LTC3109 Linear Technology, LTC3109 Datasheet - Page 17

LTC3109

Manufacturer Part Number

LTC3109

Description

Ultralow Voltage Step-Up Converter and Power Manager

Manufacturer

Linear Technology

Datasheet

1.LTC3109.pdf (24 pages)

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applicaTions inForMaTion

DESIGN EXAMPLE 1

This design example will explain how to calculate the

necessary reservoir capacitor value for V

load applications, such as a wireless sensor/transmitter.

In these types of applications, the load is very small for a

majority of the time (while the circuitry is in a low power

sleep state), with pulses of load current occurring periodi-

cally during a transmit burst.

The reservoir capacitor on V

the transmit pulse; the long sleep time between pulses

allows the LTC3109 to accumulate energy and recharge

the capacitor (either from the input voltage source or the

storage capacitor). A method for calculating the maximum

rate at which the load pulses can occur for a given output

current from the LTC3109 will also be shown.

In this example, V

allowed voltage droop during a transmit pulse is 10%, or

0.33V. The duration of a transmit pulse is 5ms, with a total

average current requirement of 20mA during the pulse.

Given these factors, the minimum required capacitance

on V

Note that this equation neglects the effect of capacitor ESR

on output voltage droop. For ceramic capacitors and low

ESR tantalum capacitors, the ESR will have a negligible

effect at these load currents. However, beware of the voltage

coefficient of ceramic capacitors, especially those in small

case sizes. This greatly reduces the effective capacitance

when a DC bias is applied.

A standard value of 330µF could be used for C

this case. Note that the load current is the total current

draw on V

of these outputs must come from V

Current contribution from the capacitor on VSTORE is not

considered, since it may not be able to recharge between

pulses. Also, it is assumed that the harvested charge

current from the LTC3109 is negligible compared to the

magnitude of the load current during the pulse.

OUT

( )

is:

µF

OUT

≥

, V

OUT2

0 33

OUT

and VLDO, since the current for all

•

is set to 3.3V, and the maximum

OUT

303

supports the load during

µF

OUT

during a pulse.

OUT

in pulsed-

OUT

To calculate the maximum rate at which load pulses can

occur, you must know how much charge current is avail-

able from the LTC3109 V

source being used. This number is best found empirically,

since there are many factors affecting the efficiency of the

converter. You must also know what the total load cur-

rent is on V

Note that this must include any losses, such as storage

capacitor leakage.

Let’s assume that the charge current available from the

LTC3109 is 150µA and the total current draw on V

VLDO in the sleep state is 17µA, including capacitor leakage.

We’ll also use the value of 330µF for the V

The maximum transmit rate (neglecting the duration of

the transmit pulse, which is very short compared to the

period) is then given by:

Therefore, in this application example, the circuit can sup-

port a 5ms transmit pulse of 20mA every 0.82 seconds.

It can be seen that for systems that only need to transmit

every few seconds (or minutes or hours), the average

charge current required is extremely small, as long as

the sleep or standby current is low. Even if the available

charge current in the example above was only 21µA, if the

sleep current was only 5µA, it could still transmit a pulse

every seven seconds.

The following formula will allow you to calculate the time

it will take to charge the LDO output capacitor and the

the charge current available from the LTC3109 must be

known. For this calculation, it is assumed that the LDO

output capacitor is 2.2µF:

If there was 150µA of charge current available and a 5µA

load on the LDO (when the processor is sleeping), the time

for the LDO to reach regulation would be only 33ms.

OUT

LDO

capacitor the first time, from zero volts. Here again,

330

150

2 2

µF

µA

CHG

OUT

• .

–

0 33

• .

–

during the sleep state (between pulses).

2 2

LDO

µA

µF

0 82

OUT

sec

pin given the input voltage

or f

MAX

www.DataSheet4U.com

LTC3109

OUT

1 2

capacitor.

OUT

and

3109f

LTC3109 Linear Technology, LTC3109 Datasheet - Page 17

LTC3109

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