LT1308A_15 Datasheet, PDF(8/20 Page) Linear Technology – High Current, Micropower Single Cell, 600kHz DC/DC Converters

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LT1308A_15 Datasheet, PDF (8/20 Pages) Linear Technology – High Current, Micropower Single Cell, 600kHz DC/DC Converters

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LT1308A/LT1308B

APPLICATIONS INFORMATION

OPERATION

The LT1308A combines a current mode, ï¬xed frequency

PWM architecture with Burst Mode micropower opera-

tion to maintain high efï¬ciency at light loads. Operation

can be best understood by referring to the block diagram

in Figure 2. Q1 and Q2 form a bandgap reference core

whose loop is closed around the output of the converter.

When VIN is 1V, the feedback voltage of 1.22V, along with

an 80mV drop across R5 and R6, forward biases Q1 and

Q2âs base collector junctions to 300mV. Because this is not

enough to saturate either transistor, FB can be at a higher

voltage than VIN. When there is no load, FB rises slightly

above 1.22V, causing VC (the error ampliï¬erâs output) to

decrease. When VC reaches the bias voltage on hyster-

etic comparator A1, A1âs output goes low, turning off

all circuitry except the input stage, error ampliï¬er and

low-battery detector. Total current consumption in this

state is 140Î¼A. As output loading causes the FB voltage to

decrease, A1âs output goes high, enabling the rest of the IC.

Switch current is limited to approximately 400mA initially

after A1âs output goes high. If the load is light, the output

voltage (and FB voltage) will increase until A1âs output goes

low, turning off the rest of the LT1308A. Low frequency

ripple voltage appears at the output. The ripple frequency

is dependent on load current and output capacitance.

This Burst Mode operation keeps the output regulated

and reduces average current into the IC, resulting in high

efï¬ciency even at load currents of 1mA or less.

If the output load increases sufï¬ciently, A1âs output

remains high, resulting in continuous operation. When the

LT1308A is running continuously, peak switch current is

controlled by VC to regulate the output voltage. The switch

is turned on at the beginning of each switch cycle. When

the summation of a signal representing switch current

and a ramp generator (introduced to avoid subharmonic

oscillations at duty factors greater than 50%) exceeds the

VC signal, comparator A2 changes state, resetting the ï¬ip-

ï¬op and turning off the switch. Output voltage increases

as switch current is increased. The output, attenuated

by a resistor divider, appears at the FB pin, closing the

overall loop. Frequency compensation is provided by an

external series RC network connected between the VC pin

and ground.

Low-battery detector A4âs open-collector output (LBO)

pulls low when the LBI pin voltage drops below 200mV.

There is no hysteresis in A4, allowing it to be used as an

ampliï¬er in some applications. The entire device is disabled

when the SHDN pin is brought low. To enable the converter,

SHDN must be at 1V or greater. It need not be tied to VIN

as on the LT1308.

The LT1308B differs from the LT1308A in that there is no

hysteresis in comparator A1. Also, the bias point on A1 is

set lower than on the LT1308B so that switching can occur

at inductor current less than 100mA. Because A1 has no

hysteresis, there is no Burst Mode operation at light loads

and the device continues switching at constant frequency.

This results in the absence of low frequency output voltage

ripple at the expense of efï¬ciency.

The difference between the two devices is clearly illus-

trated in Figure 3. The top two traces in Figure 3 shows an

LT1308A/LT1308B circuit, using the components indicated

in Figure 1, set to a 5V output. Input voltage is 3V. Load

current is stepped from 50mA to 800mA for both circuits.

Low frequency Burst Mode operation voltage ripple is

observed on Trace A, while none is observed on Trace B.

At light loads, the LT1308B will begin to skip alternate cycles.

The load point at which this occurs can be decreased by

increasing the inductor value. However, output ripple will

continue to be signiï¬cantly less than the LT1308A output

ripple. Further, the LT1308B can be forced into micropower

mode, where IQ falls from 3mA to 200Î¼A by sinking 40Î¼A

or more out of the VC pin. This stops switching by causing

A1âs output to go low.

TRACE A: LT1308A

VOUT, 100mV/DIV

AC COUPLED

TRACE B: LT1308B

VOUT, 100mV/DIV

AC COUPLED

800mA

ILOAD

50mA

200Î¼s/DIV

VIN = 3V

(CIRCUIT OF FIGURE 1)

1308 F03

Figure 3. LT1308A Exhibits Burst Mode Operation Output

Voltage Ripple at 50mA Load, LT1308B Does Not

1308abfb

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