ICL7673_05 Datasheet, PDF(4/7 Page) Intersil Corporation

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ICL7673_05 Datasheet, PDF (4/7 Pages) Intersil Corporation – Automatic Battery Back-Up Switch

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ICL7673

1mA

100mA

10nA

1nA

ILOAD = 10mA

VS = 0V

85Â°C

1000pA

10pA

25Â°C

1pA

4 56

INPUT VP (V)

FIGURE 5. IS LEAKAGE CURRENT VP TO VS AS A

FUNCTION OF INPUT VOLTAGE

Detailed Description

As shown in the Functional Diagram, the ICL7673 includes a

comparator which senses the input voltages VP and VS. The

output of the comparator drives the first inverter and the

open-drain N-Channel transistor PBAR. The first inverter

drives a large P-Channel switch, P1, a second inverter, and

another open-drain N-Channel transistor, SBAR. The second

inverter drives another large P-Channel switch P2. The

ICL7673, connected to a main and a backup power supply,

will connect the supply of greater potential to its output. The

circuit provides break-before-make switch action as it

switches from main to backup power in the event of a main

power supply failure. For proper operation, inputs VP and VS

must not be allowed to float, and, the difference in the two

supplies must be greater than 50mV. The leakage current

through the reverse biased parasitic diode of switch P2 is

very low.

Output Voltage

The output operating voltage range is 2.5V to 15V. The

insertion loss between either input and the output is a

function of load current, input voltage, and temperature. This

is due to the P-Channels being operated in their triode

region, and, the ON-resistance of the switches is a function

of output voltage VO. The ON-resistance of the P-Channels

have positive temperature coefficients, and therefore as

temperature increases the insertion loss also increases. At

low load currents the output voltage is nearly equal to the

greater of the two inputs. The maximum voltage drop across

switch P1 or P2 is 0.5V, since above this voltage the body-

drain parasitic diode will become forward biased. Complete

switching of the inputs and open-drain outputs typically

occurs in 50Âµs.

Input Voltage

The input operating voltage range for VP or VS is 2.5V to

15V. The input supply voltage (VP or VS) slew rate should be

limited to 2V per microsecond to avoid potential harm to the

circuit. In line-operated systems, the rate-of-rise (or fall) of

the supply is a function of power supply design. For battery

applications it may be necessary to use a capacitor between

the input and ground pins to limit the rate-of-rise of the

supply voltage. A low-impedance capacitor such as a

0.047ÂµF disc ceramic can be used to reduce the rate-of-rise.

Status Indicator Outputs

The N-Channel open drain output transistors can be used to

indicate which supply is connected, or can be used to drive

external PNP transistors to increase the power switching

capability of the circuit. When using external PNP power

transistors, the output current is limited by the beta and

thermal characteristics of the power transistors. The

application section details the use of external PNP

transistors.

Applications

A typical discrete battery backup circuit is illustrated in Figure

6. This approach requires several components, substantial

printed circuit board space, and high labor cost. It also

consumes a fairly high quiescent current. The ICL7673

battery backup circuit, illustrated in Figure 7, will often replace

such discrete designs and offer much better performance,

higher reliability, and lower system manufacturing cost. A

trickle charge system could be implemented with an additional

resistor and diode as shown in Figure 8. A complete low

power AC to regulated DC system can be implemented using

the ICL7673 and ICL7663S micropower voltage regulator as

shown in Figure 9.

+5V

PRIMARY

DC POWER

+5V OR

+3V

STATUS

INDICATOR

NiCAD

BATTERY

STACK

GND

FIGURE 6. DISCRETE BATTERY BACKUP CIRCUIT

FN3183.4

July 22, 2005

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