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FAN6605 mWSaver™ PWM Controller Features Description ™ mWSaver Technology Provides Industry’s Best-inClass Standby Power - <100 mW at 25-mW Load for LCDM Adaptor - Internal High-Voltage JFET Startup - Low Operating Current: Under 2 mA - Adaptively Decrease PWM Frequency with Cycle Skipping to 23 kHz at Light-Load Condition for Better Efficiency - Feedback Impedance Switching During Minimum Load or No Load Proprietary Asynchronous Frequency Hopping Technique that Reduces EMI Fixed PWM Frequency: 65 kHz Soft Gate Drive with Clamped Output Voltage: 18 V Internal Leading-Edge Blanking Built-in Synchronized Slope Compensation Auto-Restart Protection: Feedback Open-Loop Protection (OLP), VDD Over-Voltage Protection (OVP), Over-Temperature Protection (OTP), and Line Over-Voltage Protection VDD Under-Voltage Lockout (UVLO) Programmable Constant Power Limit (Full AC Input Range) Internal OTP Sensor with Hysteresis Build-in 5-ms Soft-Start Function Input Voltage Sensing (VIN Pin) for Brown-In/Out Protection with Hysteresis and Line Over-Voltage Protection This highly integrated PWM controller provides several features to enhance the performance of flyback converters. To minimize standby power consumption, a proprietary adaptive green-mode function reduces switching frequency at light-load condition. To avoid acousticnoise problems, the minimum PWM frequency is set above 23 kHz. This green-mode function enables the power supply to meet international power conservation ® requirements, such as Energy Star . With the internal high-voltage startup circuitry, the power loss caused by bleeding resistors is also eliminated. To further reduce power consumption, FAN6605 uses the BiCMOS process, which allows an operating current of only 2 mA. The standby power consumption can be under 100 mW for most of LCD monitor power supply designs. FAN6605 — mWSaver™ Controller January 2015 FAN6605 integrates a frequency-hopping function that reduces EMI emission of a power supply with minimum line filters. The built-in synchronized slope compensation achieves a stable peak-current-mode control and improves noise immunity. The proprietary line compensation ensures constant output power limit over a wide AC input voltage range from 90 VAC to 264 VAC. FAN6605 provides many protection functions. The internal feedback open-loop protection circuit protects the power supply from open-feedback-loop condition or output-short condition. It also has line under-voltage protection (brownout protection) and over-voltage protection using an input voltage sensing pin (VIN). FAN6605 is available in a 7-pin SOP package. Applications General-purpose switched-mode power supplies and flyback power converters, including: LCD Monitor Power Supply Open-Frame SMPS ENERGY STAR® is a registered trademark of the U.S. Department of Energy and the U.S. Environmental Protection Agency. © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com Part Number Operating Temperature Range FAN6605MX -40 to +105°C Package 7-Lead, Small Outline Integrated Circuit (SOIC), Depopulated JEDEC MS-112, .150 Inch Body PWM Frequency Packing Method 65 kHz Reel & Tape Application Diagram N EMI Filter Vo+ + + FAN6605— mWSaver™ Controller Ordering Information L Vo- 1 7 HV VIN VDD 6 + GATE 5 2 FB SENSE 3 4 FAN6605 Figure 1. © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 Typical Application www.fairchildsemi.com 2 HV 7 Re-start Protection Brownout Protection OTP OVP OLP VIN-OVP VDD Soft Driver VPWM Cycle Skipping VDD 6 S VDD-ON /VDD-OFF Pattern Generator Soft-Start … Current Limit Comparator VLimit Green Mode PWM Comparator Max. Duty VIN-ON / VIN-OFF Brownout Protection High/Low Line Compensation VLimit OLP Debounce Circuit Blanking OVP VDD-OVP 1 SENSE Soft-Start Comparator VRESET VIN 3 Q VRESET OSC Debounce GATE R Internal BIAS UVLO 5 FAN6605— mWSaver™ Controller Internal Block Diagram 5.3V VPWM Slope Compensation 3R 2 FB R OLP Delay VIN-OVP OLP Comparator VIN-Protect VFB-OLP 4 GND Figure 2. Internal Block Diagram Marking Information 7 Z: Plant Code X: 1-Digit Year Code Y: 1-Digit Week Code TT: 2-Digit Die Run Code T: Package Type (M: SOP) M: Manufacture Flow Code ZXYTT 6605 TM Figure 3. Top Mark © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com 3 FAN6605— mWSaver™ Controller Pin Configuration SOP-7 VIN 1 FB 2 SENSE GND Figure 4. 7 HV 3 6 VDD 4 5 GATE Pin Configuration (Top View) Pin Definitions Pin # Name Description 1 VIN Line-voltage detection. The line-voltage detection is used for brownout protection with hysteresis. Constant output power limit over universal AC input range is also achieved using this VIN pin. It is suggested to add a low-pass filter to filter out line ripple on the bulk capacitor. Pulling VIN HIGH also triggers auto-restart protection. 2 FB The signal from the external compensation circuit is fed into this pin. The PWM duty cycle is determined in response to the signal on this pin and the current-sense signal on the SENSE pin. 3 SENSE Current sense. The sensed voltage is used for peak-current-mode control and cycle-by-cycle current limiting. 4 GND Ground 5 GATE The totem-pole output driver. Soft-driving waveform is implemented for improved EMI. 6 VDD 7 HV Power supply. The internal protection circuit disables PWM output as long as V DD exceeds the OVP trigger point. For startup, this pin is connected to the line input or bulk capacitor in series with resistors. © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com 4 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 Parameter Min. Max. Unit (1, 2) VVDD DC Supply Voltage 30 V VFB FB Pin Input Voltage -0.3 6.0 V SENSE Pin Input Voltage -0.3 6.0 V VVIN VIN Pin Input Voltage -0.3 6.0 V VHV HV Pin Input Voltage 700 V PD Power Dissipation (TA<50°C) 400 mW JA Thermal Resistance (Junction-to-Air) 153 C/W TJ Operating Junction Temperature -40 +125 C Storage Temperature Range -55 +150 C +260 C VSENSE TSTG TL ESD Lead Temperature (Wave Soldering or IR, 10 Seconds) Human Body Model, JEDEC: JESD22-A114 All Pins Except HV Pin Charged Device Model, JEDEC: JESD22-C101 All Pins Except HV Pin FAN6605— mWSaver™ Controller Absolute Maximum Ratings 5.5 kV 2.0 Notes: 1. All voltage values, except differential voltages, are given with respect to the network ground terminal. 2. Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. 3. ESD with HV pin: CDM=2000 V and HBM=3500 V. © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com 5 VDD=11~24 V and TA=-40~105C unless otherwise noted. Symbol Parameter Conditions Min. Typ. Max. Unit 22 V VDD Section VOP Continuously Operating Voltage Full Load VDD-ON Start Threshold Voltage 15 16 17 V VDD-OFF Protection Mode 9 10 11 V UVLO Normal Mode 6.8 7.8 8.8 V IDD-ST Startup Current VDD-ON – 0.16 V 30 µA VDD=15 V, GATE Open IDD-OP Operating Supply Current IDD-OLP Internal Sink Current 2 mA 30 60 90 µA VDD-OLP Threshold Voltage on VDD for HV JFET Turn-On 6.5 7.5 8.0 V VDD-OVP VDD Over-Voltage Protection 25 26 27 V tD-VDDOVP VDD Over-Voltage Protection Debounce Time 75 125 200 µs 2.0 3.5 5.0 mA 1 20 µA VDD-OLP+0.1 V FAN6605— mWSaver™ Controller Electrical Characteristics HV Section IHV IHV-LC Supply Current Drawn from HV Pin VDC=120 V, VDD=10 µF, VDD=0 V Leakage Current after Startup HV=700 V, VDD=VDDOFF+1 V VDD VDD VDD-ON VDD-ON VDD-OFF UVLO VDD-OLP t t Normal Mode Protection Mode Figure 5. VDD Behavior Continued on the following page… © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com 6 VDD=11~24 V and TA=-40~105C unless otherwise noted. Symbol Parameter Conditions Min. Typ. Max. Unit 62 65 68 ±4.5 ±5.2 ±5.9 Green-Mode Frequency 20 23 26 kHz Hopping Period 10 12 14 ms 200 220 ms Oscillator Section Center Frequency fOSC Frequency in Normal Mode kHz Hopping Range fOSC-G tHOP tSKIP-N tSKIP-G Pulse-Skipping Period (4) VFB-SKIP<VFB<VFB-N 180 Pulse-Skipping Period (4) VFB-G<VFB<VFB-SKIP 90 ms fDV Frequency Variation vs. VDD Deviation VDD=11 V to 22 V 5 % fDT Frequency Variation vs. Temperature Deviation TA=TJ =-40 to 105C 5 % FAN6605— mWSaver™ Controller Electrical Characteristics VIN Section VIN-OFF PWM Turn-Off (Brownout) Threshold Voltage 0.66 0.70 0.74 V VIN-ON PWM Turn-On (Brown-in) Threshold Voltage VIN-OFF+ 0.17 VIN-OFF+ 0.20 VIN-OFF+ 0.23 V 5.1 5.3 5.5 V 60 100 140 µs VIN-Protect tVIN-Protect Threshold Voltage of VIN OverVoltage Protection Debounce Time of VIN OverVoltage Protection Current-Sense Section VLIMIT at VIN=1 V Threshold Voltage for Current Limit VIN=1 V 0.80 0.83 0.86 V VLIMIT at VIN=3 V Threshold Voltage for Current Limit VIN=3 V 0.67 0.70 0.73 V tPD Delay to Output 100 200 ns tLEB Leading-Edge Blanking Time Steady State 240 290 340 ns tSS Period During Soft-Start Time Startup Time 4.0 5.5 7.0 ms VLimit VIN-OFF =0.92V VIN-Protect =5.3V VSENSE =0.83V VSENSE =0.7V VIN VIN=1V VIN=3V Figure 6. VIN vs. VSENSE Continued on the following page… © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com 7 VDD=11~24 V and TA=-40~105C unless otherwise noted. Symbol Parameter Conditions Min. Typ. Max. Unit 1/4.5 1/4.0 1/3.5 V/V Feedback Input Section AV Internal FB Voltage Attenuation ZFB Input Impedance VFB=4 V 10 15 19 kΩ VFB-OPEN The Maximum Clamp of FB Voltage FB Pin Open 5.1 5.3 5.5 V VFB-OLP FB Open-Loop Protection Triggering Level TA=25C 4.4 4.6 4.8 V tD-OLP Delay Time of FB Pin Open-loop Protection 45.0 62.5 70.0 ms VFB-N Green-Mode Entry FB Voltage 2.8 3.0 3.2 V VFB-G Green-Mode Ending FB Voltage VFB-N - 0.6 V VFB-SKIP FB Threshold Voltage for Changing (4) Pulse-Skipping Period 2.5 2.7 2.9 V VFB-ZDCR FB Threshold Voltage for Zero-Duty Recovery 1.6 1.8 2.0 V VFB-ZDC FB Threshold Voltage for Zero-Duty 1.4 1.6 1.8 V 0.12 0.15 0.19 V VFB-ZDCR ZDC Hysteresis VFB-ZDC FAN6605— mWSaver™ Controller Electrical Characteristics PWM Frequency with cycle skipping fOSC fOSC-G VFB- ZDC VFB- ZDCR VFB-G VFB-SKIP Figure 7. VFB-N VFB Cycle Skipping vs. VFB Continued on the following page… © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com 8 VDD=11~24 V and TA=-40~105C unless otherwise noted. Symbol Parameter Conditions Min. Typ. Max. Unit 60 75 90 % 1.5 V GATE Section DCYMAX Maximum Duty Cycle VGATE-L Gate Low Voltage VDD=15 V, IO=50 mA VGATE-H Gate High Voltage VDD=12 V, IO=50 mA tr Gate Rising Time VDD=15 V, CL=1 nF 100 ns tf Gate Falling Time VDD=15 V, CL=1 nF 30 ns Gate Source Current VDD=15 V, GATE=6 V 700 mA Gate Output Clamping Voltage VDD=22 V IGATESOURCE VGATECLAMP 8 V 18 V FAN6605— mWSaver™ Controller Electrical Characteristics Over-Temperature Protection Section (OTP) TOTP TRestart Protection Junction Temperature Restart Junction Temperature (5,7) (6,7) 125 °C TOTP-25 °C Notes: 4. Guarantee by design. 5. When OTP is activated, the PWM switching is shut down. 6. When junction temperature is lower than this level, IC resumes PWM switching. 7. These parameters are guaranteed by design. © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com 9 Figure 8. Startup Current (IDD-ST) vs. Temperature Figure 9. Operation Supply Current (IDD-OP) vs. Temperature Figure 10. Start Threshold Voltage (VDD-ON) vs. Temperature Figure 11. Minimum Operating Voltage (VDD-OFF) vs. Temperature Figure 12. Supply Current Drawn from HV Pin (IHV) vs. Temperature Figure 13. HV Pin Leakage Current After Startup (IHV-LC) vs. Temperature Figure 14. Frequency in Normal Mode (fOSC) vs. Temperature Figure 15. Maximum Duty Cycle (DCYMAX) vs. Temperature © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 FAN6605— mWSaver™ Controller Typical Performance Characteristics www.fairchildsemi.com 10 Figure 16. FB Open-Loop Trigger Level (VFB-OLP) vs. Temperature Figure 17. Delay Time of FB Pin Open-Loop Protection (tD-OLP) vs. Temperature Figure 18. PWM Turn-Off Threshold Voltage (VIN-OFF & VIN-ON) vs. Temperature Figure 19. VDD Over-Voltage Protection (VDD-OVP) vs. Temperature FAN6605— mWSaver™ Controller Typical Performance Characteristics Figure 20. VIN vs. VLIMIT © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 www.fairchildsemi.com 11 Startup Current Gate Output / Soft Driving For startup, the HV pin is connected to the line input or bulk capacitor in series with diodes and/or resistors. If HV pin is connected to the line input, a 1-kV/ 1-A diode and a 100 kΩ resistor are recommended. If HV pin is connected to the bulk capacitor, only the resistor is required. Startup current drawn from pin HV (typically 3.5 mA) charges the hold-up capacitor through the diode and resistor. When the VDD capacitor level reaches VDD-ON, the startup current switches off. At this moment, only the VDD capacitor supplies the FAN6605 to maintain VDD before the auxiliary winding of the main transformer to provide the operating current. The BiCMOS output stage is a fast totem-pole gate driver. Cross conduction has been avoided to minimize heat dissipation, increase efficiency, and enhance reliability. The output driver is clamped by an internal 18 V Zener diode to protect power MOSFET transistors against undesirable gate over-voltage. A soft-driving circuit is implemented to minimize EMI. Soft-Start For many applications, it is necessary to minimize the inrush current at startup. The built-in 5.5 ms soft-start circuit significantly reduces the startup current spike and output voltage overshoot. Operating Current FAN6605— mWSaver™ Controller Functional Description Slope Compensation Operating current is below 2 mA. The low operating current enables better efficiency and reduces the requirement of VDD hold-up capacitance. The sensed voltage across the current-sense resistor is used for peak-current-mode control and pulse-by-pulse current limiting. Built-in slope compensation improves stability and prevents sub-harmonic oscillation. FAN6605 inserts a synchronized positive-going ramp at every switching cycle as slope compensation. Green-Mode Operation The proprietary green-mode function provides an offtime modulation to reduce the switching frequency in light-load and no-load conditions. The on time is limited for better abnormal or brownout protection. VFB, which is derived from the voltage feedback loop, is taken as the reference. Once VFB is lower than the threshold voltage, switching frequency is continuously decreased with cycle skipping to the minimum green-mode frequency of around 23 kHz. Constant Output Power Limit For constant output power limit over universal inputvoltage range, the peak-current threshold is adjusted by the voltage of the VIN pin. Since the VIN pin is connected to the rectified AC input line voltage through the resistive divider, a higher line voltage generates a higher VIN voltage. The threshold voltage decreases as VIN increases, making the maximum output power at high-line input voltage equal to that at low-line input. The value of R-C network should not be so large that it affects the power limit (shown in Figure 21). R and C should be less than 100 and 470 pF, respectively. Current Sensing / PWM Current Limiting Peak-current-mode control is utilized to regulate output voltage and provide pulse-by-pulse current limiting. The switching current is detected by the current-sensing resistor of SENSE pin. The PWM duty cycle is determined by this current sense signal and VFB, the feedback voltage. When the voltage on the SENSE pin reaches around VCOMP=(VFB–0.6)/4, the PWM switching turns off immediately. Leading-Edge Blanking (LEB) Each time the power MOSFET is switched on, a turn-on spike occurs on the sense resistor. To avoid premature termination of the switching pulse, a leading-edge blanking time is built in. During this blanking period, the current-limit comparator is disabled and cannot switch off the gate driver. FAN6605 Blanking Circuit GATE R SENSE C Under-Voltage Lockout (UVLO) The turn-on and turn-off thresholds are fixed internally at 16 V and 7.8 V in normal mode. During startup, the hold-up capacitor must be charged to 16 V through the startup resistor to enable the IC. The hold-up capacitor continues to supply VDD before the energy can be delivered from auxiliary winding of the main transformer. VDD must not drop below 7.8 V during startup. This UVLO hysteresis window ensures that the hold-up capacitor is adequate to supply VDD during startup. © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 Figure 21. Current-Sense R-C Filter www.fairchildsemi.com 12 Feedback Impedance Switching Limited Power Control FAN6605 actively varies FB-pin impedance (ZFB) to reduce no-load power consumption. This technique can further reduce operating current of the controller when FB-pin voltage drops below V FB-ZDC. The FB voltage is saturated HIGH when the power supply output voltage drops below its nominal value and shunt regulator (KA431) does not draw current through the opto-coupler. This occurs when the output feedback loop is open or output is short circuited. If the FB voltage is higher than a built-in threshold for longer than tD-OLP, PWM output is turned off. As PWM output is turned off, VDD begins decreasing since no more energy is delivered from the auxiliary winding. Brownout Protection Since the VIN pin is connected through a resistive divider to the rectified AC input line voltage, it can also be used for brownout protection. If VIN is less than 0.7 V, the PWM output is shut off. When VIN reaches over 0.9 V, the PWM output is turned on again. The hysteresis window for ON/OFF is around 0.2 V. The brownout voltage setting is determined by the potential divider formed with RUpper and RLower. Equations to calculate the resistors are shown below: VIN RLower VAC 2 , (unit V ) RLower RUpper As the protection is triggered, VDD enters into UVLO mode. This protection feature continues as long as the over loading condition persists. This prevents the power supply from overheating due to overloading conditions. Noise Immunity Noise on the current sense or control signal may cause significant pulse-width jitter, particularly in continuousconduction mode. Slope compensation helps alleviate this problem. Good placement and layout practices should be followed. Avoiding long PCB traces and component leads, locating compensation and filter components near the FAN6605, and increasing the gate resistor from GATE pin to MOSFET improve performance. (1) Thermal Overload Protection Thermal overload protection limits total power dissipation. When the junction temperature exceeds TJ= +140C, the thermal sensor signals the shutdown logic © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 FAN6605— mWSaver™ Controller VDD over-voltage protection prevents damage due to abnormal conditions. Once the VDD voltage is over the over-voltage protection voltage (VDD-OVP), and lasts for tDVDDOVP, the PWM pulses are disabled. When the VDD voltage drops below the UVLO, the internal startup circuit turns on, and VDD is charged to VDD-ON to restart IC. and turns off most of the internal circuitry. The thermal sensor turns internal circuitry on again after the IC’s junction temperature drops by 25C. Thermal overload protection is designed to protect the FAN6605 in the event of a fault condition. For continual operation, the controller should not exceed the absolute maximum junction temperature of TJ = +140C. VDD Over-Voltage Protection www.fairchildsemi.com 13 R6 12V 1 1 C7 N1 8 R7 12V L2 P1 2 12V C5 1 N1 N1 A N2 3 C1 L1 M1 4 2 L 1 ZD 1 TX 1 12 11 C2 C11 + R14 N5 N6 6 1 D3 VIN 2 N3 11 N N1 7 D1 R4 N2 1 8 R5 N2 0 7 1 3 R2 4 C4 4 R3 AC IN N4 C3 N2 8 1 1 2 3 2 CN 1 + C9 3 BD 1 R1 + C8 2 2 F1 R8 C10 N7 10 9 2 D4 C6 5V 1 1 5V L3 P2 2 5V 2 R17 3 C15 + C14 2 + C13 C12 R13 D5 1 2 R9 N8 Q1 N1 0 R10 D2 1 N9 R11 3 2 N3 0 SG ND N2 9 R15 R12 1 HV P3 R16 VIN U1 4 C16 HV 7 R20 VD D FB SEN SE GN D VD D GA TE 5V 1 R19 6 1 3 VIN N1 2 N1 3 U2 5 R22 GA TE 12V FAN6605MX FA N6755 C17 R28 C18 + 5V C19 K 3 SEN SE 2 2 4 1 FB FAN6605 — mWSaver™ Controller Typical Application Circuit U3 N1 4 R21 C20 R23 R24 R26 R27 R25 N1 5 R N1 6 A R18 Figure 22. © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 44 W Flyback 12 V/2 A, 5 V/4 A Application Circuit www.fairchildsemi.com 14 Designator Part Type Designator Part Type BD1 BD 4 A/600 V Q1 MOS 9 A/600 V C1 YC 2200 pF/Y1 R1 R 1.5 M 1/4 W C2 YC 2200 pF/Y1 R2 R 1.5 M 1/4 W C3 XC 0.33 µF/300 V R3 R 10 M 1/4 W C4 NC R4, R5, R6, R7 R 47 1/4 W C5 YC 2200 pF/Y1 R8, R17, R25, R27 NC C6 CC 2200 pF/100 V R9 R 50 K 1/4 W C7 CC 1000 pF/100 V R10 R 50 K 1/4 W C8 EC 1000 µF/25 V R11 R 0 1/8 W C9 EC 470 µF/25 V R12 R 47 1/8 W C10 CC 100 pF/50 V R13 R 100 K 1/8 W C11 EC 100 µF/400 V R14 R 0 1/4 W C12 C 1 µF/50 V R15 R 10 K 1/8 W C13 EC 1000 µF/10 V R16 R 1 1/8 W C14 EC 470 µF/10 V R18 R 0 1/8 W C15 CC 100 pF/50 V R19 R 100 1/8 W C16 C 1 nF/50 V R20 R 1 K 1/8 W C17 C 470 pF/50 V R21 R 4.7 K 1/8 W C18 EC 47 µF/50 V R22 R 7.5 K 1/8 W C19 C 0.01 µF/50 V R23 R 120 K 1/8 W C20 C 0.1 µF/50 V R24 R 15 K 1/8 W D1 FYP1010 R26 R 10 K 1/8 W D2 1N4148 R28 R 0.43 2 W D3 FR107 TX1 800 µH(ERL-28) D4 FR103 U1 IC FAN6605 D5 FYP1010 U2 IC PC817 ZD1 P6KE150A U3 IC TL431 F1 FUSE 4A/250 V M1 VZ 9G L1 13 mH L2 Inductor (2 µH) L3 Inductor (2 µH) © 2014 Fairchild Semiconductor Corporation FAN6605 • Rev. 1.0 FAN6605 — mWSaver™ Controller Bill of Materials www.fairchildsemi.com 15 5.00 4.80 7 A 3.81 3.81 6 0.65TYP 5 B 1.75TYP 6.20 5.80 PIN #1 4.00 3.80 1 2 3 4 1.27 (0.33) 3.85 7.35 0.25 C B A TOP VIEW 1.27 LAND PATTERN RECOMMENDATION SEE DETAIL A 0.25 0.19 0.25 0.10 OPTION A - BEVEL EDGE C 1.75 MAX 0.51 0.33 FRONT VIEW 0.10 C OPTION B - NO BEVEL EDGE 0.50 0.25 R0.23 NOTES: GAGE PLANE R0.23 0.36 A) THIS PACKAGE DOES NOT FULLY CONFORMS TO JEDEC MS-012, VARIATION AA, ISSUE C. B) ALL DIMENSIONS ARE IN MILLIMETERS. 0.90 0.406 SEATING PLANE (1.04) DETAIL A SCALE: 2:1 C) DIMENSIONS DO NOT INCLUDE MOLD FLASH OR BURRS. D) DRAWING FILENAME : M07Arev4. ON Semiconductor and are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries. ON Semiconductor owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of ON Semiconductor’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent−Marking.pdf. ON Semiconductor reserves the right to make changes without further notice to any products herein. ON Semiconductor makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does ON Semiconductor assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages. Buyer is responsible for its products and applications using ON Semiconductor products, including compliance with all laws, regulations and safety requirements or standards, regardless of any support or applications information provided by ON Semiconductor. “Typical” parameters which may be provided in ON Semiconductor data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. ON Semiconductor does not convey any license under its patent rights nor the rights of others. ON Semiconductor products are not designed, intended, or authorized for use as a critical component in life support systems or any FDA Class 3 medical devices or medical devices with a same or similar classification in a foreign jurisdiction or any devices intended for implantation in the human body. Should Buyer purchase or use ON Semiconductor products for any such unintended or unauthorized application, Buyer shall indemnify and hold ON Semiconductor and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that ON Semiconductor was negligent regarding the design or manufacture of the part. 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