SP6644 Datasheet, PDF(10/15 Page) Sipex Corporation – Single/Dual Alkaline Cell, High Efficiency Step-Up DC-DC Converter

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SP6644 Datasheet, PDF (10/15 Pages) Sipex Corporation – Single/Dual Alkaline Cell, High Efficiency Step-Up DC-DC Converter

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Internal Bootstrap Circuitry

The internal bootstrap circuitry contains a

low-voltage start-up oscillator that pumps up the

output voltage to approximately 1.9V so the

main DC-DC converter can function. At lower

battery supply voltages, the circuitry can start up

with low-load conditions. Designers can reduce

the load as needed to allow start-up with input

voltages below 1V. Refer to Figures 10 to

13. Once started, the output voltage can maintain

the load as the battery voltage decreases below

the initial start-up voltage. The start-up oscillator

is powered by VBATT driving a charge pump and

NMOS switch. During start-up, the P-channel

synchronous rectifier remains off and either its

body diode or an external diode is used as an

output rectifier.

BATTLO Circuitry

The SP6644 device has an internal comparator

for low-battery detection. If VBATT drops below

1V, BATTLO will sink current. BATTLO is an

open-drain output. The SP6645 operates in the

same manner with a threshold voltage of 2V.

Shutdown for the SP6644

A logic LOW at SHDN will drive the SP6644

into a shutdown mode where BATTLO goes

into a high-impedance state, the internal

switching MOSFET turns off, and the

synchronous rectifier turns off to prevent

reverse current from flowing from the output

back to the input. Designers should note that

in shutdown, the output can drift to one diode

drop below VBATT because there is still a forward

current path through the synchronous-rectifier

body diode from the input to the output.

To disable the shutdown feature, designers can

connect SHDN to V .

BATT

Adjustable Output Voltage

Driving FB to ground (logic LOW) will drive the

output voltage to the fixed-voltage operation of

+3.3V + 4%. Connecting FB to a voltage divider

between VOUT and ground will select an adjustable

output voltage between +2V and +5.5V. Refer to

Figure 28. FB regulates to +1.25V.

Since the FB leakage current is 10nA maximum,

designers should select the feedback resistor

R2 in the 100kâ¦ to 1Mâ¦ range. R1 can be

determined with the following equation:

R1 = R2 x

VOUT

VREF

-1

where R1 [â¦] and R2 [â¦] are the feedback

resistors in Figure 29, V [V] is the output

OUT

voltage, and V [V] is 1.25V.

REF

Battery Reversal Protection

The SP6644/6645 devices will tolerate single-

cell battery reversal up to the package power-

dissipation limits noted in the ABSOLUTE

MAXIMUM RATINGS section. An internal

diode in series with an internal 5â¦ resistor limits

any reverse current to less than 220mA

preventing damage to the devices. Prolonged

operation above 220mA reverse-battery

current can degrade performance of the devices.

The Inductor

The programmable peak inductor current feature

of the SP6644/6645 devices affords a great deal

of flexibility in choosing an inductor. The most

important point to consider when choosing an

inductor is to insure that the peak inductor current

is programmed below the saturation rating of the

inductor. If the inductor goes into saturation, the

internal switches and the inductor will be stressed

due to current peaking, potentially leading to

reliability problems with the application circuit.

The peak inductor current is programmed by

putting a resistor between the RLIM pin and ground.

The usable current range is between 150mA and

560mA. This is defined by:

IPEAK =

1400

RLIM

where IPEAK [A] is the peak inductor current, and

RLIM [â¦] is the value of the resistor connected

from pin RLIM to ground.

Date: 11/30/04

SP6644/6645 High Efficiency Boost Regulator

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