FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Features Description Linearly Decreasing PWM Frequency Green Mode Under Light-load and Zero-Load This highly integrated PWM controller provides several features to enhance the performance of low-power flyback converters. To minimize standby power consumption, a proprietary green-mode function provides off-time modulation to linearly decrease the switching frequency under light-load and zero-load conditions. This green mode enables the power supply to meet international power conservation requirements. The supply voltage VDD is also used for feedback compensation, to regulate the output voltage without requiring a conventional TL431 and a photo-coupler. A typical output CV/CC characteristic is shown in Figure 1. Conditions Constant Voltage (CV) and Constant Current (CC) around ±25% without Secondary Side Feedback Circuitry Precise Constant Voltage (CV) at ±5% by Secondary Side Feedback Circuitry Low Startup Current: 8μA Low Operating Current: 3.6mA Leading-Edge Blanking (LEB) Constant Power Limit Universal AC Input Range Synchronized Slope Compensation 140°C OTP Sensor with Hysteresis VDD Over-Voltage Clamping Cycle-by-Cycle Current Limiting Under-Voltage Lockout (UVLO) Fixed PWM Frequency with Hopping Gate Output Maximum Voltage Clamped at 17V Another advantage of the FSEZ2016 is that the typical startup current is only 8μA, while the typical operating current can be as low as 3.6mA. A large startup resistance can be used to achieve even higher power conversion efficiency. FSEZ2016 integrates frequency hopping function internally to reduce EMI emissions with minimum line filters. Also, built-in synchronized slope compensation maintains the stability of peak current-mode control. Proprietary internal compensation ensures constant output power limiting over a universal range of AC input voltages, from 90VAC to 264VAC. The FSEZ2016 provides many protection functions. Pulse-by-pulse current limiting ensures constant output current, even if a short circuit occurs. The internal protection circuit disables PWM output if VDD exceeds 22.7V. The gate output is clamped at 17V to protect the power MOS from over-voltage damage. The built-in over-temperature protection (OTP) function shuts down the controller at 140°C with a 30°C hysteresis. Applications General-purpose switching-mode power supplies and flyback power converters, such as: Battery Chargers for Cellular Phones, Cordless Phones, PDAs, Digital Cameras, Power Tools Power Adapters for Ink Jet Printers, Video Game Consoles, Portable Audio Players Maximum With Secondary Feedback Vo Open-Frame SMPS for TV/DVD Standby and 8 Auxiliary Supplies, Home Appliances, Consumer Electronics Minimum Without Secondary Feedback 7 6 Replacement for Linear Transformers and RCC SMPS PC 5V Standby Power 5 4 3 2 1 Related Resources AN-6081 — Low-Power Green-Mode EZSWITCH without Secondary Feedback © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 Io 0 0 TM 0.2 0.4 Figure 1. 0.6 0.8 1 1.2 1.4 1.6 1.8 2 Typical Output V-I Characteristic www.fairchildsemi.com FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry April 2009 Part Number FSEZ2016NY Operating Temperature Range Package Packing Method 7-Lead, Dual Outline Package (DIP-7) Tube Eco Status Green -40°C to +105°C For Fairchild’s definition of Eco Status, please visit: http://www.fairchildsemi.com/company/green/rohs_green.html. Application Diagram Figure 2. Typical Application Internal Block Diagram Figure 3. © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Ordering Information Functional Block Diagram www.fairchildsemi.com 2 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Marking Information 1’st line Z: Assembly plant code X: Year code Y: Week code TT: Die run code 3’rd line T: Package type (N=DIP) P: Y=Green package M: Manufacture flow code Figure 4. Top Mark Pin Configuration Figure 5. Pin Assignments Pin Definitions Pin # Name 1 SOURCE 2 GND 3 VDD Description Power MOSFET source. This is the high-voltage power MOSFET source. Ground Power supply 4 FB The FB pin provides feedback information to the internal PWM comparator. This feedback is used to control the duty cycle. When no feedback is provided, this pin is left open. 5 NC No connection 6 NC 8 DRAIN © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 No connection Power MOSFET drain. This is the high-voltage power MOSFET drain. www.fairchildsemi.com 3 Stresses exceeding the absolute maximum ratings may damage the device. The device may not function or be operable above the recommended operating conditions and stressing the parts to these levels is not recommended. In addition, extended exposure to stresses above the recommended operating conditions may affect device reliability. The absolute maximum ratings are stress ratings only. Symbol VDD VFB VSENSE PD θJA TJ TSTG TL ESD Parameter DC Supply Voltage Min. (1, 2) Max. Unit 30 V Input Voltage to FB Pin -0.3 7.0 V Input Voltage to Sense Pin -0.3 7.0 V Power Dissipation (TA=25°C) 1.2 W Thermal Resistance (Junction to Air) 98.7 °C/W Operating Junction Temperature -40 150 °C Storage Temperature Range -55 150 °C 260 °C Human Body Model (JEDEC:JESD22_A114) 2 KV Charged Device Model (JEDEC:JESD22_C101) 1 KV Lead Temperature (Wave Soldering or IR, 10 Seconds) Electrostatic Discharge Capability Notes: 1. All voltage values, except differential voltages, are given with respect to GND pin. 2. Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Absolute Maximum Ratings www.fairchildsemi.com 4 Unless otherwise noted, VDD=15V and TA=25°C. Symbol Parameter Conditions Min. Typ. Max. Units VDD Section VDD-OP Continuously Operation Voltage VDD-ON Turn-on Threshold Voltage VDD-OFF Turn-off Threshold Voltage With Secondary Feedback 20.0 Without Secondary Feedback 22.7 IDD-ST Startup Current VDD=VDD-ON – 0.1V IDD-OP Operating Supply Current CL=1nF VDD-G-OFF V 16 17 18 7.5 8.0 8.5 V 8 20 μA 3.6 4.6 mA VDD Low-threshold Voltage to Exit Green-off Mode V VDD-OFF +1.3 V 0.35 V/V 4.6 kΩ Feedback Input Section AV Input-Voltage to Current-Sense Attenuation ZFB Input Impedance VFB-OPEN VDD-FB IFB=0.1mA to 0.2mA Open-Loop Voltage 4.5 VDD Feedback Threshold Voltage V FB is Open 20.7 22.7 24.7 V IFB=0.4mA 18.4 20.4 22.4 V 100 150 ns Current-Sense Section tPD VSTHVA VSTHFL tLEB Propagation Delay Current Limit Valley Threshold Voltage Current Limit Flat Threshold Voltage VDD=18V 0.83 V VDD=15V 0.74 V VDD=10V 0.59 V VDD=18V 1.15 V VDD=15V 1.04 V VDD=10V 0.84 V Leading-Edge Blanking Time 220 Figure 6. © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 310 400 ns FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Electrical Characteristics Saw Limit www.fairchildsemi.com 5 Unless otherwise noted, VDD=15V and TA=25°C. Symbol Parameter Conditions Min. Typ. Max. Units Oscillator Section fOSC Frequency tHOP Hopping Period Center Frequency Hopping Range 60 65 70 ±4.1 ±4.7 ±5.3 4 fOSC-G Green Mode Frequency 14.5 VFB-N Green Mode Entry FB Voltage 2.3 VFB-G VFB-Z ms 17.0 19.5 KHz 2.6 2.9 V VFB-N 0.75 Green Mode Ending FB Voltage Zero Duty Cycle FB Voltage V 1.4 SG Green Mode Modulation Slope 40 fDV Frequency Variation vs. VDD Deviation VDD=10 to 22V fDT Frequency Variation vs. Temperature Deviation TA= -20 to 85°C kHz 70 V 100 Hz/mV 5 % 1.5 5.0 % 74 79 % Internal MOSFET Section DCYMAX Maximum Duty Cycle 69 BVDSS Drain-Source Breakdown Voltage ID=250μA, VGS=0V ΔBVDSS/ΔTJ Breakdown Voltage Temperature Coefficient ID=250μA, Referenced to 25°C 600 V 0.6 V/°C IS Maximum Continuous Drain-Source Diode Forward Current 1 A ISM Maximum Pulsed Drain-Source Diode Forward Current 4 A 11.5 Ω VDS=600V, VGS=0V, TC=25°C 5 μA VDS=480V, VGS=0V, TC=100°C 10 μA 7 24 ns Rise Time 21 52 ns Turn-off Delay Time 13 36 ns 27 64 ns 130 170 pF 19 25 pF RDS(ON) IDSS tD-ON tr tD-OFF tf Static Drain-Source On-Resistance Drain-Source Leakage Current Turn-on Delay Time ID=0.5A, VGS=10V VDS=300V, ID=1.1A, RG=25Ω Fall Time CISS Input Capacitance COSS Output Capacitance VGS=0V, VDS=25V, fS=1MHz 9.3 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Electrical Characteristics (Continued) Over Temperature Protection (OTP) TOTP Protection Junction Temperature TOTP-RESTART Restart Junction Temperature © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 140 °C 110 °C www.fairchildsemi.com 6 8.4 16.8 8.2 V DD-OFF (V) V DD-ON (V) 17 16.6 16.4 16.2 8 7.8 7.6 16 7.4 -40 -25 -10 5 20 35 50 65 80 95 110 125 -40 -25 -10 5 T emperature (℃ ) Turn-on Threshold Voltage (VDD-ON) vs. Temperature Figure 8. 14 3 12 2.8 IDD-OP (mA) IDD-ST (μA) Figure 7. 10 8 6 35 50 65 80 95 110 125 Turn-off Threshold Voltage (VDD-OFF) vs. Temperature 2.6 2.4 2.2 4 2 -40 -25 -10 5 20 35 50 65 80 95 110 125 -40 -25 -10 5 T emperature (℃ ) Figure 9. 20 35 50 65 80 95 110 125 T emperature (℃ ) Startup Current (IDD-ST) vs. Temperature Figure 10. Operating Supply Current (IDD-OP) vs. Temperature 66 77 65 76 64 75 DCY MAX (%) fOSC (KHz) 20 T emperature (℃ ) 63 62 61 74 73 72 60 71 -40 -25 -10 5 20 35 50 65 80 95 110 125 -40 T emperature (℃ ) -10 5 20 35 50 65 80 95 110 125 T emperature (℃ ) Figure 11. Center Frequency (fOSC) vs. Temperature © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 -25 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Typical Performance Characteristics Figure 12. Maximum Duty Cycle (DCYMAX) vs. Temperature www.fairchildsemi.com 7 2.2 2.8 2 V FB-G (V) V FB-N (V) 3 2.6 2.4 2.2 1.8 1.6 1.4 2 1.2 -40 -25 -10 5 20 35 50 65 80 95 110 125 -40 -25 -10 5 T emperature (℃ ) Figure 13. Green-Mode Entry FB Voltage (VFB-N) vs. Temperature 35 50 65 80 95 110 125 Figure 14. Green-Mode Ending FB Voltage (VFB-G) vs. Temperature 380 800 750 BV DSS (V) 360 tLEB (ns) 20 T emperature (℃ ) 340 320 300 700 650 600 550 280 500 -40 -25 -10 5 20 35 50 65 80 95 110 125 -40 T emperature (℃ ) -10 5 20 35 50 65 80 95 110 125 T emperature (℃ ) Figure 15. Leading-Edge Blanking Time (tLEB) vs. Temperature © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 -25 Figure 16. Drain-Source Breakdown Voltage (BVDSS) vs. Temperature FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Typical Performance Characteristics (Continued) www.fairchildsemi.com 8 FSEZ2016 devices integrate functions for low-power switch-mode power supplies. The following descriptions highlight the key features of the FSEZ2016. Oscillator Operation Startup Current Leading-Edge Blanking (LEB) The required startup current is only 8μA. This allows a high-resistance, low-wattage startup resistor to supply the controller’s startup power. A 1.5MΩ/0.25W startup resistor can be used over a wide input range (100V240VAC) with very little power loss. Each time the power MOSFET is switched on, a turn-on spike occurs at the sense-resistor. To avoid premature termination of the switching pulse, a 310ns leadingedge blanking time is built in. Conventional RC filtering is not necessary. During this blanking period, the current-limit comparator is disabled and cannot switch off the gate drive. The oscillation frequency is fixed at 65KHz. Operating Current The operating current is normally 3.6mA, which results in higher efficiency and reduces the required VDD holdup capacitance. A 10μF/25V VDD hold-up capacitor can be used over a wide input range (90V-264VAC) with very little power loss. Constant Output Power Limit When the SENSE voltage across the sense resistor RS reaches the threshold voltage, the output GATE drive is turned off following a small propagation delay, tPD. This propagation delay introduces an additional current proportional to tPD•VIN/LP. The propagation delay is nearly constant, regardless of the input line voltage VIN. Higher input line voltages result in larger additional currents. Under high input-line voltages, the output power limit is higher than under low input-line voltages. Over a wide range of AC input voltages, the variation can be significant. To compensate for this, the threshold voltage is adjusted by adding a positive ramp (Vlimit_ramp). This ramp signal can vary from 0.74V to 1.04V and flattens out at 1.04V. A smaller threshold voltage forces the output GATE drive to terminate earlier, reducing total PWM turn-on time and making the output power equal to that of the low line input. This proprietary internal compensation feature ensures a constant output power limit over a wide range of AC input voltages (90V-264VAC). Green-Mode Operation The proprietary green-mode function provides off-time modulation to linearly decrease the switching frequency under light-load and zero-load conditions. The on-time is limited to provide better protection against brownouts and other abnormal conditions. Power supplies using the FSEZ2016 can meet international restrictions regarding standby power-consumption. Constant Voltage (CV) and Constant Current (CC) without Feedback The FSEZ2016 can tightly regulate the output voltage and provide over-current protection without requiring secondary-side feedback signals. For improved CV and CC accuracy, the transformer leakage inductance should be reduced as much as possible. Under Voltage Lockout (UVLO) The turn-on/turn-off thresholds are fixed internally at 17V and 8V. To enable the FSEZ2016 during startup, the hold-up capacitor must first be charged to 17V through the startup resistor. The hold-up capacitor continues to supply VDD before energy can be delivered from the auxiliary winding of the main transformer. VDD must not drop below 8V during this startup process. This UVLO hysteresis window ensures that the hold-up capacitor can adequately supply VDD during startup. Over-Temperature Protection (OTP) The FSEZ2016 has a built-in temperature-sensing circuit to shut down PWM output if the junction temperature exceeds 140°C. While PWM output is shut down, the VDD voltage gradually drops to the UVLO voltage. Some of the internal circuits are shut down, and VDD gradually starts increasing again. When VDD reaches 17V, all the internal circuits, including the temperature-sensing circuit, operate normally. If the junction temperature is still higher than 140°C, the PWM controller shuts down immediately. This situation continues until the temperature drops below 110°C. The PWM output is then turned back on. The temperature hysteresis window for the OTP circuit is 30°C. Gate Output FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Operation Description The BiCMOS output stage is a fast totem-pole gate driver. Cross-conduction is avoided to minimize heat dissipation, increase efficiency, and enhance reliability. The output driver is clamped by an internal 17V Zener diode to protect the power MOSFET transistors against any harmful over-voltage gate signals. VDD Over-Voltage Clamping VDD over-voltage clamping is built in to prevent damage from over-voltage conditions. When VDD exceeds 22.7V, PWM output is shut down. Over-voltage conditions may be caused by an open photo-coupler loop or a short circuit in the output. © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 www.fairchildsemi.com 9 Slope Compensation Noise Immunity The sensed voltage across the current sense resistor is used for current mode control and pulse-by-pulse current limiting. The built-in slope compensation improves power supply stability. Furthermore, it prevents sub-harmonic oscillations that normally would occur because of peak current mode control. A positively sloped, synchronized ramp is activated with every switching cycle. The slope of the ramp is: 0.33 × Duty (1) Duty(max.) Noise from the current sense or the control signal may cause significant pulse-width jitter, particularly in continuous-conduction mode. Slope compensation helps alleviate this problem. Good placement and layout practices should be followed. The designer should avoid long PCB traces and component leads. Compensation and filter components should be located near the FSEZ2016. Finally, increasing the power-MOS gate resistance is advised. © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Operation Description (Continued) www.fairchildsemi.com 10 Figure 17. Reference Circuit (without Secondary-Side Feedback) BOM Reference Component Reference Component C1 CC 4.7nF/1kV F1 R 1Ω/1W C2 EC 4.7μF/400V 105°C L2 Inductor 4.7μH C3 EC 4.7μF/400V 105°C L3 Inductor 470μH C4 EC 10μF/50V 105°C L4 Inductor 80μH C5 CC 1nF/1kV R1 R 750kΩ C6 EC 560μF/10V R2 R 750kΩ C7 EC 560μF/10V R3 R 100kΩ C9 Open R4 R 10Ω C10 CC 1nF R5 R 2.2Ω D1 Diode 1N4007 R6 R 47Ω D2 Diode 1N4007 R7 R 270Ω D3 Diode 1N4007 R8 R 0Ω D4 Diode 1N4007 R9 R 2kΩ D5 Diode FR107 T1 Transformer EE-16 D6 Diode FR102 U1 IC FSEZ2016 D7 Diode SB560 © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Applications Information www.fairchildsemi.com 11 Figure 18. Reference Circuit (with Secondary-Side Feedback) BOM Reference Component Reference Component C1 CC 4.7nF/1kV L3 Inductor 470μH C2 EC 4.7μF/400V 105°C L4 Inductor 80μH C3 EC 4.7μF/400V 105°C R1 R 750kΩ C4 EC 10μF/50V 105°C R2 R 750kΩ C5 CC 1nF/1kV R3 R 100kΩ C6 EC 560μF/10V R4 R 10Ω C7 EC 560μF/10V R5 R 2.2Ω C8 CC 2.2nF R6 R 47Ω C9 Open R7 R 270Ω C10 CC 1nF R8 R 0Ω D1 Diode 1N4007 R9 R 2kΩ D2 Diode 1N4007 R10 R 560Ω D3 Diode 1N4007 R11 R 20kΩ D4 Diode 1N4007 R12 R 20kΩ D5 Diode FR107 R13 R 20kΩ D6 Diode FR102 T1 Transformer EE-16 D7 Diode SB560 U1 IC FSEZ2016 F1 R 1Ω/1W U2 IC PC817 L2 Inductor 4.7μH U3 IC TL431 © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Applications Information (Continued) www.fairchildsemi.com 12 7 10.16 9.47 5 PIN 1 INDICATOR 6.47 6.22 4 1 (0.675) 3.556 3.048 2.794 2.286 4.318 3.680 8.128 7.620 0.35 0.20 0.508 MIN 1.78 1.14 D 3.81 2.92 (7.632) 9.271 7.870 0.508 0.356 NOTES: A) THIS PACKAGE CONFORMS TO JEDEC MS-001 VARIATION AA EXCEPT LEAD COUNT. B) ALL DIMENSIONS ARE IN MILLIMETERS. C) DIMENSIONS ARE EXCLUSIVE OF BURRS, MOLD FLASH, AND TIE BAR EXTRUSIONS. D) DIMENSION WITH TERMINALS CONSTRAINED PERPENDICULAR TO PRINTED CIRCUIT BOARD. E) DRAWING FILE NAME: MKT-N07CREV1 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry Physical Dimensions Figure 19. 7-Pin DIP-7 Package Package drawings are provided as a service to customers considering Fairchild components. Drawings may change in any manner without notice. Please note the revision and/or date on the drawing and contact a Fairchild Semiconductor representative to verify or obtain the most recent revision. Package specifications do not expand the terms of Fairchild’s worldwide terms and conditions, specifically the warranty therein, which covers Fairchild products. Always visit Fairchild Semiconductor’s online packaging area for the most recent package drawings: http://www.fairchildsemi.com/packaging/. © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 www.fairchildsemi.com 13 FSEZ2016 — Low-Power Green-Mode EZSWITCHTM without Secondary Side Feedback Circuitry © 2008 Fairchild Semiconductor Corporation FSEZ2016 Rev. 1.0.0 www.fairchildsemi.com 14