AME5130_1 Datasheet, PDF(7/16 Page) Analog Microelectronics

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AME5130_1 Datasheet, PDF (7/16 Pages) Analog Microelectronics – Micropower Step-Up DC/DC Converter

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AME

AME5130

n Electrical Specifications

The AME5130 features a constant off-time control

scheme. Operation can be best understood by referring

to Figure 3. When the voltage at the FB pin is less than

1.23V, the Enable Comp in Figure 3 enables the device

and the NMOS switch is turmed on pulling the SW pin to

ground. When the NMOS switch is on, current is sup-

plied by the output capacitor C OUT. Once the current in

the inductor reaches the peak current limit, the 400ns

One Shot turns off the NMOS switch. The SW voltage

will then rise to the output voltage plus a diode drop and

the inductor current will begin to decrease as shown in

Figure 3. During this time the energy stored in the induc-

tor is transferred to C OUT and the load. After the 400ns

off-time the NMOS switch is turned on and energy is

stored in the inductor again. This energy transfer from

the inductor to the output causes a stepping effect in

the output ripple.

This cycle is continued until the voltage at FB reaches

1.23V. When FB reaches this voltage, the enable com-

parator then disables the device turning off the NMOS

switch and reducing the Iq of the device to 64 ÂµA. The

load current is then supplied solely by C OUT indicated

by the gradually decreasing slope at the output. When

the FB pin drops slightly below 1.23V, the enable com-

parator enables the device and begins the cycle de-

scribed previously. The EN pin can be used to turn off

the AME5130 and reduce the Iq to 0.01ÂµA. In shutdown

mode the output voltage will be a diode drop lower than

the input voltage.

Micropower Step-Up

DC/DC Converter

n Application Information

INDUCTOR SELECTION

The appropriate inductor for a given application is

calculated using the following equation:

ï£¬ï£¬ï£ï£«

VOUT

VIN(min)

ICL

ï£·ï£·ï£¸ï£¶TOFF

Where VD is the schottky diode voltage, I CL is the

switch current limit found in the Typical Performance Char-

acteristics section, and T OFF is the switch off time. When

using this equation be sure to use in minimum input volt-

age for the application, such as for battery powered ap-

plications.

Choosing inductors with low ESR decrease power

lossed and increase efficiency.

Care should be taken when choosing an inductor. For

applications that require an input voltage that approaches

the output voltage, such as when converting a Li-ion bat-

tery voltage to 5V, the 400ns off time may not be enough

time to discharge the energy in the inductor and transfer

the energy to the output capacitor and load. This can

cause a ramping effect in the inductor current waveform

and an increased ripple on the output voltage. Using a

smaller inductor will cause the I PK to increase and will

increase the output voltage ripple further. This can be

solved by adding a 4.7pF capacitor across the R1 feed-

back resistor (Figure 3) and slightly increasing the out-

put capacitor. A smaller inductor can then be used to

ensure proper discharge in the 400ns off time.

DIODE SELECTION

To maintain high efficiency, the average current rating

of the schottky diode should be larger than the peak in-

ductor current, I PK. Schottky diodes with a low forward

drop and fast switching speeds are ideal for increasing

efficiency in portable applications. Choose a reverse break-

down of the schottky diode larger than the output volt-

age.

Rev.F.02

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