Q

2

VI

•( )

OUT LOAD

VP

IN MAX Q

2

VV I

IN OUT LOAD

1

2

2

2

efficiency or allowable thermal dissipation. A typical high
efficiency circuit designed for 3.3V input and 2.5V at 10A
output might allow no more than 3% efficiency loss at full
load for each MOSFET. Assuming roughly 90% efficiency
at this current level, this gives a P

value of:

MAX

(2.5V)(10A/0.9)(0.03) = 0.83W per FET

and a required R

R

DS ON Q

R

DS ON Q

==Ω

()

1

()

==Ω

2

(. )•(. )

( . – . )( )

of:

DS(ON)

33 083

VW

( . )( )

25 10

VA

(. )•(. )

33 083

VW

33 25 10

VVA

2

.

0 011

2

.

0 034

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APPLICATIO S I FOR ATIO

Note that the required R

for Q2 is roughly three

DS(ON)

times that of Q1 in this example. Note also that while the
required R

values suggest large MOSFETs, the

DS(ON)

power dissipation numbers are only 0.83W per device or
less; large TO-220 packages and heat sinks are not neces­sarily required in high efficiency applications. Siliconix
Si4410DY or International Rectifier IRF7413 (both in
SO-8) or Siliconix SUD50N03-10 (TO-252) or ON Semi­conductor MTD20N03HDL (DPAK) are small footprint
surface mount devices with R

values below 0.03Ω

DS(ON)

at 5V of VGS that work well in LTC3832 circuits. Using a
higher P

value in the R

MAX

calculations generally

DS(ON)

decreases the MOSFET cost and the circuit efficiency and
increases the MOSFET heat sink requirements.

Table 1 highlights a variety of power MOSFETs for use in
LTC3832 applications.

Inductor Selection

The inductor is often the largest component in an LTC3832
design and must be chosen carefully. Choose the inductor
value and type based on output slew rate requirements. The
maximum rate of rise of inductor current is set by the
inductor’s value, the input-to-output voltage differential and

the LTC3832’s maximum duty cycle. In a typical 3.3V in­put, 2.5V output application, the maximum rise time will be:

DC V V

•( – ) .

MAX IN OUT

LL

OO

=

076

A

s

µ

where LO is the inductor value in µH. With proper fre-
quency compensation, the combination of the inductor
and output capacitor values determine the transient recov­ery time. In general, a smaller value inductor improves
transient response at the expense of ripple and inductor
core saturation rating. A 1µH inductor has a 0.76A/µs rise
time in this application, resulting in a 6.6µs delay in
responding to a 5A load current step. During this 6.6µs,
the difference between the inductor current and the output
current is made up by the output capacitor. This action
causes a temporary voltage droop at the output. To
minimize this effect, the inductor value should usually be
in the 1µH to 5µH range for most 3.3V input LTC3832
circuits. To optimize performance, different combinations
of input and output voltages and expected loads may
require different inductor values.

Once the required value is known, the inductor core type
can be chosen based on peak current and efficiency

Table 1. Recommended MOSFETs for LTC3832 Applications

TYPICAL INPUT

R

PARTS AT 25°C (mΩ) RATED CURRENT (A) C

Siliconix SUD50N03-10 19 15 at 25°C 3200 1.8 175
TO-252 10 at 100°C

Siliconix Si4410DY 20 10 at 25°C 2700 150
SO-8 8 at 70°C

ON Semiconductor MTD20N03HDL 35 20 at 25°C 880 1.67 150
DPAK 16 at 100°C

Fairchild FDS6670A 8 13 at 25°C 3200 25 150
S0-8

Fairchild FDS6680 10 11.5 at 25°C 2070 25 150
SO-8

ON Semiconductor MTB75N03HDL 9 75 at 25°C 4025 1 150
DD PAK 59 at 100°C

IR IRL3103S 19 64 at 25°C 1600 1.4 175
DD PAK 45 at 100°C

IR IRLZ44 28 50 at 25°C 3300 1 175
TO-220 36 at 100°C

Fuji 2SK1388 37 35 at 25°C 1750 2.08 150
TO-220

Note: Please refer to the manufacturer’s data sheet for testing conditions and detailed information.

DS(ON)

CAPACITANCE

(pF) θJC (°C/W) T

ISS

JMAX

sn3832 3832fs

(°C)

14

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APPLICATIO S I FOR ATIO

LTC3832/LTC3832-1

requirements. Peak current in the inductor will be equal to
the maximum output load current plus half of the peak-to­peak inductor ripple current. Ripple current is set by the
inductor value, the input and output voltage and the
operating frequency. The ripple current is approximately
equal to:

VV V

−()•()

I

RIPPLE

f

= LTC3832 oscillator frequency = 300kHz

OSC

LO = Inductor value

Solving this equation with our typical 3.3V to 2.5V appli­cation with a 1µH inductor, we get:

(. – . )• .

33 25 25

VVV

300 1 3 3

kHz H V

Peak inductor current at 10A load:

10A + (2A/2) = 11A

The ripple current should generally be between 10% and
40% of the output current. The inductor must be able 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 in
circuits not employing the current limit function, the
current in the inductor may rise above this maximum
under short-circuit or fault conditions; the inductor should
be sized accordingly to withstand this additional current.
Inductors with gradual saturation characteristics are often
the best choice.

Input and Output Capacitors

A typical LTC3832 design places significant demands on
both the input and the output capacitors. During normal
steady load operation, a buck converter like the LTC3832
draws square waves of current from the input supply at the
switching frequency. The peak current value is equal to the
output load current plus 1/2 the peak-to-peak ripple cur­rent. Most of this current is supplied by the input bypass
capacitor. The resulting RMS current flow in the input
capacitor heats it and causes premature capacitor failure
in extreme cases. Maximum RMS current occurs with
50% PWM duty cycle, giving an RMS current value equal

IN OUT OUT

=

fLV

••

OSC O IN

µ

••.

=

2

A

P

-P

to I
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 at rated temperature. Further derating of the input
capacitor ripple current beyond the manufacturer’s speci­fication is recommended to extend the useful life of the
circuit. Lower operating temperature has the largest effect
on capacitor longevity.

The output capacitor in a buck converter under steady­state conditions sees much less ripple current than the
input capacitor. Peak-to-peak current is equal to inductor
ripple current, usually 10% to 40% of the total load
current. Output capacitor duty places a premium not on
power dissipation but on ESR. During an output load
transient, the output capacitor must supply all of the
additional load current demanded by the load until the
LTC3832 adjusts 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. An 5A load step with a 0.05Ω ESR output
capacitor results in a 250mV output voltage shift; this is
10% of the output voltage for a 2.5V supply! Because of
the strong relationship between output capacitor ESR and
output load transient response, choose the output capaci­tor 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 LTC3832 applications. OS-CON
electrolytic capacitors from Sanyo and other manufactur­ers give excellent performance and have a very high
performance/size ratio for electrolytic capacitors. 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. Other capacitors that can be used
include the Sanyo POSCAP and MV-WX series.

A common way to lower ESR and raise ripple current
capability is to parallel several capacitors. A typical

/2. A low ESR input capacitor with an adequate

OUT

sn3832 3832fs

15

LTC3832/LTC3832-1

fLC

LC O OUT

=π

[]

12/ ( )( )

WUUU

APPLICATIO S I FOR ATIO

LTC3832 application might exhibit 5A input ripple cur­rent. Sanyo OS-CON capacitors, part number 10SA220M
(220µF/10V), feature 2.3A allowable ripple current at
85°C; three in parallel at the input (to withstand the input
ripple current) meet the above requirements. Similarly,
Sanyo POSCAP 4TPB470M (470µF/4V) capacitors have a
maximum rated ESR of 0.04Ω; three in parallel lower the
net output capacitor ESR to 0.013Ω.

Feedback Loop Compensation

The LTC3832 voltage feedback loop is compensated at the
COMP pin, which is the output node of the error amplifier.
The feedback loop is generally compensated with an RC +
C network from COMP to GND as shown in Figure 10a.

+

SENSE

7

LTC3832

ERR

–

+

V

REF

COMP

10

R

C

C

C1

C

Figure 10a. Compensation Pin Hook-Up

R2

R1

SENSE

3832 F10a

C2

V

FB

6

–

5

Loop stability is affected by the values of the inductor, the
output capacitor, the output capacitor ESR, the error
amplifier transconductance and the error amplifier com­pensation network. The inductor and the output capacitor
create a double pole at the frequency:

The ESR of the output capacitor and the output capacitor
value form a zero at the frequency:

f ESR C

=π

12/ ( )( )

ESR OUT

[]

The compensation network used with the error amplifier
must provide enough phase margin at the 0dB crossover
frequency for the overall open-loop transfer function. The
zero and pole from the compensation network are:

fZ = 1/[2π(RC)(CC)] and
fP = 1/[2π(RC)(C1)] respectively

Figure 10b shows the Bode plot of the overall transfer
function.

When low ESR output capacitors (Sanyo OS-CON) are
used, the ESR zero can be high enough in frequency that
it provides little phase boost at the loop crossover fre­quency. As a result, the phase margin becomes
inadequate and the load transient is not optimized. To
resolve this problem, a small capacitor can be connected

f

Z

LOOP GAIN

f

f

LC

ESR

Figure 10b. Bode Plot of the LTC3832 Overall Transfer Function Figure 10c. Bode Plot of the LTC3832 Overall

16

f

= LTC3832 SWITCHING

SW

FREQUENCY

= CLOSED-LOOP CROSSOVER

f

CO

FREQUENCY

20dB/DECADE

f

P

f

CO

= LTC3832 SWITCHING

f

SW

FREQUENCY

= CLOSED-LOOP CROSSOVER

f

CO

FREQUENCY

f

Z

LOOP GAIN

20dB/DECADE

f

CO

fPf

PC2

FREQUENCY FREQUENCY

3832 F10b

f

f

LC

ZC2

f

ESR

3832 F10c

Transfer Function Using a Low ESR Output Capacitor

sn3832 3832fs

WUUU

APPLICATIO S I FOR ATIO

LTC3832/LTC3832-1

between the top of the resistor divider network and the V

FB

pin to create a pole-zero pair in the loop compensation.
The zero location is prior to the pole location and thus,
phase lead can be added to boost the phase margin at the
loop crossover frequency. The pole and zero locations are
located at:

f

= 1/[2π(R2)(C2)] and

ZC2

f

= 1/[2π(R1||R2)(C2)]

PC2

where R1||R2 is the parallel combination resistance of R1
and R2. For low R2/R1 ratios there is not much separa­tion between f

CZ2

and f

. In this case, use multiple

PC2

capacitors with a high ESR • capacitance product to bring
f

close to fCO. Choose C2 so that the zero is located at

ESR

a lower frequency compared to fCO and the pole location
is high enough that the closed loop has enough phase
margin for stability. Figure 10c shows the Bode plot using
phase lead compensation around the LTC3832 resistor
divider network.

Although a mathematical approach to frequency compen­sation can be used, the added complication of input and/or
output filters, unknown capacitor ESR, and gross operat­ing point changes with input voltage, load current varia­tions, all suggest a more practical empirical method. This
can be done by injecting a transient current at the load and
using an RC network box to iterate toward the final values,
or by obtaining the optimum loop response using a
network analyzer to find the actual loop poles and zeros.

Table 2 shows the suggested compensation component
value for 3.3V to 2.5V applications based on Sanyo OS-CON
4SP820M low ESR output capacitors.

Table 3 shows the suggested compensation component
values for 3.3V to 2.5V applications based on 470µF Sanyo
POSCAP 4TPB470M output capacitors.

Table 3. Recommended Compensation Network for 3.3V to 2.5V
Applications Using Multiple Paralleled 470µF Sanyo POSCAP
4TPB470M Output Capacitors

L1 (µH) C

1.2 1410 13 0.0047 100

1.2 2820 27 0.0018 56

1.2 4700 51 0.0015 47

2.4 1410 33 0.0033 56

2.4 2820 62 0.0022 15

2.4 4700 82 0.001 39

4.7 1410 62 0.0022 15

4.7 2820 150 0.0015 10

4.7 4700 220 0.0015 2

(µF) RC (kΩ)C

OUT

(µF) C1 (pF)

C

Table 4 shows the suggested compensation component
values for 3.3V to 2.5V applications based on 1500µF
Sanyo MV-WX output capacitors.

Table 4. Recommended Compensation Network for 3.3V to 2.5V
Applications Using Multiple Paralleled 1500µF Sanyo MV-WX
Output Capacitors

L1 (µH) C

1.2 4500 39 0.0042 180

1.2 6000 56 0.0033 120

1.2 9000 82 0.0033 100

2.4 4500 82 0.0033 82

2.4 6000 100 0.0022 56

2.4 9000 150 0.0022 68

4.7 4500 120 0.0022 39

4.7 6000 220 0.0022 27

4.7 9000 220 0.0015 33

(µF) RC (kΩ)C

OUT

(µF) C1 (pF)

C

Table 2. Recommended Compensation Network for 3.3V to 2.5V
Applications Using Multiple Paralleled 820µF Sanyo OS-CON
4SP820M Output Capacitors

L1 (µH) C

1.2 1640 9.1 4.7 560 1500

1.2 2460 15 4.7 330 1500

1.2 4100 24 3.3 270 1500

2.4 1640 22 4.7 330 1500

2.4 2460 33 3.3 220 1500

2.4 4100 43 2.2 180 1500

4.7 1640 33 3.3 120 1500

4.7 2460 56 2.2 100 1500

4.7 4100 91 2.2 100 1500

(µF) RC (kΩ)CC (nF) C1 (pF) C2 (pF)

OUT

LAYOUT CONSIDERATIONS

When laying out the printed circuit board, use the follow­ing checklist to ensure proper operation of the LTC3832.
These items are also illustrated graphically in the layout
diagram of Figure 11. The thicker lines show the high
current paths. Note that at 10A current levels or above,
current density in the PC board itself is a serious concern.
Traces carrying high current should be as wide as pos­sible. For example, a PCB fabricated with 2oz copper
requires a minimum trace width of 0.15" to carry 10A.

sn3832 3832fs

17

LTC3832/LTC3832-1

WUUU

APPLICATIO S I FOR ATIO

1. In general, layout should begin with the location of the
power devices. Be sure to orient the power circuitry so that
a clean power flow path is achieved. Conductor widths
should be maximized and lengths minimized. After you are
satisfied with the power path, the control circuitry should
be laid out. It is much easier to find routes for the relatively
small traces in the control circuits than it is to find
circuitous routes for high current paths.

2. The GND and PGND pins should be shorted directly at
the LTC3832. This helps to minimize internal ground dis­turbances in the LTC3832 and prevent differences in ground
potential from disrupting internal circuit operation. This
connection should then tie into the ground plane at a single
point, preferably at a fairly quiet point in the circuit such as
close to the output capacitors. This is not always practical,
however, due to physical constraints. Another reasonably
good point to make this connection is between the output
capacitors and the source connection of the bottom
MOSFET Q2. Do not tie this single point ground in the trace
run between the Q2 source and the input capacitor ground,
as this area of the ground plane will be very noisy.

3. The small-signal resistors and capacitors for frequency
compensation and soft-start should be located very close
to their respective pins and the ground ends connected to
the signal ground pin through a separate trace. Do not
connect these parts to the ground plane!

4. The VCC, PV

CC1

and PV

decoupling capacitors should

CC2

be as close to the LTC3832 as possible. The 4.7µF and 1µF
bypass capacitors shown at VCC, PV

CC1

and PV

will help

CC2

provide optimum regulation performance.

5. The (+) plate of CIN should be connected as close as
possible to the drain of the upper MOSFET, Q1. An additional
1µF ceramic capacitor between VIN and power ground is
recommended.

6. The SENSE and VFB pins are very sensitive to pickup from
the switching node. Care should be taken to isolate SENSE
and VFB from possible capacitive coupling to the inductor
switching signal. Connecting the SENSE+ and SENSE– close
to the load can significantly improve load regulation.

7. Kelvin sense I

and IFB at Q1’s drain and source pins.

MAX

4.7µF

C1

C

PV

CC

100Ω

+

PV

V

1µF

GND

NC

R

C

C

C

SS

CC

FREQSET
SHDN
COMP
SS

GND PGND

GND

LTC3832

CC2

PV

I

MAX

SENSE

SENSE

CC1

I

G1

FB

+

G2

FB

–

PGND

NC

1µF

0.1µF

1k

Q1A

V

IN

PGND

+

C

IN

Q1B

L

O

Q2

V

OUT

+

C

OUT

3832 F11

Figure 11. Typical Schematic Showing Layout Considerations

18

sn3832 3832fs

WUUU

APPLICATIO S I FOR ATIO

OPTIONAL

D

Z

12V
1N5242

+

1µF

C1
180pF

10µF

SHDN

0.01µF

NC

R

C

18k

C

C

1500pF

100Ω

+

4.7µF

1N5817

PV

CC2

V

CC

SS

LTC3832
FREQSET
SHDN
COMP

SENSE

Figure 12. Typical 3.3V to 2.5V, 14A Application

PV

CC1

I

PGND

GND

SENSE

–

1N5817

G1

MAX

I

FB

G2

+

FB

NC

5.6k

1N5817

0.1µF

0.1µF

1k

0.1µF

Q2

: SANYO 6TPB330M

C

IN

: SANYO 4TPB470M

C

OUT

D1: MBRS330T3

: SUMIDA CDEP105-1R3-MC-S

L

O

Q1A, Q1B, Q2: FAIRCHILD FDS6670A

LTC3832/LTC3832-1

V

IN

+

Q1A, Q1B
2 IN PARALLEL

L

O

1.3µH

+

D1

C

IN

330µF
×2

C

OUT

470µF
×3

3.3V

V

2.5V
14A

3832 F12a

OUT

Efficiency vs Load Current

100

90
80
70

60
50

40

EFFICIENCY (%)

30

TA = 25°C

20

= 3.3V

V

IN

= 2.5V

V

10

OUT

REFER TO FIGURE 12

0

123

0

89

5674

LOAD CURRENT (A)

10 11

12 13 14

3832 F12b

15

sn3832 3832fs

19

LTC3832/LTC3832-1

TYPICAL APPLICATIO S

V

IN

3.3V

C1
68pF

+

10Ω

2.2µF

SHUTDOWN

R

C

6.8k
C

C

0.01µF

C

IN

330µF

10µF

0.47µF

NC

NC

10µF

V
SS

FREQSET
SHDN
COMP
SENSE

U

Typical 3.3V to 5V, 5A Synchronous Boost Converter

5mΩ

L

O

1.3µH

MBR330T3

Q2

Q1

PV

CC

CC1

LTC3832

+

SENSE

NC

PV

PGND

–

CC2

I

MAX

GND

5.6k

I

FB

G1

G2

FB

, C

C

IN

OUT

: SUMIDA CDEP105-1R3-MC-S

L

O

Q1, Q2: SILICONIX Si4864DY

MBR0520

MBR0520

0.1µF

0.1µF

100Ω

: SANYO POSCAP 6TPB330M

10µF

93.1k
1%

12.7k
1%

3832 TA03

V

OUT

5V

C

OUT

330µF
×2

5A

+

20

sn3832 3832fs

TYPICAL APPLICATIO S

Typical 3.3V to –5V, 5A Positive-to-Negative Converter

100Ω

1µF

D

8.2V

Z

1µF

SHUTDOWN

C1
180pF

10µF

R

C

15k

C

1.5nF

NC

NC

C

0.01µF

PV

V

CC

SS

FREQSET
SHDN
COMP
SENSE

U

CC2

LTC3832

V

IN

3.3V

+

SENSE

NC

PV

PGND

–

CC1

I

MAX

GND

G1

I

FB

G2

FB

MBR0520

3.5k

13V

CIN, C

OUT

: SUMIDA CDEP105-1R3-MC-S

L

O

Q1, Q2: SILICONIX Si7440DP

0.1µF

1k

: SANYO POSCAP 6TPB330M

0.1µF

LTC3832/LTC3832-1

+

C

IN

330µF

Q1

L

O

1.3µH

+

Q2

10µF

C

OUT

330µF

93.1k
1%

12.7k
1%

3832 TA04

V

OUT

–5V
5A

sn3832 3832fs

21

LTC3832/LTC3832-1

PACKAGE DESCRIPTIO

U

GN Package

16-Lead Plastic SSOP (Narrow .150 Inch)

(Reference LTC DWG # 05-08-1641)

.045 ±.005

.254 MIN

RECOMMENDED SOLDER PAD LAYOUT

.007 – .0098

(0.178 – 0.249)

.016 – .050

NOTE:

1. CONTROLLING DIMENSION: INCHES

2. DIMENSIONS ARE IN

3. DRAWING NOT TO SCALE
*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

(0.406 – 1.270)

INCHES

(MILLIMETERS)

.150 – .165

.0250 TYP.0165 ±.0015

.015

(0.38 ± 0.10)

0° – 8° TYP

± .004

× 45°

.229 – .244

(5.817 – 6.198)

.053 – .068

(1.351 – 1.727)

.008 – .012

(0.203 – 0.305)

16

15

12

.189 – .196*

(4.801 – 4.978)

14

12 11 10

13

5

4

3

678

.0250

(0.635)

BSC

.009

(0.229)

9

(0.102 – 0.249)

REF

.150 – .157**
(3.810 – 3.988)

.004 – .0098

GN16 (SSOP) 0502

22

sn3832 3832fs

PACKAGE DESCRIPTIO

.050 BSC

N

U

S8 Package

8-Lead Plastic Small Outline (Narrow .150 Inch)

(Reference LTC DWG # 05-08-1610)

.189 – .197

.045 ±.005

(4.801 – 5.004)

8

NOTE 3

7

6

LTC3832/LTC3832-1

5

.245
MIN

1 2 3 N/2

.030 ±.005

TYP

RECOMMENDED SOLDER PAD LAYOUT

.010 – .020

(0.254 – 0.508)

.008 – .010

(0.203 – 0.254)

NOTE:

1. DIMENSIONS IN

2. DRAWING NOT TO SCALE

3. THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.
MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED .006" (0.15mm)

×

45

.016 – .050

(0.406 – 1.270)

INCHES

(MILLIMETERS)

.160

±.005

°

0°– 8° TYP

.228 – .244

(5.791 – 6.197)

.053 – .069

(1.346 – 1.752)

.014 – .019

(0.355 – 0.483)

TYP

N

.150 – .157

(3.810 – 3.988)

N/2

1

3

2

NOTE 3

4

.004 – .010

(0.101 – 0.254)

.050

(1.270)

BSC

SO8 0502

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.

sn3832 3832fs

23

LTC3832/LTC3832-1

TYPICAL APPLICATIO

100Ω

1µF

+

4.7µF

0.1µF

SHUTDOWN

C1
180pF

0.01µF

NC

R

C

18k

C

0.01µF

U

Typical 5V to 3.3V, 10A Application

5V

+

C

L

1.3µH

IN

330µF
×2

O

3.3V

+

C

OUT

470µF
×3

45k
1%

10k
1%

3830 TA02

10A

MBR0530T1

+

CC2

CC

LTC3832

SENSE

SENSE

NC

PV

PGND

–

CC1

I

MAX

GND

G1

I

FB

G2

+

FB

PV

V
SS

FREQSET
SHDN
COMP

C

20k

0.1µF

0.1µF

1k

NC

: SANYO 6TPB330M

C

IN

: SANYO 4TPB470M

C

OUT

: SUMIDA CDEP105-1R3-MC-S

L

O

Q1A, Q1B, Q2: ON SEMICONDUCTOR MTD20N03HDL

Q1A, Q1B
2 IN PARALLEL

Q2

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24

Linear T echnology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900 ● FAX: (408) 434-0507

●

www.linear.com

sn3832 3832fs

LT/TP 1002 2K • PRINTED IN USA

 LINEAR TECHNOLOGY CORPORATION 2002