SP6644 Datasheet, PDF(8/15 Page) Sipex Corporation – Single/Dual Alkaline Cell, High Efficiency Step-Up DC-DC Converter

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SP6644 Datasheet, PDF (8/15 Pages) Sipex Corporation – Single/Dual Alkaline Cell, High Efficiency Step-Up DC-DC Converter

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DESCRIPTION

The SP6644/6645 devices are high-efficiency,

low-power step-up DC-DC converters ideal for

single or dual alkaline cell applications such as

pagers, remote controls, and other low-power

portable end products.

The SP6644/6645 devices feature a 5nA logic-

controlled shutdown mode and a dedicated

low-battery detector circuitry. Both devices

contain a 0.8â¦ synchronous rectifier, a 0.5â¦

N-channel MOSFET power switch, an internal

voltage reference, circuitry for pulse-frequency-

modulation, and an under voltage comparator.

The output voltage for the SP6644/6645 devices

can be adjusted from +2V to +5.5V by

manipulating two external resistors. The output

voltage is preset to +3.3V.

THEORY OF OPERATION

The SP6644/6645 devices are ideal for end

products that function with a single or dual alkaline

cell, such as remote controls, pagers, and other

portable consumer products. Designers can

implement the SP6644/6645 devices into

applications with the following power

management operating states: 1. where the

primary battery is good and the load is active, and

2. where the primary battery is good and

the load is sleeping.

In the first operating state where the primary

supply is good and the load is active, the

SP6644/6645 devices typically offer 88%

efficiency, drawing tens of milliamps.

Applications will predominantly operate in the

second state where the primary supply is good

and the load is sleeping. The SP6644/6645 devices

draw a very low quiescent current while the load

in its disabled state will draw typically hundreds

of microamps.

The pulse-frequency-modulation (PFM) circuitry

provides higher efficiencies at low to moderate

output loads than traditional PWM converters are

capable of delivering.

In a state where the error comparator detects that

the output voltage at VOUT is too low, the internal

N-channel MOSFET switch is turned on until the

peak inductor current is satisfied. This is indicated

by the falling edge of the I-Charge comparator

output. The approximate inductor charging time

is defined by:

tCHARGE â L x IPEAK / VBATT

where tCHARGE [s] is the approximate inductor

charging time, L [H] is the inductance, I [A]

PEAK

is the peak inductor current, and V [V] is the

BATT

input voltage to the device.

The peak inductor current, IPEAK, is programmed

externally by putting a resistor between the RLIM

pin and ground. 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.

When the charging N MOSFET turns off, the

discharging P MOSFET turns on and the inductor

current flows into the output capacitor and the

load recharging the output. When the current

through the discharging P MOSFET approaches

zero, the I-Discharge comparator indicates to the

logic to turn off the P MOSFET. The approximate

time for discharging the inductor current can be

determined by:

tDCHG â

L x IPEAK

VOUT - VBATT

where t [s] is the time to discharge the

DCHG

inductor, L [H] is the inductance, I [A] is the

PEAK

peak inductor current, V [V] is the output

OUT

voltage, and VBATT [V] is the input voltage to the

device.

The output filter capacitor stores charge while

current from the inductor is high and holds the

output voltage high until the discharge phase of

the next switching cycle, smoothing power flow

to the load. Between switching cycles, the

inductor damping switch is closed suppressing

the ringing caused by the inductor and the parasitic

capacitance on the LX node.

Date: 11/30/04

SP6644/6645 High Efficiency Boost Regulator

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