FA557171A72737455705671 Fuji Switching Power Supply Control IC Green mode Quasi-resonant IC FA5571/71A/72/73/74/ 5570/5671 Application Note April 2011 Fuji Electric Co., Ltd. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 1 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 Caution 1. The contents of this note (Product Specification, Characteristics, Data, Materials, and Structure etc.) were prepared in April 2011. The contents will subject to change without notice due to product specification change or some other reasons. In case of using the products stated in this document, the latest product specification shall be provided and the data shall be checked. 2. The application examples in this note show the typical examples of using Fuji products and this note shall neither assure to enforce the industrial property including some other rights nor grant the license. 3. Fuji Electric Co.,Ltd. is always enhancing the product quality and reliability. However, semiconductor products may get out of order in a certain probability. Measures for ensuring safety, such as redundant design, spreading fire protection design, malfunction protection design shall be taken, so that Fuji Electric semiconductor product may not cause physical injury, property damage by fire and social damage as a result. 4. Products described in this note are manufactured and intended to be used in the following electronic devices and electric devices in which ordinary reliability is required: - Computer - OA equipment - Communication equipment (Terminal) - Measuring equipment - Machine tool - Audio Visual equipment - Home appliance - Personal equipment - Industrial robot etc. 5. Customers who are going to use our products in the following high reliable equipments shall contact us surely and obtain our consent in advance. In case when our products are used in the following equipment, suitable measures for keeping safety such as a back-up-system for malfunction of the equipment shall be taken even if Fuji Electric semiconductor products break down: - Transportation equipment (in-vehicle, in-ship etc.) - Communication equipment for trunk line - Traffic signal equipment - Gas leak detector and gas shutoff equipment - Disaster prevention/Security equipment - Various equipment for the safety. 6. Products described in this note shall not be used in the following equipments that require extremely high reliability: - Space equipment - Aircraft equipment - Atomic energy control equipment - Undersea communication equipment - Medical equipment. 7. When reprinting or copying all or a part of this note, our company's acceptance in writing shall be obtained. 8. If obscure parts are found in the contents of this note, contact Fuji Electric Co.,Ltd. or a sales agent before using our products. Fuji Electric Co.,Ltd. and its sales agents shall not be liable for any damage that is caused by a customer who does not follow the instructions in this cautionary statement. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 2 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 Contents 1. Description 2. Features 3. Outline drawing 4. Block diagram 5. Functional description of pins 6. Rating and Characteristics 7. Characteristic curve 8. Basic operation 9. Description of the function 10. Method for using each pin 11. Advice for designing 12.Precautions for us 13. Example of application circuit 4 4 4 5-6 6 7-10 11-15 16 17-23 24-28 29-32 33-35 36 Caution) The contents of this note will subject to change without notice due to improvement. The application examples or the components constants in this note are shown to help your design, and variation of components and service conditions are not taken into account. In using these components, a design with due consideration for these conditions shall be conducted. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 3 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 1. Overview FA5571/71A/72/73/74/70/5671 is a quasi-resonant type switching power supply control IC with excellent stand-by characteristics. Though it is a small package with 8 pins, it has a lot of functions and enables to decrease external parts. Therefore it is possible to realize a small footprint and a high cost-performance power supply. 2. Features A quasi-resonant type switching power supply. A power supply with excellent standby characteristics. Low power consumption with a built-in startup circuit. Low current consumption, in operation: 1.35mA Built-in maximum frequency limitation function: 120kHz(FA5571/72/73/74/70), 170kHz(FA5571A/5671) Operation at light load (FA5571/71A/72/70/5671: built-in burst function, FA5573/74: built-in frequency reduction function) Built-in drive circuit possible to connect to a power MOSFET directly. Output current: 0.5A (sink) 0.25A (source) Built-in overload protection function (FA5571/71A/73/70/5671: auto restart, FA5572/74: timer latch) Built-in latch protection function with the secondary over-voltage detection. Built-in transformer short circuit protection function. Built-in low voltage malfunction protection circuit. Package: SOP-8 Function list by types Type Overload Light load operation protection FA5571 Maximum ZCD pin timer IS pin latch VCC pin OVP IS pin OCP blanking latch Delay shutdown threshold threshold frequency time TLAT1 threshold 120kHz(TYP) 2.3us(TYP) 2.0V(TYP) nonfunctional 1.0V(TYP) 170kHz(TYP) 4.5us(TYP) 2.0V(TYP) nonfunctional 1.0V(TYP) 120kHz(TYP) nonfunctional nonfunctional nonfunctional 1.0V(TYP) 170kHz(TYP) nonfunctional nonfunctional 28V(TYP) 0.5V(TYP) Auto restart Burst Auto restart Burst FA5572 Timer latch Burst 120kHz(TYP) 2.3us(TYP) 2.0V(TYP) nonfunctional 1.0V(TYP) FA5573 Auto restart Frequency reduction 120kHz(TYP) 2.3us(TYP) 2.0V(TYP) nonfunctional 1.0V(TYP) FA5574 Timer latch Frequency reduction 120kHz(TYP) 2.3us(TYP) 2.0V(TYP) nonfunctional 1.0V(TYP) FA5571A FA5570 FA5671 3. Outline drawings SOP-8 0.650.25 6.00.3 3.90.2 0 10 1 PIN MARK 0.2 0.1 0.2 1.8 MAX 5.00.25 1.27 0.40.1 Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 4 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 4. Block diagram FA5571/71A/70/5671 ZCD Valley detection 5V Start up management Logic 10.5V/9V 1 shot (380ns) Time out (14s) CLR VH Start up Current VCC Max. fsw Blanking (120kHz) Reset IS 5V 170kHz:5571A/5671 UVLO 5V Reg. 18V/8V Internal supply Driver Disable S 0.4V Current comparator Q OUT R ZCD OVP FB 4.5us:FA5571A 5570/5671:ZCD OVP (2.3us)Nonfunctional Timer (2.3s) 1/2 1/4:FA5671 Only Soft start (2.6ms) 1V 0.5V:FA5671 Only Timer 190ms Overload Timer (57s) IS 1520ms Latch OCP2 Reset VCC OVP1 2V GND 3.5/3.3V 5570/5671:Nonfunctional FA5671Only:Function 28V FA5572 ZCD Valley detection 5V Start up management Logic 10.5V/9V 1 shot (380ns) Time out (14s) CLR VH Start up Current VCC Reset IS 5V Max. fsw Blanking (120kHz) UVLO 5V Reg. 18V/8V Internal supply Driver Disable S 0.4V Current comparator Q OUT R ZCD OVP Timer (2.3s) 1/2 FB 1/2:FA5572 1V :FA5572 Overload Soft start (2.6ms) Timer 190ms Reset Timer (57s) IS OCP2 2V :FA5572 3.5/3.3V Latch GND Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 5 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 FA5573 ZCD Valley detection 5V Start up management Logic 10.5V/9V 1 shot (380ns) Time out (14s) CLR VH Start up Current VCC Reset IS 5V Max. fsw Blanking (120kHz) Variable max.120kHz to min. 0.3kHz UVLO 5V Reg. 18V/8V Internal supply Driver Disable S 0.4V Current comparator Q OUT R ZCD OVP Timer (2.3s) 1/2 FB 1/2:FA5573 Soft start (2.6ms) 1V :FA5573 Timer 190ms Overload Timer (57s) IS 1520ms Latch OCP2 Reset GND 2V :FA5573 3.5/3.3V FA5574 ZCD Valley detection 5V Start up management Logic 10.5V/9V 1 shot (380ns) Time out (14s) CLR VH Start up Current VCC Reset IS 5V Max. fsw Blanking (120kHz) Variable max.120kHz to min. 0.3kHz UVLO 5V Reg. 18V/8V Internal supply Driver Disable S 0.4V Current comparator Q OUT R ZCD OVP 1/2 FB 1/2:FA5574 1V :FA5574 Overload Soft start (2.6ms) Timer 190ms Timer (2.3s) Timer (57s) IS Latch OCP2 Reset 2V :FA5574 3.5/3.3V GND Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 6 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 5. Functional description of pins Pin number Pin name Pin function 1 ZCD Zero current detection input 2 FB Feed-back input 3 IS Current sense input 4 GND Ground 5 OUT Output 6 VCC Power supply 7 NC 8 VH High voltage input 6. Rating and characteristics * "+" shows sink and "-" shows source in current prescription. (1) Absolute maximum rating Item Power supply voltage OUT pin output peak current OUT pin voltage FB, IS pin input voltage Symbol Rating Unit VCC 30 V IOH -0.25 A IOL +0.5 A VOUT -0.3 to VCC+0.3 V VLT -0.3 to 5.0 V ISOZCD -2.0 ISIZCD +3.0 VH pin input voltage VVH -0.3 to 500 V Total loss (Ta<25) Pd 400 (SOP-8) mW ZCD pin current Maximum junction temperature Storage temperature mA Tj 125 Tstg 40 to +150 * Allowable loss reduction characteristics Allowable loss 400mW(SOP) 0 -30 85 25 Ambient temperature Ta [] 125 Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 7 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (2) Recommended operating condition Item Symbol Power supply voltage(FA5571/ 71A/72/73/70) VCC Power supply voltage(FA5671) VH pin input voltage TYP MAX Unit 11 15 28 V 11 15 26 V 80 - 450 V CVCC 10 47 220 F Ta -40 - 85 VVH VCC pin capacity MIN Operating ambient temperature (3) Electric characteristics (Unless otherwise specified : Vcc=15V, Tj=25) Current sensing part (IS pin) Item Symbol Input bias current IIS Maximum input threshold voltage VthIS Voltage gain AVIS Minimum ON width Tonmin Output delay time *1 Latch shutdown threshold voltage TpdIS Condition MIN TYP MAX Unit VIS=0V -60 -50 -40 A VFB=3V, FA5571/71A/72 /73/74/70 0.9 1.0 1.1 V VFB=3V, FA5671 0.45 0.5 0.55 V VFB/VIS 1.75 2.0 2.25 V/V FB=3V, IS=1.5V 260 380 500 ns IS input: 0V to 1.5V (Pulse signal) 100 175 320 ns 1.8 2.0 2.2 V VthISat Feedback part (FB pin) Item Symbol Condition MIN TYP MAX Unit Pulse shutdown FB pin voltage VTHFB0 Duty cycle=0% 340 400 460 mV FA5571/71A/72/70/5671 VFB=1V to 2V 14.4 18.0 21.6 k FB pin input resistance RFB FA5573/74 VFB=1V to 2V 17.6 22.0 26.4 k FB pin current IFB0 VFB=0V -240 -200 -160 A FB pin threshold voltage for light load mode VFBM FA5573/74 0.95 1.15 1.35 V Minimum oscillation frequency Fmin FA5573/74 VFB=0.5V 0.15 0.3 0.4 kHz TYP MAX Unit Zero current detection part (ZCD pin) Item Input threshold voltage Hysteresis width Symbol Condition MIN VTHZCD1 VZCD decreasing 40 60 100 mV VTHZCD2 VZCD increasing 150 250 340 mV 110 190 240 mV VHYZCD VIH IZCD=+3mA (High state) 8.2 9.2 10.2 V VIL IZCD=-2mA (Low state) -0.93 -0.8 - V - 155 300 ns FA5571/72/73/74/70 108 120 140 kHz FA5571A/5671 155 170 185 kHz Input clamp voltage ZCD delay time *1 TZCD Maximum blanking frequency Fmax Timeout period from the last ZCD trigger *1 TOUT 10 14 18 s ZCD pin internal resistance Rzcd 22.5 30 37.5 k Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 8 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 Over-voltage protection part (ZCD pin) Item Symbol MIN TYP MAX Unit 6.4 7.2 8.0 V FA5671 26 28 30 V Delay from turn-off FA5571/72/73/74 1.8 2.3 2.8 s Delay from turn-off FA5571A 3.5 4.5 5.5 s Delay from exceeding the Vovp voltage 40 57 75 s Condition MIN TYP MAX Unit VOLP1 VFB increasing 3.3 3.5 3.8 V VOLP2 VFB decreasing 3.0 3.3 3.6 V TOLP FA5571/71A/73/70/5671 : Switching continuing time after detecting overload. FA5572/74 : Timer latch delay time after detecting overload. 133 190 247 ms TOFF Switching shutdown time after TOLP period 930 1330 1730 ms MIN TYP MAX Unit 1.6 2.6 3.6 ms Condition MIN TYP MAX Unit 0.5 1.0 2.0 V ZCD pin over-voltage threshold level VOVP VCC pin over-voltage threshold level VOVP1 Timer latch delay time *1 TLAT1 TLAT2 Condition Overload protection part (FB pin) Item FB pin overload detection threshold level *1 OLP delay time OLP output shutdown time *1 Symbol FA5571/ 71A/73/70/ 5671 Soft start part Item Soft start time *1 Symbol Condition TSFT Output part (OUT pin) Item Symbol L output voltage VOL IOL=100mA VCC=15V H output voltage VOH IOH=-100mA VCC=15V 12 13.2 14.5 V Rise time *1 tr CL=1nF, Tj=25C 20 40 100 ns Fall time *1 tf CL=1nF, Tj=25C 15 30 70 ns Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 9 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 High voltage input part (VH pin) Item VH pin input current Symbol Condition MIN TYP MAX Unit IVHrun VVH=400V, VCC>VSTOFF 10 30 60 A IVH1 VCC=6.5V, VVH=100V Tj=25C 4.0 6.8 9.6 mA IVH0 VCC=0V, VVH=100V Tj=25C 0.8 1.6 2.5 mA Ipre1 VCC=8V, VVH=100V Tj=25C -9 -6.4 -3.7 mA Ipre2 VCC=16V, VVH=100V Tj=25C -8 -4.8 -3 mA MIN TYP MAX Unit VCC pin charging current Low voltage malfunction protection circuit (UVLO) part (VCC pin) Item Symbol Condition ON threshold voltage VCCON UVLO 16 18 20 V OFF threshold voltage VCCOFF UVLO 7 8 9 V Hysteresis width VHYS1 8 10 12 V Startup current shutdown voltage VSTOFF Vcc increasing 9.5 10.5 12 V Startup current reset voltage VSTRST1 Vcc decreasing 8 9 10 V 0.5 1.5 2.0 V Condition MIN TYP MAX Unit ICCOP1 VFB=2.5VVIS1.5V VZCD=0V OUT=no_load 0.9 1.35 2.0 mA ICCOP2 Duty cycle=0%, VFB=0V 0.9 1.33 1.9 mA FB=open VCC=11V 350 500 650 A Hysteresis width (startup current) VHYS2 Current consumption (VCC pin) Item Power supply current in operation Power supply current at latch Symbol ICClat *1 : Regarding to these items, 100% test is not carried out. A specified value is a design guarantee. The column showing `-` has no specified value. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 10 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 7. Characteristic curve Unless otherwise specified : Ta=25, VCC=15V(*FA5571) "+" shows sink and "-" shows source in current prescription. Data listed here shows the typical characteristics of an IC and does not guarantee the characteristics. Maximum fsw blanking (Fmax) vs. Junction temperature (Tj) 128 128 124 124 Fmax (kHz) Fmax (kHz) Maximum fsw blanking (Fmax) vs. VCC pin voltage (VCC) 120 120 116 116 112 5 10 15 20 25 112 -50 30 0 VC C (V) 174 FA5571A FA5671 Fmax (kHz) Fmax (kHz) 150 178 178 170 FA5571A FA5671 170 166 166 162 -50 162 5 10 15 20 25 30 0 50 100 150 Tj (degree) VC C (V) 280 100 Maximum fsw blanking (Fmax) vs. Junction temperature (Tj) Maximum fsw blanking (Fmax) vs. VCC pin voltage (VCC) 174 50 Tj (degree) ZCD pin input threshold voltage (Vthzcd2) vs. Junction temperature (Tj) 70 ZCD pin input threshold voltage (Vthzcd1) vs. Junction temperature (Tj) Vzcd=decreasing 65 Vthzcd1 (mV) Vthzcd2 (mV) 265 250 235 60 55 Vzcd=increasing 220 -50 0 50 100 50 -50 150 Tj (degree) 0 50 100 150 Tj (degree) Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 11 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 18.4 UVLO ON threshold voltage (Vccon) vs. Junction temperature (Tj) UVLO OFF threshold voltage (Vccoff) vs. Junction temperature (Tj) 8.6 8.3 Vccoff (V) Vccon (V) 18.2 18 17.8 8 7.7 17.6 -50 0 50 100 7.4 -50 150 0 Tj (degree) 11.5 Start-up circuit off threshold voltage (Vstoff) vs. Junction temperature (Tj) 9.4 Vstrst (V) Vstoff (V) 150 9.8 10.5 10 9 8.6 9.5 -50 0 50 100 8.2 -50 150 0 Tj (degree) 100 150 OLP threshold voltage (Volp1) vs. Junction temperature (Tj) 3.7 VFB=3V VIS=1.5V VC C =15V Volp1 (V) 3.6 380 360 340 -50 50 Tj (degree) Minimum ON width (Tonmin) vs. Junction temperature (Tj) 400 Tonmin (ns) 100 Start-up circuit restart threshold voltage (Vstrst) vs. Junction temperature (Tj) 11 420 50 Tj (degree) 3.5 3.4 0 50 100 3.3 -50 150 Tj (degree) 0 50 100 150 Tj (degree) Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 12 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 Delaytime to OLP (Tolp) vs. Junction temperature (Tj) 230 OLP offtime (Toff) vs. Junction temperature (Tj) 1500 210 Toff (ms) Tolp (ms) 1400 190 1300 1200 170 1100 150 -50 0 50 100 1000 -50 150 0 50 Tj (degree) High output voltage (VOH) vs. Supply voltage (Vcc) IOH=-100mA IOL=100mA 3 2.5 2.5 2 2 VOL (V) Vcc - VOH (V) 150 Low output voltage (VOL) vs. Supply voltage (Vcc) 3.5 3.5 3 100 Tj (degree) 1.5 1.5 1 1 0.5 0.5 0 0 0 10 20 30 0 10 Vcc (V) 20 30 Vcc (V) IS pin maximum threshold voltage (VthIS) vs. FB pin voltage (VFB) IS pin maximum threshold voltage (VthIS) vs. Junction temperature (Tj) 1.1 1.2 1 1.05 VthIS (V) VthIS (V) 0.8 1 0.6 0.4 0.95 0.2 0.9 -50 0 0 50 100 150 0 Tj (degree) 1 2 3 4 VFB (V) Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 13 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 IS pin maximum threshold voltage (VthIS) vs. FB pin voltage (VFB) IS pin maximum threshold voltage (VthIS) vs. Junction temperature (Tj) 0.6 0.6 0.5 0.55 FA5671 VthIS (V) VthIS (V) 0.4 FA5671 0.5 0.3 0.2 0.45 0.1 0 0.4 -50 0 50 100 0 150 1 2 IS pin latch threshold voltage (VthISlat) vs. Junction temperature (Tj) 7.5 2.05 7.35 VOVP (V) VthISlat (V) 4 ZCD pin OVP threshold voltage (VOVP) vs. Junction temperature (Tj) 2.1 2 1.95 7.2 7.05 1.9 -50 0 50 100 6.9 -50 150 0 Tj (degree) 0 3 VFB (V) Tj (degree) 50 100 150 Tj (degree) Charge current for VCC pin (Ipre) vs. Junction temperature (Tj) Charge current for VCC pin (Ipre) vs. VCC pin voltage (VCC) -1.2 VVH=100V VC C =0V -1.3 -2 VVH=100V Ipre (mA) Ipre (mA) -1.4 -4 -1.5 -1.6 -6 -1.7 -8 0 5 10 15 -1.8 -50 20 VC C (V) 0 50 100 150 Tj (degree) Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 14 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 Charge current for VCC pin (Ipre) vs. Junction temperature (Tj) 8 -5 VVH=100V VC C =6.5V -5.5 VH pin input current (Ipre) vs. VH pin voltage (VVH) 7 IVH (mA) Ipre (mA) -6 -6.5 6 VC C =6.5V Tj=25degree 5 -7 4 -7.5 -8 -50 3 0 50 100 0 150 100 -180 200 300 400 500 VVH (V) Tj (degree) Operating-state supply current (Iccop) vs. VCC pin voltage (VCC) FB pin source currnt (Ifb0) vs. Junction temperature (Tj) 1.6 1.5 -190 Iccop (mA) Ifb0 (uA) 1.4 -200 1.3 OUT=no_load VFB=2.5V VIS=1V fsw=110kHz 1.2 VFB=0V VC C =15V -210 -220 -50 1.1 1 0 50 100 150 5 Tj (degree) 10 15 20 25 30 VC C (V) VCC pin OVP threshold Voltage(Vovp1) vs. Junction temperature (Tj) 29 Ipre (mA) 28.5 FA5671 28 27.5 27 -50 0 50 100 150 Tj (degree) Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 15 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 8. Basic operation The basic operation of the power supply using IC is not switching operation with fixed frequency using an oscillator but switching with OUT (Q1 gate) self-excited oscillation. This is shown in Fig.1 Schematic circuit diagram and Fig.2 Waveform in the basic operation. t1 to t2 Q1 Vds Q1 turns ON and then Q1 drain current Id (primary current of T1) begins to rise from zero. Q1 current is converted into the voltage by Rs and is input into IS pin. t2 Q1 Id When the current of Q1 get to the reference voltage of the current comparator that is fixed by the voltage of FB pin, a reset signal is input into RS flip-flop and Q1 turns OFF. D1 IF t2 to t3 When Q1 turns OFF, then the coil voltage of the transformer turns over and the current IF is provided from the transformer into the secondary side through D1. Vsub t3 to t4 When the current from the transformer into the secondary side stops and the current of D1 gets to zero, the voltage of Q1 turns down ZCD Pin 6mV rapidly due to the resonance of the transformer inductance and the capacitor Cd. At the same time the transformer auxiliary coil voltage Vsub also drops rapidly. 1 shot out put (Valley signalset) ZCD pin receives this auxiliary coil voltage but then it has a little delay time because of CR circuit composed with RZCD and CZCD on the way. t4 Current comparator out put (reset) If ZCD pin voltage turns down lower than the threshold voltage (60mV(typ.)) of Valley detection, a set signal is input into R-S flip-flop and Q1 turns ON again. If the delay time of CR circuit placed between t1 the auxiliary coil and ZCD pin is adjusted properly, Q1 voltage can be turned on at the bottom. This operation makes the switching loss of t2 t3 t4 Fig.2 Waveform in basic operation TURN ON to the minimum. (Return to t1) Subsequently repeat from t1 to t4 and continue switching. T1 ZCD comparator Cd Q1 Driver 5 1 shot Q D1 Valley detection 1 OUT ZCD Vds R ZCD Rs C ZCD S Vsub R 3 F.F. Current comparator Level shift 2 IS FB Fig.1 Schematic circuit diagram in basic operation Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 16 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 9. Description of the function (1) Steady- state operation and burst operation at light load (FA5571/72/70) FA5571A/5671 Maximum blanking frequency170kHz Steady- state operation Vds Max fsw 120kHz 120kHz 120kHz Valley Signal OUT pulse Heavy load middle load light load (stand-by) Fig.3 Steady-state operation timing chart At each switching cycle, TURN ON is carried out at the first Valley signal that exceeds the time corresponding to the maximum frequency limit of 120kHz (170kHz : 5571A/5671), counting from the previous TURN ON. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 17 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 Burst operation at light load FB pin Voltage Pulse stop voltage VTHFB0 0.4 V (typ.) OUT pin Switching pulse Heavy load Light load (burst switching) Fig.4 Burst operation at light load When FB pin voltage drops lower than the pulse shutdown threshold voltage, switching is shut down. On the contrary when FB pin voltage rises higher than the pulse shutdown threshold voltage, switching is started again. FB pin voltage overshoots and undershoots centering around the pulse shutdown threshold voltage for mode change. Continuous pulse is output during the overshoot period and long period burst frequency is obtained during the undershoot period. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 18 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (2) Steady-state operation and frequency reduction operation at light load (FA5573/74) fsw Max fsw 120kHz Min (ex0.3 Po Fig. 5 Oscillation frequency (f sw) vs output power characteristics (Po) Vds Max fsw 120kHz Max fsw decrease ex : 0.3 120kHz Valley signal OUT pulse Heavy load Middle load Light load Fig.6 Steady-state operation timing chart In the normal operation, each switching cycle is turned on at the first valley signal beyond the time corresponding to the maximum frequency limitation of 120 kHz after the previous turn-on. Moreover, in the light load operation, the maximum frequency limitation is decreased. The frequency lowers approximately to 0.3 kHz at minimum. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 19 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (3) Startup circuit and auxiliary coil voltage Vcc 18V 10.5V 9V 8V Start up circuit Switching Fig.7 Startup and shutdown (the auxiliary coil voltage is higher than 9 V) Vcc 18V 10.5V 9V 8V Start up circuit Switching Fig.8 Startup and shutdown (the auxiliary coil voltage is lower than 9 V) If the auxiliary coil voltage is higher than 9V, the startup circuit operates only at the startup and since then operates being provided with the auxiliary coil voltage as a power supply. While the auxiliary coil voltage is lower than 9V, the startup circuit continues to keep Vcc between 9V and 10.5V by ON-OFF. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 20 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (4) Operation at overload FA5571/71A/73/70/5671 (Auto restart type) 18V 10.5V Vcc 9V 8V Start up Circuit On/Off signal FB pin 3.5V Timer operation 190ms 190ms 1330ms 1520ms 190ms Timer output 1520ms Switching Normal load Over load Normal load Fig.9 Operation at overload (FA5571/71A/73/70/5671) If the overload condition continues longer than 190ms, switching is forced to shut down using an internal timer. The startup circuit is possible to operate within 1520ms after the beginning of the overload condition. If the overload condition continues, switching is done for 190ms and after then Vcc is provided with the startup circuit for 1330ms and the operation shutdown condition is maintained. When 1520ms passes after the beginning of the overload condition, a startup circuit stops its operation and Vcc begins to decrease. When Vcc gets down to 8.0V, the IC is once reset and restarted. Since then startup and shutdown are repeated if the overload condition continues. If the load returns to normal, the IC returns to the normal operation. Even then, the output voltage must rise up to the setting value at the startup within 190ms settled with a timer. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 21 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 FA5572/74(latch type) Fig.10 Operation at overload (FA5572/74) If the overload condition continues longer than 190ms, switching is forced to shut down using an internal timer, and changes to latch mode to maintain this condition. During the condition when switching is shut down due to an overload latch, Vcc is provided with the startup circuit and the operation shutdown condition is maintained. To reset the overload latch, shut down the supply of Vcc from the startup circuit by stopping the input voltage and reduces Vcc lower than 8.0V, the OFF-threshold voltage. Even then, the output voltage must rise up to the setting value at the startup within 190ms settled with a timer. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 22 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (5) Others By pulling-up ZCD pin voltage higher than 7.2V from the outside, shutdown can be carried out. This condition is maintained until the input voltage is shut down and Vcc drops to the OFF threshold voltage of UVLO. Automatic reset with overload protection If Vcc is provided by other power supply, latch-stop is carried out. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 23 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 10. Direction for use of pins (1) No.1 pin (ZCD) Function ( ) Detection of timing to make a MOSFET turn ON. Cd ( ) Latch protection with an external signal. ZCD () Latch protection for over-voltage on the secondary side. 1 30k RZCD 9.2V Usage CZCD () Detection of turn-on timing Connection Fig.11 ZCD pin circuit This pin is connected to a transformer auxiliary winding through CR circuit with RZCD and CZCD. (Fig.11) Be careful about polarity of an auxiliary winding. ZCD Operation 1 When ZCD pin voltage drops lower than 60mV, MOSFET is Clamp current 9.2V 30k turned on. The auxiliary winding voltage swings + and - direction widely along with switching. A clamp circuit is equipped to Fig.12 Clamping circuit (auxiliary coil voltage is plus) protect IC from this voltage. If the auxiliary winding voltage is plus, it passes a current shown in Fig. 12 and if minus, shown in Fig.13. And then it clamps ZCD pin voltage. Complement ZCD 1 Since the threshold voltage of latch protection by an external signal is 6.4V (min.) as described in function (), 9.2V 30k the resistor RZCD must be adjusted for ZCD pin voltage not Clamp current to exceed 6.4V in ordinary operation. At the same time the resistor RZCD must be adjusted for ZCD pin current not to Fig.13 Clamping circuit (auxiliary coil voltage is minus) exceed the absolute maximum rating. The MOSFET voltage oscillates just before TURN ON due to the resonance effect between transformer inductance and resonant capacitor Cd. CZCD is adjusted for MOSFET to turn on at the bottom of this resonance (Fig.14). Vds Generally RZCD is several 10k and CZCD is several 10pF. However CZCD is unnecessary if good timing is obtained. ( ) Latch protection with an external signal Fig.14 Vds waveform Connection Pull up ZCD pin by an external signal. 0.47uF A connection example in case of over-voltage on the 6 primary side is shown in Fig.15. (Constants are examples. 2.2k VCC Check the behavior in actual circuit.) Operation 2.2k If ZCD pin voltage exceeds 7.2V (typ.) and this condition continues longer than 57s(typ.), latch protection is carried 8.2k 24V ZCD out. 1 Once latch protection is carried out, the output pulse of the Constants are examples, and IC is shut down and this condition is maintained. do not guarantee the operation. Reset is done by decreasing Vcc lower than UVLO offthreshold voltage. Fig.15 Over-voltage protection circuit for the primary side Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 24 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 () Latch protection for over-voltage on the secondary side Connection (FA5571/71A/72/73/74) Same as ( ) Detection of turn-on timing. Operation If the secondary output voltage (Vo) gets to the Vo over-voltage, the auxiliary coil voltage and ZCD pin voltage also rise. 0V When ZCD pin voltage exceeds 7.2V (typ.) and 2.3 uS 2.3us(typ) (typ.) (71A4.5us) passes after FET turns off, the latch operation is carried out being fitted with the upper condition and output switching is shut down. (Fig.16) zcd pin In the latch operation, Vcc voltage is maintained by the start-up circuit and the latch operation is maintained. 7.2V(typ) 0V (2) No.2 pin (FB pin) Fig.16 ZCD pin waveform for over-voltage on the secondary side Function () Input of a feed-back signal from secondary error-amplifier. () Detection of an overload condition. Usage () Input of a feedback signal 5V Connection This pin is connected with the receiver unit of a photo coupler. Concurrently it is connected a capacitor in parallel with the photo coupler to protect noise. (Fig. 17) 20k Operation 1000pF 0.01uF 2 This pin is biased by an IC internal power supply through a FB diode and a resistor. The FB pin voltage is level-shifted and is input into a current comparator and finally gives the threshold voltage for MOSFET current signal that is detected on IS pin. Fig.17 FB pin circuit () Detection of overload Connection Same as () Input of the feed back signal. Operation If the output voltage of a power supply drops lower than the set value in an overload condition, FB pin voltage rises and scales out. This state is detected and judged as an overload condition. The threshold voltage to detect an overload is 3.5V (typ). Complement FA5571/71A/73/70/5671 operates intermittently in an overload condition and auto restart if the overload condition is removed. Refer to pages 20 for detail operation. FA5572/74 stops switching in an overload condition and goes into latch mode to maintain this condition. Refer to page 21 for detail operation. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 25 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (3) No.3 pin (IS pin) Function increases the more power consumption in waiting increases. ( ) Detection of MOSFET current ( ) Difficulty for a burst operation at light load (FA5571/71A/72/70/5671) () fsw reduction adjustment (FA5573/74) () Detection of transformer short circuit protection Usage () Current detection Connection Current Comparator Connect a current detecting resistor Rs between a source pin of MOSFET and GNC. Input The current signal that arises in the MOSFET is input to this resistor (Fig.18). Operation A MOSFET current signal that is input into IS pin is input into a current comparator. When it gets to the threshold voltage that is designated by FB pin, it turns off MOSFET. The maximum threshold voltage is 1V (typ.). MOSFET current is restricted by the current that corresponds to this voltage (1V) even in a transient condition at the startup or in an abnormal condition at overload 3 IS Rs Fig.18 IS pin circuit Current Comparator () Burst operation adjustment (for FA5571/71A/72/70/5671) Connection A resistor RIS is inserted additionally between the current detecting resistor Rs and IS pin (Fig. 19). Operation A 50A current supply is included in IS pin of FA5571/71A/ 72/70/5671, and electric current is sent out from IS pin. The voltage that is equal to the multiplication of the current value and the resistor value is effective to restrain burst operation. Compliment For example, when getting into burst operation in case of a heavy load, the output ripple becomes bigger. If this is a problem, this pin should be used. However the more difficult it becomes to get into burst operation, the more electric power consumption in waiting increases. Ris 3 IS Rs Fig.19 IS pin filter () fsw reduction adjustment Connection Same as ( ) Burst operation adjustment Operation FA5573/74 has 50A internal current source inside IS pin and electric current flows out from IS pin. With the effect of the voltage resulting from the multiplication of this current value and the resistor Ris value, the frequency at light load has difficulty to lower. Compliment For example, if switching frequency gets down to the audible frequency in waiting state and this is the problem, this method is used. However, the more the difficulty to lower frequency Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 26 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 And also attention should be paid in selecting a MOSFET to () Detection of transformer short circuit protection drive because there is limitation of the current to be Connection provided when it is driven only by the startup circuit. Same as ( ) Burst operation adjustment. Operation If IS pin voltage exceeds 2.0V (typ.) due to the transformer short circuit and so on, FA5571/71A/72/73/74 causes latch stop. 6 VCC Driver (4) No.4 pin (GND pin) OUT Function 5 This is the standard voltage for each IC. GND (5) No.5 pin (OUT pin) Function 4 Driving of MOSFET. Fig.20 OUT pin circuit (1) Usage Connection This pin is connected to MOSFET gate pin through a resistor (Fig.20, Fig.21, & Fig.22). Operation During the period MOSFET is ON, this pin is kept in high position and almost the same voltage as Vcc is output. During the period MOSFET is OFF, this pin is kept in low position and nearly zero voltage is output. 6 VCC Driver OUT 5 GND 4 Compliment A gate resistor is connected to restrict current of OUT pin Fig.21 OUT pin circuit (2) and to protect oscillation of gate pin voltage. Output current rating of IC is 0.25A for source and 0.5A for sink. 6 VCC (6) No.6 pin (VCC pin) Driver OUT Function 5 ( ) Provide power supply for IC () Detect over-voltage in primary side and activate latch protection. (FA5671) GND 4 Fig.22 OUT pin circuit (3) Usage ( ) Provide power supply for IC Connection 6 Generally the auxiliary coil voltage of a transformer is VCC rectified and smoothed and is connected to this pin. (Fig. 23) In addition the auxiliary coil that is connected to ZCD pin can also be used for this pin. ZCD Operation R ZCD 1 The voltage provided by the auxiliary coil should be set 11V C ZCD to 28V(11V to 26V : FA5671) in normal operation. It is possible to drive an IC with the current provided by the Fig.23 VCC circuit startup circuit without using an auxiliary coil, but standby power increases and heat dissipation of the IC also increases. Therefore it is better to provide Vcc from an auxiliary coil if lower standby power is required. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 27 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 and heat dissipation increases. Therefore it is better to () Protection of over voltage (FA5671) Connection Same as the connection described in () Provision of power supply for IC. provide Vcc by an auxiliary winding for low standby power dissipation requirement. In addition, much attention is required in selecting MOSFET to drive, because there is a limit to the current to be Operation If Vcc exceeds 28V (typ.) and maintains more than 57s (typ.), protection of over voltage is activated and IC is latched. provided when IC is driven only by a startup circuit. Compliment For example, if the output voltage rises abnormally due to the error of a feedback circuit, also Vcc rises abnormally. When Vcc exceeds 28V, latch protection is activated. Therefore that operates as over voltage protection of primary side detection. VH Startup circuit on/off 8 start 6 VCC Fig.24 VH pin circuit (1) (7) No.7 pin (N.C.) As this pin is next to a high voltage pin, this pin is not yet connected to IC inside. (8) No.8 pin (VH pin) Function VH 8 Startup circuit Provides startup current. on/off Usage VCC start 6 Connection This pin is connected to a high voltage line. If this is Fig.25 VH pin circuit (2) connected after the current is rectified, this should be connected through a resistor of several k (Fig.24). On the other hand, if connected before the current is rectified, this should be connected to a high voltage line through a resistor of several kand a diode (Fig.25, Fig.26). Operation If VH pin is connected to high voltage, current flows out VH from Vcc pin through the startup circuit in the IC. This Startup circuit current charges the capacitor between Vcc and GND, and on/off Vcc voltage rises. When Vcc exceeds 18V (typ), IC is 8 start 6 VCC activated and begins to operate. If Vcc is provided by an auxiliary winding, a startup circuit Fig.26 VH pin circuit (3) goes into shutdown state. On the other hand, if no power is supplied from the auxiliary winding, IC operates normally with a current provided by the startup circuit. Compliment If Vcc is provided not by an auxiliary winding but only by a startup circuit, standby power requirement becomes larger Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 28 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 11. Advice for designing (1) Compensation for overload current detection If the output of the power supply gets to the overload condition, the current to the MOSFET is limited by the maximum input threshold voltage of IS pin and the output voltage of the power supply drops down. If this condition continues, the current is shut down in the latch mode with overload protection function. (For the details of overload C1 protection function, refer "9-(4) operation at overload".) R1 At this time, the output current shut down in the latch mode IS varies according to the input voltage. In some case of Ris 3 shutdown in the latch mode, the higher the input voltage is, the bigger the output current becomes. Rs FA5571/72/ 73/74 If this behavior is a problem, a resistor Ris should be 4 connected between a current detection resistor Rs and IS GND pin and additionally a resistor R1 should be added for compensation. A resistor R1 is approximately several Fig.27 Compensation for overload protection 100k to several Meg depending on Ris. Be careful that even if the input voltage is low with compensation, the output current of a power supply that is shut down in the latch mode is reduced a little. C1 (2) Input power improvement at light load (FA5573/74) FA5573/74 has a function in it that reduces the power loss IS by reducing oscillating frequency at light load. Ris 3 But if reduction of the switching frequency is insufficient depending on a circuit being used, the power loss reduction FA5571/72/ 73/74 at light load may be insufficient. Rs R2 VCC 6 In such a case, a resistor R2 should be connected between 4 an auxiliary coil and IS pin as shown in Fig.28. If Ris is 1k, GND R2 is approximately several 100 k to 1Meg. If R2 value is made smaller, the switching frequency can be decreased more at light load. Fig.28 Compensation for input power improvement at light load But during the MOSFET is ON, the minus voltage may be impressed to IS pin by R2 for a length of time. This minus voltage should not be lower than the absolute maximum rating, -0.3V. In addition, if the switching frequency at light load is set too low, some noise in the transformer may be caused. Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 29 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (3) Noise malfunction protection This IC is an analog IC. Therefore if noise is impressed into each pin of this IC, malfunction may be caused. When any malfunction is detected, use the unit after checking fully of the power supply set by referring below. In addition, capacitors that are connected to each pin for noise protection should be connected nearest to the IC so as to operate effectively and also be careful about wiring layout. Vout (3-1) FB pin FA5571/72/ 5 73/74 FB pin provides the threshold voltage to a current comparator. If this pin is impressed noise, it causes OUT 2 disturbance of the output pulse. Usually a capacitor C2 is FB connected for noise protection as shown in Fig.29. Shunt Regulator C2 (3-2) IS pin Since this IC has blanking function, it hardly causes the malfunction due to the surge current generated at turn-on of Fig.29 Noise malfunction protection (FB pin) a MOSFET. But if the surge current generated at turn-on is big or the noise other than turn-on is impressed from outside, the malfunction may occur. C1 In such a case, a CR filter should be added to IS pin as shown in Fig. 30. Ris (3-3) VCC pin IS C3 3 Big current flows into VCC pin at the moment to drive a MOSFET and relatively big noise is easy to occur. Rs FA5571/72/ 73/74 The current provided from an auxiliary coil also generates the noise. 4 If this noise is big, it may cause malfunction of IC. A GND decoupling capacitor C4 (over 0.1uF) should be added between VCC and GND in addition to an electrolytic Fig.30 Noise malfunction protection (IS pin) condenser to reduce the noise generated in VCC pin as shown in Fig.31. C4 should be allocated nearest to VCC pin of the IC. 6 C4 VCC ZCD 1 Fig.31 Noise malfunction protection (VCC pin) Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 30 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (4) Malfunction protection due to the minus voltage on a pin If the minus high voltage is impressed to each pin of an IC, a parasitic element in the IC works and may cause malfunction. The voltage impressed to each pin should be not higher than -0.3V. FA5571/72/ 73/74 If the voltage oscillation generated after MOSFET turns off is impressed on to OUT pin through a parasitic capacitor of a MOSFET, minus voltage may be impressed on to OUT GND 4 OUT Rg 5 SBD pin. And also IS pin may be impressed minus voltage due to the current oscillation like surge generated at turn-off of a Fig.32 Minus voltage protection circuit MOSFET. In such a case a Schottky diode should be connected between each pin and GND. The forward voltage of a Schottky diode can prevent minus voltage of each pin. In this case a Schottky diode with the low forward voltage should be used. An example that a Schottky diode is connected to OUT pin is shown in Fig.32 (5) Loss calculation In order to use an IC within the rating, it is also necessary to calculate the loss of the IC. But it is difficult to measure the loss directly. Here an example of a rough calculation of the loss is shown. The total loss Pd of an IC is roughly calculated in the following equation. Pd Vcc x (Iccop1 + Qg x fsw) + VVH x IHrun Where, VVH is the voltage impressed to VH pin, IHrun is the current flowing into VH pin in operation, Vcc is the voltage of power supply, Iccop1 is current consumption of an IC, Qg is the gate input electric charge of a MOSFET and fsw is the switching frequency. The rough value of the total loss Pd is obtained by this equation and it is a little greater than the practical loss. In addition, it should be taken into account that each characteristic value has its variation and respective temperature characteristics. Example) If VH pin is connected to half-wave rectifier in case of AC 100V input, the average voltage impressed to VH pin is about 45V. In this condition we suppose Vcc=15V, Qg=80nC and fsw=60kHz at Tj=25. In case of FA5571, each value is as follows according to specific data. IHrun=30A (typ.), Iccop1=1.35mA (typ.) Then the typical loss of the IC is calculated as follows. Pd 15V x (1.35mA + 80nC x 60kHz) + 45V x 30A 93.6mW Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 31 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (6) Protection of over-voltage on the secondary side (FA5571/71A/72/73/74) This IC can protect over-voltage on the secondary side with ZCD pin. The secondary over-voltage protection is performed as follows. If the voltage of ZCD pin exceeds 7.2V (typ.) after 2.3S (typ.) (71A4.5us) of turn-off of a FET, latch shutdown is carried out. Rzcd that fixes the input threshold voltage of ZCD pin and Cd Czcd that adjusts the resonance bottom point of Vds are FA5571/72/ ZCD 73/74 1 connected to ZCD pin. If these values of Rzcd and Czcd are not adequate, RZCD over-voltage protection may not operate normally. The CZCD waveform of ZCD pin at over-voltage protection is shown in Fig.34. The waveform of ZCD pin in the upper part of Fig.34 shows Fig.33 ZCD pin connection circuit that the voltage is normally detected at over-voltage on the secondary side and latch shutdown is carried out with the 2.3uS protection operation, but the lower waveform shows that as it does not exceed the threshold voltage for latch shutdown 7.2V 2.3S later, the protection operation is not carried out. In such a case Rzcd and Czcd should be readjusted. 0V (7) Transformer short circuit protection with IS pin (FA5571/71A/72/73/74) 7.2V This IC has function in it that carries out latch shutdown instantly when the voltage higher than 2V is impressed to IS pin to protect a transformer short circuit. This is shown in 0V Fig.35. This function also carries out instantly latch shutdown Fig.34 ZCD pin waveform at over-voltage except a transformer short circuit when the voltage higher than 2V (typ.) is impressed to IS pin. Therefore if the high voltage is impressed to the input side such as lightning short C1 surge, the protection operation may carry out latch shutdown. Ris In such a case the values of IS pin filter Ris, C3 and a surge protection element for the input line should be readjusted. IS C3 3 Rs FA5571/72/ 73/74 4 GND Fig.35 Transformer short circuit protection Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 32 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 12. Precautions for use (1) Precautions for pattern design In order to prevent the malfunction of the control IC (unstable voltage, unstable waveform, latch stop, etc.) caused by the surge voltage (noise) when a current is applied to the pattern on the minus side because of a principal current, a lightning surge test, an AC input surge test, and a static electricity test, consider the following contents when designing the pattern. The power supply has the following current paths: 1) A principal current applied from the electrolytic capacitor to the primary winding of the transformer, the MOSFET, and the current sensing resistor after AC power supply rectification 2) A rectified current applied from the auxiliary winding of the transformer to the electrolytic capacitor; a drive current applied from the electrolytic capacitor to the control IC and the MOSFET gate. 3) A control current of the control IC for output feedback or the like 4) Filter and surge currents applied between the primary and secondary sides Separate the patterns on the minus side in 1) to 4) to avoid interference from each other. To reduce the surge voltage of the MOSFET, minimize the loop of the principal current path. Install the electrolytic and film capacitors between the VCC terminal and the GND in a closest position to each terminal in order to connect them at the shortest distance. Install the filter capacitors for the FB, IS, and ZCD terminals and the like in a closest position to each terminal in order to connect them at the shortest distance. Especially, separate the pattern on the minus side of the FB terminal from the other patterns if possible. Avoid installing the control circuit and pattern with high impedance directly below the transformer. Principal current 1 10,11,12 4 7,8,9 1 Output AC Input FB1 4 CN2 Drive current 6 8 VH 7 (NC) 6 VCC 5 OUT FA5571/72/ 73/74 ZCD 1 FB 2 IS 3 5 GND 4 Filter and surge current Control current Fig.36 Pattern design image Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 33 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (2) Latch stop in a surge test The latch stop function of the IC has the following four modes: 1) Short-circuit protection function of the transformer Latch stop immediately occurs if the IS terminal becomes 2.0 V or more because of short circuit of the transformer or the like. 2) Overvoltage protection function (FA5571/71A/72/73/74) Latch stop is immediately caused if overvoltage occurs at the output on the secondary side and the ZCD terminal is 7.2 V or more when 2.3 us(71A4.5us) passes after it is turned off because of the increased auxiliary winding voltage. 3) Latch function by an external signal Latch stop occurs if the ZCD terminal is 7.2 V or more for 57 s or more by an external signal or the like. 4) Overload protection function Latch stop occurs if the FB terminal voltage is 3.5 V or more for 190 ms during overload. (FA5571/71A/73/70/5671: auto restart, FA5572/74: latch) Especially the latch stop functions in 1) and 2) above added for the FA5571 series may cause latch stop in noise tests such as a surge test. Any of the following adjustments can be performed as a measure in some cases: (2-1) If the overvoltage protection function is estimated to have caused the latch stop The latch by surge may be prevented if a capacitor CZCD with as much capacity as possible is attached to the ZCD terminal. Since the timing of the bottom detection when it is turned on is changed if the capacity of the capacitor CZCD is increased, reduce the resistance RZCD to adjust the time constant. However, the overvoltage detection level is increased because of the reduced RZCD. As shown in fig. 37, add and connect resistor R1 in parallel with the IC built-in resistor to adjust the overvoltage detection level. Since there is a possibility that this affects the standby electricity, check if it does. (2-2) If the short-circuit protection function of the transformer is estimated to have caused the latch stop The latch by surge may be prevented if increasing filter capacitor Cis of the IS terminal as much as possible. However, reduce the resistance Ris to adjust the time constant of the filter. When the resistance Ris cannot be much increased because of the increased capacitor Cis, if it is intended to prevent the burst mode from being easily entered in particular, the adjustment cannot be performed. In that case, as shown in fig. 38, add resistor R2 between the IS and VCC terminals to increase the IS terminal voltage in order to prevent the burst mode from being easily entered. VCC ZCD 6 RZCD 1 30k R1 FA5571/72/ 73/74 CZCD R2 Ris 3 IS Cis Rs 4 GND Fig. 37 Cause: overvoltage protection function Fig. 38 Cause: short-circuit protection function of the transformer Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 34 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 (3) Abnormal sound of the transformer 1) Abnormal sound made by bottom skip operation In the case of pseudo resonance, the lower the output load is, the higher the frequency is. Since the maximum blanking frequency of this IC is 120 kHz(71A/5671170kHz), if the frequency reaches 120 kHz, bottom skip operation is performed instead of continuous operation, limiting the frequency. In the beginning after the frequency reaches 120 kHz, the bottom skip operation and the continuous operation are combined. The combined operation includes audio frequency and the transformer may make an abnormal sound. In that case, when designing the transformer, reduce the minimum frequency at the maximum load as much as possible so that the bottom skip mode is entered at the lowest possible load. 2) Abnormal sound made by burst operation (FA5571/71A/72/70/5671) Moving the burst point When burst operation starts at light load, if the frequency is in the audio range, the transformer may make an abnormal sound. In this case, because increasing the resistance Ris in fig. 39 prevents the burst operation from being easily performed, the burst operation point can be moved to the light load side (see (ii) Burst operation adjustment on p. 25). However, if increasing the resistance Ris, reduce Cis to prevent the CR time constant of the filter from being changed. Otherwise the burst operation may not be much changed. Changing the burst frequency If the burst frequency is in the audio range, an abnormal sound may be made. In this case, change the resistance R3 to change the photocoupler current in fig. 40 so that the burst frequency is changed. However, when increasing the resistance and reducing the frequency, if increasing the resistance too much, the shunt REG cannot operate properly and the transient response performance of the output is deteriorated. Therefore, determine the operation after sufficient evaluation. 3) Abnormal sound made by decreased frequency (FA5573/FA5574) If the frequency is reduced by the frequency reduction function at light load and the frequency is in the audio range, the transformer may make an abnormal sound. In this case, change the frequency using the same method in 2) Abnormal sound made by burst operation (FA5571/71A/72/ 70/5671) for moving the burst point in order to identify the frequency for a smaller abnormal noise. Larger resistance Ris prevents the frequency from being easily reduced and smaller resistance Ris makes it easier to reduce the frequency. R3 Ris FA5571/72/ 5 73/74 IS 3 Cis Rs Vout OUT 2 FA5571/72/ 73/74 FB Shunt Regulator 4 GND Fig. 39 Moving the burst point Fig. 40 Changing the burst frequency Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 35 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/ FA557171A72737455705671 13. Application circuit examples These application examples show common specification for FA5571/71A/72/73/74/70/5671. (1) Application circuit 1 R19 22 C15 470pF DS3 YG865C15R 150V/20A F1 NF1 8mH 1 AC85 to 264V R1 1M R2 1M 3 C2 2200pF DS1 D10XB60H C4 0.22uF L1 2.2uH 1 R3 100k C6 470uF C1 0.47uF C7 0.01uF P2 T1 Np:Ns:Nb=35:8:8 Lp=340uH FB1 CN1 P1 R12 4.7k D2 200V/1A 8 VH IC1 7 (NC) 6 VCC FB4 FB 2 IS 3 R4 10k R13 4.7 C19 0.1uF P4 HS2 R5 0.22 R20 2.2k 3 R22 13k C21 2200pF R23 10k 5 OUT C13 100uF CN2 PC1A R21 2.2k D4 400V/1A 6 FA5571/72/ 73/74 ZCD 1 R14 100k R10 22 C18 470uF 7,8,9 C8 470pF R7 47 C17 2200uF C16 2200uF C23 0.1uF R6 22 R11 4.7k 19V / 5A 2 4 4 TR1 2SK3677-01MR 700V/12A HS1 1 DS2 YG865C15R 150V/20A D1 1kV/0.5A C3 2200pF 5 P3 10,11,12 C22 0.1uF IC2 TA76431F 5 R24 1.8k GND 4 C9 2200pF RV1 C12 22pF C10 1000pF PC1B C11 0.022uF (2) Application circuit 2 (To speed up latch reset after AC shutdown, VH pin (No.8) for start-up is connected to AC side.) R19 22 C15 470pF DS3 YG865C15R 150V/20A F1 NF1 8mH 1 AC85 to 264V R1 1M 3 R2 1M C2 2200pF DS1 D10XB60H C4 0.22uF L1 2.2uH 1 R3 100k C6 470uF C1 0.47uF CN1 T1 Np:Ns:Nb=35:8:8 Lp=340uH P1 D3 600V/1A R7 47 R12 4.7k D2 200V/1A 8 VH IC1 7 (NC) FB 2 IS 3 R4 10k R13 4.7 C19 0.1uF P4 HS2 R5 0.22 R20 2.2k R21 2.2k D4 400V/1A 3 R22 13k PC1A R23 10k 5 OUT C13 100uF CN2 C21 2200pF 6 FA5571/72/ 73/74 ZCD 1 R14 100k 6 VCC FB4 C18 470uF 7,8,9 C8 470pF R10 22 C17 2200uF C16 2200uF C23 0.1uF R6 22 R11 4.7k 19V / 5A 2 4 4 TR1 2SK3677-01MR 700V/12A HS1 1 DS2 YG865C15R 150V/20A FB1 C3 2200pF 5 C7 0.01uF D1 1kV/0.5A P2 P3 10,11,12 IC2 TA76431F 5 GND 4 C9 2200pF C22 0.1uF R24 1.8k RV1 C12 22pF C10 1000pF PC1B C11 0.022uF Fuji Electric Co., Ltd. AN-022E Rev.1.5 April 2011 36 http://store.iiic.cc/ http://www.fujielectric.co.jp/products/semiconductor/