AME7739 Datasheet, PDF(6/11 Page) Analog Microelectronics – Step-Up / Step-Down 60mA Regulated Charge Pump

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

AME7739 Datasheet, PDF (6/11 Pages) Analog Microelectronics – Step-Up / Step-Down 60mA Regulated Charge Pump

◁

AME, Inc.

AME7739

Step-Up / Step-Down

60mA Regulated Charge Pump

n Detailed Description

The AME7739 regulated charge pump provides a regulated

input voltages ranging from less than the output to greater

than the input. This is accomplshed by automatic mode switch-

ing within the device.

n Short Circuit and Thermal

Protection

The AME7739 has a thermal protection and shutdown cir-

cuit that continuously monitors the IC junction temperature.

If the thermal protection circuit senses the die temperature

exceeding approximately 160OC, the thermal shutdown will

disable the charge pump switching cycle operation, The ther-

mal limit system has 20OC of system hysteresis before the

charge pump can reset. Once the over current event is re-

moved from the output and the junction temperature drops

below 140OC, the charge pump will the become active again.

The thermal protection system will cycle on and off if an out-

put short circuit condition persists. This will allow the

AME7739 to operate indefinitely a short circuit condition with-

out damage to the device.

n Shutdown Mode

A control pin EN on the regulator can be used to place the

device into an energy-saving shutdown mode. In this mode,

the output is disconnected from the input as long as V is

greater than or equal to minimum VIN and input quiescent

current is reduced to 1ÂµA maximum.

n Capacitor Selection

n Efficiency

The efficiency of the charge pump regulator varies

with the output voltage version, the applied input volt-

age, the load current, and the internal operation mode

of the device.

The approximate efficiency is given by:

5.5V 5V Version (VIN<= VOUT)

Efficiency (%) = VOUT / 2VIN 100%

Others Version (V > V )

OUT

Efficiency (%) = VOUT / VIN 100%

n Layout

Large ripple currents flow in the VIN and VOUT traces.

To minimized both input and output ripple, keep the

capacitors as close as possible to the regulator using

short, direct circuit traces.

The trace lengths from the input and output capaci-

tors have been kept as short as possible. A star ground

system has been implemented, with GND pin as the

center of the star. No ground plane is provided in other

layers, as this will provide capacitive coupling for noise

spikes.

For minimum output voltage ripple, the output capacitor

C should be a ceramic, surface-mount type. Tantalum ca-

OUT

pacitors generally have a higher Effective Series Resistance

(ESR) and may contribute to higher output voltage ripple.

Leaded capacitors also increase ripple due to the higher in-

ductance of the package itself. To achieve best operation with

low input voltage and high load current, the input and pump

capacitors (C , C respectively) should also be surface-

IN PUMP

mount ceramic types. In all cases, X7R dielectric is recom-

mended.

With light loads or higher input voltage, a smaller 0.1ÂµF

pump

capacitor

(C )

PUMP

and

smaller

1ÂµF

input

and

output

ca-

pacitor (CIN and COUT, respectively) can be used. To minimize

output voltage ripple, increase the output capacitor, COUT, to

10ÂµF or larger.

REV. A.02

▷