AME5172 Datasheet, PDF(7/12 Page) Analog Microelectronics – 0.85V Single Cell Boost DC-DC Converter

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AME5172 Datasheet, PDF (7/12 Pages) Analog Microelectronics – 0.85V Single Cell Boost DC-DC Converter

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AME, Inc.

AME5172

0.85V Single Cell Boost

DC-DC Converter

n Detailed Description

The AME5172 is a fixed frequency synchronous boost

converter in SOT-25 package. The feature include current

mode PWM control with internal frequency compensa-

tion, low R MOSFET switch, synchronous rectifica-

DS(ON)

tion and 800mA peak switching current limit.

Synchronous Rectification

Built-in 0.35â¦ NMOS switch and 0.45â¦ PMOS syn-

chronous rectification significantly improves efficiency and

eliminates the need for an external Schottky diode. High

switching frequency (at 1.2MHz) also allows easy filter-

ing and faster loop performance.

Low Voltage Start-Up

The AME5172 will start-up at typical input voltage of

0.85V. At start-up, switching frequency is determined by

the start-up oscillator and start-up current limit. When

VOUT exceeds 2.3V, the start-up circuit will disabled and

the PWM mode is initiated.

Thermal Shutdown Protection

The AME5172 has thermal shutdown protection at

160OC (Typ.). If the device temperature rises above 160OC,

the internal power MOSFET will turn off. Once the tem-

perature falls below 140OC, the device resumes normal

operation. However, device functionality is only guaran-

teed to a maximum junction temperature of +125OC.

Rev. A.02

n Application Information

Inductor Selection

An inductor value of 4.7ÂµH performs well in most appli-

cation. Larger values of inductance can reduce the induc-

tor ripple current. Choosing inductors with low ESR de-

crease power loss and increase efficiency.

The approximate output current capability versus induc-

tance value is given in the equation below:

IOUT (max)

= Î· (1 â

D)ï£¯ï£®ICL

ï£°

VIN Ã D

2Ã L Ã fSW

ï£¹

ï£º

ï£»

where:

Î· = efficiency

D = VOUT âVIN

VOUT

I =switching peak current limit

V =input voltage

L=inductance value

FSW=switching frequency

Output Capacitor Selection

A single ceramic capacitor of value 4.7ÂµF to 10ÂµF will

provide sufficient output capacitance for most applications.

Larger capacitance with low ESR can be used to improve

ripple and transient response.

An output capacitor with excessive ESR can also re-

duce phase margin and cause instability. In general, if

electrolytic are used, it is recommended to parallel with

ceramic capacitors to reduce ringing, switching losses,

and output voltage ripple.

Input Capacitor Selection

An input capacitor is required to serve as an energy res-

ervoir for the current which must flow into the coil each

time the switch turns ON. This capacitor must have ex-

tremely low ESR, so ceramic is the best choice. We rec-

ommend a nominal value of 4.7ÂµF, but larger values can

be used. Since this capacitor reduces the amount of volt-

age ripple seen at the input pin, it also reduces the amount

of EMI passed back to other circuitry.

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