MC44603 Datasheet, PDF(15/24 Page) ON Semiconductor – MIXED FREQUENCY MODE GREENLINE PWM CONTROLLER

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MC44603 Datasheet, PDF (15/24 Pages) ON Semiconductor – MIXED FREQUENCY MODE GREENLINE PWM CONTROLLER

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MC44603

So, as fS = 1 /(Tcharge + Tdischarge) when the Regul

arrangement is not activated, the operating frequency can be

obtained from the graph in Figure 1.

NOTE: The output is disabled by the signal VOSC prot when

VCT is lower than 1.0 V (refer to Figure 30).

Synchronization and Demagnetization Blocks

To enable the output, the LOSC latch complementary

output must be low. Reset is activated by the Ldisch output

during the discharge phase. To restart, the LOSC has to be set

(refer to Figure 34). To perform this, the demagnetization

signal and the synchronization must be low.

â¢ Synchronization:

The synchronization block consists of two comparators

that compare the synchronization signal (external) to 0.7 and

3.7 V (typical values). The comparatorsâ outputs are

connected to the input of an AND gate so that the final output

of the block should be :

â high when 0.7 < SYNC < 3.7 V

â low in the other cases.

As a low level is necessary to enable the output,

synchronized low level pulses have to be generated on the

output of the synchronization block. If synchronization is not

required, the Pin 9 must be connected to the ground.

A diode D has been incorporated to clamp the positive

applied voltages while an active clamping system limits the

negative voltages to typically â0.33 V. This negative clamp

level is sufficient to avoid the substrate diode switching on.

In addition to the comparator, a latch system has been

incorporated in order to keep the demagnetization block

output level low as soon as a voltage lower than 65 mV is

detected and as long as a new restart is produced (high level

on the output) (refer to Figure 38). This process prevents

ringing on the signal at Pin 8 from disrupting the

demagnetization detection. This results in a very accurate

demagnetization detection.

The demagnetization block output is also directly

connected to the output, disabling it during the

demagnetization phase (refer to Figure 33).

NOTE: The demagnetization detection can be inhibited by

connecting Pin 8 to the ground.

Figure 38. Demagnetization Block

Oscillator

Output

Buffer

Demag

VCC

Figure 36. Synchronization

VDemag Out

Negative Active

Clamping System

Oscillator

Output Buffer

3.7 V

Sync

0.7 V

C Dem

65 mV

Standby

â¢ Power Losses in a Classical Flyback Structure

â¢ Demagnetization:

In flyback applications, a good means to detect magnetic

saturation of the transformer core, or demagnetization,

consists in using the auxiliary winding voltage. This voltage is:

â negative during the onâtime,

â positive during the offâtime,

â equal to zero for the deadâtime with generally some

â ringing (refer to Figure 37).

That is why, the MC44603 demagnetization detection

consists of a comparator that can compare the auxiliary

winding voltage to a reference that is typically equal to

65 mV.

Figure 37. Demagnetization Detection

Figure 39. Power Losses in a Classical

Flyback Structure

Vin

RICL

Clamping

Network

AC Line

Rstartup

VCC

MC44603

Snubber

VPin 8

Zero Current

Detection

OnâTime OffâTime DeadâTime

0.75 V

65 mV

â0.33 V

In a classical flyback (as depicted in Figure 39), the

standby losses mainly consist of the energy waste due to:

â the startup resistor Rstartup

â the consumption of the IC and

â the power switch control

â the inrush current limitation resistor RICL

â the switching losses in the power switch

â the snubber and clamping network

Pstartup is nearly constant and is equal to:

Ç(VinâVCC)2ÅRstartupÇ

Pstartup

Pcontrol

PICL

PSW

PSNâCLN

MOTOROLA ANALOG IC DEVICE DATA

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