SIP32413_12 VISHAY [Vishay Siliconix], SIP32413_12 Datasheet - Page 11

SIP32413_12

Manufacturer Part Number

SIP32413_12

Description

Dual 2 A, 1.2 V, Slew Rate Controlled Load Switch

Manufacturer

VISHAY [Vishay Siliconix]

Datasheet

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DETAILED DESCRIPTION

SiP32413, SiP32414 and SiP32416 are dual n-channel

power MOSFETs designed as high side load switch with

slew rate control to prevent in-rush current. Once enable the

device charges the gate of the power MOSFET to 5 V gate

to source voltage while controlling the slew rate of the turn on

time. The mostly constant gate to source voltage keeps the

on resistance low through out the input voltage range. For

SiP32414, when disable the output discharge circuit turns on

to help pull the output voltage to ground more quickly. For all

parts, in disable mode, the reverse blocking circuit is

activated to prevent current from going back to the input in

case the output voltage is higher than the input voltage. Input

voltage is needed for the reverse blocking circuit to work

properly, it can be as low as V

APPLICATION INFORMATION

Input Capacitor

While bypass capacitors on the inputs are not required,

2.2 µF or larger capacitors for C

all applications. The bypass capacitors should be placed as

physically close as possible to the device’s input to be

effective in minimizing transients on the input. Ceramic

capacitors are recommended over tantalum because of their

ability to withstand input current surges from low impedance

sources such as batteries in portable devices.

Output Capacitor

A 0.1 µF capacitor or larger across V

recommended to insure proper slew operation. C

increased without limit to accommodate any load transient

condition with only minimal affect on the turn on slew rate

time. There are no ESR or capacitor type requirement.

Control

The CNTRL pins are compatible with both TTL and CMOS

logic voltage levels.

Protection Against Reverse Voltage Condition

SiP32413, SiP32414 and SiP32416 contain reverse blocking

circuitries to protect the current from going to the input from

the output in case where the output voltage is higher than the

input voltage when the main switch is off. Supply voltages as

low as the minimum required input voltage are necessary for

these circuitries to work properly.

Thermal Considerations

All three parts are designed to maintain constant output load

current. Due to physical limitations of the layout and

assembly of the device the maximum switch current is 2.4 A,

as stated in the Absolute Maximum Ratings table. However,

another limiting characteristic for the safe operating load

current is the thermal power dissipation of the package. To

obtain the highest power dissipation (and a thermal

resistance of 95) the power pad of the device should be

connected to a heat sink on the printed circuit board.

Vishay Siliconix maintains worldwide manufacturing capability. Products may be manufactured at one of several qualified locations. Reliability data for Silicon

Technology and Package Reliability represent a composite of all qualified locations. For related documents such as package/tape drawings, part marking, and

reliability data, see www.vishay.com/ppg?71437.

Document Number: 71437

S11-2472-Rev. B, 19-Dec-11

THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT

IN(min.)

is recommended in almost

OUT

This document is subject to change without notice.

and GND is

OUT

may be

The maximum power dissipation in any application is

dependant

for the TDFN4 1.2 mm x 1.6 mm package, 

and the ambient temperature, T

expressed as:

It then follows that, assuming an ambient temperature of

70 °C, the maximum power dissipation will be limited to about

580 mW.

So long as the load current is below the 2.4 A limit, the

maximum continuous switch current becomes a function two

things: the package power dissipation and the R

ambient temperature.

As an example let us calculate the worst case maximum load

current at T

occurs at an input voltage of 1.2 V and is equal to 75 m. The

the following formula:

Where T

we have

= 86.5 m

The maximum current limit is then determined by

which in case is 2.6 A, assuming one switch turn on at a time.

Under the stated input voltage condition, if the 2.6 A current

limit is exceeded the internal die temperature will rise and

eventually, possibly damage the device.

To avoid possible permanent damage to the device and keep

a reasonable design margin, it is recommended to operate

the device maximum up to 2.4 A only as listed in the Absolute

Maximum Ratings table.

LOAD

J(max.)

DS(ON

DS(ON)

(max.)

SiP32413, SiP32414, SiP32416

(max.)

) at 70 °C can be extrapolated from this data using

= 125 °C, the junction-to-ambient thermal resistance

(at 70 °C) = R

(at 70 °C) = 75 m x (1 + 0.0034 x (70 °C - 25 °C))

is 3400 ppm/°C. Continuing with the calculation

= 70 °C. The worst case R

(max.)

the

(max.)

(

DS(ON)

maximum

)

(at 25 °C) x (1 + T

, which may be formulaically

125

Vishay Siliconix

junction

www.vishay.com/doc?91000

DS(ON)

www.vishay.com

J-A

temperature,

DS(ON)

= 95 °C/W,

x T)

at 25 °C

at the

SIP32413_12 VISHAY [Vishay Siliconix], SIP32413_12 Datasheet - Page 11

SIP32413_12

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