Infineon CoolSET-F3R ICE3BRXX65JZ series, CoolSET-F3R ICE3BRXX65JG series Design Manual

Never stop thinking.

Power Management & Supply

ICE3BRxx65J(Z)(G)

CoolSET®-F3R (DIP-8, DIP-7 & DSO-16/12)
new Jitter version Design Guide

Application Note, V 2.2, June 2010

Edition 2010-06-20
Published by Infineon Technologies Asia Pacific,

8 Kallang Sector,
349282 Singapore, Singapore

© Infineon Technologies AP 2008.
All Rights Reserved.

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ICE3BRXX65J(Z)(G)

Revision History: 2010-06-20 V2.2

Previous Version: V2.1a

Page Subjects (major changes since last revision)

Add ICE3BR4765JZ

CoolSET®-F3R (DIP-8, DIP-7 & DSO-16/12) new Jitter version Design Guide:
License to Infineon Technologies Asia Pacific Pte Ltd AN-PS0025

Kyaw Zin Min
Kok Siu Kam Eric

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ICE3BRXX65J(Z)(G)

Table of Contents Page

Application Note 4 2010-06-20

1 Introduction ...................................................................................................................................5

2 List of Features .............................................................................................................................5

3 Package..........................................................................................................................................5

4 Block Diagram ...............................................................................................................................7

5 Typical Application Circuit...........................................................................................................8

6 Functional description and component design .........................................................................9

6.1 Startup time .....................................................................................................................................9

6.1.1 Vcc capacitor...................................................................................................................................9

6.2 Soft Start .......................................................................................................................................10

6.3 Low standby power - Active Burst Mode.......................................................................................10

6.3.1 Entering Active Burst Mode...........................................................................................................10

6.3.2 Working in Active Burst Mode .......................................................................................................11

6.3.3 Leaving Active Burst Mode ...........................................................................................................12

6.3.4 Minimum VCC supply voltage during burst mode...........................................................................13

6.4 Low EMI noise...............................................................................................................................13

6.4.1 Frequency jittering.........................................................................................................................13

6.4.2 Soft gate drive ...............................................................................................................................13

6.4.3 Other suggestions to solve EMI issue...........................................................................................14

6.5 Tight maximum power control - Propagation delay compensation ...............................................14

6.6 Protection Features .......................................................................................................................15

6.6.1 Auto Restart Protection Mode .......................................................................................................15

6.6.2 Blanking Time for over load protection .........................................................................................16

6.6.3 User defined protection by external protection enable pin............................................................17

7 Input power curve .......................................................................................................................17

8 Layout Recommendation ...........................................................................................................20

9 Product portfolio of CoolSET®-F3R (DIP-8, DIP-7 & DSO-16/12) new Jitter version ............20

10 Useful formula & external component design .........................................................................21

11 References ...................................................................................................................................22

ICE3BRXX65J(Z)(G)

Application Note 5 2010-06-20

1 Introduction

The CoolSET®-F3R, ICE3BRxx65J(Z)(G) is the latest development of the CoolSET®-F3. It is a PWM
controller with power MOSFET and startup cell in a DIP or DSO package. The switching frequency is running
at 65 KHz and it targets for DVD player, set-top box, portable game console, auxiliary power supply, etc.

The ICE3BRxx65J(Z)(G) adopts the BiCMOS technology and provides a wider Vcc operating range up to
25V. It inherits the proven good features of CoolSET

®

-F3 such as the active burst mode achieving the lowest
standby power, the propagation delay compensation making the most precise current limit control in wide
input voltage range, etc. In addition, it also adds on some useful features such as built-in soft start time, built­in basic with extendable blanking time for over load protection and built-in switching frequency modulation (
frequency jittering ), external auto-restart enable, etc.

2 List of Features

3 Package

The package for F3R ICE3BRXX65J Jitter mode product is DIP-8.

Figure 1 Pin configuration –

ICE3BRxx65J

1

at Tj=110°C

650V avalanche rugged CoolSET® with built-in Startup Cell

Active Burst Mode for lowest Standby Power

Fast load jump response in Active Burst Mode

65 kHz internally fixed switching frequency

Auto Restart Protection Mode for Over-load, Open Loop, Vcc Undervoltage, Over temperature & Vcc
Over-voltage

Built-in Soft Start

Built-in blanking window with extendable blanking time for short duration high current

External auto-restart enable pin

Max Duty Cycle 75%

Overall tolerance of Current Limiting < ±5%

Internal PWM Leading Edge Blanking

BiCMOS technology provides wide VCC range

Built-in Frequency jitter feature and soft driving for low EMI

Pin Name Description

1 BA extended Blanking & Auto-restart enable

2 FB FeedBack

3 CS

Current Sense / 650V

1

CoolMOS® Source

4 Drain

650V

1

CoolMOS® Drain

5 Drain

650V

1

CoolMOS® Drain

6 n.c. Not Connected

7 VCC Controller Supply Voltage

8 GND Controller Ground

1

6

7

8

4

3

2

5

GND BA

FB

CS

VCC

n.c

Drain

Drain

ICE3BRXX65J(Z)(G)

Application Note 6 2010-06-20

The package for F3R ICE3BRXX65JZ Jitter mode product is DIP-7.

Figure 2 Pin configuration – ICE3BRxx65JZ

The package for F3R ICE3BRXX65JG Jitter mode product is DSO-16/12.

Figure 3 Pin configuration – ICE3BRxx65JG

1

at Tj=110°C

Pin Name Description

1 BA extended Blanking & Auto-restart enable

2 FB FeedBack

3 CS

Current Sense / 650V

1

CoolMOS® Source

4 n.c. Not connected

5 Drain

650V

1

CoolMOS® Drain

6 - No Pin

7 VCC Controller Supply Voltage

8 GND Controller Ground

Pin Name Description

1 N.C. Not Connected

2 BA extended Blanking & Auto-restart enable

3 FB FeedBack

4 CS

Current Sense / 650V

1

CoolMOS® Source

5 Drain

650V

1

CoolMOS® Drain

6 Drain

650V

1

CoolMOS® Drain

7 Drain

650V

1

CoolMOS® Drain

8 Drain

650V

1

CoolMOS® Drain

9 N.C. Not Connected

10 N.C. Not Connected

11 VCC Controller Supply Voltage

12 GND Controller Ground

ICE3BRXX65J(Z)(G)

Application Note 7 2010-06-20

4 Block Diagram

Figure 4 Block Diagram of ICE3BRXX65J(Z)(G)

ICE3BRXX65J(Z)(G)

Application Note 8 2010-06-20

5 Typical Application Circuit

Figure 5 Typical application circuit with ICE3BR4765J 12W 5V

5V/2 . 4A

COM

F1

3. 15 A

C1

0. 1uF/2 75V

EMI

2 x 4 7mH, 0. 4A

BR1

2KBB80R

+

C2

47uF/ 400V

R1

150k /2W

D1

UF4005

C3

2. 2nF/4 00V

2

1

3

4

IC2

SFH 617A- 3

C7

10nF

+

C5 22uF/50V

C6

0. 1uF

D2

1N41 48

R2

510R

Rc6

470R

R4

1. 5R

IC3

TL431

Cc2

1nF

Rc4

6. 8k

Cc1

1uF

Rc2

0R

Rc3

10k

+

C21

1800 uF/ 25V

L2 1

1. 5uH

+

C22

220u F/25V

85V - 26 5V ac

12W 5V SMPS Demoboard with ICE3BR4765J(V0.2)

Eric Kok, Kyaw Zin Min / 8 Nov 2007

L1

L

N

Rc5

2. 2K

Rc1

10 k

C4

1nF/ 250V, Y1

C8

1nF

R4A

15R

Rc3A

*

C23

*

R21 *

ZD1

24V

R3

39R

*SG 1

*SG 2

65

4

3

9

2

1

TR1 830uH

BA

CS

Vcc

DRAIN

GND FB

ICE3BR4765 J

345

1

82 7

IC1

C13

0. 1uF/50V

L2

D21

SB540

ICE3BRXX65J(Z)(G)

Application Note 9 2010-06-20

6 Functional description and component design

6.1 Startup time

Startup time is counted from applying input voltage to IC turn on. ICE3BRXX65J(Z)(G) has a startup cell
which is connected to input bulk capacitor. When there is input voltage, the startup cell will act as a constant
current source to charge up the Vcc capacitor and supply energy to the IC. When the Vcc capacitor reaches
the Vcc_on threshold 18V, the IC turns on. Then the startup cell is turned off and the Vcc is supplied by the
auxiliary winding. Start up time is independent from the AC line input voltage and it can be calculated by the
equation (1). Figure 6 shows the start up time of 85Vac line input.

3arg eVCCch

VccVCCon

STARTUP

I

CV

t

⋅

=

(1)

where, I

VCCcharge3

: constant current to charge Vcc capacitor ( 0.7mA ),

V

VCCon

: IC turns on threshold ( 18V ), C

VCC

: Vcc capacitor

Pls refer to the datasheet for the symbol used in the equation.

Channel 1; C1 : CS Voltage (V

CS

)

Channel 2; C2 : Supply Voltage (V

CC

)

Channel 3; C3 : FB voltage (V

FB

)

Channel 4; C4 : BA Voltage (V

BA

)

Startup time = 0.54s

Startup delay time @ Vin=85Vac & 12W
load

Figure 6 The startup delay time at AC line input voltage of 85Vac

Precaution : For a typical application, start up should be VCC ramps up first, other pin (such as FB pin)

voltage will follow VCC voltage to ramp up. It is recommended not to have any voltage on other
pins (such as FB; BA and CS) before VCC ramps up.

6.1.1 Vcc capacitor

The minimum value of the Vcc capacitor is determined by voltage drop during the soft start time. The formula
is expressed in equation (2).

3

2

2sup

⋅

⋅

=

CChys

ssVCC

VCC

V

tI

C

(2)

where, I

VCCsup2

: IC consumption current ( 4.2mA ), tss : soft start time ( 20ms ),

V

CChys

: Vcc turn-on/off hysteresis voltage ( 7.5V )

Therefore, the minimum Vcc capacitance can be 7.4µF. In order to give more margins, 22uF is taken for the
design. The startup time t

STARTUP

is then 0.528s. The measured start up time is 0.54s (Figure 6). A 0.1uF

filtering capacitor is always needed to add as near as possible to the Vcc pin to filter the high frequency
noise. The filter capacitor C6 and the auxiliary series resistor R2 form a R-C filter which can effectively filter
the transformer switching noise from auxiliary winding going into the IC.

0.54s

V

CS

V

CC

V

FB

VBA

ICE3BRXX65J(Z)(G)

Application Note 10 2010-06-20

6.2 Soft Start

When the IC is turned on after the Startup time, a digital soft start circuit is activated. A gradually increased
soft start voltage is generated by the digital soft start circuit, which in turn releases the duty cycle gradually
from zero. The duty cycle increases to maximum (which is limited by the transformer design) at the end of
the soft start period. When the soft start time ends, IC goes into normal mode and the duty cycle is controlled
by the FB signal. The soft start time is set at 20ms for maximum load. The soft start time is load dependent;
shorter soft start time with lighter load.

Figure 7 shows the soft start behavior at 85Vac input. The primary peak current increases slowly to the
maximum in the soft start period.

Channel 1; C1 : CS Voltage (V

CS

)

Channel 2; C2 : Supply Voltage (V

CC

)

Channel 3; C3 : FB voltage (V

FB

)

Channel 4; C4 : BA Voltage (V

BA

)

Soft start time = 20ms

20ms built in SoftStart time @
Vin=85Vac & 12W load

Figure 7 Soft start at AC line input voltage of 85Vac

6.3 Low standby power - Active Burst Mode

The IC will enter Active Burst Mode function at light load condition which enables the system to achieve the
lowest standby power requirement of less than 50mW. Active Burst Mode means the IC is always in the
active state and can therefore immediately respond to any changes on the FB signal, V

FB

.

6.3.1 Entering Active Burst Mode

Because of the current mode control scheme, the feedback voltage VFB actually controls the power delivery
to output. An important relationship between the V

CS

and the VFB is expressed in equation (3).

RampOffsetVCSFB

VAVV

−

+⋅= (3)

where, V

FB

:feedback voltage, VCS:current sense voltage, AV:PWM OP gain, V

Offset-Ramp

:voltage ramp offset

When the output load reduces, the feedback voltage V

FB

drops. If the VFB stays below 1.35V for 20ms, the IC

enters into the Active Burst Mode. The threshold power to enter burst mode is expressed in equation (4).

SW

Vsense

RampOffsetFBC

PSW

sense

CS

PSW

p

PenterBURST

f

AR

VV

Lf

R

V

LfILP ⋅

⋅

−

⋅⋅=⋅⋅⋅=⋅⋅⋅=

−

2

5

22

_

)(

2

1

)(

2

1

2

1

(4)

where, L

p

: transformer primary inductance

R

sense

: current sense resistance, fsw: switching frequency, V

FBC5

: Feedback level to enter burst mode

Figure 8 shows the waveform with the load change from nominal load to light load. After the 20ms blanking
time IC goes into burst mode.

20ms

1V

VCS

V

BA

V

CC

V

FB

ICE3BRXX65J(Z)(G)

Application Note 11 2010-06-20

Channel 1; C1 : Drain-Source Voltage (VDS)
Channel 2; C2 : Supply Voltage (V

CC

)

Channel 3; C3 : FB voltage (V

FB

)

Channel 4; C4 : BA Voltage (V

BA

)

Entering Active Burst mode with preset
time 20ms when load changes from full to
light @ Vin=85Vac

Figure 8 Entering Burst Mode

6.3.2 Working in Active Burst Mode

In the active burst mode, the IC is constantly monitoring the output voltage by feedback pin, VFB, which
controls burst duty cycle and burst frequency. The burst “ON” starts when V

FB

reaches 3.5V and it stops

when V

FB

is dropped to 3.0V. During burst “ON”, the primary current limit is set to 34% of maximum peak

current (V

CS

=0.34V) to reduce the conduction losses and to avoid audible noise. The FB voltage is changing
like a saw tooth between 3.0V and 3.5V. The corresponding secondary output ripple (peak to peak) is
controlled to be small. It can be calculated by equation (5).

FB

TLoptoFB

opto

pprippleout

V

GGR

R

V ∆⋅

⋅⋅

=

431

__

(5)

where, R

opto

: series resistor with opto-coupler at secondary side (e.g. Rc6 in Figure 5), RFB : IC internal pull

up resistor connected to FB pin (R

FB

=15.4K), G

opto

: current transfer gain of opto-coupler, G

TL431

: voltage

transfer gain of the loop compensation network (e.g. Rc1, Rc2, Rc3, Rc4, Cc1, Cc2 in Figure 5),

∆

V

FB

:

feedback voltage change (0.5V)

Usually there is a noise coupling capacitor at the FB pin to filter the switching noise and spike (e.g. C8 in
Figure 5). However, if this capacitor is too large (>10nF), it would affect the normal operation of the
controller. This capacitor should be as small as possible (without the capacitor is the best). In the mean time,
it is found that this filter capacitor will also affect the output ripple voltage during burst mode; larger
capacitance will get larger ripple voltage and smaller capacitance get lower ripple voltage.

Figure 9 is the output ripple waveform of the 12W demo board. The burst ripple voltage is about 50mV.

Channel 2; C2 : Output ripple Voltage (V

o

)

Output ripple voltage at light load @ Vin=85Vac

Figure 9 Output ripple during Active Burst Mode at light load

VDS

V

BA

20ms

50mV

VFB

V

CC

V

o

ICE3BRXX65J(Z)(G)

Application Note 12 2010-06-20

6.3.3 Leaving Active Burst Mode

When the output load increases to be higher than the maximum burst power, P

burst_max

, V

out

will drop and VFB

will rise up fast to exceed 4.0V. The system leaves burst mode immediately when V

FB

reaches 4.0V. Once

system leaves burst mode, the current sense voltage limit, V

CS_MAX

, is released to 1V, the feedback voltage

V

FB

swings back to the normal control level.

The leaving burst power threshold (i.e. maximum power to be handled during burst operation) is expressed
in equation (6).

max_

2

max_

2

max_max_

1156.0)34.0(5.0)34.0(5.0

inSW

sense

CS

PSWpPburst

Pf

R

V

LfILP ⋅=⋅⋅⋅⋅=⋅⋅⋅⋅= (6)

where,

max_p

I : maximum primary peak current, V

CS_max

: current limit threshold at CS pin, P

in_max

: maximum

input power

The calculated maximum power in burst mode is around 6.76% of P

in_max

. However, the actual power can be

higher as it would include propagation delay time.

The leave burst mode timing diagram is shown in Figure 10. The maximum output drop during the transition
can be estimated in equation (7).

431431

max__

75.0

)

2

5.33

4(

TLoptoFB

opto

TLoptoFB

opto

dropout

GGR

R

GGR

R

V

⋅⋅

⋅

=

+

−⋅

⋅⋅

= (7)

Figure 10 Timing diagram of leaving burst mode

Figure 11 is the captured waveform when there is a load jump from light load to full load. The output ripple
drop during the transition is about 88mV.

Channel 1; C1 : CS Voltage (V

CS

)

Channel 2; C2 : Output Voltage (V

o

)

Channel 3; C3 : FB voltage (V

FB

)

Leaving Active Burst mode when load change from
light to full @ Vin=85Vac

Figure 11 Leaving burst mode waveform

V

FB

V

out_AV

V

out_drop_max

3.5V

3.0V

V

out

4.0V

V

CS

0.34V

1.03V

88mV

Vo

VFB

V

CS

ICE3BRXX65J(Z)(G)

Application Note 13 2010-06-20

6.3.4 Minimum VCC supply voltage during burst mode

It is particularly important that the Vcc voltage must stay above V

VCCoff

(i.e. 10.5V). Otherwise, the expected
low standby power cannot be achieved. The IC will go into auto-restart mode instead of Active Burst Mode. A
reference Vcc circuit is presented in Figure 5. This is for a low cost transformer design where the transformer
coupling is not too good. Thus the circuit R3 and Zd1 is added to clamp the Vcc voltage exceeding 25V in
extreme case such as high load and the Vcc OVP protection is triggered. If the transformer coupling is good,
this circuit is not needed.

6.4 Low EMI noise

6.4.1 Frequency jittering

The IC is running at a fixed frequency of 65 KHz with jittering frequency at +/-2.6 KHz in a switching
modulation period of 4ms. This kind of frequency modulation can effectively help to obtain a low EMI noise
level particularly for conducted EMI. The jittering frequency measured is 63.8 KHz ~ 67.4 KHz (refer to
Figure 12).

Channel 1; C1 : Drain to Source Voltage (V

DS

)

Frequency jittering at full load @ Vin=85Vac

Figure 12 Switching frequency jittering ( Vds )

6.4.2 Soft gate drive

The gate soft driving is to split the gate driving slope into 2 so that the MOSFET turns on speed is relatively
slower comparing to a single slope drive (see Figure 13). In this way, the high I/t noise is greatly reduced
and the noise signal reflected in the EMI spectrum is also reduced.

Figure 13 Soft gate drive waveform

67.4kHz

63.8kHz

VDS

ICE3BRXX65J(Z)(G)

Application Note 14 2010-06-20

6.4.3 Other suggestions to solve EMI issue

Some more suggestions to improve the EMI performance and is listed below.

1. Add capacitor (C

ds

) at the drain source pin: it can slow down the turn off speed of the MOSFET and

the high V/t noise will be reduced and so is the EMI noise. The drawback is more energy will be
dissipated due to slower turn off speed of MOSFET.

2. Add snubber circuit to the output rectifier: Most of the radiated EMI noise comes out from the output
of the system esp. for a system with output cable. Adding snubber circuit (R21 and C23) to the
output rectifier is a more direct way to suppress those EMI noise (refer to Figure 5).

6.5 Tight maximum power control - Propagation delay compensation

The maximum power of the system is changed with the input voltage; higher voltage got higher maximum
power. This is due to the propagation delay of the IC and the different rise time of the primary current under
different input voltage. The propagation delay time is around 200ns. But if the primary current rise time is
faster, the maximum power will increase. The power difference can be as high as >14% between high line
and low line. In order to make the maximum power control become tight, a propagation delay compensation
network is implemented so that the power difference is greatly reduced to best around 2%. Figure 14 shows
the compensation scheme of the IC. The equation (8) explains the rate of change of the current sense
voltage is directly proportional to the input voltage and current sense resistor. For a DCM operation, the
operating range for the dV

sense

/dt is from 0.1 to 0.7. It can show in Figure 14 that higher dV

sense

/dt will give

more compensation; i.e. lower value of V

sense

.

p

in

sense

sense

p

in

sense

p

sense

p

in

p

L

V

R

dt

dV

L

V

R

dt

dI

R

L

V

dt

dI

⋅=⇒⋅=⋅⇒=

(8)

where, I

p

: primary peak current, V

in

: input voltage, Lp : primary inductance of the transformer,

V

sense

: current sense voltage, R

sense

: current sense resistor

The measured maximum input power for the 12W demo boards at 85Vac and 265Vac shows ±1.71% of
maximum input power. This function is limited to discontinuous conduction mode flyback converter only.

0,9

0,95

1

1,05

1,1

1,15

1,2

1,25

1,3

0 0,2 0,4 0,6 0,8 1 1,2 1,4 1,6 1,8 2

with compensation

without compensation

dt

dV

Sense

s

V

µ

Sense

V

V

Figure 14 Propagation delay compensation curve

ICE3BRXX65J(Z)(G)

Application Note 15 2010-06-20

6.6 Protection Features

The IC provides several protection features which lead to the Auto Restart Protection Mode. The following
table shows the conditions of the system failure and the associate protection mode.

Protection function Failure condition Protection Mode

Vcc Over-voltage

1. Vcc > 25.5V or

2. Vcc > 20.5V & FB > 4.0V & during soft start period

Auto Restart

Over-temperature
(controller junction)

T

J

> 130°C Auto Restart

Over-load / Open loop

V

FB

> 4.0V and VBA > 4.0V

(Blanking time counted from charging V

BA

from 0.9V to

4.0V )

Auto Restart

Vcc Under-voltage / short
Opto-coupler

Vcc < 10.5V Auto Restart

Auto-restart enable VBA < 0.33V Auto Restart

Table 1 Protection functions and failure conditions

The 25.5V OVP protection is inactivated during burst mode so that it can achieve lower standby power
performance.

6.6.1 Auto Restart Protection Mode

When the failure condition meets the auto restart protection mode, the IC will go into auto-restart. The
switching pulse will stop. Then the Vcc voltage will drop. When the Vcc voltage drops to 10.5V, the startup
cell will turn on again. The Vcc voltage is then charged up. When it hits 18V, the IC will turn on and the
startup cell will turn off. It would then start the startup phase with soft start. After the startup phase the failure
condition is checked to determine whether the fault persists. If the fault is removed, it will go to normal
operation. Otherwise, the IC will repeat the auto restart protection and the switching pulse stop again.

Figure 15 shows the switching waveform of the V

CC

and the feedback voltage VFB when the output is

overloaded by shorting the outputs. The IC is turned on at V

CC

= 18V. After going through the startup phase,

IC is off again due to the presence of the fault. V

CC

is discharged until 10.5V. Then, the Startup Cell is

activated again to charge up capacitor at V

CC

that initiates another restart cycle.

Channel 1; C1 : Drain-Source Voltage (V

DS

)

Channel 2; C2 : Supply Voltage (V

CC

)

Channel 3; C3 : Feedback Voltage ( V

FB )

Channel 4; C4 : BA voltage ( V

BA )

System enters auto restart mode when output
voltage short circuit @ Vin=85Vac

Figure 15 Auto Restart Mode

VDS

Vcc

VFB

VBA

ICE3BRXX65J(Z)(G)

Application Note 16 2010-06-20

6.6.2 Blanking Time for over load protection

The IC controller provides a blanking window before entering into the auto restart mode due to output
overload/short circuit. The purpose is to ensure that the system will not enter protection mode unintentionally.
There are 2 kinds of the blanking time; basic and the extendable. The basic one is a built-in feature which is
set at 20ms. The extendable one is to extend the basic one with a user defined additional blanking time. The
extendable blanking time can be achieved by adding a capacitor, C

BK

to the BA pin. When there is over load

occurred ( V

FB

> 4V ), the CBK capacitor will be charged up by a constant current source, IBK ( 13uA ) from

0.9V to 4.0V. Then the auto restart protection will be activated. The charging time from 0.9V to 4.0V to the
C

BK

capacitor is the extended blanking time. The total blanking time is the addition of the basic and the

extended blanking time.

BK

BK

BK

blanking

Cms

I

C

msExtendedBasict *5.23846120

*)9.00.4(

20 +=

−

+=+= (9)

The measured total blanking time showing in Figure 17 is 45ms using C

BK

=0.1uF.

In case of output overload or short circuit, the transferred power during the blanking period is limited to the
maximum power defined by the value of the sense resistor R

sense

.

The noise level in BA pin can be quite high particularly in some high power application. In order to avoid mis­triggering of other protection features, it is recommended to add a minimum 100pF filter capacitor at BA pin.

The maximum capacitor added at BA is restricted to be less than 0.65uF. Otherwise, the IC cannot be
startup properly.

Channel 1; C1 : Output Voltage ( V

o

)

Channel 2; C2 : Output current ( I

o

)

Channel 3; C3 : Feedback Voltage ( V

FB )

Channel 4; C4 : BA voltage ( V

BA )

Blanking time to enter auto-restart mode : 19ms

Over load protection without extended blanking
time;Cba=100pF @ Vin=85Vac and output power
step from 2.4A to 4A load

Figure 16 Blanking window for output over load protection ( basic blanking time )

Channel 1; C1 : Output Voltage ( V

o

)

Channel 2; C2 : Output current ( I

o

)

Channel 3; C3 : Feedback Voltage ( V

FB )

Channel 4; C4 : BA voltage ( V

BA )

Blanking time to enter auto-restart mode : 71ms

Over load protection with extended blanking
time;C7 = 0.22µF @ Vin=85Vac and output power
step from 2.4A to 4A load

Figure 17 Blanking window for output overload protection ( extended blanking time=24ms with

C

BK

=0.1uF )

19ms

52ms

19ms

Vo

Io

V

FB

V

BA

Vo

Io

V

FB

V

BA

ICE3BRXX65J(Z)(G)

Application Note 17 2010-06-20

6.6.3 User defined protection by external protection enable pin

Although there are lots of pre-defined Auto Restart Protection is implemented in the IC, customer still can
have some tailor-made protection for the application needs by pulling down the BA pin to lower 0.33V. When
BA pin lower than 0.33V, the gate drive switching will be stopped and IC will enter to auto restart mode until
the external auto restart enable signal released.

Figure 18 User defined Auto Restart Protection circuit

7 Input power curve

The purpose of the input power curve is to simplify the selection of the CoolSET® device. The curve is a
function of ambient temperature to the input power of the system in which the input filter loss, bridge rectifier
loss and the MOSFET power loss are considered. The only information needed is the required output power,
the input voltage range, the operating ambient temperature and the efficiency of the system. The required
input power can then be calculated as equation (10).

η

o

in

P

P =

(10)

where P

in

: input power, Po : output power,  : efficiency

It then simply looks up the closed input power at the required ambient temperature from the input power
curve.

The input power curves for the CoolSET-F3R (DIP-8 & DIP-7) family are listed below.

ICE3BR0665J : Vin=85Vac~265Vac ICE3BR0665J : Vin=230Vac±15%

Figure 19 Input power curve for ICE3BR0665J

Ambient Temperature [°C]

Input power (230Vac) [W]

PI-002-ICE3X2565_230Vac

0

10

20

30

40

50

60

70

80

90

100

0 102030405060708090100110120130

Ambient Temperature [°C]

Input power (85~265Vac) [W]

PI-001-ICE3X2565_85Vac

0

6

12

18

24

30

36

42

48

54

60

0 10 20 30 40 50 60 70 80 90 100 110 120 130

ICE3BRXX65J(Z)(G)

Application Note 18 2010-06-20

ICE3BR1765J : Vin=85Vac~265Vac ICE3BR1765J : Vin=230Vac±15%

Figure 20 Input power curve for ICE3BR1765J

ICE3BR4765J : Vin=85Vac~265Vac ICE3BR4765J : Vin=230Vac±15%

Figure 21 Input power curve for ICE3BR4765J

ICE3BR0665JZ : Vin=85Vac~265Vac ICE3BR0665JZ : Vin=230Vac±15%

Figure 22 Input power curve for ICE3BR0665JZ

Ambient Temperature [°C]

Input power (230Vac) [W]

PI-0010-ICE3X0565_230Vac

0

3

6

9

12

15

18

21

24

27

30

33

0 1020304050 60708090100110120130

Ambient Temperature [°C]

Input power (85~265Vac) [W]

PI-009-ICE3X0565_85Vac

0

3

6

9

12

15

18

21

24

27

0 102030405060708090100110120130

Ambient Temperature [°C]

Input power (230Vac) [W]

PI-006-ICE3X1565_230Vac

0

6

12

18

24

30

36

42

48

54

60

0 102030405060708090100110120130

Ambient Temperature [°C]

Input power (85~265Vac) [W]

PI-005-ICE3X1565_85Vac

0

4

8

12

16

20

24

28

32

36

40

0 102030405060708090100110120130

ICE3BRXX65J(Z)(G)

Application Note 19 2010-06-20

ICE3BR1765JZ : Vin=85Vac~265Vac ICE3BR1765JZ : Vin=230Vac±15%

Figure 23 Input power curve for ICE3BR1765JZ

ICE3BR4765JZ : Vin=85Vac~265Vac ICE3BR4765JZ : Vin=230Vac±15%

Figure 24 Input power curve for ICE3BR4765JZ

Ambient Temperature [°C]

Input power (85~265Vac) [W]

PI-003-ICE3B0565JG_85Vac

0

3

6

9

12

15

18

21

24

27

0 10 20 30 40 50 60 70 80 90 100 110 120 130

Ambient Temperature [°C]

Input power (230Vac) [W]

PI-004-ICE3B0565JG_230Vac

0

3

6

9

12

15

18

21

24

27

30

33

0 10 20 30 40 50 60 70 80 90 100 110 120 130

ICE3BR4765JG : Vin=85Vac~265Vac ICE3BR4765JG : Vin=230Vac±15%

Figure 25 Input power curve for ICE3BR4765JG

ICE3BRXX65J(Z)(G)

Application Note 20 2010-06-20

The major assumption for the calculation is listed below.

1. Reflection voltage from secondary side to primary side is 100V.

2. The maximum power for the device is estimated when the junction temperature of the integrated
CoolMOS

®

reaches 125°C. (With some margins to reach the over temperature protection of the

device : 130°C). The maximum R

dson

of the device at 125°C is taken for calculation.

3. There is no copper area as heatsink and the R

thja

=90K/W for DIP-8, R

thja

=96K/W for DIP-7 &

R

thja

=110K/W for DSO-16/12.

4. Saturation current (I

d_max

@ 125°C) of the MOSFET is considered. The voltage drop for the bridge
rectifier is assumed to be 1V. The typical resistance of the EMI filter is estimated for different
CoolSET. Those parameters are listed in the below table

Rdson_125°C () I

d_max

@125°C (A) R

EMI_filter

() V

F_bridge

(V)

ICE3BR0665J(Z) 1.58 9.95 2 * 0.56 2 * 1

ICE3BR1765J(Z) 4.12 4.03 2 * 1 2 * 1

ICE3BR4765J(Z)(G) 12.5 1.67 2 * 3 2 * 1

8 Layout Recommendation

In order to get the optimized ruggedness of the IC to the transient surge events like ESD and lightning Surge
test, the grounding of the PCB layout must be connected carefully. From the circuit diagram in Figure 5, it
indicates that the grounding for the controller can be split into several groups; signal ground, Vcc ground,
Current sense resistor ground and EMI return ground. All the split grounds should be “star” connected to the
bulk capacitor ground directly. The split grounds are described as below.

• Signal ground includes all small signal grounds connecting to the controller GND pin such as filter
capacitor ground, C6, C7, C8 and opto-coupler ground.

• Vcc ground includes the Vcc capacitor ground, C5 and the auxiliary winding ground, pin 2 of the power
transformer.

• Current Sense resistor ground includes current sense resistor R4 and R4a.

• EMI return ground includes Y capacitor, C4.

9 Product portfolio of CoolSET®-F3R (DIP-8, DIP-7 & DSO-16/12)

new Jitter version

Device Package V

DS

1

Frequency

/ kHz

R

dson

/Ω2 P

in

85-265Vac 3

P

in

230Vac±15%

3

ICE3BR0665J PG-DIP-8 650V 65 0.65 49W 74W

ICE3BR1765J PG-DIP-8 650V 65 1.70 31W 46W

ICE3BR4765J PG-DIP-8 650V 65 4.70 18W 27W

ICE3BR0665JZ PG-DIP-7 650V 65 0.65 47W 71W

ICE3BR1765JZ PG-DIP-7 650V 65 1.70 29.5W 44.5W

ICE3BR4765JZ PG-DIP-7 650V 65 4.70 18W 26W

ICE3BR4765JG PG-DSO-16/12 650V 65 4.70 16.5W 24W

1

Tj=110°C

2

Typ @ 25°C

3

Calculated maximum input power rating at Ta=50°C, Tj=125°C and without copper area as heat sink. Refer to the input power curve

for other T

a

ICE3BRXX65J(Z)(G)

Application Note 21 2010-06-20

10 Useful formula & external component design

Transformer calculation (DCM flyback)

Input data

V

in_min

= 90Vdc, V

in_max

= 380Vdc,

V

ds_max

= 470V for 600V MOSFET,

D

max

≤ 50%

Turn ratio

diodeout

inds

ratio

VV

VV

N

+

−

=

max_max_

Maximum Duty ratio

ratiodiodeoutin

ratiodiodeout

NVVV

NVV

D

⋅++

⋅

+

=

)(

)(

min_

max

Primary Inductance

swin

in

p

fP

DV

L

⋅⋅

⋅

≤

2

)(

2

maxmin_

Primary peak current

swp

in

p

fL

DV

I

⋅

⋅

=

maxmin_

max_

Primary turns

minmax

max_

AB

LI

N

pp

p

⋅

⋅

≥

Secondary turns

ratio

p

s

N

N

N =

Auxiliary turns

s

diodeout

diodecc

aux

N

VV

VV

N ⋅

+

+

=

ICE3BRXX65J(Z)(G) external component Design

Current sense resistor

max_p

csth

sense

I

V

R ≤

Soft start time

mstss20=

Vcc capacitor

3

2

2sup

×

×

=

VCChys

ssVCC

VCC

V

tI

C

Startup delay time

3argeVCCch

VccVCCon

DELAY

I

CV

t

×

=

Enter burst mode power

SW

Vsense

RampOffsetFBC

PenterBURST

f

AR

VV

LP ×

×

−

××=

−

2

5

_

)(5.0

Leave burst mode power

SWpPburst

fILP ××××=

2

max_max_

)34.0(5.0

ICE3BRXX65J(Z)(G)

Application Note 22 2010-06-20

Output ripple during burst mode

FB

TLoptoFB

opto

pprippleout

V

GGR

R

V ∆×

××

=

431

__

Voltage drop when leave burst mode

431

max__

75.0

TLoptoFB

opto

dropout

GGR

R

V

××

×

=

Total blanking time for over load
protection

BK

BK

blanking

I

C

mst

×

−

+=

)9.00.4(

20

11 References

[1] Infineon Technologies, Datasheet “CoolSET®-F3R ICE3BR4765J Off-Line SMPS Current Mode

Controller with Integrated 650V CoolMOS

®

and Startup Cell (frequency jitter mode) in DIP-8”

[2] Infineon Technologies, Datasheet “CoolSET

®

-F3R ICE3BR1765J Off-Line SMPS Current Mode

Controller with Integrated 650V CoolMOS

®

and Startup Cell (frequency jitter mode) in DIP-8”

[3] Infineon Technologies, Datasheet “CoolSET

®

-F3R ICE3BR0665J Off-Line SMPS Current Mode

Controller with Integrated 650V CoolMOS

®

and Startup Cell (frequency jitter mode) in DIP-8”

[4] Infineon Technologies, Datasheet “CoolSET

®

-F3R ICE3BR4765JZ Off-Line SMPS Current Mode

Controller with Integrated 650V CoolMOS

®

and Startup Cell (frequency jitter mode) in DIP-7”

[5] Infineon Technologies, Datasheet “CoolSET

®

-F3R ICE3BR1765JZ Off-Line SMPS Current Mode

Controller with Integrated 650V CoolMOS

®

and Startup Cell (frequency jitter mode) in DIP-7”

[6] Infineon Technologies, Datasheet “CoolSET

®

-F3R ICE3BR0665JZ Off-Line SMPS Current Mode

Controller with Integrated 650V CoolMOS

®

and Startup Cell (frequency jitter mode) in DIP-7”

[7] Infineon Technologies, Datasheet “CoolSET

®

-F3R ICE3BR4765JG Off-Line SMPS Current Mode

Controller with Integrated 650V CoolMOS

®

and Startup Cell (frequency jitter mode) in DSO-16/12”

[8] Eric Kok Siu Kam, Kyaw Zin Min, Infineon Technologies, Application Note “AN-EVALSF3-

ICE3BR4765J, 12W 5.0V SMPS Evaluation Board with CoolSET

®

-F3R ICE3BR4765J”

[9] Eric Kok Siu Kam, Kyaw Zin Min, Infineon Technologies, Application Note “AN-EVALSF3-

ICE3BR0665J, 30W 16V SMPS Evaluation Board with CoolSET

®

-F3R ICE3BR0665J”

[10] Harald Zoellinger, Rainer Kling, Infineon Technologies, Application Note “AN-SMPS-ICE2xXXX-1,

CoolSET

TM

ICE2xXXXX for Off-Line Switching Mode Power supply (SMPS )”