ICE1PCS02 Datasheet, PDF(7/18 Page) Infineon Technologies AG – Standalone Power Factor Correction (PFC) Controller in Continuous Conduction Mode (CCM) with Input Brown-Out Protection

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ICE1PCS02 Datasheet, PDF (7/18 Pages) Infineon Technologies AG – Standalone Power Factor Correction (PFC) Controller in Continuous Conduction Mode (CCM) with Input Brown-Out Protection

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Functional Description

CCM-PFC

ICE1PCS02/G

Functional Description

3.1 General

The ICE1PCS02/G is a 8 pin control IC for power factor

correction converters. It comes in both DIP and DSO

packages and is suitable for wide range line input

applications from 85 to 265 VAC. The IC supports

converters in boost topology and it operates in

continuous conduction mode (CCM) with average

current control.

It is a design derivative from the ICE1PCS01/G with the

differences in the supporting functions, namely the

input brown-out detection, internal fixed switching

frequency 65kHz and shortened startup time.

The IC operates with a cascaded control; the inner

current loop and the outer voltage loop. The inner

current loop of the IC controls the sinusoidal profile for

the average input current. It uses the dependency of

the PWM duty cycle on the line input voltage to

determine the corresponding input current. This means

the average input current follows the input voltage as

long as the device operates in CCM. Under light load

condition, depending on the choke inductance, the

system may enter into discontinuous conduction mode

(DCM) resulting in a higher harmonics but still meeting

the Class D requirement of IEC 1000-3-2.

The outer voltage loop controls the output bus voltage.

Depending on the load condition, OTA1 establishes an

appropriate voltage at VCOMP pin which controls the

amplitude of the average input current.

The IC is equipped with various protection features to

ensure safe operating condition for both the system

and device.

3.2 Power Supply

An internal under voltage lockout (UVLO) block

monitors the VCC power supply. As soon as it exceeds

11.2V and both voltages at pin 6 (VSENSE) >0.8V and

pin 4 (VINS) >1.5V, the IC begins operating its gate

drive and performs its Startup as shown in Figure 3.

VCC

( VVSENSE > 0.8 V) (VVSENSE < 0.8 V) (VVSENSE > 0.8 V)

AND (VVINS > 1.5 V) OR (VVINS < 0.8 V) AND (VVINS > 1.5 V)

11.2 V

10.5 V

If VCC drops below 10.2V, the IC is off. The IC will then

be consuming typically 200ÂµA, whereas consuming

18mA during normal operation.

The IC can be turned off and forced into standby mode

by pulling down the voltage at pin 6 (VSENSE) to lower

than 0.8V. In this standby mode, the current

consumption is reduced to 3mA. Other condition that

can result in the standby mode is when a Brown-out

condition occurs, ie pin 4 (VINS) <0.8V.

3.3 Start-up

Figure 4 shows the operation of voltage loopâs OTA1

during startup. The VCOMP pin is pull internally to

ground via switch S1 during UVLO and other fault

conditions (see later section on âSystem Protectionâ).

During power up when VOUT is less than 85% of the

rated level, it sources a constant 30ÂµA into the

compensation network at pin 5 (VCOMP) causing the

voltage at this pin to rise linearly. This results in a

controlled linear increase of the input current from 0A

thus reducing the stress on the external component.

VSENSE

( R3 + R4 x V OUT )

VCOMP

+/-30uA, 42uS

OTA1

fault

ICE1PCS02/G

Figure4 Startup Circuit

As VOUT has not reached within 5% from the rated

value, VCOMP voltage is level-shifted by the window

detect block as shown in Figure 5, to ensure there is no

long period of low or no current.

When V OUT approaches its rated value, OTA1âs

sourcing current drops and so does the level shift of the

window detect block. The normal voltage loop then

takes control.

IC's

State

OFF

Start Normal

Up Operation

Open loop/

Standby

Normal

Operation

OFF

Figure3 State of Operation respect to VCC

Version 1.1

28 Dec 2004

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