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LTC1875

1875f

15µA Quiescent Current

1.5A Monolithic Synchronous

Step-Down Regulator

■

Portable Computers

■

Portable Instruments

■

Wireless Modems

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

High Efficiency Step-Down Converter

■

High Efficiency: Up to 95%

■

Low Quiescent Current: Only 15µA with No Load

■

550kHz Constant Frequency Operation

■

2.65V to 6V Input Voltage Range

■

OUT

from 0.8V to V

, I

OUT

to 1.5A

■

True PLL Frequency Locking from 350kHz to 750kHz

■

Power Good Output Voltage Monitor

■

Low Dropout Operation: 100% Duty Cycle

■

Burst Mode

or Pulse Skipping Operation

■

Current Mode Operation for Excellent Line and Load

Transient Response

■

Shutdown Mode Draws <1µA Supply Current

■

±2% Output Voltage Accuracy

■

Overcurrent and Overtemperature Protected

■

Available in 16-Lead SSOP Package

The LTC

1875 is a high efficiency 1.5A monolithic syn-

chronous buck regulator using a constant frequency,

current mode architecture. Operating supply current is

only 15µA with no load and drops to <1µA in shutdown.

The input supply voltage range of 2.65V to 6V makes the

LTC1875 ideally suited for single Li-Ion battery-powered

applications. 100% duty cycle provides low dropout op-

eration, extending battery life in portable systems.

The switching frequency is internally set to 550kHz, allow-

ing the use of small surface mount inductors and capaci-

tors. For noise sensitive applications, the LTC1875 can be

externally synchronized from 350kHz to 750kHz. Burst

Mode operation is inhibited during synchronization or

when the SYNC/MODE pin is pulled low.

The internal synchronous switch increases efficiency and

eliminates the need for an external Schottky diode. Low

output voltages are easily supported with a 0.8V feedback

reference voltage. The LTC1875 is available in a 16-lead

SSOP package.

Burst Mode is a registered trademark of Linear Technology Corporation.

RUN/SS

SYNC/MODE

PGOOD

SWP

SWN

PGND

LTC1875

28.0k

: TAIYO YUDEN CERAMIC JMK325BJ226MM

OUT

: SANYO POSCAP 6TPA47M

L1: TOKO 646CY-6R8M

OUT

CONNECTED TO V

(MINUS SWITCH AND L1 VOLTAGE DROP) FOR 2.65V < V

< 3.3V

1875 TA01

220pF

150k

88.7k

OUT

47µF

OUT

3.3V

6.8µH

SGND

47pF

22µF

2.65V TO 6V

Efficiency vs Output Load Current

OUPUT CURRENT (mA)

EFFICIENCY (%)

100

550.1 10 100

1875 TA01a

1 1000

Burst Mode OPERATION

VOUT = 3.3V

L = 6.8µH

VIN = 4.2V

VIN = 6V

VIN = 3.6V

FEATURES

DESCRIPTIO

APPLICATIO S

TYPICAL APPLICATIO

LTC1875

1875f

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

VFB

Feedback Current (Note 4) ●860 nA

Regulated Output Voltage (Note 4) 0°C ≤ T

≤ 85°C 0.784 0.80 0.816 V

(Note 4) –40°C ≤ T

≤ 85°C●0.740 0.80 0.840 V

∆V

OVL

Overvoltage Trip Limit with Respect to V

∆V

OVL

= V

OVL

– V

●20 60 110 mV

∆V

UVL

Undervoltage Trip Limit with Respect to V

∆V

UVL

= V

– V

UVL

●20 60 110 mV

∆V

Reference Voltage Line Regulation V

= 2.65V to 6V (Note 4) 0.05 0.25 %/V

LOADREG

Output Voltage Load Regulation Measured in Servo Loop, V

ITH

= 0.9V to 1.2V ● 0.1 0.6 %

Measured in Servo Loop, V

ITH

= 1.6V to 1.2V ●–0.1 –0.6 %

Input Voltage Range ●2.65 6 V

Input DC Bias Current (Note 5)

Pulse Skipping Mode 2.65V < V

< 6V, V

SYNC/MODE

= 0V, I

OUT

= 0A 270 365 µA

Burst Mode Operation V

SYNC/MODE

= V

, I

OUT

= 0A 15 22 µA

Shutdown V

RUN

= 0V, V

= 6V 0 1 µA

SYNC

SYNC Capture Range 350 750 kHz

OSC

Oscillator Frequency V

≥ 0.7V 495 550 605 kHz

= 0V 80 kHz

PLLLPF

Phase Detector Output Current

Sinking Capability f

PLLIN

< f

OSC

● 3 10 20 µA

Sourcing Capability f

PPLIN

> f

SOC

●–3 –10 –20 µA

PFET

DS(ON)

of P-Channel FET I

= 100mA, V

= 5V 0.28 0.35 Ω

NFET

DS(ON)

of N-Channel FET I

= –100mA, V

= 5V 0.35 0.4 Ω

Peak Inductor Current V

= 0.7V, Duty Cycle < 35%, V

= 3V 1.6 2.15 2.75 A

LSW

SW Leakage V

RUN

= 0V, V

= 0V or 6V, V

= 6V ±0.01 ±2.5 µA

SYNC/MODE

SYNC/MODE Threshold ●0.2 1.0 1.5 V

SYNC/MODE

SYNC/MODE Leakage Current ±0.01 ±1µA

(Note 1) ORDER PART

NUMBER

LTC1875EGN

JMAX

= 125°C, θ

= 110°C/ W, θ

= 40°C/W

The ● denotes specifications which apply over the full operating

temperature range, otherwise specifications are TA = 25°C. VIN = 3.6V unless otherwise noted.

ABSOLUTE MAXIMUM RATINGS

PACKAGE/ORDER INFORMATION

ELECTRICAL CHARACTERISTICS

Input Supply Voltage .................................. –0.3V to 7V

, PLL_LPF Voltages............................. –0.3V to 2.7V

RUN/SS, V

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

SYNC/MODE Voltage ................................. –0.3V to V

PVIN

– V

SWP

) Voltage............................... –0.3V to 7V

SWN

Voltage.............................................. –0.3V to 7V

P-Channel Switch Source Current (DC) .................... 2A

N-Channel Switch Sink Current (DC) ........................ 2A

Peak Switching Sink and Source Current ................. 3A

Operating Ambient Temperature Range

(Note 2) ............................................. –40°C to 85°C

Junction Temperature (Note 3, 6)........................ 125°C

Storage Temperature Range ................ –65°C to 150°C

Lead Temperature (Soldering, 10 sec)................. 300°C

TOP VIEW

GN PACKAGE

16-LEAD PLASTIC SSOP

SGND

RUN/SS

SWP1

SWN1

PGND1

IN1

PLL_LPF

SYNC/MODE

PGOOD

SWP2

SWN2

PGND2

IN2

GN PART

MARKING

1875

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

LTC1875

1875f

RUN

RUN Threshold V

RUN

Ramping Up ●0.2 0.7 1.5 V

RUN

RUN Input Current V

RUN

= 0V ±0.01 ±1µA

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

The ● denotes specifications which apply over the full operating

temperature range, otherwise specifications are TA = 25°C. VIN = 3.6V unless otherwise noted.

ELECTRICAL CHARACTERISTICS

Note 1: Absolute Maximum Ratings are those values beyond which the life

of a device may be impaired.

Note 2: The LTC1875E is guaranteed to meet specified performance 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 3: T

is calculated from the ambient temperature T

and power

dissipation P

according to the following formula:

LTC1875: T

= T

+ (P

• 110°C/W)

Note 4: The LTC1875 is tested in a feedback loop which servos V

to the

balance point for the error amplifier (V

ITH

= 1.2V)

Note 5: Dynamic supply current is higher due to the gate charge being

delivered at the switching frequency.

Note 6: This IC includes overtemperature protection that is intended to

protect the device during momentary overload conditions. Junction

temperature will exceed 125°C when overtemperature protection is active.

Continuous operation above the specified maximum operating junction

temperature may impair device reliability.

TEMPERATURE (°C)

–50 –25 0 25 50 75 100 125

RDS(ON) (Ω)

1875 G01

0.8

0.7

0.6

0.5

0.4

0.3

0.2

0.1

VIN = 5V

VIN = 3V

SYNCHRONOUS SWITCH

MAIN SWITCH

VIN = 3V

TEMPERATURE (°C)

–50 –25 0 25 50 75 100 125

FREQUENCY (kHz)

1875 G02

595

575

555

535

515

495

VIN = 3.6V

SUPPLY VOLTAGE (V)

02468

OSC FREQUENCY (kHz)

1875 G03

580

570

560

550

540

530

RDS(ON) vs Temperature Oscillator Frequency

vs Temperature Oscillator Frequency

vs Supply Voltage

TYPICAL PERFOR A CE CHARACTERISTICS

TEMPERATURE (°C)

–50 0 50 100 125

SUPPLY CURRENT (µA)

1875 G04

300

250

200

150

100

PULSE SKIPPING MODE

BURST MODE

VIN = 3.6V

DC Supply Current

vs Temperature

INPUT VOLTAGE (V)

02468

RDS(ON) (Ω)

1875 G05

0.6

0.5

0.4

0.3

0.2

0.1

SYNCHRONOUS SWITCH

MAIN SWITCH

TEMPERATURE (°C)

–50 0 50 100 125

SWITCH LEAKAGE (µA)

1875 G06

MAIN SWITCH

SYNCHRONOUS SWITCH

VIN = 7V

RUN = 0V

RDS(ON) vs Input Voltage Switch Leakage Current

vs Temperature

LTC1875

1875f

TYPICAL PERFOR A CE CHARACTERISTICS

LOAD CURRENT (mA)

0 500 1000 1500 2000

OUTPUT VOLTAGE (V)

1875 G07

1.84

1.82

1.80

1.78

1.76

1.74

1.72

1.70

Burst Mode OPERATION

VIN = 3.6V

L = 4.7µH

Output Voltage vs Load Current

Load Step (Burst Mode Operation)

OUT

100mV/DIV

1A/DIV

1V/DIV

50µs/DIV 1875 G08

= 3.6V C

= 22µF

OUT

= 1.5V C

OUT

= 47µF

L = 6.8µHI

LOAD

= 200mA to 1700mA

TEMPERATURE (°C)

–50 –25 0 25 50 75 100 125

REFERENCE VOLTAGE (mV)

1875 G13

805

804

803

802

801

800

799

798

797

796

795

VIN = 6V

OUTPUT CURRENT (mA)

EFFICIENCY (%)

500.1 10 100

1875 G14

1 1000

= 6V

= 4.2V

= 3V

= 3.6V

OUT

= 1.8V

L = 4.7µH

Burst Mode OPERATION

OUTPUT CURRENT (mA)

EFFICIENCY (%)

100

00.1 10 100

1875 G15

1 1000

= 3.6V

OUT

= 1.8V

L = 4.7µH

Burst Mode OPERATION

PULSE SKIPPING MODE

= 4.2V

= 3.6V

= 4.2V

INPUT VOLTAGE (V)

EFFICIENCY (%)

100

50 2

1875 G16

3456

OUT

= 2.5V

L = 6.8µH

Burst Mode OPERATION

100mA

1mA

0.1mA

10mA

Reference Voltage vs

Temperature

Efficiency vs Output Current

Efficiency vs Input Voltage

Efficiency vs Output Current

LTC1875

1875f

Load Step Response (Pulse

Skipping Mode) Pulse Skipping Mode Operation

Burst Mode Operation Soft-Start with Shorted Output

TYPICAL PERFOR A CE CHARACTERISTICS

200mA/DIV

OUT

100mV/DIV

5V/DIV

OUT

100mV/DIV

1A/DIV

1V/DIV

200mA/DIV

OUT

100mV/DIV

5V/DIV

VIN

500mA/DIV

RUN/SS

1V/DIV

100µs/DIV 1875 G09

= 3.6V C

= 22µF

OUT

= 1.5V C

OUT

= 47µF

L = 6.8µHI

LOAD

= 200mA to 1700mA

1µs/DIV 1875 G10

= 4.2V C

= 22µF

OUT

= 2.5V C

OUT

= 47µF

L = 6.8µHI

LOAD

= 50mA

25µs/DIV 1875 G11

= 4.2V C

= 22µF

OUT

= 2.5V C

OUT

= 47µF

L = 6.8µHI

LOAD

= 50mA

5ms/DIV 1875 G12

= 3.6V C

= 22µF

OUT

= 0V C

OUT

= 47µF

L = 6.8µHI

LOAD

= 0A

LTC1875

1875f

PI FU CTIO S

SGND (Pin 1): Signal Ground Pin.

RUN/SS (Pin 2): Combination of Soft-Start and Run

Control Inputs. Forcing this pin below 0.7V shuts down the

device. In shutdown all functions are disabled and device

draws zero supply current. For the proper operation of the

part, force this pin above 2.5V. Do not leave this pin

floating. Soft-start can be accomplished by raising the

voltage on this pin gradually with an RC circuit.

(Pin 3): Feedback Pin. Receives the feedback voltage

from an external resistor divider across the output.

(Pin 4): Error Amplifier Compensation Point. The

current output increases with this control voltage. Nomi-

nal voltage range for this pin is 0.5V to 1.8V.

SWP1, SWP2 (Pins 5, 12): Upper Switch Nodes. These

pins connect to the drains of the internal main PMOS

switches and should always be connected together

externally.

SWN1, SWN2 (Pins 6, 11): Lower Switch Nodes. These

pins connect to the drains of the internal synchronous

NMOS switches and should always be connected together

externally.

PGND1, PGND2 (Pins 7, 10): Power Ground Pins. Ground

pins for the internal drivers and switches. These pins

should always be tied together.

IN1

, PV

IN2

(Pins 8, 9): Power Supply Pins for the

Internal Drivers and Switches. These pins should always

be tied together.

(Pin 13): Signal Power Supply Pin.

PGOOD (Pin 14): Power Good Indicator Pin. Power good

is an open-drain logic output. The PGOOD pin is pulled to

ground when the voltage on the V

pin is not within

±7.5% of its nominally regulated potential. This pin re-

quires a pull-up resistor for power good indication. Power

good indication works in all modes of operation.

SYNC/MODE (Pin 15): External Clock Synchronization

and Mode Select Input. To synchronize, apply an external

clock with a frequency between 350kHz and 750kHz. To

select Burst Mode operation, tie pin to SV

. Grounding

this pin selects pulse skipping mode. Do not leave this pin

floating.

PLL_LPF (Pin 16): Output of the Phase Detector and

Control Input of Oscillator. Connect a series RC lowpass

network from this pin to ground if externally synchronized.

If unused, this pin may be left open.

LTC1875

1875f

BLOCK DIAGRA

–

BURST

SLEEP

0.8V

0.86V

0.6V

FREQ

SHIFT

SLOPE

COMP

OSC

VCO

AND

OSC

BURST DEFEAT

YY = “0” ONLY WHEN X IS A CONSTANT “1”

RUN/SS

SYNC/MODE

PLL_LPF

RS LATCH

0.45V

QSWITCHING

LOGIC

AND

BLANKING

CIRCUIT

THERMAL

SHUTDOWN

ANTI-

SHOOT-

THROUGH

OVDET

–

RCMP

–

0.74V UVDET

PGOOD

SHUTDOWN

SGND

SOFT-START

0.8V REF

–+

COMP

2.9Ω

PGND

7, 10

6, 11

8, 9

TOP

MOSFET

BOTTOM

MOSFET

1875 FD

SWN

0.8V

5, 12

SWP

LTC1875

1875f

OPERATIO

Main Control Loop

The LTC1875 uses a constant frequency, current mode

step-down architecture. Both the top MOSFET and syn-

chronous bottom MOSFET switches are internal. During

normal operation, the internal top power MOSFET is

turned on each cycle when the oscillator sets the RS latch,

and turned off when the current comparator, I

COMP

, resets

the RS latch. The peak inductor current at which I

COMP

turns the top MOSFET off is controlled by the voltage on

the I

pin, which is the output of error amplifier EA. When

the load current increases, it causes a slight decrease in

the feedback voltage, V

, relative to the 0.8V internal

reference, which, in turn, causes the I

voltage to in-

crease until the average inductor current matches the new

load current. While the top MOSFET is off, the bottom

MOSFET is turned on until either the inductor current

starts to reverse direction or the next clock cycle begins.

Comparator OVDET guards against transient overshoots

>7.5% by turning the main switch off and keeping it off

until the fault is removed.

Burst Mode Operation

The LTC1875 is capable of Burst Mode operation in which

the internal power MOSFETs operate intermittently based

on load demand. To enable Burst Mode operation, simply

tie the SYNC/MODE pin to SV

or connect it to a logic high

SYNC/MODE

> 1.5V). To disable Burst Mode operation

and enable PWM pulse skipping mode, connect the SYNC/

MODE pin to SGND. In this mode, the efficiency is lower at

light loads but becomes comparable to Burst Mode opera-

tion when the output load exceeds 100mA. The advantage

of pulse skipping mode is lower output ripple.

When the converter is in Burst Mode operation, the peak

current of the inductor is set to approximately 400mA,

even though the voltage at the I

pin indicates a lower

value. The voltage at the I

pin drops when the inductor’s

average current is greater than the load requirement. As

the I

voltage drops below approximately 0.45V, the

BURST comparator trips, turning off both power MOSFETs.

The I

pin is then disconnected from the output of the EA

amplifier and held 0.65V above ground.

In sleep mode, both power MOSFETs are held off and the

internal circuitry is partially turned off, reducing the quies-

cent current to 15µA. The load current is now being

supplied from the output capacitor. When the output

voltage drops, the I

pin reconnects to the output of the

EA amplifier and the top MOSFET is again turned on and

this process repeats.

Soft-Start/Run Function

The RUN/SS pin provides a soft-start function and a

means to shut down the LTC1875. Soft-start reduces the

input current surge by gradually increasing the regulator’s

maximum output current. This pin can also be used for

power supply sequencing.

Pulling the RUN/SS pin below 0.7V shuts down the

LTC1875, which then draws <1µA current from the sup-

ply. This pin can be driven directly from logic circuits as

shown in Figure 1. It is recommended that this pin is driven

to V

during normal operation. Note that there is no

current flowing out of this pin. Soft-start action is accom-

plished by connecting an external RC network to the RUN/

SS pin as shown in Figure 1. The LTC1875 actively pulls

the RUN/SS pin to ground under low input supply voltage

conditions.

(Refer to Block Diagram)

3.3V OR 5V

VIN

RUN/SS

D1*

0.32V RSS

CSS

*ZETEX BAT54 1875 F01

Figure 1. RUN/SS Pin Interfacing

LTC1875

1875f

Power Good Indicator

The power good function monitors the output voltage in all

modes of operation. Its open-drain output is pulled low

when the output voltage is not within ±7.5% of its nomi-

nally regulated voltage. The feedback voltage is filtered

before it is fed to a power good window comparator in

order to prevent false tripping of the power good signal

during fast transients. The window comparator monitors

the output voltage even in Burst Mode operation. In

shutdown mode, open drain is actively pulled low to

indicate that the output voltage is invalid.

Short-Circuit Protection

When the output is shorted to ground, the frequency of

the oscillator is reduced to about 80kHz, 1/7 the nominal

frequency. This frequency foldback ensures that the in-

ductor current has more time to decay, thereby preventing

runaway. The oscillator’s frequency will progressively

increase to 550kHz (or to the synchronized frequency)

when V

rises above 0.3V.

Frequency Synchronization

The LTC1875 can be synchronized to an external clock

source connected to the SYNC/MODE pin. The turn-on of

the top MOSFET is synchronized to the rising edge of the

external clock.

When the LTC1875 is clocked by an external source, Burst

Mode operation is disabled. In this synchronized mode,

when the output load current is very low, current compara-

tor, I

COMP

, may remain tripped for several cycles and force

the main switch to stay off for the same number of cycles.

Increasing the output load slightly allows constant fre-

quency PWM operation to resume.

Frequency synchronization is inhibited when the feedback

voltage V

is below 0.6V. This prevents the external clock

from interfering with the frequency foldback for short-

circuit protection.

Low Dropout Operation

When the input supply voltage decreases toward the

output voltage in a buck regulator, the duty cycle in-

creases toward the maximum on-time. Further reduction

of the supply voltage forces the main switch to remain on

for more than one cycle until it reaches 100% duty cycle.

The output voltage will then be determined by the input

voltage minus the voltage drop across the top MOSFET

and the inductor.

Low Supply Operation

The LTC1875 is designed to operate down to an input

supply voltage of 2.65V although the maximum allowable

output current is reduced at this low voltage. Figure 2

shows the reduction in the maximum output current as a

function of input voltage.

Another important detail to remember is that at low input

supply voltages, the R

DS(ON)

of the P-channel switch

increases. Therefore, the user should calculate the power

dissipation when the LTC1875 is used at 100% duty cycle

with low supply voltage (see Thermal Considerations in

the Applications Information section).

INPUT VOLTAGE (V)

2.5

MAX OUTPUT CURRENT (mA)

500

1000

1500

2000

3.5 4.5 5.5 6.5

1875 F02

7.5

OUT

= 1.5V

OUT

= 2.5V

OUT

= 3.3V

Figure 2. Maximum Output Current vs Input Voltage

OPERATIO

(Refer to Block Diagram)

LTC1875

1875f

OPERATIO

Slope Compensation and Inductor Peak Current

Slope compensation is required in order to prevent sub-

harmonic oscillation at high duty cycles. It is accom-

plished by internally adding a compensating ramp to the

inductor current signal at duty cycles in excess of 40%. As

a result, the maximum inductor peak current is reduced for

duty cycles >40%. This is shown in the decrease of the

inductor peak current as a function of duty cycle graph in

Figure 3.

Figure 3. Maximum Inductor Peak Current vs Duty Cycle

APPLICATIO S I FOR ATIO

WUUU

The basic LTC1875 application circuit is shown on the first

page of this data sheet. External component selection is

driven by the load requirement and begins with the selec-

tion of L followed by C

and C

OUT

Inductor Value Calculation

The inductor selection will depend on the operating fre-

quency of the LTC1875. The internal nominal frequency is

550kHz, but can be externally synchronized from 350kHz

to 750kHz.

The operating frequency and inductor selection are inter-

related in that higher operating frequencies allow the use

of smaller inductor and capacitor values. However, oper-

ating at a higher frequency results in lower efficiency

because of increased switching losses.

The inductor value has a direct effect on ripple current. The

ripple current ∆I

decreases with higher inductance or

frequency and increases with higher input voltages.

∆=

()()











IfL

L OUT OUT

11–

(1)

Accepting larger values of ∆I

allows the use of smaller

inductors, but results in higher output voltage ripple.

A reasonable starting point for setting ripple current is

∆I

= 0.3(I

MAX

The inductor value also has an effect on Burst Mode

operation. The transition to low current operation begins

when the inductor current peaks fall to approximately

500mA. Lower inductor values (higher ∆I

) will cause this

to occur at lower load currents, which can cause a dip in

efficiency in the upper range of low current operation. In

Burst Mode operation, lower inductance values will cause

the burst frequency to increase.

Inductor Selection

The inductor should have a saturation current rating

greater than the peak inductor current set by the current

comparator of LTC1875. Also, consideration should be

given to the resistance of the inductor. Inductor conduc-

tion losses are directly proportional to the DC resistance

of the inductor.

Manufacturers sometimes provide maxi-

mum current ratings based on the allowable losses in the

inductor.

Suitable inductors are available from Coilcraft, Coiltron-

ics, Dale, Sumida, Toko, Murata, Panasonic and other

manufacturers.

DUTY CYCLE (%)

MAXIMUM INDUCTOR PEAK CURRENT (mA)

2200

2000

1800

1600

1400

1200

1000

800 20 40 60 80

1875 F03

100

= 3V

LTC1875

1875f

and C

OUT

Selection

In continuous mode, the source current of the top MOSFET

is a trapezoidal waveform of duty cycle V

OUT

. To

prevent large voltage transients, a low ESR input capacitor

sized for the maximum RMS current must be used. The

maximum RMS input capacitor current is given by:

VVV

RMS CIN OMAX OUT IN OUT

()

(– )

≅

[]

This formula has a maximum at VIN = 2VOUT, where

IRMS = IOUT/2. This simple worst-case condition is com-

monly used for design because even significant devia-

tions do not offer much relief. Note that the capacitor

manufacturer’s ripple current ratings are often based on

2000 hours of life. This makes it advisable to further

derate the capacitor, or choose a capacitor rated at a

higher temperature than required. Several capacitors may

also be paralleled to meet size or height requirements in

the design. Always consult the manufacturer if there are

any questions.

Depending on how the LTC1875 circuit is powered up,

you may need to check for input voltage transients. Input

voltage transients may be caused by input voltage steps

or by connecting the circuit to an already powered up

source such as a wall adapter. The sudden application of

input voltage will cause a large surge of current in the

input leads that will store energy in the parasitic induc-

tance of the leads. This energy will cause the input voltage

to swing above the DC level of the input power source and

it may exceed the maximum voltage rating of the input

capacitor and LTC1875.

The easiest way to suppress input voltage transients is to

add a small aluminum electrolytic capacitor in parallel

with the low ESR input capacitor. The selected capacitor

needs to have the right amount of ESR in order to critically

dampen the resonant circuit formed by the input lead

inductance and the input capacitor. The typical values of

ESR will fall in the range of 0.5Ω to 2Ω and capacitance

will fall in the range of 5µF to 50µF.

The selection of C

OUT

is driven by the required effective

series resistance (ESR). Typically, once the ESR require-

ment is satisfied, the capacitance is adequate for filtering.

The output ripple ∆V

OUT

is determined by:

∆≅∆ +











V I ESR fC

OUT L OUT

where f = operating frequency, C

OUT

= output capacitance

and ∆I

= ripple current in the inductor. The output ripple

is highest at maximum input voltage since ∆I

increases

with input voltage. For the LTC1875, the general rule for

proper operation is:

ESR

COUT

< 0.125Ω

The choice of using a smaller output capacitance in-

creases the output ripple voltage due to the frequency

dependent term but can be compensated for by using

capacitor(s) of very low ESR to maintain low ripple volt-

age. The I

pin compensation components can be opti-

mized to provide stable high performance transient

response regardless of the output capacitor selected.

Manufacturers such as Taiyo Yuden, AVX, Kemet and

Sanyo should be considered for low ESR, high perfor-

mance capacitors. The POSCAP solid electrolytic chip

capacitor available from Sanyo is an excellent choice for

output bulk capacitors due to its low ESR/size ratio. Once

the ESR requirement for COUT has been met, the RMS

current rating generally far exceeds the IRIPPLE(P-P)

requirement.

Output Voltage Programming

The output voltage is set by a resistor divider according to

the following formula:

OUT =+











08 1 1

(2)

The external resistor divider is connected to the output,

allowing remote voltage sensing as shown in Figure 4.

APPLICATIO S I FOR ATIO

WUUU

LTC1875

1875f

APPLICATIO S I FOR ATIO

WUUU

filter network on the PLL_LPF pin. The relationship be-

tween the voltage on the PLL_LPF pin and operating

frequency is shown in Figure 5. A simplified block diagram

is shown in Figure 6.

If the external frequency (V

SYNC/MODE

) is greater than

550kHz, the center frequency, current is sourced continu-

ously, pulling up the PLL_LPF pin. When the external

frequency is less than 550kHz, current is sunk continu-

ously, pulling down the PLL_LPF pin. If the external and

internal frequencies are the same but exhibit a phase

difference, the current sources turn on for an amount of

time corresponding to the phase difference. Thus the

voltage on the PLL_LPF pin is adjusted until the phase and

frequency of the external and internal oscillators are

identical. At this stable operating point the phase com-

parator output is open and the filter capacitor C

holds the

voltage.

The loop filter components C

and R

smooth out the

current pulses from the phase detector and provide a

stable input to the voltage controlled oscillator. The filter

components C

and R

determine how fast the loop

acquires lock. Typically R

= 10k and C

is 2200pF to

0.01µF. When not synchronized to an external clock, the

internal connection to the VCO is disconnected. This

disallows setting the internal oscillation frequency by a DC

voltage on the V

PLLLPF

pin.

Figure 5. Relationship Between Oscillator Frequency

and Voltage at PLL_LPF Pin

DIGITAL

PHASE/

FREQUENCY

DETECTOR

SYNC/

MODE

PLL_LPF

2.4V C

1875 F06

VCO

Figure 6. Phase-Locked Loop Block Diagram

Phase-Locked Loop and Frequency Synchronization

The LTC1875 has an internal voltage-controlled oscillator

and phase detector comprising a phase-locked loop. This

allows the MOSFET turn-on to be locked to the rising edge

of an external frequency source. The frequency range of

the voltage-controlled oscillator is 350kHz to 750kHz. The

phase detector used is an edge sensitive digital type that

provides zero degrees phase shift between the external

and internal oscillators. This type of phase detector will not

lock up on input frequencies close to the harmonics of the

VCO center frequency. The PLL hold-in range ∆f

is equal

to the capture range, ∆f

= ∆f

= ±200kHz.

The output of the phase detector is a pair of complemen-

tary current sources charging or discharging the external

LTC1875

0.8V ≤ V

OUT

≤ 6V

SGND

1875 F04

Figure 4. Setting the LTC1875 Output Voltage

PLLLPF

(V)

OSC FREQUECNY (kHz)

1000

900

800

700

600

500

400

300

200

100

1875 F05

0.5 1 1.5 2

LTC1875

1875f

Efficiency Considerations

The 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. Efficiency can be expressed as:

Efficiency = 100% – (L1 + L2 + L3 + ...)

Where L1, L2, etc. are the individual losses as a percentage

of input power.

Although all dissipative elements in the circuit produce

losses, two main sources usually account for most of the

losses in LTC1875 circuits: supply quiescent currents and

R losses. The supply quiescent current loss dominates

the efficiency loss at very low load current whereas the I

loss dominates the efficiency loss at medium to high load

currents. In a typical efficiency plot, the efficiency curve at

very low load currents can be misleading since the actual

power lost is of no consequence as illustrated in Figure 7.

The supply quiescent current is due to two compo-

nents: the DC bias current as given in the Electrical

Characteristics and the internal main switch and syn-

chronous switch gate charge currents. The gate charge

current results from switching the gate capacitance of

the internal power MOSFET switches. Each time the

gate is switched from high to low to high again, a

packet of charge dQ moves from PVIN to ground. The

resulting dQ/dt is the current out of PVIN that is typically

larger than the DC bias current. In continuous mode,

IGATECHG = f(QT + QB) where QT and QB are the gate

charges of the internal top and bottom switches. Both

the DC bias and gate charge losses are proportional to

supply voltage and thus their effects will be more

pronounced at higher supply voltages.

2. I

R losses are calculated from the resistances of the

internal switches R

and external inductor R

. In

continuous mode the average output current flowing

through inductor L is “chopped” between the main

switch and the synchronous switch. Thus, the series

resistance looking into SW pins is a function of both top

and bottom MOSFET R

DS(ON)

and the duty cycle (DC) as

follows:

= (R

DS(ON)TOP

)(DC) + R

DS(ON)BOT

)(1 – DC)

The R

DS(ON)

for both the top and bottom MOSFETs can

be obtained from the Typical Performance Characteris-

tics curves. Thus, to obtain I

R losses, simply add R

to R

and multiply by the square of the average output

current.

Other losses including C

and C

OUT

ESR dissipative

losses, MOSFET switching losses and inductor core losses

generally account for less than 2% total additional loss.

Thermal Considerations

In most applications, the LTC1875 does not dissipate

much heat due to its high efficiency. But, in applications

where the LTC1875 is running at high ambient tempera-

ture with low supply voltage and high duty cycles, such as

in dropout, the heat dissipated may exceed the maximum

junction temperature of the part. If the junction tempera-

ture reaches approximately 150°C, both power switches

will be turned off and the SW nodes will become high

impedance.

APPLICATIO S I FOR ATIO

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Figure 7. Power Lost vs Load Current

LOAD CURRENT (mA)

0.001

POWER LOST (W)

0.01

0.1

0.1 10 100 1000

1875 F07

0.0001 1

= 6V

OUT

= 3.3V

L = 6.8µH

Burst Mode

OPERATION

LTC1875

1875f

To avoid the LTC1875 from exceeding the maximum

junction temperature, the user will need to do some

thermal analysis. The goal of the thermal analysis is to

determine whether the power dissipated exceeds the

maximum junction temperature of the part. Normally,

some iterative calculation is required to determine a rea-

sonably accurate value. The temperature rise is given by:

= P • θ

where P is the power dissipated by the regulator and θ

is the thermal resistance from the junction of the die to the

ambient temperature.

The junction temperature is given by:

= T

+ T

where TA is the ambient temperature. Because the power

transistor RDS(ON) is a function of temperature, it is

usually necessary to iterate 2 to 3 times through the

equations to achieve a reasonably accurate value for the

junction temperature.

As an example, consider the LTC1875 in dropout at an

input voltage of 3V, a load current of 0.8A and an ambient

temperature of 70°C. From the typical performance graph

of switch resistance, the R

DS(ON)

of the P-channel switch

at 70°C is 0.35Ω. Therefore, power dissipated by the IC is:

P = I

• R

DS(ON)

= 0.224W

For the SSOP package, the θ

is 110°C/W. Thus the

junction temperature of the regulator is:

= 70°C + (0.224)(110) = 95°C

However, at this temperature, the R

DS(ON)

is actually 0.4Ω.

Therefore:

= 70°C + (0.256)(140) = 98°C

which is below the maximum junction temperature of

125°C.

Note that at higher supply voltages, the junction tempera-

ture is lower due to reduced switch resistance (R

DS(ON)

Checking Transient Response

The regulator loop response can be checked by looking at

the load transient response. Switching regulators take

several cycles to respond to a step in load current. When

a load step occurs, V

OUT

immediately shifts by an amount

equal to (∆I

LOAD

• ESR), where ESR is the effective series

resistance of C

OUT

. ∆I

LOAD

also begins to charge or

discharge C

OUT

, generating a feedback error signal. The

regulator loop then acts to return V

OUT

to its steady-state

value. During this recovery time, V

OUT

can be monitored

for overshoot or ringing that would indicate a stability

problem. The I

pin can be used for external compensa-

tion as shown in Figure 9. (The capacitor, C

, is typically

needed for noise decoupling.)

A second, more severe transient is caused by switching in

loads with large (>1µF) supply bypass capacitors. The

discharged bypass capacitors are effectively put in parallel

with C

OUT

, causing a rapid drop in V

OUT

. No regulator can

deliver enough current to prevent this problem if the load

switch resistance is low and it is driven quickly. The only

solution is to limit the rise time of the switch drive so that

the load rise time is limited to approximately (25 • C

LOAD

Thus, a 10µF capacitor charging to 3.3V would require a

250µs rise time, limiting the charging current to about

130mA.

APPLICATIO S I FOR ATIO

WUUU

LTC1875

1875f

DUT

RSVIN

RPL

PGND VOUT

VIN

COUT

CIN2

CIN1

RPG

CPL

CC2

CC1

RFB2

RSS

CSS

RFB1

VIA CONNECTION TO RFB1

VIA CONNECTION TO VIN

VIAS TO GND PLANE

1875 F08

APPLICATIO S I FOR ATIO

WUUU

PC Board Layout Checklist

As with all high frequency switchers, when considering

layout, care must be taken in order to achieve optimal

electrical, thermal and noise performance. Figure 8 is a

sample of PC board layout for the design example shown

in Figure 9. A 4-layer PC board is used in this design.

Several guidelines are followed in this layout:

1. In order to minimize switching noise and improve

output load regulation, the PGND pins of the LTC1875

should be connected directly to 1) the negative terminal

of the output decoupling capacitors, 2) the negative

terminal of the input capacitor and 3) vias to the ground

plane immediately adjacent to Pins 1, 7 and 10. The

ground trace on the top layer of the PC board should be

as wide and short as possible to minimize series resis-

tance and inductance.

2. Beware of ground loops in multiple layer PC boards. Try

to maintain one central ground node on the board and

use the input capacitor to avoid excess input ripple for

high output current power supplies. If the ground is to

be used for high DC currents, choose a path away from

the small-signal components.

3. The high di/dt loop from the top terminal of the input

capacitor, through the power MOSFETs and back to the

input capacitor should be kept as tight as possible to

reduce inductive ringing. Excess inductance can cause

increased stress on the power MOSFET and increase

noise on the input. If low ESR ceramic capacitors are

used to reduce input noise, place these capacitors close

to the DUT in order to keep the series inductance to a

minimum.

Figure 8. Typical Application and Suggested Layout (Topside Only)

LTC1875

1875f

APPLICATIO S I FOR ATIO

WUUU

4. Place the small-signal components away from high

frequency switching nodes. In the layout shown in

Figure 8, all of the small-signal components have been

placed on one side of the IC and all of the power

components have been placed on the other.

5. For optimum load regulation and true sensing, the top

of the output resistor divider should connect indepen-

dently to the top of the output capacitor (Kelvin connec-

tion), staying away from any high dV/dt traces. Place

the divider resistors near the LTC1875 in order to keep

the high impedance FB node short.

Design Example

As a design example, assume the LTC1875 is used in a

single lithium-ion battery-powered cellular phone applica-

tion. The V

will be operating from a maximum of 4.2V

down to about 2.65V. The load current requirement is a

maximum of 1.5A but most of the time it will be on standby

mode, requiring only 2mA. Efficiency at both low and high

load currents is important. Output voltage is 2.5V. With

this information we can calculate L using equation (1),

LfI

LOUT OUT

()

∆

()











11–

(3)

Substituting VOUT = 2.5V, VIN = 4.2V, ∆IL = 450mA and

f = 550kHz in equation (3) gives:

kHz mA

VH=







=µ

550 450 125

42 409

•–.

A 4.7µH inductor works well for this application. For good

efficiency choose a 2A inductor with less than 0.125Ω

series resistance.

will require an RMS current rating of at least 0.75A at

temperature and C

OUT

will require an ESR of less than

0.125Ω. In most applications, the requirements for these

capacitors are fairly similar.

For the feedback resistors, choose R2 = 412k. R1 can then

be calculated from equation (2) to be:

RVR k use k

OUT

108 1 2 875 5 887=







=

.–• .,

Figure 9 shows the complete circuit along with its effi-

ciency curve.

LTC1875

1875f

1875 F09a

SWP

SWN

150k

PLL_LPF

RUN/SS

PGOOD

SGND

PGND

SYNC/MODE

SVIN

10Ω

LTC1875 L1

4.7µHV

OUT

2.5V/1.5A

2.65V TO 4.2V

GND

R1 887k

412k

IN1

10µF

OUT

47µF

1513

SVIN

0.1µF

47pF

BOLD LINES INDICATE HIGH CURRENT PATHS

220pF

IN1

, C

IN2

: TAIYO-YUDEN CERAMIC JMK316BJ106ML

OUT

: TDK CERAMIC C4532X5R0J476M

L1: TOKO A921CY-4R7M

*1.5A IS THE MAXIMUM OUTPUT CURRENT

POWER

GOOD

100k

0.1µF

IN2

10µF

Figure 9a. Single Lithium-Ion to 2.5V/1.5A Regulator from Design Example

APPLICATIO S I FOR ATIO

WUUU

Figure 9b. Efficiency vs Output Current for Design Example

OUTPUT CURRENT (mA)

EFFICIENCY (%)

100

600.1 10 100

1875 F09b

1 1000

= 4.2V

= 3V

OUT

= 2.5V

L = 4.7µH

= 3.6V

LTC1875

1875f

1875 TA02

SWP

SWN

150k

PLL_LPF

RUN/SS

PGOOD

SGND

PGND

SYNC/MODE

SVIN

10Ω

LTC1875 L1

4.7µH

OUT

1.8V/1.5A

3V TO 4.2V

GND

IN1

10µF

OUT

47µF

1513

SVIN

0.1µF

47pF

BOLD LINES INDICATE HIGH CURRENT PATHS

220pF

IN1

, C

IN2

: TAIYO YUDEN CERAMIC JMK316BJ106ML

OUT

: TDK CERAMIC C4532X5R0J476M

L1: TOKO A921CY-4R7M

*1.5A IS THE MAXIMUM OUTPUT CURRENT

100k

0.1µF

POWER

GOOD C

IN2

10µF

R1 523k

412k

TYPICAL APPLICATIO

Single Li-Ion to 1.8V/1.5A Regulator Using All Ceramic Capacitors

Efficiency vs Output Current

OUPUT CURRENT (mA)

EFFICIENCY (%)

100

400.1 10 100

1875 TA02a

1 1000

VOUT = 1.8V

L = 4.7µH

VIN = 4.2V

VIN = 3.3V

LTC1875

1875f

PACKAGE DESCRIPTION

GN Package

16-Lead Plastic SSOP (Narrow .150 Inch)

(Reference LTC DWG # 05-08-1641)

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 represen-

tation that the interconnection of its circuits as described herein will not infringe on existing patent rights.

GN16 (SSOP) 0502

345678

.229 – .244

(5.817 – 6.198)

.150 – .157**

(3.810 – 3.988)

16 15 14 13

.189 – .196*

(4.801 – 4.978)

12 11 10 9

.016 – .050

(0.406 – 1.270)

.015 ± .004

(0.38 ± 0.10) × 45°

0° – 8° TYP

.007 – .0098

(0.178 – 0.249)

.053 – .068

(1.351 – 1.727)

.008 – .012

(0.203 – 0.305)

.004 – .0098

(0.102 – 0.249)

.0250

(0.635)

BSC

.009

(0.229)

REF

.254 MIN

RECOMMENDED SOLDER PAD LAYOUT

.150 – .165

.0250 TYP.0165 ±.0015

.045 ±.005

*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

INCHES

(MILLIMETERS)

NOTE:

1. CONTROLLING DIMENSION: INCHES

2. DIMENSIONS ARE IN

3. DRAWING NOT TO SCALE

LTC1875

1875f

 LINEAR TECHNOLOGY CORPORATION 2001

LT/TP 0403 2K • PRINTED IN USA

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900

●

FAX: (408) 434-0507

●

www.linear.com

1875 TA03

SWP

SWN

150k

PLL_LPF

RUN/SS

PGOOD

SGND

PGND

SYNC/MODE

SVIN

10Ω

LTC1875 L1

4.7µHV

OUT

3.3V*

1A**

3V TO 4.2V

GND

IN1

10µF

OUT

47µF

1513

SVIN

0.1µF

POWER

GOOD

47pF

BOLD LINES INDICATE HIGH CURRENT PATHS

220pF

100k

0.1µF

IN2

10µF

1.29M

412k C

IN1

, C

IN2

: TAIYO YUDEN CERAMIC JMK316BJ106ML

OUT

: TDK CERAMIC C4532X5R0J476M

L1: TOKO A921CY-4R7M

OUT

CONNECTED TO V

FOR 3V < V

< 3.3V

**1A IS THE MAXIMUM OUTPUT CURRENT

TYPICAL APPLICATIO

Single Li-Ion to 3.3V/1A Regulator Using All Ceramic Capacitors

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ThinSOT is a trademark of Linear Technology Corporation.