LTC3780IUHPBF_技术文档

LTC3780

High Efﬁciency, Synchronous,

4-Switch Buck-Boost Controller

FeaTures

DescripTion

The LTC^®3780 is a high performance buck-boost switch-

ing regulator controller that operates from input voltages

above, below or equal to the output voltage. The constant

frequency current mode architecture allows a phase-

lockable frequency of up to 400kHz. With a wide 4V to

30V(36Vmaximum)inputandoutputrangeandseamless

transfers between operating modes, the LTC3780 is ideal

for automotive, telecom and battery-powered systems.

n

Single Inductor Architecture Allows V Above,

IN

Below or Equal to V

OUT

n

Wide V Range: 4V to 36V Operation

IN

n

Synchronous Rectiﬁcation: Up to 98% Efﬁciency

n

Current Mode Control

n

±1% Output Voltage Accuracy: 0.8V < V

< 30V

OUT

n

Phase-Lockable Fixed Frequency: 200kHz to 400kHz

Power Good Output Voltage Monitor

Internal LDO for MOSFET Supply

Theoperatingmodeofthecontrollerisdeterminedthrough

the FCB pin. For boost operation, the FCB mode pin can

selectamongBurstMode^®operation,discontinuousmode

and forced continuous mode. During buck operation, the

FCB mode pin can select among skip-cycle mode, discon-

tinuous mode and forced continuous mode. Burst Mode

operation and skip-cycle mode provide high efﬁciency

operation at light loads while forced continuous mode

and discontinuous mode operate at a constant frequency.

Quad N-Channel MOSFET Synchronous Drive

V

Disconnected from V During Shutdown

OUT

IN

Adjustable Soft-Start Current Ramping

Foldback Output Current Limiting

Selectable Low Current Modes

Output Overvoltage Protection

Available in 24-Lead SSOP and Exposed Pad

(5mm × 5mm) 32-Lead QFN Packages

Fault protection is provided by an output overvoltage

comparatorandinternalfoldbackcurrentlimiting.Apower

good output pin indicates when the output is within 7.5%

of its designed set point.

L, LT, LTC, LTM, Linear Technology, Burst Mode, µModule and the Linear logo are registered

trademarks of Linear Technology Corporation. All other trademarks are the property of their

respective owners. Protected by U.S. Patents, including 5481178, 6304066, 5929620, 5408150,

6580258, patent pending on current mode architecture and protection.

applicaTions

n

Automotive Systems

n

Telecom Systems

n

DC Power Distribution Systems

High Power Battery-Operated Devices

n

Industrial Control

Typical applicaTion

High Efﬁciency Buck-Boost Converter

V

12V

5A

OUT

V

IN

5V TO 32V

Efﬁciency and Power Loss

V_OUT= 12V, I_LOAD= 5A

100µF

16V

CER

+

22µF

50V

CER

+

330µF

16V

1µF

CER

4.7µF

V

IN

PGOOD INTV

A

B

D

C

CC

100

95

10

9

8

7

6

5

4

3

2

1

0

TG2

TG1

0.1µF

BOOST2

SW2

BOOST1

SW1

90

LTC3780

BG2

BG1

PLLIN

RUN

85

I

TH

105k

1%

2200pF

20k

ON/OFF

SS

V

0.1µF

OSENSE

FCB

80

75

70

SGND

SENSE SENSE PGND

7.5k

1%

+

–

0

5

10

15

V

20

25

30

35

0.010Ω

4.7µH

(V)

IN

3780 TA01b

3780 TA01

3780ff

For more information www.linear.com/LTC3780

1

LTC3780

absoluTe MaxiMuM raTings ^{(Note 1)}

Input Supply Voltage (V )........................ –0.3V to 36V

I , V

Voltages .............................. –0.3V to 2.4V

IN

TH OSENSE

Topside Driver Voltages

Peak Output Current <10µs (TG1, TG2, BG1, BG2).....3A

(BOOST1, BOOST2) .................................. –0.3V to 42V

Switch Voltage (SW1, SW2) ........................ –5V to 36V

INTV Peak Output Current ................................. 40mA

CC

Operating Junction Temperature Range (Notes 2, 7)

LTC3780E............................................. –40°C to 85°C

LTC3780I............................................ –40°C to 125°C

LTC3780MP ....................................... –55°C to 125°C

Storage Temperature Range................... –65°C to 125°C

Lead Temperature (Soldering, 10 sec)

INTV , EXTV , (BOOST – SW1),

CC

(BOOST2 – SW2), PGOOD.......................... –0.3V to 7V

RUN, SS....................................................... –0.3V to 6V

PLLIN Voltage.......................................... –0.3V to 5.5V

PLLFLTR Voltage....................................... –0.3V to 2.7V

FCB, STBYMD Voltages........................ –0.3V to INTV

SSOP Only........................................................ 300°C

CC

pin conFiguraTion

TOP VIEW

1

2

BOOST1

TG1

24

23

22

21

20

19

18

17

16

15

14

13

PGOOD

SS

32 31 30 29 28 27 26 25

+

SENSE

I

1

2

3

4

5

6

7

8

24 SW1

3

SW1

SENSE

–

23

V

IN

4

V

IN

SENSE

EXTV

INTV

22

TH

CC

5

EXTV

CC

I

TH

V

21

OSENSE

SGND

CC

6

INTV

CC

V

OSENSE

SGND

33

20 BG1

7

BG1

RUN

FCB

PGND

19

8

PGND

BG2

RUN

FCB

18 BG2

17 SW2

9

PLLFTR

10

11

12

SW2

PLLFLTR

PLLIN

9

10 11 12 13 14 15 16

TG2

BOOST2

STBYMD

G PACKAGE

24-LEAD PLASTIC SSOP

UH PACKAGE

32-LEAD (5mm × 5mm) PLASTIC QFN

T

= 125°C, θ = 130°C/W

JA

JMAX

T

= 125°C, θ = 34°C/W

JMAX JA

EXPOSED PAD (PIN 33) IS SGND, MUST BE SOLDERED TO PCB

3780ff

2

For more information www.linear.com/LTC3780

LTC3780

orDer inForMaTion

LEAD FREE FINISH

LTC3780EG#PBF

LTC3780IG#PBF

LTC3780EUH#PBF

LTC3780IUH#PBF

LEAD BASED FINISH

LTC3780EG

TAPE AND REEL

LTC3780EG#TRPBF

LTC3780IG#TRPBF

LTC3780EUH#TRPBF

LTC3780IUH#TRPBF

TAPE AND REEL

LTC3780EG#TR

PART MARKING

LTC3780EG

LTC3780IG

3780

PACKAGE DESCRIPTION

TEMPERATURE RANGE

–40°C to 85°C

24-Lead Plastic SSOP

–40°C to 125°C

–40°C to 85°C

32-Lead (5mm × 5mm) Plastic QFN

PACKAGE DESCRIPTION

3780I

–40°C to 125°C

TEMPERATURE RANGE

–40°C to 85°C

PART MARKING

LTC3780EG

LTC3780IG

LTC3780MPG

3780

24-Lead Plastic SSOP

LTC3780IG

LTC3780IG#TR

24-Lead Plastic SSOP

–40°C to 125°C

–55°C to 125°C

–40°C to 85°C

LTC3780MPG

LTC3780MPG#TR

LTC3780EUH#TR

LTC3780IUH#TR

24-Lead Plastic SSOP

LTC3780EUH

32-Lead (5mm × 5mm) Plastic QFN

LTC3780IUH

3780I

–40°C to 125°C

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

For more information on lead free part marking, go to: http://www.linear.com/leadfree/

For more information on tape and reel speciﬁcations, go to: http://www.linear.com/tapeandreel/

elecTrical characTerisTics ^Thel denotes the speciﬁcations which apply over the full operating

junction temperature range, otherwise speciﬁcations are at T_A= 25°C. (Note 7) V_IN= 15V unless otherwise noted.

SYMBOL

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

Main Control Loop

l

V

Feedback Reference Voltage

I

= 1.2V, –40°C ≤ T ≤ 85°C (Note 3)

TH

0.792

0.800

0.808

0.811

V

OSENSE

–55°C ≤ T ≤ 125°C

I

Feedback Pin Input Current

(Note 3)

–5

–50

nA

VOSENSE

V

Output Voltage Load Regulation

(Note 3)

LOADREG

l

∆I = 1.2V to 0.7V

0.1

–0.1

0.5

–0.5

%

TH

∆I = 1.2V to 1.8V

TH

V

Reference Voltage Line Regulation

Error Ampliﬁer Transconductance

Error Ampliﬁer GBW

V

= 4V to 30V, I = 1.2V (Note 3)

0.002

0.32

0.6

0.02

%/V

mS

REF(LINEREG)

m(EA)

IN

TH

g

I

= 1.2V, Sink/Source = 3µA (Note 3)

TH

(Note 8)

(Note 4)

MHz

m(GBW)

I

Q

Input DC Supply Current

Normal

2400

1500

55

µA

Standby

V

= 0V, V

> 2V

= Open

RUN

STBYMD

Shutdown Supply Current

70

V

Forced Continuous Threshold

Forced Continuous Pin Current

0.76

0.800

–0.18

5.3

0.84

–0.1

5.5

V

µA

V

FCB

I

V

= 0.85V

–0.30

FCB

V

Burst Inhibit (Constant Frequency)

Threshold

Measured at FCB Pin

BINHIBIT

l

UVLO

Undervoltage Reset

V

Falling

3.8

0.86

–380

0.7

4

V

IN

V

OVL

Feedback Overvoltage Lockout

Sense Pins Total Source Current

Start-Up Threshold

Measured at V

0.84

0.4

0.88

OSENSE

+

–

I

V

= V = 0V

SENSE

µA

V

SENSE

V

Rising

STBYMD(START)

STBYMD(KA)

STBYMD

Keep-Alive Power-On Threshold

Rising, V

= 0V

1.25

V

RUN

3780ff

For more information www.linear.com/LTC3780

3

LTC3780

elecTrical characTerisTics ^Thel denotes the speciﬁcations which apply over the full operating

junction temperature range, otherwise speciﬁcations are at T_A= 25°C. (Note 7) V_IN= 15V unless otherwise noted.

SYMBOL

PARAMETER

CONDITIONS

MIN

TYP

99

MAX

UNITS

%

DF MAX, Boost

DF MAX, Buck

Maximum Duty Factor

RUN Pin On Threshold

Soft-Start Charge Current

Maximum Current Sense Threshold

% Switch C On

% Switch A On (in Dropout)

99

%

V

Rising

= 2V

1

1.5

1.2

2

V

RUN(ON)

RUN

I

SS

0.5

µA

l

V

Boost: V

= V – 50mV

REF

120

–95

160

–110

185

–150

mV

SENSE(MAX)

OSENSE

REF

Buck: V

= V – 50mV

V

Minimum Current Sense Threshold

TG Rise Time

Discontinuous Mode

–6

50

45

55

80

mV

ns

SENSE(MIN,BUCK)

TG1, TG2 t

C

= 3300pF (Note 5)

= 3300pF Each Driver

r

f

LOAD

TG Fall Time

BG1, BG2 t

BG Rise Time

r

BG Fall Time

f

TG1/BG1 t

BG1/TG1 t

TG2/BG2 t

BG2/TG2 t

Mode

TG1 Off to BG1 On Delay,

Switch C On Delay

1D

BG1 Off to TG1 On Delay,

Synchronous Switch D On Delay

C

= 3300pF Each Driver

80

ns

2D

3D

4D

LOAD

TG2 Off to BG2 On Delay,

Synchronous Switch B On Delay

BG2 Off to TG2 On Delay,

Switch A On Delay

80

BG1 Off to BG2 On Delay,

Switch A On Delay

250

200

180

Transition 1

Mode

Transition 2

BG2 Off to BG1 On Delay,

Synchronous Switch D On Delay

t

Minimum On-Time for Main Switch in

Boost Operation

Switch C (Note 6)

Switch B (Note 6)

ON(MIN,BOOST)

ON(MIN,BUCK)

t

Minimum On-Time for Synchronous

Switch in Buck Operation

Internal V Regulator

CC

l

V

Internal V Voltage

7V < V < 30V, V = 5V

EXTVCC

5.7

5.4

6

6.3

2

V

%

INTVCC

CC

IN

Internal V Load Regulation

I

CC

I

CC

= 0mA to 20mA, V = 5V

EXTVCC

0.2

5.7

300

150

∆V

CC

LDO(LOADREG)

V

EXTV Switchover Voltage

= 20mA, V

Rising

V

EXTVCC

CC

EXTVCC

EXTV Switchover Hysteresis

mV

∆V

CC

EXTVCC(HYS)

EXTV Switch Drop Voltage

I

CC

= 20mA, V

= 6V

300

CC

EXTVCC

Oscillator and Phase-Locked Loop

f

Nominal Frequency

V

= 1.2V

= 0V

260

170

340

300

200

400

50

330

220

440

kHz

kΩ

NOM

LOW

HIGH

PLLFLTR

Lowest Frequency

Highest Frequency

= 2.4V

R

PLLIN Input Resistance

Phase Detector Output Current

PLLIN

I

f

< f

> f

–15

15

µA

PLLLPF

PLLIN

OSC

(Note 9)

3780ff

4

For more information www.linear.com/LTC3780

LTC3780

elecTrical characTerisTics ^Thel denotes the speciﬁcations which apply over the full operating

junction temperature range, otherwise speciﬁcations are at T_A= 25°C. (Note 7) V_IN= 15V unless otherwise noted.

SYMBOL

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

PGOOD Output

PGOOD Upper Threshold

PGOOD Lower Threshold

PGOOD Hysteresis

V

Rising

5.5

7.5

–7.5

2.5

10

%

V

∆V

OSENSE

FBH

Falling

–5.5

–10

∆V

FBL

Returning

∆V

FB(HYST)

V

PGL

PGOOD Low Voltage

I

= 2mA

= 5V

0.1

0.3

1

PGOOD

I

PGOOD Leakage Current

V

µA

PGOOD

Note 1: Stresses beyond those listed under Absolute Maximum Ratings

may cause permanent damage to the device. Exposure to any Absolute

Maximum Rating condition for extended periods may affect device

reliability and lifetime.

Note 6: The minimum on-time condition is speciﬁed for an inductor

peak-to-peak ripple current ≥ 40% of I (see minimum on-time

considerations in the Applications Information section).

MAX

Note 7: The LTC3780 is tested under pulsed load conditions such that T ≈

J

Note 2: T for the QFN package is calculated from the temperature T and

T . The LTC3780E is guaranteed to meet speciﬁcations from 0°C to 85°C

A

J

A

power dissipation P according to the following formula:

junction temperature. Speciﬁcations over the –40°C to 85°C operating

junction temperature range are assured by design, characterization and

correlation with statistical process controls. The LTC3780I is guaranteed

over the –40°C to 125°C operating junction temperature range, and

the LTC3780MP is tested and guaranteed over the full –55°C to 125°C

operating junction temperature range.

D

T = T + (P • 34°C/W)

J

A

D

Note 3: The IC is tested in a feedback loop that servos V to a speciﬁed

ITH

voltage and measures the resultant V

.

OSENSE

Note 4: Dynamic supply current is higher due to the gate charge being

delivered at the switching frequency.

Note 5: Rise and fall times are measured using 10% and 90% levels. Delay

times are measured using 50% levels.

Note 8: This parameter is guaranteed by design.

Note 9: f

is the running frequency for the application.

OSC

3780ff

For more information www.linear.com/LTC3780

5

LTC3780

Typical perForMance characTerisTics ^T_A^{= 25°C, unless otherwise noted.}

Efﬁciency vs Output Current

(Boost Operation)

Efﬁciency vs Output Current

(Buck Operation)

100

90

80

70

60

50

40

100

90

80

70

60

50

40

100

90

80

70

60

50

40

BURST

DCM

SC

DCM

CCM

DCM

CCM

V

= 12V

V

= 18V

V

= 6V

IN

OUT

IN

OUT

IN

OUT

= 12V

0.01

0.1

1

10

0.01

0.1

1

10

0.01

0.1

1

10

I

(A)

I

(A)

LOAD

I

(A)

LOAD

3780 G02

3780 G03

3780 G01

Supply Current vs Input Voltage

Internal 6V LDO Line Regulation

EXTV_CCVoltage Drop

2500

2000

1500

1000

500

6.5

6.0

5.5

5.0

120

100

V

= 0V

FCB

STANDBY

80

60

4.5

4.0

3.5

40

20

0

SHUTDOWN

0

5

10

15

20

25

30

35

20

INPUT VOLTAGE (V)

30

35

0

5

10

15

25

0

10

20

30

40

50

INPUT VOLTAGE (V)

CURRENT (mA)

3780 G04

3780 G05

3780 G06

INTV_CCand EXTV_CCSwitch

Voltage vs Temperature

EXTV_CCSwitch Resistance

vs Temperature

Load Regulation

6.05

6.00

5.95

5.90

5.85

5.80

5.75

5.70

5.65

5.60

5.55

5

4

3

2

1

0

–0.1

–0.2

–0.3

–0.4

–0.5

V

= 18V

IN

INTV VOLTAGE

CC

V

IN

= 12V

V

IN

= 6V

EXTV SWITCHOVER THRESHOLD

CC

FCB = 0V

V

OUT

= 12V

–75 –50

0

25 50 75 100 125

–75 –50 –25

0

25 50 75 100 125

–25

0

1

2

3

4

5

TEMPERATURE (°C)

LOAD CURRENT (A)

3780 G07

3780 G08

3780 G09

3780ff

6

For more information www.linear.com/LTC3780

LTC3780

T_A= 25°C, unless otherwise noted.

Typical perForMance characTerisTics

Continuous Current Mode

(CCM, V_IN= 6V, V_OUT= 12V)

Continuous Current Mode

(CCM, V_IN= 12V, V_OUT= 12V)

Continuous Current Mode

(CCM, V_IN= 18V, V_OUT= 12V)

SW2

10V/DIV

SW2

10V/DIV

SW2

10V/DIV

SW1

10V/DIV

SW1

10V/DIV

SW1

10V/DIV

V

OUT

V

OUT

V

100mV/DIV

OUT

100mV/DIV

I

L

2A/DIV

3780 G10

3780 G11

3780 G12

V

= 6V

5µs/DIV

V

= 12V

5µs/DIV

IN

OUT

V

= 18V

5µs/DIV

IN

OUT

IN

OUT

= 12V

Burst Mode Operation

(V_IN= 6V, V_OUT= 12V)

Burst Mode Operation

(V_IN= 12V, V_OUT= 12V)

Skip-Cycle Mode

(V_IN= 18V, V_OUT= 12V)

SW2

10V/DIV

SW2

10V/DIV

SW2

10V/DIV

SW1

10V/DIV

SW1

10V/DIV

SW1

10V/DIV

V

OUT

V

OUT

500mV/DIV

200mV/DIV

100mV/DIV

I

L

I

L

2A/DIV

I

L

1A/DIV

3780 G14

3780 G15

3780 G13

V

= 12V

10µs/DIV

V

= 18V

2.5µs/DIV

V

= 6V

25µs/DIV

IN

OUT

IN

OUT

IN

OUT

= 12V

Discontinuous Current Mode

(DCM, V_IN= 6V, V_OUT= 12V)

Discontinuous Current Mode

(DCM, V_IN= 12V, V_OUT= 12V)

Discontinuous Current Mode

(DCM, V_IN= 18V, V_OUT= 12V)

SW2

10V/DIV

SW2

10V/DIV

SW2

10V/DIV

SW1

10V/DIV

SW1

10V/DIV

SW1

10V/DIV

V

OUT

V

OUT

100mV/DIV

I

L

1A/DIV

I

L

1A/DIV

2A/DIV

3780 G17

3780 G18

3780 G16

V

= 12V

5µs/DIV

V

= 18V

2.5µs/DIV

V

= 6V

5µs/DIV

IN

OUT

IN

OUT

IN

OUT

= 12V

3780ff

For more information www.linear.com/LTC3780

7

LTC3780

T_A= 25°C, unless otherwise noted.

Typical perForMance characTerisTics

Oscillator Frequency

vs Temperature

Undervoltage Reset

vs Temperature

Minimum Current Sense

Threshold vs Duty Factor (Buck)

–20

4.2

4.0

3.8

3.6

3.4

3.2

3.0

450

400

350

300

250

200

150

100

50

V

= 2.4V

= 1.2V

PLLFLTR

–40

–60

–80

V

= 0V

PLLFLTR

0

–75 –50 –25

0

25 50 75 100 125

100

80

60

40

20

0

–75 –50 –25

0

25

125

50 75 100

TEMPERATURE (°C)

DUTY FACTOR (%)

TEMPERATURE (°C)

3780 G20

3780 G21

3780 G19

Maximum Current Sense

Threshold vs Duty Factor (Boost)

Maximum Current Sense

Threshold vs Duty Factor (Buck)

Minimum Current Sense

Threshold vs Temperature

200

150

180

160

140

120

100

140

130

120

110

BOOST

100

50

0

–50

–100

BUCK

–150

50

TEMPERATURE (°C)

100 125

–75 –50 –25

0

25

75

0

20

40

60

80

100

0

20

40

60

80

100

DUTY FACTOR (%)

3780 G24

3780 G22

3780 G23

Peak Current Threshold

vs V_ITH(Boost)

Valley Current Threshold

vs V_ITH(Buck)

Current Foldback Limit

200

150

100

50

100

50

200

160

120

80

BOOST

BUCK

0

–50

0

–100

–150

40

0

–50

–100

0

0.8

1.2

(V)

1.6

1.8

2.4

0

0.8

1.2

(V)

1.6

2.0

2.4

0.4

0

0.2

0.4

0.6

0.8

V

(V)

ITH

OSENSE

3780 G32

3780 G25

3780 G26

3780ff

8

For more information www.linear.com/LTC3780

LTC3780

T_A= 25°C, unless otherwise noted.

Typical perForMance characTerisTics

Load Step

V

OUT

500mV/DIV

OUT

500mV/DIV

I

L

I

5A/DIV

I

L

5A/DIV

3780 G28

3780 G29

3780 G27

V

= 12V

200µs/DIV

V

= 6V

200µs/DIV

V

= 18V

200µs/DIV

IN

OUT

IN

OUT

IN

OUT

= 12V

LOAD STEP: 0A TO 5A

CONTINUOUS MODE

LOAD STEP: 0A TO 5A

CONTINUOUS MODE

LOAD STEP: 0A TO 5A

CONTINUOUS MODE

Line Transient

V

IN

V

IN

10V/DIV

V

OUT

V

OUT

500mV/DIV

I

L

1A/DIV

3780 G30

3780 G31

V

I

= 12V

= 1A

500µs/DIV

V

I

= 12V

= 1A

500µs/DIV

OUT

LOAD

IN

OUT

LOAD

IN

V

STEP: 7V TO 20V

V

STEP: 20V TO 7V

CONTINUOUS MODE

3780ff

For more information www.linear.com/LTC3780

9

LTC3780

pin FuncTions ^(SSOP/QFN)

PGOOD (Pin 1/Pin 30): Open-Drain Logic Output. PGOOD

is pulled to ground when the output voltage is not within

7.5% of the regulation point.

operation. When the pin is tied to INTV , the constant

CC

frequency discontinuous current mode is active in buck

or boost operation.

SS (Pin 2/Pin 31): Soft-start reduces the input power

sources’ surge currents by gradually increasing the

controller’s current limit. A minimum value of 6.8nF is

recommended on this pin.

PLLFLTR (Pin 10/Pin 8): The phase-locked loop’s

lowpass ﬁlter is tied to this pin. Alternatively, this pin can

be driven with an AC or DC voltage source to vary the

frequency of the internal oscillator.

+

SENSE (Pin 3/Pin 1): The (+) Input to the Current Sense

PLLIN (Pin 11/Pin 10): External Synchronization Input to

Phase Detector. This pin is internally terminated to SGND

with 50kΩ. The phase-locked loop will force the rising

bottom gate signal of the controller to be synchronized

with the rising edge of the PLLIN signal.

andReverseCurrentDetectComparators.TheI pinvolt-

TH

–

+

ageandbuilt-inoffsetsbetweenSENSE andSENSE pins,

in conjunction with R

, set the current trip threshold.

SENSE

–

SENSE (Pin 4/Pin 2): The (–) Input to the Current Sense

and Reverse Current Detect Comparators.

STBYMD (Pin 12/Pin 11): LDO Control Pin. Determines

whethertheinternalLDOremainsactivewhenthecontrol-

ler is shut down. See Operation section for details. If the

STBYMD pin is pulled to ground, the SS pin is internally

pulled to ground, preventing start-up and thereby provid-

ing a single control pin for turning off the controller. To

keep the LDO active when RUN is low, for example to

power a “wake up” circuit which controls the state of the

RUN pin, bypass STBYMD to signal ground with a 0.1µF

I

(Pin 5/Pin 3): Current Control Threshold and Error

TH

Ampliﬁer Compensation Point. The current comparator

threshold increases with this control voltage. The voltage

ranges from 0V to 2.4V.

V

(Pin 6/Pin 4): Error Ampliﬁer Feedback Input.

OSENSE

This pin connects the error ampliﬁer input to an external

resistor divider from V

.

OUT

capacitor, or use a resistor divider from V to keep the

IN

SGND(Pin7/Pin5,ExposedPadPin33):SignalGround.All

small-signalcomponentsandcompensationcomponents

shouldconnecttothisground,whichshouldbeconnected

to PGND at a single point. The QFN exposed pad must be

solderedtoPCBgroundforelectricalconnectionandrated

thermal performance.

pin within 2V to 5V.

BOOST2, BOOST1 (Pins 13, 24/Pins 14, 27): Boosted

Floating Driver Supply. The (+) terminal of the bootstrap

capacitorC andC (Figure11)connectshere.TheBOOST2

A

B

pin swings from a diode voltage below INTV up to V

CC

IN

+ INTV . The BOOST1 pin swings from a diode voltage

CC

RUN (Pin 8/Pin 6): Run Control Input. Forcing the RUN

pin below 1.5V causes the IC to shut down the switching

regulator circuitry. There is a 100k resistor between the

RUN pin and SGND in the IC. Do not apply >6V to this pin.

below INTV up to V

+ INTV .

CC

OUT

CC

TG2,TG1(Pins14,23/Pins15,26):TopGateDrive.Drives

the top N-channel MOSFET with a voltage swing equal to

INTV superimposed on the switch node voltage SW.

CC

FCB (Pin 9/Pin 7): Forced Continuous Control Input. The

voltage applied to this pin sets the operating mode of the

controller. When the applied voltage is less than 0.8V, the

forced continuous current mode is active. When this pin

is allowed to ﬂoat, the Burst Mode operation is active in

boost operation and the skip-cycle mode is active in buck

SW2,SW1(Pins15,22/Pins17,24):SwitchNode.The(–)

terminal of the bootstrap capacitor C and C (Figure 11)

A

B

connectshere. TheSW2pinswingsfromaSchottkydiode

(external) voltage drop below ground up to V . The SW1

IN

pin swings from a Schottky diode (external) voltage drop

below ground up to V

.

OUT

3780ff

10

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LTC3780

pin FuncTions ^(SSOP/QFN)

BG2, BG1 (Pins 16, 18/Pins 18, 20): Bottom Gate Drive.

EXTV (Pin 20/Pin 22): External V Input. When EXT-

CC CC

CC

Drives the gate of the bottom N-channel MOSFET between

V

exceeds 5.7V, an internal switch connects this pin to

ground and INTV .

INTV and shuts down the internal regulator so that the

CC

controller and gate drive power is drawn from EXTV . Do

CC

PGND (Pin 17/Pin 19): Power Ground. Connect this pin

not exceed 7V at this pin and ensure that EXTV < V .

CC

IN

closelytothesourceofthebottomN-channelMOSFET,the

(–)terminalofC andthe(–)terminalofC (Figure11).

V (Pin 21/Pin 23): Main Input Supply. Bypass this pin

VCC

IN

to SGND with an RC ﬁlter (1Ω, 0.1µF).

INTV (Pin19/Pin21):Internal6VRegulatorOutput. The

CC

driver and control circuits are powered from this voltage.

Bypass this pin to ground with a minimum of 4.7µF low

ESR tantalum or ceramic capacitor.

3780ff

For more information www.linear.com/LTC3780

11

LTC3780

block DiagraM

INTV

CC

V

IN

BOOST2

TG2

STBYMD

FCB

I

LIM

SW2

+

–

BUCK

LOGIC

INTV

CC

BG2

R

SENSE

PGND

BG1

I

REV

+

–

FCB

INTV

CC

BOOST

LOGIC

SW1

TG1

1.2V

4(V

)

FB

I

CMP

+

–

BOOST1

0.86V

1.2µA

OV

EA

SS

–

+

INTV

CC

V

OUT

RUN

SLOPE

V

OSENSE

100k

–

+

V

FB

0.80V

I

TH

SHDN

RST

FB

RUN/

SS

4(V

)

+

SENSE

–

SENSE

PLLIN

50k

V

REF

F

IN

PHASE DET

V

IN

V

IN

+

–

5.7V

PLLFLTR

CLK

R

LP

OSCILLATOR

6V

LDO

REG

C

LP

EXTV

INTV

CC

–

+

0.86V

6V

+

CC

PGOOD

INTERNAL

SUPPLY

SGND

V

OSENSE

–

+

0.74V

3780 BD

3780ff

12

For more information www.linear.com/LTC3780

LTC3780

operaTion

MAIN CONTROL LOOP

V

OUT

IN

The LTC3780 is a current mode controller that provides an

output voltage above, equal to or below the input voltage.

TheLTCproprietarytopologyandcontrolarchitectureem-

ploys a current-sensing resistor in buck or boost modes.

The sensed inductor current is controlled by the voltage

TG2

BG2

A

D

TG1

BG1

L

SW2

SW1

B

C

R

SENSE

on the I pin, which is the output of the ampliﬁer EA. The

TH

3780 F01

V

pin receives the voltage feedback signal, which

OSENSE

Figure 1. Simpliﬁed Diagram of the Output Switches

is compared to the internal reference voltage by the EA.

The top MOSFET drivers are biased from ﬂoating boost-

strapcapacitorsC andC (Figure11), whicharenormally

98%

MAX

BOOST

D

A

B

A ON, B OFF

rechargedthroughanexternaldiodewhenthetopMOSFET

is turned off. Schottky diodes across the synchronous

switch D and synchronous switch B are not required, but

provide a lower drop during the dead time. The addition of

the Schottky diodes will typically improve peak efﬁciency

by 1% to 2% at 400kHz.

BOOST REGION

PWM C, D SWITCHES

D

MIN

BOOST

FOUR SWITCH PWM

BUCK/BOOST REGION

BUCK REGION

D

MAX

BUCK

D ON, C OFF

PWM A, B SWITCHES

3%

MIN

BUCK

D

3780 F02

The main control loop is shut down by pulling the RUN

pin low. When the RUN pin voltage is higher than 1.5V, an

internal 1.2µA current source charges soft-start capacitor

Figure 2. Operating Mode vs Duty Cycle

C

at the SS pin. The I voltage is then clamped to the

SS

TH

and switch A is turned on for the remainder of the cycle.

switches A and B will alternate, behaving like a typical

synchronous buck regulator. The duty cycle of switch A

increases until the maximum duty cycle of the converter

SS voltage while C is slowly charged during start-up.

SS

This “soft-start” clamping prevents abrupt current from

being drawn from the input power supply.

in buck mode reaches D , given by:

MAX_BUCK

POWER SWITCH CONTROL

D

= 100% – D

BUCK-BOOST

MAX_BUCK

Figure 1 shows a simpliﬁed diagram of how the four

where D

range:

= duty cycle of the buck-boost switch

BUCK-BOOST

power switches are connected to the inductor, V , V

IN OUT

and GND. Figure 2 shows the regions of operation for the

LTC3780asafunctionofdutycycleD. Thepowerswitches

are properly controlled so the transfer between modes is

D

= (200ns • f) • 100%

BUCK-BOOST

and f is the operating frequency in Hz.

continuous. When V approaches V , the buck-boost

IN

OUT

Figure 3 shows typical buck mode waveforms. If V

region is reached; the mode-to-mode transition time is

IN

approaches V , the buck-boost region is reached.

typically 200ns.

OUT

Buck-Boost (V @ V

)

Buck Region (V > V

)

IN

OUT

IN

OUT

When V is close to V , the controller is in buck-boost

Switch D is always on and switch C is always off during

this mode. At the start of every cycle, synchronous switch

B is turned on ﬁrst. Inductor current is sensed when

synchronous switch B is turned on. After the sensed in-

ductor current falls below the reference voltage, which is

IN

OUT

mode. Figure 4 shows typical waveforms in this mode.

Every cycle, if the controller starts with switches B and D

turned on, switches A and C are then turned on. Finally,

switches A and D are turned on for the remainder of the

time. If the controller starts with switches A and C turned

proportional to V , synchronous switch B is turned off

ITH

3780ff

For more information www.linear.com/LTC3780

13

LTC3780

operaTion

of the cycle. switches C and D will alternate, behaving like

a typical synchronous boost regulator.

CLOCK

SWITCH A

SWITCH B

ThedutycycleofswitchCdecreasesuntiltheminimumduty

cycle of the converter in boost mode reaches D

given by:

,

MIN_BOOST

0V

SWITCH C

SWITCH D

HIGH

D

= D

MIN_BOOST

BUCK-BOOST

I

L

where D

is the duty cycle of the buck-boost

3780 F03

BUCK-BOOST

switch range:

Figure 3. Buck Mode (V_IN> V_OUT

)

D

= (200ns • f) • 100%

BUCK-BOOST

and f is the operating frequency in Hz.

CLOCK

Figure 5 shows typical boost mode waveforms. If V ap-

SWITCH A

IN

proaches V , the buck-boost region is reached.

OUT

SWITCH B

SWITCH C

SWITCH D

CLOCK

HIGH

0V

SWITCH A

SWITCH B

I

L

3780 F04a

SWITCH C

SWITCH D

(4a) Buck-Boost Mode (V_IN≥ V_OUT

)

I

L

CLOCK

3780 F05

SWITCH A

SWITCH B

Figure 5. Boost Mode (V_IN< V_OUT

)

LOW CURRENT OPERATION

SWITCH C

SWITCH D

The FCB pin is used to select among three modes for both

buck and boost operations by accepting a logic input.

Figure 6 shows the different modes.

I

L

3780 F04b

FCB PIN

0V to 0.75V

0.85V to 5V

>5.3V

BUCK MODE

BOOST MODE

(4b) Buck-Boost Mode (V_IN≤ V_OUT

)

Force Continuous Mode

Skip-Cycle Mode

Force Continuous Mode

Burst Mode Operation

DCM with Constant Freq

Figure 4. Buck-Boost Mode

DCM with Constant Freq

on, switches B and D are then turned on. Finally, switches

A and D are turned on for the remainder of the time.

Figure 6. Different Operating Modes

When the FCB pin voltage is lower than 0.8V, the controller

behavesasacontinuous,PWMcurrentmodesynchronous

switching regulator. In boost mode, switch A is always on.

switch C and synchronous switch D are alternately turned

on to maintain the output voltage independent of direction

of inductor current. Every ten cycles, switch A is forced off

Boost Region (V < V

)

OUT

IN

Switch A is always on and synchronous switch B is always

off in boost mode. Every cycle, switch C is turned on ﬁrst.

Inductor current is sensed when switch C is turned on.

After the sensed inductor current exceeds the reference

voltagewhichisproportionaltoV ,switchCisturnedoff

and synchronous switch D is turned on for the remainder

for about 300ns to allow boost capacitor C (Figure 13) to

A

ITH

recharge. In buck mode, synchronous switch D is always

3780ff

14

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LTC3780

operaTion

on. switch A and synchronous switch B are alternately

turned on to maintain the output voltage independent of

direction of inductor current. Every ten cycles, synchro-

controller will enter continuous current buck mode for

one cycle to discharge inductor current. In the following

cycle, thecontrollerwillresumeDCMboostoperation. For

buckoperation,constantfrequencydiscontinuouscurrent

mode sets a minimum negative inductor current level.

synchronous switch B is turned off whenever inductor

current is lower than this level. At very light loads, this

constant frequency operation is not as efﬁcient as Burst

Mode operation or skip-cycle, but does provide lower

noise, constant frequency operation.

nous switch D is forced off for about 300ns to allow C

B

to recharge. This is the least efﬁcient operating mode at

light load, but may be desirable in certain applications. In

this mode, the output can source or sink current.

WhentheFCBpinvoltageisbelowV

–1V,butgreater

INTVCC

than 0.8V, the controller enters Burst Mode operation in

boost operation or enters skip-cycle mode in buck opera-

tion. During boost operation, Burst Mode operation sets a

minimum output current level before inhibiting the switch

C and turns off synchronous switch D when the inductor

current goes negative. This combination of requirements

FREQUENCY SYNCHRONIzATION AND

FREQUENCY SETUP

The phase-locked loop allows the internal oscillator to be

synchronized to an external source via the PLLIN pin. The

phase detector output at the PLLFLTR pin is also the DC

frequency control input of the oscillator. The frequency

ranges from 200kHz to 400kHz, corresponding to a DC

voltage input from 0V to 2.4V at PLLFLTR. When locked,

the PLL aligns the turn on of the top MOSFET to the ris-

ing edge of the synchronizing signal. When PLLIN is left

open, the PLLFLTR pin goes low, forcing the oscillator to

its minimum frequency.

will, at low currents, force the I pin below a voltage

TH

threshold that will temporarily inhibit turn-on of power

switches C and D until the output voltage drops. There is

100mV of hysteresis in the burst comparator tied to the

I

pin. This hysteresis produces output signals to the

TH

MOSFETs C and D that turn them on for several cycles,

followed by a variable “sleep” interval depending upon the

loadcurrent.Themaximumoutputvoltagerippleislimited

to 3% of the nominal DC output voltage as determined

by a resistive feedback divider. During buck operation at

no load, switch A is turned on for its minimum on-time.

This will not occur every clock cycle when the output load

current drops below 1% of the maximum designed load.

The body diode of synchronous switch B or the Schottky

diode, which is in parallel with switch B, is used to dis-

charge the inductor current; switch B only turns on every

INTV /EXTV Power

CC

Power for all power MOSFET drivers and most inter-

nal circuitry is derived from the INTV pin. When the

CC

EXTV pin is left open, an internal 6V low dropout linear

CC

regulator supplies INTV power. If EXTV is taken above

CC

5.7V, the 6V regulator is turned off and an internal switch

ten clock cycles to allow C to recharge. As load current

B

is turned on, connecting EXTV to INTV . This allows

CC

is applied, switch A turns on every cycle, and its on-time

begins to increase. At higher current, switch B turns on

brieﬂy after each turn-off of switch A. switches C and D

remain off at light load, except to refresh CA (Figure 11)

every 10 clock cycles. In Burst Mode operation/skip-cycle

mode, the output is prevented from sinking current.

the INTV power to be derived from a high efﬁciency

CC

external source.

POWER GOOD (PGOOD) PIN

ThePGOODpinisconnectedtoanopendrainofaninternal

MOSFET. TheMOSFETturnsonandpullsthepinlowwhen

the output is not within 7.5% of the nominal output level

as determined by the resistive feedback divider. When

the output meets the 7.5% requirement, the MOSFET

is turned off and the pin is allowed to be pulled up by an

external resistor to a source of up to 7V.

When the FCB pin voltage is tied to the INTV pin, the

CC

controllerentersconstantfrequencydiscontinuouscurrent

mode (DCM). For boost operation, synchronous switch D

is held off whenever the I pin is below a threshold volt-

TH

age. In every cycle, switch C is used to charge inductor

current. After the output voltage is high enough, the

3780ff

For more information www.linear.com/LTC3780

15

LTC3780

operaTion

FOLDBACK CURRENT

SHORT-CIRCUIT PROTECTION AND CURRENT LIMIT

Foldback current limiting is activated when the output

voltage falls below 70% of its nominal level, reducing

power waste. During start-up, foldback current limiting

is disabled.

SwitchAon-timeislimitedbyoutputvoltage.Whenoutput

voltage is reduced and is lower than its nominal level,

switch A on-time will be reduced.

In every boost mode cycle, current is limited by a voltage

reference, which is proportional to the I pin voltage. The

TH

INPUT UNDERVOLTAGE RESET

maximum sensed current is limited to 160mV. In every

buck mode cycle, the maximum sensed current is limited

to 130mV.

The SS capacitor will be reset if the input voltage is al-

lowed to fall below approximately 4V. The SS capacitor

will attempt to charge through a normal soft-start ramp

after the input voltage rises above 4V.

STANDBY MODE PIN

TheSTBYMDpinisathree-stateinputthatcontrolscircuitry

within the IC as follows: When the STBYMD pin is held at

ground, the SS pin is pulled to ground. When the pin is

left open, the internal SS current source charges the SS

capacitor, allowing turn-on of the controller and activat-

ing necessary internal biasing. When the STBYMD pin is

taken above 2V, the internal linear regulator is turned on

independentofthestateontheRUNandSSpins,providing

an output power source for “wake-up” circuitry. Bypass

the pin with a small capacitor (0.1µF) to ground if the pin

is not connected to a DC potential.

OUTPUT OVERVOLTAGE PROTECTION

An overvoltage comparator guards against transient over-

shoots (>7.5%) as well as other more serious conditions

thatmayovervoltagetheoutput.Inthiscase,synchronous

switch B and synchronous switch D are turned on until the

overvoltage condition is cleared or the maximum negative

current limit is reached. When inductor current is lower

than the maximum negative current limit, synchronous

switch B and synchronous switch D are turned off, and

switch A and switch C are turned on until the inductor

current reaches another negative current limit. If the

comparator still detects an overvoltage condition, switch

A and switch C are turned off, and synchronous switch B

and synchronous switch D are turned on again.

3780ff

16

For more information www.linear.com/LTC3780

LTC3780

applicaTions inForMaTion

Figure 11 is a basic LTC3780 application circuit. External

component selection is driven by the load requirement,

Inductor Selection

The operating frequency and inductor selection are inter-

relatedinthathigheroperatingfrequenciesallowtheuseof

smaller inductor and capacitor values. The inductor value

has a direct effect on ripple current. The inductor current

and begins with the selection of R

and the inductor

SENSE

value. Next, the power MOSFETs are selected. Finally, C

IN

and C

are selected. This circuit can be conﬁgured for

OUT

operation up to an input voltage of 36V.

ripple ∆I is typically set to 20% to 40% of the maximum

L

inductor current at boost mode V

. For a given ripple

IN(MIN)

Selection of Operation Frequency

the inductance terms in continuous mode are as follows:

The LTC3780 uses a constant frequency architecture and

has an internal voltage controlled oscillator. The switching

frequencyisdeterminedbytheinternaloscillatorcapacitor.

This internal capacitor is charged by a ﬁxed current plus

an additional current that is proportional to the voltage

appliedtothePLLFLTRpin.Thefrequencyofthisoscillator

can be varied over a 2-to-1 range. The PLLFLTR pin can

be grounded to lower the frequency to 200kHz or tied to

2.4V to yield approximately 400kHz. When PLLIN is left

open, the PLLFLTR pin goes low, forcing the oscillator to

minimum frequency.

V

²• V_OUT– V

•100

(

)

IN(MIN)

L_BOOST

>

H,

2

ƒ •I_OUT(MAX)• %Ripple • V_OUT

V_OUT• V_IN(MAX)– V_OUT•100

(

)

L_BUCK

>

H

ƒ •I_OUT(MAX)• %Ripple • V

IN(MAX)

where:

f is operating frequency, Hz

% Ripple is allowable inductor current ripple, %

A graph for the voltage applied to the PLLFLTR pin vs

frequency is given in Figure 7. As the operating frequency

isincreasedthegatechargelosseswillbehigher, reducing

efﬁciency. The maximum switching frequency is approxi-

mately 400kHz.

V

I

is minimum input voltage, V

is maximum input voltage, V

is output voltage, V

IN(MIN)

IN(MAX)

OUT

is maximum output load current

OUT(MAX)

For high efﬁciency, choose an inductor with low core

loss, such as ferrite and molypermalloy (from Magnetics,

Inc.). Also, the inductor should have low DC resistance to

450

400

350

300

250

200

150

100

50

2

reduce the I R losses, and must be able to handle the peak

inductor current without saturation. To minimize radiated

noise, use a toroid, pot core or shielded bobbin inductor.

R

Selection and Maximum Output Current

SENSE

R

SENSE

is chosen based on the required output current.

The current comparator threshold sets the peak of the

inductorcurrentinboostmodeandthemaximuminductor

valleycurrentinbuckmode. Inboostmode, themaximum

0

2

2.5

0.5

1

1.5

PLLFLTR PIN VOLTAGE (V)

3780 F07

average load current at V

is:

IN(MIN)

Figure 7. Frequency vs PLLFLTR Pin Voltage

V





∆I_L

2

160mV

IN(MIN)

I_{OUT(MAX,BOOST)}

=

–

•





R

V_OUT





SENSE

3780ff

For more information www.linear.com/LTC3780

17

LTC3780

applicaTions inForMaTion

to handle the maximum RMS current. For buck operation,

the input RMS current is given by:

where ∆I is peak-to-peak inductor ripple current. In buck

L

mode, the maximum average load current is:

130mV ∆I_L

V_OUT

V

IN

V

IN

V_OUT

I_{OUT(MAX,BUCK)}

=

+

I_RMS≈I_OUT(MAX)

•

– 1

R_SENSE

2

Figure 8 shows how the load current (I

varies with input and output voltage

• R

)

SENSE

MAXLOAD

This formula has a maximum at V = 2V , where

IN

OUT

I

= I

/2. This simple worst-case condition

RMS

OUT(MAX)

is commonly used for design because even signiﬁcant

deviations do not offer much relief. Note that ripple cur-

rentratingsfromcapacitormanufacturersareoftenbased

on only 2000 hours of life which makes it advisable to

derate the capacitor.

The maximum current sensing R

mode is:

value for the boost

SENSE

R_SENSE(MAX)

=

2•160mV •V

IN(MIN)

2•I_{OUT(MAX,BOOST)}•V_OUT+ ∆I_L,BOOST•V

In boost mode, the discontinuous current shifts from the

IN(MIN)

input to the output, so C

must be capable of reducing

OUT

The maximum current sensing R

mode is:

value for the buck

the output voltage ripple. The effects of ESR (equivalent

series resistance) and the bulk capacitance must be

considered when choosing the right capacitor for a given

output ripple voltage. The steady ripple due to charging

and discharging the bulk capacitance is given by:

SENSE

2•130mV

2•I_{OUT(MAX,BUCK)}– ∆I_L,BUCK

R_SENSE(MAX)

=

The ﬁnal R

SENSE(MAX)

30% margin is usually recommended.

value should be lower than the calculated

I_OUT(MAX)• V

– V

IN(MIN)

SENSE

(

)

OUT

Ripple(Boost,Cap)=

Ripple(Buck,Cap)=

V

R

in both the boost and buck modes. A 20% to

C_OUT• V_OUT• f

I_OUT(MAX)• V_IN(MAX)– V

(

)

OUT

C and C Selection

IN

OUT

C_OUT• V_IN(MAX)• f

In boost mode, input current is continuous. In buck mode,

inputcurrentisdiscontinuous.Inbuckmode,theselection

of input capacitor C is driven by the need to ﬁlter the

input square wave current. Use a low ESR capacitor sized

where C

is the output ﬁlter capacitor.

OUT

IN

The steady ripple due to the voltage drop across the ESR

is given by:

160

∆V

= I

• ESR

L(MAX,BOOST)

BOOST,ESR

150

140

130

120

110

100

= I

• ESR

BUCK,ESR

L(MAX,BUCK)

Multiple capacitors placed in parallel may be needed to

meet the ESR and RMS current handling requirements.

Dry tantalum, special polymer, aluminum electrolytic and

ceramic capacitors are all available in surface mount

packages. Ceramic capacitors have excellent low ESR

characteristics but can have a high voltage coefﬁcient.

Capacitors are now available with low ESR and high ripple

current ratings, such as OS-CON and POSCAP.

0.1

1

10

V

/V

(V)

IN OUT

3780 F08

Figure 8. Load Current vs V_IN/V_OUT

3780ff

18

For more information www.linear.com/LTC3780

LTC3780

applicaTions inForMaTion

Power MOSFET Selection and

Efﬁciency Considerations

Switch B operates in buck mode as the synchronous

rectiﬁer. Its power dissipation at maximum output current

is given by:

TheLTC3780requiresfourexternalN-channelpowerMOS-

FETs, two for the top switches (switch A and D, shown in

Figure 1) and two for the bottom switches (switch B and C

shown in Figure 1). Important parameters for the power

V – V_OUT

IN

P

=

•I_OUT(MAX)²• ρ_T•R_DS(ON)

B,BUCK

V

IN

Switch C operates in boost mode as the control switch.

Its power dissipation at maximum current is given by:

MOSFETs are the breakdown voltage V

, threshold

BR,DSS

, reverse transfer

voltage V

, on-resistance R

GS,TH

DS(ON)

and maximum current I

capacitance C

.

RSS

DS(MAX)

The drive voltage is set by the 6V INTV supply. Con-

V

– V V

IN OUT

CC

(

)

OUT

P_C,BOOST

=

•I_OUT(MAX)²• ρ_T•R_DS(ON)

sequently, logic-level threshold MOSFETs must be used

in LTC3780 applications. If the input voltage is expected

to drop below 5V, then the sub-logic threshold MOSFETs

should be considered.

2

V

IN

I_OUT(MAX)

3

+ k • V_OUT

•

•C_RSS• f

V

IN

In order to select the power MOSFETs, the power dis-

sipated by the device must be known. For switch A, the

maximumpowerdissipationhappensinboostmode,when

it remains on all the time. Its maximum power dissipation

at maximum output current is given by:

whereC isusuallyspeciﬁedbytheMOSFETmanufactur-

RSS

ers. The constant k, which accounts for the loss caused

by reverse recovery current, is inversely proportional to

the gate drive current and has an empirical value of 1.7.

For switch D, the maximum power dissipation happens in

boost mode, when its duty cycle is higher than 50%. Its

maximum power dissipation at maximum output current

is given by:

 V_OUT

²



P_A,BOOST

=

•I • ρ_T•R_DS(ON)

_OUT(MAX)



 V

IN

where ρ is a normalization factor (unity at 25°C) ac-

T



²

V_OUT

V

V_OUT

counting for the signiﬁcant variation in on-resistance with

temperature,typicallyabout0.4%/°CasshowninFigure 9.

For a maximum junction temperature of 125°C, using a

IN

P_D,BOOST

=

•

•I_OUT(MAX)•ρ_T•R_DS(ON)







V



IN

For the same output voltage and current, switch A has the

highest power dissipation and switch B has the lowest

power dissipation unless a short occurs at the output.

value ρ = 1.5 is reasonable.

T

2.0

1.5

1.0

0.5

0

From a known power dissipated in the power MOSFET, its

junction temperature can be obtained using the following

formula:

T = T + P • R

J

A

TH(JA)

The R

to be used in the equation normally includes

TH(JA)

the R

for the device plus the thermal resistance from

TH(JC)

the case to the ambient temperature (R

). This value

TH(JC)

of T can then be compared to the original, assumed value

J

50

100

–50

150

0

used in the iterative calculation process.

JUNCTION TEMPERATURE (°C)

3780 F09

Figure 9. Normaliꢀed R_DS(ON)vs Temperature

3780ff

For more information www.linear.com/LTC3780

19

LTC3780

applicaTions inForMaTion

Schottky Diode (D1, D2) Selection

and Light Load Operation

INTV Regulator

CC

An internal P-channel low dropout regulator produces 6V

TheSchottkydiodesD1andD2showninFigure13conduct

during the dead time between the conduction of the power

MOSFET switches. They are intended to prevent the body

diode of synchronous switches B and D from turning on

and storing charge during the dead time. In particular, D2

signiﬁcantly reduces reverse recovery current between

switch D turn-off and switch C turn-on, which improves

converterefﬁciencyandreducesswitchCvoltagestress.In

orderforthediodetobeeffective,theinductancebetweenit

and the synchronous switch must be as small as possible,

mandating that these components be placed adjacently.

at the INTV pin from the V supply pin. INTV powers

CC IN CC

the drivers and internal circuitry within the LTC3780. The

INTV pin regulator can supply a peak current of 40mA

CC

and must be bypassed to ground with a minimum of 4.7µF

tantalum,10µFspecialpolymerorlowESRtypeelectrolytic

capacitor. A1µFceramiccapacitorplaceddirectlyadjacent

to the INTV and PGND IC pins is highly recommended.

CC

Good bypassing is necessary to supply the high transient

current required by MOSFET gate drivers.

Higher input voltage applications in which large MOSFETs

are being driven at high frequencies may cause the maxi-

mum junction temperature rating for the LTC3780 to be

exceeded.Thesystemsupplycurrentisnormallydominated

by the gate charge current. Additional external loading of

In buck mode, when the FCB pin voltage is 0.85 < V

FCB

< 5V, the converter operates in skip-cycle mode. In this

mode, synchronous switch B remains off until the induc-

tor peak current exceeds one-ﬁfth of its maximum peak

current. As a result, D1 should be rated for about one-half

to one-third of the full load current.

the INTV also needs to be taken into account for the

CC

power dissipation calculations. The total INTV current

CC

can be supplied by either the 6V internal linear regulator

or by the EXTV input pin. When the voltage applied to

CC

In boost mode, when the FCB pin voltage is higher than

5.3V,theconverteroperatesindiscontinuouscurrentmode.

In this mode, synchronous switch D remains off until the

inductor peak current exceeds one-ﬁfth of its maximum

peak current. As a result, D2 should be rated for about

one-third to one-fourth of the full load current.

the EXTV pin is less than 5.7V, all of the INTV current

CC

is supplied by the internal 6V linear regulator. Power dis-

sipation for the IC in this case is V • I , and overall

IN INTVCC

efﬁciency is lowered. The junction temperature can be

estimated by using the equations given in Note 2 of the

Electrical Characteristics. For example, a typical applica-

tion operating in continuous current mode might draw

Inbuckmode,whentheFCBpinvoltageishigherthan5.3V,

the converter operates in constant frequency discontinu-

ous current mode. In this mode, synchronous switch B

remains on until the inductor valley current is lower than

the sense voltage representing the minimum negative

24mA from a 24V supply when not using the EXTV pin:

CC

T = 70°C + 24mA • 24V • 34°C/W = 90°C

J

Use of the EXTV input pin reduces the junction tem-

CC

inductor current level (V

= –5mV). Both switch A

perature to:

SENSE

and B are off until next clock signal.

T = 70°C + 24mA • 6V • 34°C/W = 75°C

J

In boost mode, when the FCB pin voltage is 0.85 < V

FCB

To prevent maximum junction temperature from being

exceeded, the input supply current must be checked op-

erating in continuous mode at maximum V .

< 5.3V, the converter operates in Burst Mode operation.

In this mode, the controller clamps the peak inductor

current to approximately 20% of the maximum inductor

current. The output voltage ripple can increase during

Burst Mode operation.

IN

3780ff

20

For more information www.linear.com/LTC3780

LTC3780

applicaTions inForMaTion

EXTV Connection

supply the gate drive voltage for the topside MOSFET

switches A and D. When the top MOSFET switch A turns

CC

The LTC3780 contains an internal P-channel MOSFET

switch connected between the EXTV_CCand INTV_CCpins.

When the voltage applied to EXTV_CCrises above 5.7V, the

internal regulator is turned off and a switch connects the

EXTV_CCpin to the INTV_CCpin thereby supplying internal

power. The switch remains closed as long as the voltage

applied to EXTV_CCremains above 5.5V. This allows the

MOSFET driver and control power to be derived from the

output when (5.7V < V_OUT< 7V) and from the internal

regulator when the output is out of regulation (start-up,

short-circuit). If more current is required through the

EXTV_CCswitch than is speciﬁed, an external Schottky

diode can be interposed between the EXTV_CCand INTV_CC

pins. Ensure that EXTV_CC≤ V_IN.

on, the switch node SW2 rises to V and the BOOST2

IN

pin rises to approximately V + INTV . When the bottom

IN

CC

MOSFET switch B turns on, the switch node SW2 drops

to low and the boost capacitor C is charged through D

B

from INTV . When the top MOSFET switch D turns on,

CC

the switch node SW1 rises to V

rises to approximately V

and the BOOST1 pin

CC

OUT

+ INTV . When the bottom

OUT

MOSFET switch C turns on, the switch node SW1 drops

to low and the boost capacitor C is charged through D

A

from INTV . The boost capacitors C and C need to

CC

A

B

store about 100 times the gate charge required by the top

MOSFET switch A and D. In most applications a 0.1µF to

0.47µF, X5R or X7R dielectric capacitor is adequate.

The following list summarizes the three possible connec-

Run Function

tions for EXTV :

CC

The RUN pin provides simple ON/OFF control for the

LTC3780. Driving the RUN pin above 1.5V permits the

controller to start operating. Pulling RUN below 1.5V puts

theLTC3780intolowcurrentshutdown.Donotapplymore

than 6V to the RUN pin.

1. EXTV left open (or grounded). This will cause INTV

CC

to be powered from the internal 6V regulator at the cost

of a small efﬁciency penalty.

2. EXTV connected directly to V

(5.7V < V

< 7V).

CC

OUT

This is the normal connection for a 6V regulator and

provides the highest efﬁciency.

Soft-Start Function

Soft-start reduces the input power sources’ surge cur-

rents by gradually increasing the controller’s current

limit (proportional to an internally buffered and clamped

3. EXTV connected to an external supply. If an external

CC

supply is available in the 5.5V to 7V range, it may be

used to power EXTV provided it is compatible with

CC

equivalent of V ).

ITH

the MOSFET gate drive requirements.

An internal 1.2µA current source charges up the C ca-

SS

Output Voltage

pacitor. As the voltage on SS increases from 0V to 2.4V,

the internal current limit rises from 0V/R

to 150mV/

SENSE

The LTC3780 output voltage is set by an external feedback

resistivedividercarefullyplacedacrosstheoutputcapacitor.

Theresultantfeedbacksignaliscomparedwiththeinternal

precision 0.800V voltage reference by the error ampliﬁer.

The output voltage is given by the equation:

R

. The output current limit ramps up slowly, taking

SENSE

1.5s/µFtoreachfullcurrent.Theoutputcurrentthusramps

up slowly, eliminating the starting surge current required

from the input power supply.

2.4V

1.2µA

T

=

•C_SS= 1.5s/µF •C

SS

(

)

IRMP

R2

R1







V_OUT= 0.8V • 1+







Do not apply more than 6V to the SS pin.

Topside MOSFET Driver Supply (C , D , C , D )

A

B

Current foldback is disabled during soft-start until the

voltage on C reaches 2V. Make sure C is large enough

SS

Referring to Figure 11, the external bootstrap capacitors

C and C connected to the BOOST1 and BOOST2 pins

when there is loading during start-up.

A

B

3780ff

For more information www.linear.com/LTC3780

21

LTC3780

applicaTions inForMaTion

The Standby Mode (STBYMD) Pin Function

Fault Conditions: Overvoltage Protection

Thestandbymode(STBYMD)pinprovidesseveralchoices

for start-up and standby operational modes. If the pin is

pulled to ground, the SS pin is internally pulled to ground,

preventing start-up and thereby providing a single control

pin for turning off the controller. If the pin is left open or

bypassedtogroundwithacapacitor,theSSpinisinternally

providedwithastartingcurrent,permittingexternalcontrol

for turning on the controller. If the pin is connected to a

A comparator monitors the output for overvoltage con-

ditions. The comparator (OV) detects overvoltage faults

greaterthan7.5%abovethenominaloutputvoltage.When

the condition is sensed, switches A and C are turned off,

and switches B and D are turned on until the overvoltage

condition is cleared. During an overvoltage condition, a

negative current limit (V

= –60mV) is set to limit

SENSE

negative inductor current. When the sensed current in-

ductor current is lower than –60mV, switch A and C are

turned on, and switch B and D are turned off until the

sensed current is higher than –20mV. If the output is still

in overvoltage condition, switch A and C are turned off,

and switch B and D are turned on again.

voltage greater than 1.25V, the internal regulator (INTV )

CC

will be on even when the controller is shut down (RUN

pin voltage < 1.5V). In this mode, the onboard 6V linear

regulator can provide power to keep-alive functions such

as a keyboard controller.

Fault Conditions: Current Limit and Current Foldback

Efﬁciency Considerations

The maximum inductor current is inherently limited in a

current mode controller by the maximum sense voltage.

In boost mode, maximum sense voltage and the sense

resistance determines the maximum allowed inductor

peak current, which is:

The percent efﬁciency of a switching regulator is equal to

the output power divided by the input power times 100%.

It is often useful to analyze individual losses to determine

what is limiting the efﬁciency and which change would

produce the most improvement. Although all dissipative

elements in circuit produce losses, four main sources

account for most of the losses in LTC3780 circuits:

160mV

I_L(MAX,BOOST)

=

R_SENSE

2

1. DC I R losses. These arise from the resistances of the

MOSFETs, sensing resistor, inductor and PC board

traces and cause the efﬁciency to drop at high output

currents.

In buck mode, maximum sense voltage and the sense

resistance determines the maximum allowed inductor

valley current, which is:

2. Transition loss. This loss arises from the brief amount

of time switch A or switch C spends in the saturated

region during switch node transitions. It depends upon

the input voltage, load current, driver strength and

MOSFET capacitance, among other factors. The loss

is signiﬁcant at input voltages above 20V and can be

estimated from:

130mV

R_SENSE

I_L(MAX,BUCK)

=

To further limit current in the event of a short circuit to

ground, the LTC3780 includes foldback current limiting.

If the output falls by more than 30%, then the maximum

sense voltage is progressively lowered to about one third

of its full value.

–1

Transition Loss ≈ 1.7A • V • I

• C

• f

IN2 OUT

RSS

where C

is the reverse transfer capacitance.

RSS

3780ff

22

For more information www.linear.com/LTC3780

LTC3780

applicaTions inForMaTion

3. INTV current. This is the sum of the MOSFET driver

Thehighestvalueofripplecurrentoccursatthemaximum

input voltage. In boost mode, the ripple current is:

CC

and control currents. This loss can be reduced by sup-

plying INTV current through the EXTV pin from a

CC

V

IN



V

IN



∆I_L,BOOST

=

• 1–

high efﬁciency source, such as an output derived boost







f •L  V_OUT

network or alternate supply if available.

∆I_L,BOOST•100

4. C and C

loss. The input capacitor has the difﬁcult

IN

OUT

I_RIPPLE,BOOST

=

%

jobofﬁlteringthelargeRMSinputcurrenttotheregula-

tor in buck mode. The output capacitor has the more

difﬁcult job of ﬁltering the large RMS output current in

I

IN

The highest value of ripple current occurs at V = V /2.

IN

OUT

boost mode. Both C and C

are required to have

IN

OUT

A 6.8µH inductor will produce 11% ripple in boost mode

(V = 6V) and 29% ripple in buck mode (V = 18V).

2

low ESR to minimize the AC I R loss and sufﬁcient

capacitance to prevent the RMS current from causing

additional upstream losses in fuses or batteries.

IN

The R

resistor value can be calculated by using the

maximum current sense voltage speciﬁcation with some

accommodation for tolerances.

SENSE

5. Other losses. Schottky diode D1 and D2 are respon-

sible for conduction losses during dead time and light

load conduction periods. Inductor core loss occurs

predominately at light loads. Switch C causes reverse

recovery current loss in boost mode.

2•160mV •V

IN(MIN)

R_SENSE

=

2•I_{OUT(MAX,BOOST)}•V_OUT+ ∆I_L,BOOST•V

IN(MIN)

Select an R

of 10mΩ.

SENSE

Whenmakingadjustmentstoimproveefﬁciency, theinput

current is the best indicator of changes in efﬁciency. If you

make a change and the input current decreases, then the

efﬁciency has increased. If there is no change in input

current, then there is no change in efﬁciency.

Output voltage is 12V. Select R1 as 20k. R2 is:

V_OUT•R1

R2 =

–R1

0.8

Select R2 as 280k. Both R1 and R2 should have a toler-

ance of no more than 1%.

Design Example

As a design example, assume V = 5V to 18V (12V nomi-

IN

Next, choose the MOSFET switches. A suitable choice is

nal), V

= 12V (5%), I

= 5A and f = 400kHz.

OUT

OUT(MAX)

the Siliconix Si4840 (R

= 0.009Ω (at V = 6V),

DS(ON)

= 150pF, θ = 40°C/W).

GS

Set the PLLFLTR pin at 2.4V for 400kHz operation. The

inductance value is chosen ﬁrst based on a 30% ripple

current assumption. In buck mode, the ripple current is:

C

RSS

JA

The maximum power dissipation of switch A occurs in

boost mode when switch A stays on all the time. Assum-





V_OUT

f •L

V_OUT

ing a junction temperature of T = 150°C with ρ

=

J

150°C

∆I_L,BUCK

=

• 1–







1.5, the power dissipation at V = 5V is:

V

IN



IN



²



12

5

∆I_L,BUCK•100

P_A,BOOST

=

•5 •1.5•0.009=1.94W







I_RIPPLE,BUCK

=

%

I_OUT

3780ff

For more information www.linear.com/LTC3780

23

LTC3780

applicaTions inForMaTion

Double-check the T in the MOSFET with 70°C ambient

C is chosen to ﬁlter the square current in buck mode. In

J

IN

temperature:

this mode, the maximum input current peak is:

29%

2







T = 70°C + 1.94W • 40°C/W = 147.6°C

J

I_{IN,PEAK(MAX,BUCK)}= 5• 1+

= 5.7A







The maximum power dissipation of switch B occurs in

buckmode. AssumingajunctiontemperatureofT =80°C

J

A low ESR (10mΩ) capacitor is selected. Input voltage

ripple is 57mV (assuming ESR dominate ripple).

with ρ

= 1.2, the power dissipation at V = 18V is:

80°C

IN

18–12

•5²•1.2•0.009=90mW

C

is chosen to ﬁlter the square current in boost mode.

OUT

P_B,BUCK

=

18

In this mode, the maximum output current peak is:

12

5

11%

2







Double-check the T in the MOSFET at 70°C ambient

J

I_{OUT,PEAK(MAX,BOOST)}

=

•5• 1+

=10.6A







temperature:

T = 70°C + 0.09W • 40°C/W = 73.6°C

J

A low ESR (5mΩ) capacitor is suggested. This capacitor

will limit output voltage ripple to 53mV (assuming ESR

dominate ripple).

ThemaximumpowerdissipationofswitchCoccursinboost

mode.AssumingajunctiontemperatureofT =110°Cwith

J

ρ

= 1.4, the power dissipation at V = 5V is:

110°C

IN

PC Board Layout Checklist

12–5 •12

(

)

P_C,BOOST

=

•5²•1.4•0.009

The basic PC board layout requires a dedicated ground

plane layer. Also, for high current, a multilayer board

provides heat sinking for power components.

5²

5

+ 2•12³• •150p•400k =1.27W

5

• The ground plane layer should not have any traces and

it should be as close as possible to the layer with power

MOSFETs.

Double-check the T in the MOSFET at 70°C ambient

J

temperature:

T = 70°C + 1.08W • 40°C/W = 113°C

J

•

Place C , switch A, switch B and D1 in one com-

IN

pact area. Place C , switch C, switch D and D2 in

The maximum power dissipation of switch D occurs

in boost mode when its duty cycle is higher than 50%.

OUT

one compact area. One layout example is shown in

Figure 10.

Assuming a junction temperature of T = 100°C with

J

ρ

= 1.35, the power dissipation at V = 5V is:

100°C

IN

V

SW2

SW1

V

OUT

IN

5

12

5



²

•5 •1.35•0.009= 0.73W

L

D2

QD

P_D,BOOST

=

•









QA

Double-check the T in the MOSFET at 70°C ambient

J

D1

temperature:

QB

QC

T = 70°C + 0.73W • 40°C/W = 99°C

J

C

OUT

IN

R

SENSE

LTC3780

CKT

GND

3780 F10

Figure 10. Switches Layout

3780ff

24

For more information www.linear.com/LTC3780

LTC3780

applicaTions inForMaTion

• Useimmediateviastoconnectthecomponents(includ-

ing the LTC3780’s SGND and PGND pins) to the ground

plane.Useseverallargeviasforeachpowercomponent.

• Connect the top driver boost capacitor C closely to the

A

BOOST1 and SW1 pins. Connect the top driver boost

capacitor C closely to the BOOST2 and SW2 pins.

B

• Use planes for V and V

to maintain good voltage

• Connect the input capacitors C and output capacitors

IN

OUT

ﬁltering and to keep power losses low.

C

closely to the power MOSFETs. These capacitors

OUT

carry the MOSFET AC current in boost and buck mode.

• Floodallunusedareasonalllayerswithcopper.Flooding

with copper will reduce the temperature rise of power

components. Connect the copper areas to any DC net

• Connect V pin resistive dividers to the (+) termi-

OSENSE

nalsofC

andsignalground. AsmallV

bypass

OUT

OSENSE

(V or GND).

capacitormaybeconnectedcloselytotheLTC3780SGND

pin. The R2 connection should not be along the high

current or noise paths, such as the input capacitors.

IN

• Segregate the signal and power grounds. All small-

signal components should return to the SGND pin at

one point, which is then tied to the PGND pin close to

the sources of switch B and switch C.

–

+

• RouteSENSE andSENSE leadstogetherwithminimum

PC trace spacing. Avoid sense lines pass through noisy

area,suchasswitchnodes.Theﬁltercapacitorbetween

• Place switch B and switch C as close to the controller as

+

–

SENSE and SENSE should be as close as possible

to the IC. Ensure accurate current sensing with Kelvin

connections at the SENSE resistor. One layout example

is shown in Figure 12.

possible, keeping the PGND, BG and SW traces short.

• Keep the high dV/dT SW1, SW2, BOOST1, BOOST2,

TG1 and TG2 nodes away from sensitive small-signal

nodes.

• Connect the I pin compensation network close to the

TH

• The path formed by switch A, switch B, D1 and the C

IC, between I and the signal ground pins. The capaci-

IN

TH

capacitor should have shortleads andPCtrace lengths.

tor helps to ﬁlter the effects of PCB noise and output

The path formed by switch C, switch D, D2 and the

voltage ripple voltage from the compensation loop.

C

capacitor also should have short leads and PC

OUT

trace lengths.

• ConnecttheINTV bypasscapacitor, C , closetothe

CC

VCC

IC,betweentheINTV andthepowergroundpins.This

CC

• Theoutputcapacitor(–)terminalsshouldbeconnected

as close as possible the (–) terminals of the input

capacitor.

capacitor carries the MOSFET drivers’ current peaks.

Anadditional1µFceramiccapacitorplacedimmediately

next to the INTV and PGND pins can help improve

CC

noise performance substantially.

3780ff

For more information www.linear.com/LTC3780

25

LTC3780

applicaTions inForMaTion

V

OUT

R

PU

V

C

PULLUP

OUT

C

A

1

2

24

23

C

SS

PGOOD BOOST1

SS

TG1

D

C

D2

LTC3780

+

D

A

3

4

22

SENSE

SW1

C

C2

C

–

C

21

20

19

18

17

16

15

F

C

V

IN

C1

R

C

5

6

I

EXTV

TH

CC

R2

VCC

L

R1

V

INTV

OSENSE

7

SGND

RUN

BG1

PGND

BG2

R

SENSE

8

D1

9

FCB

B

A

10

PLLFLTR

SW2

D

B

11

12

14

13

f

PLLIN

TG2

IN

C

B

C

IN

STBYMD BOOST2

R

IN

V

IN

3780 F11

Figure 11. LTC3780 Layout Diagram

PGND

C

R

SGND

3780 F12

Figure 12. Sense Lines Layout

3780ff

26

For more information www.linear.com/LTC3780

LTC3780

package DescripTion

Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.

G Package

24-Lead Plastic SSOP (5.3mm)

(Reference LTC DWG # 05-08-1640)

7.90 – 8.50*

(.311 – .335)

1.25 ±0.12

24 23 22 21 20 19 18 17 16 15 14

13

7.8 – 8.2

5.3 – 5.7

7.40 – 8.20

(.291 – .323)

0.42 ±0.03

RECOMMENDED SOLDER PAD LAYOUT

0.65 BSC

5

7

8

1

2

3

4

6

9 10 11 12

2.0

5.00 – 5.60**

(.197 – .221)

(.079)

MAX

0° – 8°

0.65

(.0256)

BSC

0.09 – 0.25

0.55 – 0.95

(.0035 – .010)

(.022 – .037)

0.05

0.22 – 0.38

(.009 – .015)

TYP

(.002)

NOTE:

MIN

1. CONTROLLING DIMENSION: MILLIMETERS

MILLIMETERS

2. DIMENSIONS ARE IN

(INCHES)

G24 SSOP 0204

3. DRAWING NOT TO SCALE

*DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH

SHALL NOT EXCEED .152mm (.006") PER SIDE

**DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD

FLASH SHALL NOT EXCEED .254mm (.010") PER SIDE

3780ff

For more information www.linear.com/LTC3780

27

LTC3780

package DescripTion

Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.

UH Package

32-Lead Plastic QFN (5mm × 5mm)

(Reference LTC DWG # 05-08-1693 Rev D)

0.70 ±0.05

5.50 ±0.05

4.10 ±0.05

3.45 ± 0.05

3.50 REF

(4 SIDES)

3.45 ± 0.05

PACKAGE OUTLINE

0.25 ± 0.05

0.50 BSC

RECOMMENDED SOLDER PAD LAYOUT

APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED

BOTTOM VIEW—EXPOSED PAD

PIN 1 NOTCH R = 0.30 TYP

OR 0.35 × 45° CHAMFER

R = 0.05

TYP

0.00 – 0.05

R = 0.115

TYP

0.75 ± 0.05

5.00 ± 0.10

(4 SIDES)

31 32

0.40 ± 0.10

PIN 1

TOP MARK

(NOTE 6)

1

2

3.45 ± 0.10

3.50 REF

(4-SIDES)

3.45 ± 0.10

(UH32) QFN 0406 REV D

0.200 REF

0.25 ± 0.05

0.50 BSC

NOTE:

1. DRAWING PROPOSED TO BE A JEDEC PACKAGE OUTLINE

M0-220 VARIATION WHHD-(X) (TO BE APPROVED)

2. DRAWING NOT TO SCALE

3. ALL DIMENSIONS ARE IN MILLIMETERS

4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE

MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.20mm ON ANY SIDE

5. EXPOSED PAD SHALL BE SOLDER PLATED

6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION

ON THE TOP AND BOTTOM OF PACKAGE

3780ff

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 representa-

tion that the interconnection of its cinircfouits as described he inarw l not infringe on existing patent rights.

For more rmation www.linree .cilom/LTC3780

28

LTC3780

revision hisTory ^{(Revision history begins at Rev F)}

REV

DATE

DESCRIPTION

PAGE NUMBER

F

4/13

Updated Note 7, ﬁxed typos

2, 3, 4, 5

3780ff

For more information www.linear.com/LTC3780

29

LTC3780

Typical applicaTion

V

12V

5A

OUT

R

PU

22µF

16V, X7R

× 3

C

A

V

PULLUP

0.22µF

+

C

OUT

SS

1

24

23

330µF

16V

0.022µF

PGOOD BOOST1

2

D

SS

TG1

D2

Si7884DP

C

C2

LTC3780

+

B320A

D

A

47pF

BO540W

68pF

3

4

5

6

22

21

20

19

SENSE

SW1

C

C1

C 0.1µF

F

R

–

C

V

0.01µF

IN

100k

Si7884DP

L

I

EXTV

4.7µH

TH

CC

C

VCC

4.7µF

9mΩ

R1

8.06k, 1%

V

INTV

OSENSE

R2 113k, 1%

ON/OFF

7

8

18

17

16

15

SGND

RUN

BG1

PGND

BG2

9

B

D1

B340A

FCB

Si7884DP

10

PLLFLTR

SW2

D

B

10k

BO540W

C

22µF

35V

IN

A

11

12

14

13

+

PLLIN

TG2

Si7884DP

STBYMD BOOST2

2V

3.3µF

C

STBYMD

C 0.22µF

B

50V, X5R

10Ω

0.01µF

× 3

V

IN

100Ω

5V TO 32V

3780 TA02

100Ω

Figure 13. LTC3780 12V/5A, Buck-Boost Regulator

relaTeD parTs

PART NUMBER

DESCRIPTION

COMMENTS

4V ≤ V ≤ 38V, 0.8V ≤ V

LTC3789

38V High Efﬁciency Synchronous 4-Switch Buck-Boost

DC/DC Controller

≤ 38V 4mm × 5mm QFN-28, SSOP-28

OUT

IN

LT3791-1

LT8705

60V High Efﬁciency Synchronous 4-Switch Buck-Boost

DC/DC Controller

4.7V ≤ V ≤ 60V, 1.2V ≤ V

≤ 30V TSSOP-38

IN

OUT

80V High Efﬁciency Synchronous 4-Switch Buck-Boost

DC/DC Controller

2.8V ≤ V ≤ 80V, 1.3V ≤ V

≤ 80V 5mm × 7mm QFN-38,

≤ 10V 4mm × 4mm QFN-24

≤ 14V 4mm × 5mm DFN-16,

≤ 40V 4mm × 5mm DFN-16,

IN

TSSOP-38

LTC3785

LTC3112

LTC3115-1

10V High Efﬁciency Synchronous 4-Switch Buck-Boost

DC/DC Controller

2.7V ≤ V ≤ 10V, 2.7V ≤ V

IN

15V, 2.5A Synchronous Buck-Boost DC/DC Converter

2.7V ≤ V ≤ 15V, 2.5V ≤ V

IN

TSSOP-20

40V, 2A Synchronous Buck-Boost DC/DC Converter

2.7V ≤ V ≤ 40V, 2.7V ≤ V

IN

TSSOP-20

LTM4607

LTM4609

High Efﬁciency Buck-Boost DC/DC µModule^®

High Efﬁciency Buck-Boost DC/DC µModule

4.5V ≤ V ≤ 36V, 0.8V ≤ V

≤ 25V 15mm × 15mm × 2.8mm

≤ 34V 15mm × 15mm × 2.8mm

IN

OUT

4.5V ≤ V ≤ 36V, 0.8V ≤ V

IN

3780ff

LT 0413 REV F • PRINTED IN USA

30 ^{LinearTechnology Corporation}

For more information www.linear.com/LTC3780

(408)432-1900 FAX: (408) 434-0507 www.linear.com/LTC3780

1630 McCarthy Blvd., Milpitas, CA 95035-7417

●

 LINEAR TECHNOLOGY CORPORATION 2005


型号：	LTC3780IUHPBF
厂家：	Linear
描述：	High Efficiency, Synchronous 4-Switch Buck-Boost Controller 高效率，同步四开关降压 - 升压型控制器开关控制器
文件：	总30页 (文件大小：629K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

LTC3780IUHPBF [Linear]

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