LTC660 Datasheet, PDF(8/12 Page) Linear Technology

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LTC660 Datasheet, PDF (8/12 Pages) Linear Technology – 100mA CMOS Voltage Converter

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LTC660

TYPICAL APPLICATIONS N

Negative Voltage Converter

Figure 7 shows a typical connection which will provide a

negative supply from an available positive supply. This

circuit operates over full temperature and power supply

ranges without the need of any external diodes. The LV pin

(Pin 6) is shown grounded, but for V+ â¥ 3V, it may be

floated, since LV is internally switched to ground (Pin 3)

for V + â¥ 3V.

1 BOOST

V+ 8

2 CAP+

OSC 7

150ÂµF

LTC660

GND

4 CAPâ

VOUT 5

VIN

1.5V TO 5.5V

VOUT = âVIN

150ÂµF

LTC660 â¢ F07

Figure 7. Voltage Inverter

The output voltage (Pin 5) characteristics of the circuit are

those of a nearly ideal voltage source in series with a 6.5â¦

resistor. The 6.5â¦ output impedance is composed of two

terms: 1) the equivalent switched-capacitor resistance

(see Theory of Operation), and 2) a term related to the on-

resistance of the MOS switches.

At an oscillator frequency of 10kHz and C1 = 150ÂµF, the

first term is:

( ) REQUIV =

fOSC/2 C1

= 1.3â¦.

5 â¢ 103 â¢ 150 â¢ 10â6

Notice that the equation for REQUIV is not a capacitive

reactance equation (XC = 1/ÏC) and does not contain a

2Ï term.

The exact expression for output impedance is complex,

but the dominant effect of the capacitor is clearly shown on

the typical curves of output impedance and power effi-

ciency versus frequency. For C1 = C2 = 150ÂµF, the output

impedance goes from 6.5â¦ at fOSC = 10kHz to 110â¦ at

fOSC = 100Hz. As the 1/fC term becomes large compared

to the switch on-resistance term, the output resistance is

determined by 1/fC only.

Voltage Doubling

Figure 8 shows the LTC660 operating in the voltage

doubling mode. The external Schottky (1N5817) diode is

for start-up only. The output voltage is 2 â¢ VIN without a

load. The diode has no effect on the output voltage.

1N5817*

VIN

2.5V

TO 5.5V

C1 +

150ÂµF

1 BOOST

V+ 8

2 CAP+

OSC 7

LTC660

GND

4 CAPâ

VOUT 5

* SCHOTTKY DIODE IS FOR START-UP ONLY

VOUT = 2VIN

150ÂµF

LTC660 â¢ F08

Figure 8. Voltage Doubler

Ultraprecision Voltage Divider

An ultraprecision voltage divider is shown in Figure 9. To

achieve the 0.002% accuracy indicated, the load current

should be kept below 100nA. However, with a slight loss

in accuracy, the load current can be increased.

LTC660

150ÂµF

V+

Â± 0.002%

TMIN â¤ TA â¤ TMAX

IL â¤ 100nA

150ÂµF

V+

3V TO 11V

LTC660 â¢ F09

Figure 9. Ultraprecision Voltage Divider

Battery Splitter

A common need in many systems is to obtain positive and

negative supplies from a single battery or single power

supply system. Where current requirements are small, the

circuit shown in Figure 10 is a simple solution. It provides

symmetrical positive or negative output voltages, both

equal to one-half the input voltage. The output voltages are

both referenced to Pin 3 (Output Common).

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