Application Note, V1.0, Sep 2011 AN-EVAL3BR1465JF. 60W 18V SMPS Evaluation Board with CoolSET F3R ICE3BR1465JF. Power Management & Supply

Transcription

1 Application Note, V1.0, Sep 2011 AN-EVAL3BR1465JF 60W 18V SMPS Evaluation Board with CoolSET F3R ICE3BR1465JF Power Management & Supply N e v e r s t o p t h i n k i n g.

2 Published by Infineon Technologies AG Munich, Germany 2011 Infineon Technologies AG All Rights Reserved. Legal Disclaimer The information given in this document shall in no event be regarded as a guarantee of conditions or characteristics. With respect to any examples or hints given herein, any typical values stated herein and/or any information regarding the application of the device, Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind, including without limitation, warranties of non-infringement of intellectual property rights of any third party. Information For further information on technology, delivery terms and conditions and prices, please contact the nearest Infineon Technologies Office ( Warnings Due to technical requirements, components may contain dangerous substances. For information on the types in question, please contact the nearest Infineon Technologies Office. Infineon Technologies components may be used in life-support devices or systems only with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered.

3 Revision History: V1.0 Previous Version: none Page Subjects (major changes since last revision) 60W 18V SMPS Evaluation Board with CoolSET F3R ICE3BR1465JF: License to Infineon Technologies Asia Pacific Pte Ltd AN-PS0059 Kyaw Zin Min Kok Siu Kam Eric We Listen to Your Comments Any information within this document that you feel is wrong, unclear or missing at all? Your feedback will help us to continuously improve the quality of this document. Please send your proposal (including a reference to this document) to: ap-lab.admin@infineon.com

4 Table of Contents Page 1 Abstract Evaluation board List of features Technical specifications Circuit description Introduction Line input Start up Operation mode Soft start RCD clamper circuit Peak current control of primary current Output stage Feedback and regulation Blanking window for load jump Active burst mode Jitter mode Protection modes Circuit diagram PCB layout Top side Bottom side Component list Transformer construction Test results Efficiency Input standby power Line regulation Load regulation Maximum input power ESD test Lightning surge test Conducted EMI Waveforms and scope plots Start up at low and high AC line input voltage and maximum load Soft start at low and high AC line input voltage and maximum load Frequency jittering Drain to source voltage and maximum load Load transient response ( Dynamic load from 10% to 100%) Output ripple voltage at maximum load Output ripple voltage during burst mode at 1 W load Entering active burst mode Vcc overvoltage protection Over load protection (built-in 20ms blanking time) Over load protection (built-in + extended blanking time) Open loop protection V CC under voltage/short optocoupler protection Auto restart enable Appendix Slope compensation for CCM operation References Application Note

5 1 Abstract This document is an engineering report that describes a universal input power supply designed in an 18V 60W off line flyback converter that utilizes the IFX F3R CoolSET ICE3BR1465JF. The application demo board is operated in discontinuous conduction mode (DCM) and is running at 67 khz switching frequency. It has one output voltage with secondary side control regulation. It is especially suitable for AC/DC power supply such as LCD monitors, adapters for printers and notebook computers, DVD players and recorder, Blue-Ray DVD player and recorder, set-top boxes and industrial auxiliary power supplies. The ICE3BR1465JF is a current mode control PWM integrated with CoolMOS. With the 650V startup cell, active burst mode and BiCMOS technologies, the standby power can be <100mW at no load and V in = 265Vac. The frequency jitter mode and the soft gate drive can give a low EMI performance. The built-in 20ms blanking window and the extendable blanking time concept can prevent the IC from entering the auto restart mode due to over load protection unintentionally. The outstanding propagation delay compensation feature can allow a very precise current limit between low line and high line. The IC provides auto-restart protection mode for Vcc over-voltage, over temperature, over load, open loop, Vcc under-voltage, short opto-coupler. In case it needs customer defined protection, the external auto restart enable feature can fulfill the requirement. 2 Evaluation board Figure 1 EVAL3BR1465JF This document contains the list of features, the power supply specification, schematic, bill of material and the transformer construction documentation. Typical operating characteristics such as performance curve and scope waveforms are showed at the rear of the report. Application Note

6 3 List of features 650V avalanche rugged CoolMOS with built-in Startup Cell Active Burst Mode for lowest Standby Power Fast load jump response in Active Burst Mode 67 khz internally fixed switching frequency Auto Restart Protection Mode for Overload, Open Loop, Vcc Undervoltage, Overtemperature & Vcc Overvoltage 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 4 Technical specifications Input voltage Input frequency Input Standby Power 85VAC~265VAC 60Hz, 50Hz < 100mW at no load Output voltage and current 18V +/- 2% Output current 3.33A Output power Efficiency Output ripple voltage 60W >83% at average efficiency(25%,50%,75% & 100%load) < 180mVp-p Application Note

7 5 Circuit description 5.1 Introduction The EVAL3BR1465JF demo board is a low cost off line flyback switch mode power supply ( SMPS ) using the ICE3BR1465JF integrated power IC from the CoolSET -F3R family. The circuit, shown in Figure 2, details a 18V, 60W power supply that operates from an AC line input voltage range of 85Vac to 265Vac, suitable for applications in open frame supply or enclosed adapter. 5.2 Line input The AC line input side comprises the input fuse F1 as over-current protection. The choke L11, L12, X-capacitors C11, C14 and Y-capacitor C12 act as EMI suppressors. Optional surge absorber device SA1, SA2 and varistor VAR can absorb high voltage stress during lightning surge test. A rectified DC voltage (120V ~ 374V) is obtained through the bridge rectifier BR1 and the input bulk capacitor C Start up Since there is a built-in startup cell in the ICE3BR1465JF, there is no need for external start up resistors. The startup cell is connecting the drain pin of the IC. Once the voltage is built up at the Drain pin of the ICE3BR1465JF, the startup cell will charge up the Vcc capacitor C16 and C17. When the Vcc voltage exceeds the UVLO at 18V, the IC starts up. Then the Vcc voltage is bootstrapped by the auxiliary winding to sustain the operation. 5.4 Operation mode During operation, the Vcc pin is supplied via a separate transformer winding with associated rectification D12 and buffering C16, C17. Resistor R12 is used for current limiting. In order not to exceed the maximum voltage at Vcc pin, an external zener diode ZD11 and resistor R13 can be added. 5.5 Soft start The Soft-Start is a built-in function and is set at 20ms. 5.6 RCD clamper circuit While turns off the CoolMOS, the clamper circuit R11, C15 and D11 absorbs the current caused by transformer leakage inductance once the voltage exceeds clamp capacitor voltage. Finally drain-source voltage of CoolMOS is lower than maximum break down voltage of CoolMOS. 5.7 Peak current control of primary current The CoolMOS drain source current is sensed via external shunt resistors R14 and R15 which determine the tolerance of the current limit control. Since ICE3BR1465JF is a current mode controller, it would have a cycle-by-cycle primary current and feedback voltage control and can make sure the maximum power of the converter is controlled in every switching cycle. Besides, the patented propagation delay compensation is implemented to ensure the maximum input power can be controlled in an even tighter manner throughout the wide range input voltage. The demo board shows approximately +/-2.68% (refer to Figure 12). Application Note

8 5.8 Output stage On the secondary side the power is coupled out by a schottky diode D21. The capacitor C22 provides energy buffering following with the LC filter L21 and C23 to reduce the output voltage ripple considerably. Storage capacitor C22 is selected to have an internal resistance as small as possible (ESR) to minimize the output voltage ripple. 5.9 Feedback and regulation The output voltage is controlled using a TL431 (IC21). This device incorporates the voltage reference as well as the error amplifier and a driver stage. Compensation network C25, C26, R24, R25, R26, R27 and R28 constitutes the external circuitry of the error amplifier of IC21. This circuitry allows the feedback to be precisely matched to dynamically varying load conditions and provides stable control. The maximum current through the optocoupler diode and the voltage reference is set by using resistors R22 and R23. Optocoupler IC12 is used for floating transmission of the control signal to the Feedback input via capacitor C18 of the ICE3BR1465JF control device. The optocoupler used meets DIN VDE 884 requirements for a wider creepage distance Blanking window for load jump In case of Load Jumps the Controller provides a Blanking Window before activating the Over Load Protection and entering the Auto Restart Mode. The blanking time is built-in at 20ms. If a longer blanking time is required, a capacitor, C19 can be added to BA pin to extend it. The extended time can be achieved by an internal 13.5µA constant current at BA pin to charge C19 ( C BK =10nF) from 0.9V to 4.0V. Thus the overall blanking time is the addition of 20ms and the extended time. The voltage at Feedback pin can rise above 4.3V without switching off due to over load protection within this blanking time frame. During the operation the transferred power is limited to the maximum peak current defined by the value of the current sense resistor, R14 and R15. ( )* CBK Tblanking = Basic + Extended = 20 ms + = 20ms * CBK = ms IBK The blanking time to enter the Active Burst Mode is built-in at 20ms with no extension. If a low load condition is detected when V FB is falling below 1.22V, the system will only enter Active Burst Mode after 20ms blanking time while V FB is still below 1.22V Active burst mode At light load condition, the SMPS enters into Active Burst Mode. At this start, the controller is always active and thus the V CC must always be kept above the switch off threshold V CCoff 10.5V. During active burst mode, the efficiency increases significantly and at the same time it supports low ripple on V OUT and fast response on load jump. When the voltage level at FB falls below 1.22V, the internal blanking timer starts to count. When it reaches the built-in 20ms blanking time, it will enter Active Burst Mode. The Blanking Window is generated to avoid sudden entering of Burst Mode due to load jump. During Active Burst Mode the current sense voltage limit is reduced from 1.06V to 0.26V so as to reduce the conduction losses and audible noise. All the internal circuits are switched off except the reference and bias voltages to reduce the total V CC current consumption to below 0.5mA. At burst mode, the FB voltage is changing like a saw tooth between 3.1 and 3.6V. To leave Burst Mode, FB voltage must exceed 4.5V. It will reset the Active Burst Mode and turn the SMPS into Normal Operating Mode. Maximum current can then be provided to stabilize V OUT Jitter mode The ICE3BR1465JF has frequency jittering feature to reduce the EMI noise. The jitter frequency is internally set at 67 khz (+/- 2.7 khz) and the jitter period is set at 4ms. Application Note

9 5.13 Protection modes Protection is one of the major factors to determine whether the system is safe and robust. Therefore sufficient protection is necessary. ICE3BR1465JF provides all the necessary protections to ensure the system is operating safely. The protections include Vcc overvoltage, overtemperature, overload, open loop, Vcc undervoltage, short optocoupler, etc. When those faults are found, the system will go into auto restart which means the system will stop for a short period of time and restart again. If the fault persists, the system will stop again. It is then until the fault is removed, the system resumes to normal operation. A list of protections and the failure conditions are showed in the below table. Protection function Failure condition Protection Mode Vcc Overvoltage 1. Vcc > 20.5V & FB > 4.5V & during soft start period 2. Vcc > 25.5V Auto Restart Overtemperature (controller junction) Overload / Open loop Vcc Undervoltage / Short Optocoupler T J > 130 C V FB > 4.5V and V BA > 4.0V (Blanking time counted from charging V BA from 0.9V to 4.0V ) Vcc < 10.5V Auto Restart Auto Restart Auto Restart Auto-restart enable V BA < 0.33V Auto Restart Application Note

10 6 Circuit diagram Figure 2 60W 18V ICE3BR1465JF power supply schematic Application Note

11 N.B. : In order to get the optimized performance of the CoolSET, the grounding of the PCB layout must be connected very carefully. From the circuit diagram above, it indicates that the grounding for the CoolSET can be split into several groups; signal ground, Vcc ground, Current sense resistor ground and EMI return ground. All the split grounds should be connected to the bulk capacitor ground separately. Signal ground includes all small signal grounds connecting to the CoolSET GND pin such as filter capacitor ground, C17, C18, C19 and opto-coupler ground. Vcc ground includes the Vcc capacitor ground, C16 and the auxiliary winding ground, pin 2 of the power transformer. Current Sense resistor ground includes current sense resistor R14 and R15. EMI return ground includes Y capacitor, C12. Application Note

12 7 PCB layout 7.1 Top side Figure 3 Top side component legend 7.2 Bottom side Figure 4 Bottom side copper Application Note

13 8 Component list No Designator Component description Part No. Manufacturer 1 BR1 KBU4G(400V 4A) 2 C11 220nF/305V B32922C3224M000 EPCOS 3 C12 2.2nF/250V DE1E3KX222MA4BL01 MURATA 4 C13 120uF/400V B43501A9127M000 EPCOS 5 C14 100nF/305V B32922C3104K000 EPCOS 6 C15 10nF 630V 7 C16 22uF 35V 8 C17 100nF 63V 9 C18, C26 1nF 63V 10 C19 10nF 63V 11 C uF 25V 12 C uF 25V 13 C25 150nF 63V 14 C pF 1kV DESD33A101KA2B MURATA 15 D11 UF4005(600V 1A) 16 D12 1N485B(200V 0.2A) 17 D21 VF30200C(200V 30A) VF30200C-E3/4W VISHAY 18 F1 2A 19 HS11 Heat Sink B02500G AAVID 20 HS21 Heat Sink B02551G AAVID 21 IC11 ICE3BR1465JF ICE3BR1465JF INFINEON 22 IC12 SFH617 A3 23 IC21 TL J11,J12,J13,J21, Jumper NTC,R27,L22 25 L N, +18V Com Connector 26 L11 39mH 1.4A B82734R2142B030 EPCOS 27 L12 6.8mH 1.3A B82734R2322B030 EPCOS 28 L21 1.5uH,6.3A 29 R11 39k 2W 30 R12 200R 31 R R 1W, 1% 32 R22 750R 33 R23 1.2k 34 R24 100k 35 R26 10k 1% 36 R28 62k 1% 37 TR1 220µH(28:6:6) ER28/17/11(N72) EPCOS Application Note

14 9 Transformer construction Core and material : ER28/17/11, N72 Bobbin: ERB28L-P1212-F Primary Inductance, Lp=220μH(±5%), measured between pin 6 and pin 4 (Gapped to Inductance) Transformer structure: Figure 5 Transformer structure and top view of transformer complete Wire size requirement: Start Stop No. of turns Wire size Layer XAWG#24 1 / 2 Primary XAWG#24 Secondary XAWG#24 1 / 2 Primary XAWG#24 Auxilary Application Note

15 10 Test results 10.1 Efficiency Active-Mode Efficiency versus AC Line Input Voltage Efficiency [ % ] AC Line Input Voltage [ Vac ] Full load Efficiency Average Efficiency(25%,50%,75% & 100%) Figure 6 Efficiency Vs. AC line input voltage Efficiency versus Output Power Efficiency [ % ] Output Power [ % ] Vin=115Vac Vin=230Vac Figure 7 Efficiency Vs. output low and high Line Application Note

16 10.2 Input standby power Figure 8 Input standby no load Vs. AC line input voltage ( measured by Yokogawa WT210 power meter - integration mode ) Standby Power versus AC Line Input Voltage Input Power [ W ] AC Line Input Voltage [ Vac ] Po=1W Po=2W Po=3W Figure 9 Input standby 1W, 2W & 3W Vs. AC line input voltage ( measured by Yokogawa WT210 power meter - integration mode ) Application Note

17 10.3 Line regulation Line Regulation : Output Max. Load versus AC Line Input Voltage Output Voltage [ V ] AC Line Input Voltage [ Vac ] max. load Figure 10 Line regulation full load vs. AC line input voltage 10.4 Load regulation Load Regulation: Vout versus Outoput Power Ouput Voltage [ V ] Output Power [ % ] Output 230Vac Output 115Vac Figure 11 Load regulation Vout vs. output power Application Note

18 10.5 Maximum input power Max. Overload Input Power ( Peak Power ) versus AC Line Input Voltage Max. Overload input Power [ W ] Pin=77.76±2.68%(W) AC Line Input Voltage [ Vac ] Peak Input Power Figure 12 Maximum input power ( before overload protection ) vs. AC line input voltage 10.6 ESD test Pass (EN ): 10kV for contact discharge (without surge absorber device) Pass (EN ): 20kV for contact discharge (with surge absorber device; SA1 & SA2 (DA38-102MB)) 10.7 Lightning surge test Pass (EN ): 2kV for line to earth (without surge absorber device) Pass (EN ): 5kV for line to earth (with surge absorber device; SA1 & SA2 (DA38-102MB)) Application Note

19 10.8 Conducted EMI The conducted EMI was measured by Schaffner (SMR4503) and followed the test standard of EN55022 (CISPR 22) class B. The demo board was set up at maximum load (10W) with input voltage of 115Vac and 230Vac EN_V_QP EN_V_AV QP Pre AV Pre 50 dbµv f / MHz Figure 13 Maximum load (60W) with 115 Vac (Line) EN_V_QP EN_V_AV QP Pre AV Pre 50 dbµv f / MHz Figure 14 Maximum load (60W) with 115 Vac (Neutral) Application Note

20 EN_V_QP EN_V_AV QP Pre AV Pre 50 dbµv f / MHz Figure 15 Maximum load (60W) with 230 Vac (Line) EN_V_QP EN_V_AV QP Pre AV Pre dbµv f / MHz Figure 16 Maximum load (60W) with 230 Vac (Neutral) Pass conducted EMI EN55022 (CISPR 22) class B with > 8dB margin. Application Note

21 11 Waveforms and scope plots All waveforms and scope plots were recorded with a LeCroy 6050 oscilloscope 11.1 Start up at low and high AC line input voltage and maximum load 550ms 550ms Channel 1; C1 : Drain voltage (V Drain ) Startup time = 550ms Figure 17 85Vac & max. load Channel 1; C1 : Drain voltage (V Drain ) Startup time = 550ms Figure Vac & max. load 11.2 Soft start at low and high AC line input voltage and maximum load 18.85ms 18.85ms Soft Star time = 18.85ms(32 steps) Figure 19 Soft 85Vac & max. load Soft Star time = 18.85ms(32 steps) Figure 20 Soft 265Vac & max. load Application Note

22 11.3 Frequency jittering 64.4kHz 69kHz 64.4kHz 69kHz Channel 2; C2 : Drain to source voltage (V DS ) Channel 2; C2 : Drain to source voltage (V DS ) Frequency jittering from 64.4 khz ~ 69kHz Figure 21 Frequency 85Vac and max. load Frequency jittering from 64.4kHz ~ 69kHz Figure 22 Frequency 265Vac and max. load 11.4 Drain to source voltage and maximum load Channel 1; C1 : Drain Current ( I DS ) Channel 2; C2 : Drain Source Voltage ( V DS ) Duty cycle = 50%, V DS_peak =226V Duty cycle = 11.3% V DS_peak =525V Figure 23 Vin = 85Vac and max. load Channel 1; C1 : Drain Current ( I DS ) Channel 2; C2 : Drain Source Voltage ( V DS ) Figure 24 Vin = 265Vac and max. load Application Note

23 11.5 Load transient response ( Dynamic load from 10% to 100%) Channel 1; C1 : Output Current ( I o ) Channel 2; C2 : Output ripple Voltage ( V o ) V ripple_pk_pk =199mV (Load change from10% to 100%,100Hz,0.4A/μS slew rate) Probe terminal end with decoupling capacitor of 0.1uF(ceramic) & 1uF(Electrolytic), 20MHz filter Figure 25 Load transient 85Vac Channel 1; C1 : Output Current ( I o ) Channel 2; C2 : Output ripple Voltage ( V o ) V ripple_pk_pk =200mV (Load change from10% to 100%,100Hz,0.4A/μS slew rate) Probe terminal end with decoupling capacitor of 0.1uF(ceramic) & 1uF(Electrolytic), 20MHz filter Figure 26 Load transient 265Vac 11.6 Output ripple voltage at maximum load Channel 2; C2 : Output Ripple Voltage ( V o_ripple ) Channel 2; C2 : Output Ripple Voltage ( V o_ripple ) V ripple_pk_pk =91mV Probe terminal end with decoupling capacitor of 0.1uF(ceramic) & 1uF(Electrolytic), 20MHz filter Figure 27 AC output Vin=85Vac and max. load V ripple_pk_pk =114mV Probe terminal end with decoupling capacitor of 0.1uF(ceramic) & 1uF(Electrolytic), 20MHz filter Figure 28 AC output Vin=265Vac and max. load Application Note

24 11.7 Output ripple voltage during burst mode at 1 W load Channel 1; C1 : Output ripple voltage (Vo) V ripple_pk_pk =44mV Probe terminal end with decoupling capacitor of 0.1uF(ceramic) & 1uF(Electrolytic), 20MHz filter Figure 29 AC output 85Vac and 1W load Channel 1; C1 : Output ripple voltage (Vo) V ripple_pk_pk = 51mV Probe terminal end with decoupling capacitor of 0.1uF(ceramic) & 1uF(Electrolytic), 20MHz filter Figure 30 AC output 265Vac and 1W load 11.8 Entering active burst mode Blanking time to enter burst mode : 19ms (load step down from 3.33A to 0.056A) Figure 31 Active burst 85Vac Blanking time to enter burst mode : 19ms (load step down from 3.33A to 0.056A) Figure 32 Active burst Vin=265Vac Application Note

25 11.9 Vcc overvoltage protection V CC OVP2 V CC OVP1 V CC OVP2 V CC OVP1 VCC OVP2 first & follows VCC OVP1 (R28 disconnected during system operating with no load) Figure 33 Vcc overvoltage 85Vac VCC OVP2 first & follows VCC OVP1 (R28 disconnected during system operating with no load) Figure 34 Vcc overvoltage 265Vac Over load protection (built-in 20ms blanking time) Over load protection with 19.34ms blanking time (output load change from 3.33A to 4A, C19=100pF) Figure 35 Over load protection with built-in 20ms blanking 85Vac) Over load protection with 19.34ms blanking time (output load change from 3.33A to 4A, C19=100pF) Figure 36 Over load protection with built-in 20ms blanking 265Vac) Application Note

26 11.11 Over load protection (built-in + extended blanking time) Over load protection with 21.54ms( ) blanking time (output load change from 3.33A to 4A, C19=10nF) Figure 37 Over load protection with built-in+extended blanking 85Vac Over load protection with 21.54ms( ) blanking time (output load change from 3.33A to 4A, C19=10nF) Figure 38 Over load protection with built-in+extended blanking 265Vac Open loop protection Open loop protection (R28 disconnected during system operation at max. load) over load protection Figure 39 Open loop 85Vac Open loop protection (R28 disconnected during system operation at max. load) over load protection Figure 40 Open loop 265Vac Application Note

27 11.13 V CC under voltage/short optocoupler protection V CC under voltage/short optocoupler protection (short the transistor of optocoupler during system full load) Figure 41 V cc under voltage/short optocoupler 85Vac V CC under voltage/short optocoupler protection (short the transistor of optocoupler during system full load) Figure 42 V cc under voltage/short optocoupler 265Vac Auto restart enable External protection enable (short BA pin to Gnd by 10Ω resistor) Figure 43 External protection 85Vac External protection enable (short BA pin to Gnd by 10Ω resistor) Figure 44 External protection 265Vac Application Note

28 12 Appendix 12.1 Slope compensation for CCM operation This demo board is designed in Discontinuous Conduction Mode ( DCM ) operation. If the application is designed in Continuous Conduction Mode ( CCM ) operation where the maximum duty cycle exceeds the 50% threshold, it needs to add the slope compensation network. Otherwise, the circuitry will be unstable. In this case, three more components ( 2 ceramic capacitors C17 / C18 and one resistor R19) is needed to add as shown in the circuit diagram below. Figure 45 Circuit diagram switch mode power supply with slope compensation More information regarding how to calculate the additional components, see application note AN_SMPS_ICE2xXXX available on the internet: (directory : Home > Power Semiconductors > Integrated Power ICs > CoolSET F2) 13 References [1] Infineon Technologies, Datasheet CoolSET -F3R ICE3BR1465JF Off-Line SMPS Current Mode Controller with Integrated 650V CoolMOS and Startup cell ( frequency jitter Mode ) in FullPak [2] Eric Kok Siu Kam, Kyaw Zin Min, Infineon Technologies, Application Note ICE3BRxx65JF CoolSET F3R(FullPak) new Jitter version Design Guide [3] Harald Zoellinger, Rainer Kling, Infineon Technologies, Application Note AN-SMPS-ICE2xXXX-1, CoolSET. ICE2xXXXX for Off-Line Switching Mode Power supply (SMPS ) Application Note