VIPER53DIP-E STMicroelectronics, VIPER53DIP-E Datasheet - Page 19

VIPER53DIP-E

Manufacturer Part Number

VIPER53DIP-E

Description

IC OFFLINE SWIT PWM CM OTP 8DIP

Manufacturer

STMicroelectronics

Series

VIPER™r

Type

Pulse Width Modulator Controllerr

Datasheets

1.VIPER53SPTR-E.pdf (36 pages)

2.VIPER53DIP-E.pdf (7 pages)

3.VIPER53DIP-E.pdf (24 pages)

Specifications of VIPER53DIP-E

Output Isolation

Isolated

Frequency Range

93 ~ 300kHz

Voltage - Input

8.4 ~ 19 V

Voltage - Output

620V

Power (watts)

30W

Operating Temperature

25°C ~ 125°C

Package / Case

8-DIP (0.300", 7.62mm)

Current, Supply

9 mA

Frequency, Oscillator

100 kHz

Package Type

DIP-8

Regulator Type

Switching

Resistance, Thermal, Junction To Case

20 °C/W

Temperature, Operating, Range

-40 to +150 °C

Time, Fall

100 ns

Time, Rise

50 ns

Voltage, Supply

13 V

Power Switch Family

VIPer53DIP

Input Voltage

0 to 19V

Power Switch On Resistance

900mOhm

Output Current

1.6A

Number Of Outputs

Single

Mounting

Through Hole

Supply Current

9mA

Operating Temperature (min)

-40C

Operating Temperature (max)

150C

Operating Temperature Classification

Automotive

Pin Count

Mounting Style

Through Hole

For Use With

497-8435 - BOARD EVAL FOR VIPER53 28W497-6458 - BOARD EVAL BASED ON VIPER53-E497-6262 - BOARD REF SGL VIPER53 90-264VAC497-5866 - EVAL BOARD 24W NEG OUT VIPER53E

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

497-6171-5

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VIPer53 - E

Current mode topology

The VIPer53-E implements the conventional current mode control method for regulating the

output voltage. This kind of feedback includes two nested regulation loops:

The inner loop controls the peak primary current cycle by cycle. When the Power MOSFET

output transistor is on, the inductor current (primary side of the transformer) is monitored

with a SenseFET technique and converted into a voltage. When V

power switch is turned off. This structure is completely integrated as shown on the Block

Diagram

function and the PWM latch. The following formula gives the peak current in the Power

MOSFET according to the compensation voltage:

Equation 1

The outer loop defines the level at which the inner loop regulates peak current in the power

switch. For this purpose, V

optocoupler in secondary feedback configuration, see

accordingly the peak drain current for each switching cycle.

As the inner loop regulates the peak primary current in the primary side of the transformer,

all input voltage changes are compensated for before impacting the output voltage. This

results in an improved line regulation, instantaneous correction to line changes, and better

stability for the voltage regulation loop.

Current mode topology also provides a good converter start-up control. The compensation

voltage can be controlled to increase slowly during the start-up phase, so the peak primary

current will follow this soft voltage slope to provide a smooth output voltage rise, without any

overshoot. The simpler voltage mode structure which only controls the duty cycle, leads

generally to high current at start-up with the risk of transformer saturation.

An integrated blanking filter inhibits the PWM comparator output for a short time after the

integrated Power MOSFET is switched on. This function prevents anomalous or premature

termination of the switching pulse in the case of current spikes caused by primary side

transformer capacitance or secondary side rectifier reverse recovery time when working in

continuous mode.

on page

1, with the current amplifier, the PWM comparator, the blanking time

COMP

is driven by the feedback network (TL431 through an

Dpeak

------------------------------------------------- -

COMP

–

COMPos

Figure 19 on page

Current mode topology

reaches V

17) and is sets

COMP

, the

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VIPER53DIP-E STMicroelectronics, VIPER53DIP-E Datasheet - Page 19

VIPER53DIP-E

Specifications of VIPER53DIP-E

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