AP2280 Datasheet, PDF(8/9 Page) Diodes Incorporated – SINGLE CHANNEL SLEW RATE CONTROLLED LOAD SWITCH

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AP2280 Datasheet, PDF (8/9 Pages) Diodes Incorporated – SINGLE CHANNEL SLEW RATE CONTROLLED LOAD SWITCH

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Application Note

AP2280

SINGLE CHANNEL SLEW RATE CONTROLLED LOAD

SWITCH

Input Capacitor

A 1Î¼F capacitor is recommended to connect

between IN and GND pins to decouple input power

supply glitch and noise. The input capacitor has no

specific type or ESR (Equivalent Series Resistance)

requirement. However, for higher current

application, ceramic capacitors are recommended

due to their capability to withstand input current

surges from low impedance sources, such as

batteries in portable applications. This input

capacitor must be located as close as possible to

the device to assure input stability and less noise.

For PCB layout, a wide copper trace is required for

both IN and GND.

Output Capacitor

A 0.1Î¼F capacitor is recommended to connect

between OUT and GND pins to stabilize and

accommodate load transient condition. The output

capacitor has no specific type or ESR requirement.

The amount of the capacitance may be increased

without limit. For PCB layout, the output capacitor

must be placed as close as possible to OUT and

GND pins, and keep the traces as short as

possible.

Enable/Shutdown Operation

The AP2280 is turned on by setting the EN pin high

and is turned off by pulling it low. To ensure proper

operation, the signal source used to drive the EN

pin must be able to swing above and below the

specified turn-on/off voltage thresholds listed in the

Electrical Characteristics section under VIL and VIH.

Discharge Operation

The AP2280 offers a discharge option that helps to

discharge the output when disabled. To use this

feature, the DIS pin is connected to the OUT pin

externally. If this feature is not used, the DIS pin

should be left open.

Power Dissipation

The device power dissipation and proper sizing of

the thermal plane is critical to avoid thermal

shutdown and ensure reliable operation. Power

dissipation of the device depends on input voltage

and load conditions and can be calculated by:

PD = IOUT 2 xRDSON

(1)

However, the maximum power dissipation that can

be handled by the device depends on the

maximum junction to ambient thermal resistance,

maximum ambient temperature, and maximum

device junction temperature, which can be

approximated by the equation below:

PD (max@ TA )

(+125Â°C â TA )

Î¸ JA

(2)

For example at VIN = 5V, the typical RDSON = 80mâ¦.

For IOUT = 2A, the maximum power dissipation

calculated using equation (1) is PD = 0.32W. Based

on Î¸JA = 160Â°C/W and equation (2), the calculated

junction temperature rise from ambient is

approximately 51Â°C. Since the maximum junction

temperature is 125Â°C, the operating ambient

temperature must be kept below 74Â°C to safely

operate the device.

On the other hand, at TA = 85Â°C and VIN = 5V, the

calculated maximum power dissipation from

equation (2) is PDmax = 0.25W. Hence the safe

operating maximum continuous current is 1.77A.

For other application conditions, the users should

recalculate the device maximum power dissipation

based on the operating conditions.

AP2280 Rev. 2

8 of 9

www.diodes.com

OCTOBER 2007

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