LT1054L_15 Datasheet, PDF(7/16 Page) Linear Technology – Switched-Capacitor Voltage Converter with Regulator

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LT1054L_15 Datasheet, PDF (7/16 Pages) Linear Technology – Switched-Capacitor Voltage Converter with Regulator

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LT1054/LT1054L

Pin Functions

is charging, the peak supply current will be approximately

equal to 2.2 times the output current. During the time that

CIN is delivering charge to COUT the supply current drops

to approximately 0.2 times the output current. An input

supply bypass capacitor will supply part of the peak input

current drawn by the LT1054 and average out the current

drawn from the supply. A minimum input supply bypass

capacitor of 2ÂµF, preferably tantalum or some other low ESR

type is recommended. A larger capacitor may be desirable

in some cases, for example, when the actual input supply

is connected to the LT1054 through long leads, or when

the pulse current drawn by the LT1054 might affect other

circuitry through supply coupling.

Applications Information

Theory of Operation

To understand the theory of operation of the LT1054, a re-

view of a basic switched-capacitor building block is helpful.

In Figure 3 when the switch is in the left position, capaci-

tor C1 will charge to voltage V1. The total charge on C1

will be q1 = C1V1. The switch then moves to the right,

discharging C1 to voltage V2. After this discharge time

the charge on C1 is q2 = C1V2. Note that charge has been

transferred from the source V1 to the output V2. The

amount of charge transferred is:

âq = q1 â q2 = C1(V1 â V2)

If the switch is cycled f times per second, the charge

transfer per unit time (i.e., current) is:

I = (f)(âq) = (f)[C1(V1 â V2)]

To obtain an equivalent resistance for the switched-

capacitor network we can rewrite this equation in terms

of voltage and impedance equivalence:

I= V1â V2 = V1â V2

1/ fC1 REQUIV

A new variable REQUIV is defined such that REQUIV = 1/fC1.

Thus the equivalent circuit for the switched-capacitor

network is as shown in Figure 4. The LT1054 has the same

switching action as the basic switched-capacitor building

block. Even though this simplification doesnât include finite

switch on-resistance and output voltage ripple, it provides

an intuitive feel for how the device works.

These simplified circuits explain voltage loss as a function

of frequency (see Typical Performance Characteristics).

As frequency is decreased, the output impedance will

LT1054 â¢ F03

Figure 3. Switched-Capacitor Building Block

REQUIV

fC1

LT1054 â¢ F04

Figure 3. Switched-Capacitor Equivalent Circuit

eventually be dominated by the 1/fC1 term and voltage

losses will rise.

Note that losses also rise as frequency increases. This is

caused by internal switching losses which occur due to

some finite charge being lost on each switching cycle. This

charge loss per-unit-cycle, when multiplied by the switching

frequency, becomes a current loss. At high frequency this

loss becomes significant and voltage losses again rise.

The oscillator of the LT1054 is designed to run in the

frequency band where voltage losses are at a minimum.

Regulation

The error amplifier of the LT1054 servos the drive to the

PNP switch to control the voltage across the input capaci-

tor (CIN) which in turn will determine the output voltage.

Using the reference and error amplifier of the LT1054,

an external resistive divider is all that is needed to set

the regulated output voltage. Figure 5 shows the basic

regulator configuration and the formula for calculating

the appropriate resistor values. R1 should be chosen to

1954lfh

For more information www.linear.com/LT1054

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