MC44603A Enhanced Mixed Frequency Mode GreenLinet PWM Controller: Fixed Frequency, Variable Frequency, Standby Mode The MC44603A is an enhanced high performance controller that is specifically designed for off−line and dc−to−dc converter applications. This device has the unique ability of automatically changing operating modes if the converter output is overloaded, unloaded, or shorted, offering the designer additional protection for increased system reliability. The MC44603A has several distinguishing features when compared to conventional SMPS controllers. These features consist of a foldback facility for overload protection, a standby mode when the converter output is slightly loaded, a demagnetization detection for reduced switching stresses on transistor and diodes, and a high current totem pole output ideally suited for driving a power MOSFET. It can also be used for driving a bipolar transistor in low power converters (< 150 W). It is optimized to operate in discontinuous mode but can also operate in continuous mode. Its advanced design allows use in current mode or voltage mode control applications. Features Operation up to 250 kHz Output Switching Frequency Inherent Feed Forward Compensation Latching PWM for Cycle−by−Cycle Current Limiting Oscillator with Precise Frequency Control MC44603AP AWLYYWWG 16 PDIP−16 1 P SUFFIX CASE 648 1 16 SOIC−16 DW SUFFIX CASE 751G A WL YY WW G High Flexibility Externally Programmable Reference Current Secondary or Primary Sensing7 Synchronization Facility High Current Totem Pole Output Undervoltage Lockout with Hysteresis MC44603ADW AWLYYWWG 1 = Assembly Location = Wafer Lot = Year = Work Week = Pb−Free Package PIN CONNECTIONS Safety/Protection Features • • • • • • • • 16 1 Current or Voltage Mode Controller • • • • • MARKING DIAGRAMS 16 • This is a Pb−Free and Halide−Free Device • • • • http://onsemi.com Overvoltage Protection Against Open Current and Open Voltage Loop Protection Against Short Circuit on Oscillator Pin Fully Programmable Foldback Soft−Start Feature Accurate Maximum Duty Cycle Setting Demagnetization (Zero Current Detection) Protection Internally Trimmed Reference Enhanced Output Drive VCC 1 16 Rref VC 2 15 Output 3 RFrequency Standby Voltage Feedback 14 Input GND 4 13 Error Amp Output Foldback Input 5 12 RPower Standby Overvoltage Protection (OVP) 6 11 Current Sense Input 7 10 CT Demag Detection 8 9 Soft-Start/Dmax/ Voltage Mode Sync Input (Top View) GreenLine Controller: Low Power Consumption in Standby Mode • Low Startup and Operating Current • Fully Programmable Standby Mode • Controlled Frequency Reduction in Standby Mode © Semiconductor Components Industries, LLC, 2011 April, 2011 − Rev. 5 ORDERING INFORMATION See detailed ordering and shipping information in the package dimensions section on page 23 of this data sheet. 1 Publication Order Number: MC44603A/D MC44603A • Low dV/dT for Low EMI Radiations *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. http://onsemi.com 2 MC44603A MAXIMUM RATINGS Rating Total Power Supply and Zener Current Supply Voltage with Respect to Ground (Pin 4) Symbol Value Unit (ICC + IZ) 30 mA VC VCC 18 V IO(Source) −750 IO(Sink) 750 Output Current (Note 1) mA Source Sink Output Energy (Capacitive Load per Cycle) W 5.0 J RF Stby, CT, Soft−Start, Rref, RP Stby Inputs Vin −0.3 to 5.5 V Foldback Input, Current Sense Input, E/A Output, Voltage Feedback Input, Overvoltage Protection, Synchronization Input Vin −0.3 to VCC + 0.3 V Synchronization Input High State Voltage VIH VCC + 0.3 V Low State Reverse Current VIL −20 mA Demagnetization Detection Input Current mA Source Sink Error Amplifier Output Sink Current Idemag−ib (Source) −4.0 Idemag−ib (Sink) 10 IE/A (Sink) 20 mA PD 0.6 W RJA 100 °C/W Power Dissipation and Thermal Characteristics P Suffix, Dual−In−Line, Case 648 Maximum Power Dissipation at TA = 85°C Thermal Resistance, Junction−to−Air DW Suffix, Surface Mount, Case 751G Maximum Power Dissipation at TA = 85°C PD 0.45 W RJA 145 °C/W Operating Junction Temperature TJ 150 °C Operating Ambient Temperature TA −25 to +85 °C Thermal Resistance, Junction−to−Air Maximum ratings are those values beyond which device damage can occur. Maximum ratings applied to the device are individual stress limit values (not normal operating conditions) and are not valid simultaneously. If these limits are exceeded, device functional operation is not implied, damage may occur and reliability may be affected. 1. ESD data available upon request. http://onsemi.com 3 MC44603A ELECTRICAL CHARACTERISTICS (VCC and VC = 12 V, (Note 2), Rref = 10 k, CT = 820 pF, for typical values TA = 25°C, for min/max values TA = −25° to +85°C (Note 3), unless otherwise noted.) Symbol Characteristic Min Typ Max Unit OUTPUT SECTION V Output Voltage (Note 4) Low State (ISink = 100 mA) Low State (ISink = 500 mA) VOL − − 1.0 1.4 1.2 2.0 High State (ISource = 200 mA) High State (ISource = 500 mA) VOH − − 1.5 2.0 2.0 2.7 − − − − 0.1 0.1 1.0 1.0 1.0 Output Voltage During Initialization Phase VCC = 0 to 1.0 V, ISink = 10 A VCC = 1.0 to 5.0 V, ISink = 100 A VCC = 5.0 to 13 V, ISink = 1.0 mA VOL V Output Voltage Rising Edge Slew−Rate (CL = 1.0 nF, TJ = 25°C) dVo/dT − 300 − V/s Output Voltage Falling Edge Slew−Rate (CL = 1.0 nF, TJ = 25°C) dVo/dT − −300 − V/s VFB 2.42 2.5 2.58 V Input Bias Current (VFB = 2.5 V) IFB−ib −2.0 −0.6 − A Open Loop Voltage Gain (VE/A out = 2.0 to 4.0 V) AVOL 65 70 − dB ERROR AMPLIFIER SECTION Voltage Feedback Input (VE/A out = 2.5 V) Unity Gain Bandwidth BW MHz TJ = 25°C − 4.0 − TJ = −25° to +85°C − − 5.5 VFBline−reg −10 − 10 ISink 2.0 12 − ISource −2.0 − −0.2 Voltage Feedback Input Line Regulation (VCC = 10 to 15 V) Output Current mV mA Sink (VE/A out = 1.5 V, VFB = 2.7 V) TA = −25° to +85°C Source (VE/A out = 5.0 V, VFB = 2.3 V) TA = −25° to +85°C Output Voltage Swing V High State (IE/A out (source) = 0.5 mA, VFB = 2.3 V) VOH 5.5 6.5 7.5 Low State (IE/A out (sink) = 0.33 mA, VFB = 2.7 V) VOL − 1.0 1.1 Vref 2.4 2.5 2.6 Iref −500 − −100 A Vref −40 − 40 mV REFERENCE SECTION Reference Output Voltage (VCC = 10 to 15 V) Reference Current Range (Iref = Vref/Rref, R = 5.0 k to 25 k) Reference Voltage Over Iref Range V OSCILLATOR AND SYNCHRONIZATION SECTION fOSC Frequency TA = 0° to +70°C TA = −25° to +85°C kHz 44.5 48 51.5 44 − 52 Frequency Change with Voltage (VCC = 10 to 15 V) fOSC/V − 0.05 − %/V Frequency Change with Temperature (TA = −25° to +85°C) fOSC/T − 0.05 − %/°C 2. Adjust VCC above the startup threshold before setting to 12 V. 3. Low duty cycle pulse techniques are used during test to maintain junction temperature as close to ambient as possible. 4. VC must be greater than 5.0 V. 5. Standby is disabled for VR P Stby < 25 mV typical. 6. If not used, Synchronization input must be connected to Ground. 7. Synchronization Pulse Width must be shorter than tOSC = 1/fOSC. 8. This function can be inhibited by connecting Pin 8 to GND. This allows a continuous current mode operation. 9. This function can be inhibited by connecting Pin 5 to VCC. 10. The MC44603A can be shut down by connecting the Soft−Start pin (Pin 11) to Ground. http://onsemi.com 4 MC44603A ELECTRICAL CHARACTERISTICS (continued) (VCC and VC = 12 V, (Note 2), Rref = 10 k, CT = 820 pF, for typical values TA = 25°C, for min/max values TA = −25° to +85°C (Note 3), unless otherwise noted.) Characteristic Symbol Min Typ Max Unit Oscillator Voltage Swing (Peak−to−Peak) VOSC(pp) 1.65 1.8 1.95 V Ratio Charge Current/Reference Current Icharge/Iref OSCILLATOR AND SYNCHRONIZATION SECTION − TA = 0° to +70°C (VCT = 2.0 V) 0.375 0.4 0.425 TA = −25° to +85°C 0.37 − 0.43 78 80 82 Fixed Maximum Duty Cycle = Idischarge/(Idischarge + Icharge) D Ratio Standby Discharge Current versus IR F Stby (Note 5) Idisch−Stby/ TA = 0° to +70°C IR F Stby % − 0.46 0.53 0.6 0.43 − 0.63 VR F Stby 2.4 2.5 2.6 V FStby 18 21 24 kHz IR F Stby −200 − −50 A VinthH VinthL 3.2 0.45 3.7 0.7 4.3 0.9 V ISync−in −5.0 − 0 A tSync − − 0.5 s Startup Threshold Vstup−th 13.6 14.5 15.4 V Output Disable Voltage After Threshold Turn−On (UVLO 1) Vdisable1 TA = −25° to +85°C (Note 8) VR F Stby (IR F Stby = 100 A) Frequency in Standby Mode (RF Stby (Pin 15) = 25 k) Current Range Synchronization Input Threshold Voltage (Note 6) Synchronization Input Current Minimum Synchronization Pulse Width (Note 7) UNDERVOLTAGE LOCKOUT SECTION TA = 0° to +70°C V 8.6 TA = −25° to +85°C Reference Disable Voltage After Threshold Turn−On (UVLO 2) 9.0 9.4 8.3 − 9.6 Vdisable2 7.0 7.5 8.0 V Vdemag−th 50 65 80 mV − − 0.25 − s DEMAGNETIZATION DETECTION SECTION (Note 8) Demagnetization Detect Input Demagnetization Comparator Threshold (VPin 9 Decreasing) Propagation Delay (Input to Output, Low to High) Input Bias Current (Vdemag = 65 mV) Idemag−lb −0.5 − − A Negative Clamp Level (Idemag = −2.0 mA) CL(neg) − −0.38 − V Positive Clamp Level (Idemag = 2.0 mA) CL(pos) − 0.72 − V SOFT−START SECTION (Note 10) Iss(ch)/Iref Ratio Charge Current/Iref TA = 0° to +70°C − 0.37 TA = −25° to +85°C Discharge Current (Vsoft−start = 1.0 V) Clamp Level 0.4 0.43 0.36 − 0.44 Idischarge 1.5 5.0 − mA Vss(CL) 2.2 2.4 2.6 V 2. Adjust VCC above the startup threshold before setting to 12 V. 3. Low duty cycle pulse techniques are used during test to maintain junction temperature as close to ambient as possible. 4. VC must be greater than 5.0 V. 5. Standby is disabled for VR P Stby < 25 mV typical. 6. If not used, Synchronization input must be connected to Ground. 7. Synchronization Pulse Width must be shorter than tOSC = 1/fOSC. 8. This function can be inhibited by connecting Pin 8 to GND. This allows a continuous current mode operation. 9. This function can be inhibited by connecting Pin 5 to VCC. 10. The MC44603A can be shut down by connecting the Soft−Start pin (Pin 11) to Ground. http://onsemi.com 5 MC44603A ELECTRICAL CHARACTERISTICS (continued) (VCC and VC = 12 V, (Note 2), Rref = 10 k, CT = 820 pF, for typical values TA = 25°C, for min/max values TA = −25° to +85°C (Note 3), unless otherwise noted.) Characteristic Symbol Min Typ Max Unit Dsoft−start 12k Dsoft−start 36 − 42 − 49 0 % VOVP−th 2.42 2.5 2.58 V 1.0 − 3.0 s SOFT−START SECTION (Note 10) Duty Cycle (Rsoft−start = 12 k) Duty Cycle (Vsoft−start (Pin 11) = 0.1 V) OVERVOLTAGE SECTION Protection Threshold Level on VOVP Propagation Delay (VOVP > 2.58 V to Vout Low) Protection Level on VCC VCC prot TA = 0° to +70°C TA = −25° to +85°C Input Resistance V 16.1 17 17.9 15.9 − 18.1 − k TA = 0° to +70°C 1.5 2.0 3.0 TA = −25° to +85°C 1.4 − 3.4 VCS−th 0.86 0.89 0.9 V Ifoldback−lb −6.0 −2.0 − A FOLDBACK SECTION (Note 9) Current Sense Voltage Threshold (Vfoldback (Pin 5) = 0.9 V) Foldback Input Bias Current (Vfoldback (Pin 5) = 0 V) STANDBY SECTION Ratio IR P Stby/Iref IR P Stby/Iref − TA = 0° to +70°C 0.37 0.4 0.43 TA = −25° to +85°C 0.36 − 0.44 Ratio Hysteresis (Vh Required to Return to Normal Operation from Standby Operation) Vh/VR P Stby − TA = 0° to +70°C 1.42 1.5 1.58 TA = −25° to +85°C 1.4 − 1.6 VCS−Stby 0.28 0.31 0.34 V Maximum Current Sense Input Threshold (Vfeedback (Pin 14) = 2.3 V and Vfoldback (Pin 6) = 1.2 V) VCS−th 0.96 1.0 1.04 V Input Bias Current ICS−ib −10 −2.0 − A − − 120 200 ns Current Sense Voltage Threshold (VR P Stby (Pin 12) = 1.0 V) CURRENT SENSE SECTION Propagation Delay (Current Sense Input to Output at VTH of MOS transistor = 3.0 V) TOTAL DEVICE ICC Power Supply Current mA Startup (VCC = 13 V with VCC Increasing) − 0.3 0.45 Operating TA = −25° to +85°C (Note 2) 13 17 20 VZ 18.5 − − V − − 155 − °C Power Supply Zener Voltage (ICC = 25 mA) Thermal Shutdown 2. Adjust VCC above the startup threshold before setting to 12 V. 3. Low duty cycle pulse techniques are used during test to maintain junction temperature as close to ambient as possible. 4. VC must be greater than 5.0 V. 5. Standby is disabled for VR P Stby < 25 mV typical. 6. If not used, Synchronization input must be connected to Ground. 7. Synchronization Pulse Width must be shorter than tOSC = 1/fOSC. 8. This function can be inhibited by connecting Pin 8 to GND. This allows a continuous current mode operation. 9. This function can be inhibited by connecting Pin 5 to VCC. 10. The MC44603A can be shut down by connecting the Soft−Start pin (Pin 11) to Ground. http://onsemi.com 6 MC44603A RF Stby Rref RF Stby 15 16 Vref Negative Active Clamp Demag Detect 8 R Q S UVLO2 VCC + 65 mV Sync Input 9 Vref Vref VOSC prot Vaux VCC Reference Block Synchro + 0.7 V 0.4 Iref + VDemag Out + 3.7 V 18.0 V 1 14.5 V/7.5 V Iref To Power Transformer IF Stby 1.0 V R VC Q 1.6 V CT S R 2 Q 10 + CT S VOSC 3.6 V Output S 3 Q R 0.4 Iref IDischarge Vref Vref Vref 0.6 Iref 0.4 Iref Vref 0.25 IF Stby 0.8 Iref 2.0 s Delay Thermal Shutdown Vref 0.4 Iref 11.6 k 5.0 s Delay OVP 2.0 k VCC IDischarge/2 1.0 mA + Current Mirror X2 2R 2.5 V VCC Vref 0.2 Iref 12 + 4 GND Vref RPwr Stby Feedback 14 VOVP Out Vref 5 Foldback Input ROVP + 2.5 V 1.6 V Error Amplifier Current Sense Input Compensation 13 6 7 R 1.0 V UVLO1 2.4 V 5.0 mA 11 SS/Dmax/VM = Sink only = Positive True Logic RSS CSS This device contains 243 active transistors. Figure 1. Representative Block Diagram http://onsemi.com 7 VCC + 9.0 V MC44603A 10000 CT = 100 pF VCC = 16 V TA = 25°C CT = 500 pF VCC = 16 V TA = 25°C Rref = 10 k C T, TIMING CAPACITOR (pF) Rref , TIMING RESISTANCE (k Ω ) 100 CT = 1000 pF 10 RF Stby = 2.0 k RF Stby = 5.0 k 1000 RF Stby = 27 k RF Stby = 100 k CT = 2200 pF 3.0 10 k 100 k 300 10 k 1.0 M Figure 2. Timing Resistor versus Oscillator Frequency Figure 3. Standby Mode Timing Capacitor versus Oscillator Frequency Icharge/Iref = RATIO CHARGE CURRENT/ REFERENCE CURRENT 50 49 48 47 46 VCC = 12 V Rref = 10 k CT = 820 pF 45 -25 0 25 50 100 0.43 0.42 0.41 0.40 0.39 VCC = 12 V Rref = 10 k CT = 820 pF 0.38 0.37 -50 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) TA, AMBIENT TEMPERATURE (°C) Figure 4. Oscillator Frequency versus Temperature Figure 5. Ratio Charge Current/Reference Current versus Temperature 70 VCC = 12 V CL = 2200 pF TA = 25°C 400 Current 60 50 0 40 -200 30 -400 20 Voltage -600 10 -800 0 -10 -1000 60 50 VCC = 12 V CL = 2200 pF TA = 25°C 20 10 Current 40 0 30 -1 20 -2 10 VO -3 Voltage 0 -10 1.0 s/Div -4 ICC -5 1.0 s/Div Figure 6. Output Waveform Figure 7. Output Cross Conduction http://onsemi.com 8 100 30 70 VO , OUTPUT DRIVE VOLTAGE (V) 600 I O , OUTPUT CURRENT (mA) 75 VO , OUTPUT DRIVE VOLTAGE (V) f OSC, OSCILLATOR FREQUENCY (kHz) 51 200 1.0 M fOSC, Oscillator Frequency (Hz) 52 44 -50 100 k fOSC, Oscillator Frequency (Hz) VOH , SOURCE OUTPUT SATURATION VOLTAGE (V) MC44603A 475 450 425 400 375 325 -25 0 25 50 75 100 VCC = 12 V Rref = 10 k CT = 820 pF TA = 25°C 1.0 0 100 200 300 400 500 Figure 8. Oscillator Discharge Current versus Temperature Figure 9. Source Output Saturation Voltage versus Load Current 80 Sink Saturation (Load to VCC) TA = 25°C VCC = 12 V 80 s Pulsed Load 120 Hz Rate 0.4 40 200 300 400 50 0 500 100 101 10 2 -40 104 103 f, FREQUENCY (kHz) Figure 10. Sink Output Saturation Voltage versus Sink Current Figure 11. Error Amplifier Gain and Phase versus Frequency Vdemag-th, DEMAG COMPARATOR THRESHOLD (mV) Isink, SINK OUTPUT CURRENT (mA) VFB, VOLTAGE FEEDBACK INPUT (V) 2.60 VCC = 12 V G = 10 VO = 2.0 to 4.0 V RL = 100 k 2.55 2.50 2.45 -25 0 25 50 75 140 20 -20 100 VCC = 12 V G = 10 Vin = 30 mV VO = 2.0 to 4.0 V RL = 100 k TA = 25°C 60 0.8 2.40 -50 1.5 Isource, OUTPUT SOURCE CURRENT (mA) 1.2 0 0 2.0 TA, AMBIENT TEMPERATURE (°C) 2.0 1.6 2.5 PHASE (DEGREES) 300 -50 VOL , SINK OUTPUT SATURATION VOLTAGE (V) VCC = 12 V Rref = 10 k CT = 820 pF 350 GAIN (dB) Idisch , DISCHARGE CURRENT (μA) 500 100 80 VCC = 12 V 75 70 65 60 55 50 -50 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) TA, AMBIENT TEMPERATURE (°C) Figure 12. Voltage Feedback Input versus Temperature Figure 13. Demag Comparator Threshold versus Temperature http://onsemi.com 9 100 A VCS, CURRENT SENSE GAIN 3.1 3.0 VCC = 12 V Rref = 10 k CT = 820 pF 2.9 -25 0 25 50 75 100 TA, AMBIENT TEMPERATURE (°C) 80 L 4.0 2.0 oz Copper 3.0 40 2.0 PD(max) for TA = 70°C 20 1.0 0 50 0 0 10 20 30 L, LENGTH OF COPPER (mm) 40 Figure 15. Thermal Resistance and Maximum Power Dissipation versus P.C.B. Copper Length 140 0.35 0.30 STARTUP CURRENT (mA) PROPAGATION DELAY (ns) ÉÉ ÉÉÉ ÉÉÉÉÉ L 3.0 mm Graphs represent symmetrical layout RJA 60 Figure 14. Current Sense Gain versus Temperature 120 100 VCC = 12 V Rref = 10 k CT = 820 pF 80 -50 0.25 0.20 0.15 0.10 Rref = 10 k CT = 820 pF 0.05 0 -25 0 25 50 75 0 100 2.0 4.0 6.0 8.0 10 12 TA, AMBIENT TEMPERATURE (°C) VCC, SUPPLY VOLTAGE (V) Figure 16. Propagation Delay Current Sense Input to Output versus Temperature Figure 17. Startup Current versus VCC 14 21.5 16 14 VZ, ZENER VOLTAGE (V) ICC , SUPPLY CURRENT (mA) 5.0 Printed circuit board heatsink example P D, MAXIMUM POWER DISSIPATION (W) 100 3.2 2.8 -50 R θ JA , THERMAL RESISTANCE JUNCTION-TO-AIR (° C/W) MC44603A 12 10 8.0 6.0 4.0 2.0 0 2.0 TA = 25°C Rref = 10 k CT = 820 pF VFB = 0 V VCS = 0 V 4.0 6.0 8.0 10 12 14 21.0 20.5 20.0 19.5 19.0 -50 16 ICC = 25 mA -25 0 25 50 75 VCC, SUPPLY VOLTAGE (V) TA, AMBIENT TEMPERATURE (°C) Figure 18. Supply Current versus Supply Voltage Figure 19. Power Supply Zener Voltage versus Temperature http://onsemi.com 10 100 9.50 15.0 9.25 Vdisable1 , UVLO1 (V) 15.5 14.5 VCC Increasing 14.0 13.5 -50 -25 0 25 50 75 Vdisable2 , UVLO2 (V) 0 25 50 75 Figure 21. Disable Voltage After Threshold Turn−On (UVLO1) versus Temperature 7.4 VCC Decreasing 7.2 7.0 -25 0 25 50 75 100 100 2.60 2.55 2.50 2.45 VCC = 12 V 2.40 2.35 2.30 -50 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) TA, AMBIENT TEMPERATURE (°C) Figure 22. Disable Voltage After Threshold Turn−On (UVLO2) versus Temperature Figure 23. Protection Threshold Level on VOVP versus Temperature 100 3.0 18 Rref = 10 k CT = 820 pF Pin 6 Open PROPAGATION DELAY (μs) VCC prot , PROTECTION LEVEL (V) -25 Figure 20. Startup Threshold Voltage versus Temperature 7.6 17 16.5 16 -50 8.55 TA, AMBIENT TEMPERATURE (°C) 7.8 17.5 VCC Decreasing TA, AMBIENT TEMPERATURE (°C) 8.0 6.8 -50 9.00 8.50 -50 100 VOVP-th, PROTECTION THRESHOLD LEVEL (V) Vstup-th , STARTUP THRESHOLD VOLTAGE (V) MC44603A -25 0 25 50 75 2.5 2.0 1.0 -50 100 VCC = 12 V Rref = 10 k CT = 820 pF 1.5 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) TA, AMBIENT TEMPERATURE (°C) Figure 24. Protection Level on VCC versus Temperature Figure 25. Propagation Delay (VOVP > 2.58 V to Vout Low) versus Temperature http://onsemi.com 11 100 270 VCS-stby , CURRENT SENSE THRESHOLD STANDBY MODE (V) I R P Stby , STANDBY REFERENCE CURRENT (μA) MC44603A 265 260 255 250 VR P Stdby (Pin 12) Voltage Increasing 245 240 235 230 -50 -25 0 25 50 75 100 0.33 0.32 VCC = 12 V Rref = 10 k CT = 820 pF Pin 12 Clamped at 1.0 V 0.31 0.30 -50 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) TA, AMBIENT TEMPERATURE (°C) Figure 26. Standby Reference Current versus Temperature Figure 27. Current Sense Voltage Threshold Standby Mode versus Temperature 100 PIN FUNCTION DESCRIPTION Pin Name 1 VCC This pin is the positive supply of the IC. The operating voltage range after startup is 9.0 to 14.5 V. Description 2 VC The output high state (VOH) is set by the voltage applied to this pin. With a separate connection to the power source, it can reduce the effects of switching noise on the control circuitry. 3 Output 4 GND The ground pin is a single return, typically connected back to the power source; it is used as control and power ground. 5 Foldback Input The foldback function provides overload protection. Feeding the foldback input with a portion of the VCC voltage (1.0 V max) establishes on the system control loop a foldback characteristic allowing a smoother startup and sharper overload protection. Above 1.0 V the foldback input is inactive. 6 Overvoltage Protection 7 Current Sense Input A voltage proportional to the current flowing into the power switch is connected to this input. The PWM latch uses this information to terminate the conduction of the output buffer when working in a current mode of operation. A maximum level of 1.0 V allows either current or voltage mode operation. 8 Demagnetization Detection A voltage delivered by an auxiliary transformer winding provides to the demagnetization pin an indication of the magnetization state of the flyback transformer. A zero voltage detection corresponds to complete core saturation. The demagnetization detection ensures a discontinuous mode of operation. This function can be inhibited by connecting Pin 8 to GND. 9 Synchronization Input The synchronization input pin can be activated with either a negative pulse going from a level between 0.7 V and 3.7 V to GND or a positive pulse going from a level between 0.7 V and 3.7 V up to a level higher than 3.7 V. The oscillator runs free when Pin 9 is connected to GND. 10 CT 11 Soft−Start/Dmax/ Voltage−Mode 12 RP Standby 13 E/A Out 14 Voltage Feedback This is the inverting input of the Error Amplifier. It can be connected to the switching power supply output through an optical (or other) feedback loop. 15 RF Standby The reduced frequency or standby frequency programming is made by the RF Standby resistance choice. 16 Rref Peak currents up to 750 mA can be sourced or sunk, suitable for driving either MOSFET or Bipolar transistors. This output pin must be shunted by a Schottky diode, 1N5819 or equivalent. When the overvoltage protection pin receives a voltage greater than 17 V, the device is disabled and requires a complete restart sequence. The overvoltage level is programmable. The normal mode oscillator frequency is programmed by the capacitor CT choice together with the Rref resistance value. CT, connected between Pin 10 and GND, generates the oscillator sawtooth. A capacitor, resistor or a voltage source connected to this pin limits the switching duty−cycle. This pin can be used as a voltage mode control input. By connecting Pin 11 to Ground, the MC44603A can be shutdown. A voltage level applied to the RP Standby pin determines the output power level at which the oscillator will turn into the reduced frequency mode of operation (i.e. standby mode). An internal hysteresis comparator allows to return in the normal mode at a higher output power level. The error amplifier output is made available for loop compensation. Rref sets the internal reference current. The internal reference current ranges from 100 A to 500 A. This requires that 5.0 k ≤ Rref ≤ 25 k. http://onsemi.com 12 MC44603A No-Take Over Startup VCC Loop Failure Restart VCC prot Vstup-th >2.0 s Normal Mode Vdisable1 Vdisable2 Vref UVLO1 VPin 11 (Soft-Start) VOVP Out ÏÏ ÏÏÏÏÏÏÏÏ ÏÏ ÏÏÏÏÏÏÏÏ ÏÏ ÏÏÏÏÏÏÏÏ Output ICC 17 mA ÏÏÏ ÏÏÏ ÏÏÏ 0.3 mA Figure 28. Starting Behavior and Overvoltage Management VDemag In Output (Pin 3) VDemag Out VDemag In Demagnetization Management VDemag Out Oscillator Buffer Figure 29. Demagnetization http://onsemi.com 13 Output MC44603A VCC Vstup-th Vdisable1 Vdisable2 Vref UVLO1 VPin 11 (Soft-Start) ÏÏÏ ÏÏÏ Output (Pin 3) ICC 17 mA 0.3 mA Figure 30. Switching Off Behavior 3.6 V VCT 1.6 V 1.0 V VStby VDemag Out VOSC VOSC prot VDemag Out VOSC prot Synchronization Input Oscillator CT VStby Figure 31. Oscillator http://onsemi.com 14 VOSC MC44603A Vref VCSS + 1.6 V Internal Clamp Soft-Start External Clamp VCT 3.6 V VCT low 1.6 V VOSC Output (Pin 3) Figure 32. Soft−Start & Dmax OPERATING DESCRIPTION Error Amplifier + A fully compensated Error Amplifier with access to the inverting input and output is provided. It features a typical DC voltage gain of 70 dB. The noninverting input is internally biased at 2.5 V and is not pinned out. The converter output voltage is typically divided down and monitored by the inverting input. The maximum input bias current with the inverting input at 2.5 V is −2.0 A. This can cause an output voltage error that is equal to the product of the input bias current and the equivalent input divider source resistance. The Error Amp output (Pin 13) is provided for external loop compensation. The output voltage is offset by two diode drops (≈ 1.4 V) and divided by three before it connects to the inverting input of the Current Sense Comparator. This guarantees that no drive pulses appear at the Output (Pin 3) when Pin 13 is at its lowest state (VOL). The Error Amp minimum feedback resistance is limited by the amplifier’s minimum source current (0.2 mA) and the required output voltage (VOH) to reach the current sense comparator’s 1.0 V clamp level: Rf(min) [ 1.0 mA Compensation Error Amplifier 13 RFB Rf Cf 14 2.5 V R Voltage Feedback Input Current Sense Comparator 1.0 V 5 Foldback Input R1 R2 2R GND 4 From Power Supply Output Figure 33. Error Amplifier Compensation Current Sense Comparator and PWM Latch The MC44603A can operate as a current mode controller or as a voltage mode controller. In current mode operation, the MC44603A uses the current sense comparator. The output switch conduction is initiated by the oscillator and terminated when the peak inductor current reaches the threshold level established by the Error Amplifier output 3.0 (1.0 V) ) 1.4 V + 22 k 0.2 mA http://onsemi.com 15 MC44603A (Pin 13). Thus, the error signal controls the peak inductor current on a cycle−by−cycle basis. The Current Sense Comparator PWM Latch ensures that only a single pulse appears at the Source Output during the appropriate oscillator cycle. The inductor current is converted to a voltage by inserting the ground referenced sense resistor RS in series with the power switch Q1. This voltage is monitored by the Current Sense Input (Pin 7) and compared to a level derived from the Error Amp output. The peak inductor current under normal operating conditions is controlled by the voltage at Pin 13 where: Ipk [ the discharge current source has to be higher than the charge current to be able to decrease the CT voltage (refer to Figure 36). This condition is performed, its value being (2.0 Iref) in normal working and (0.4 Iref + 0.5 IF Stby in standby mode). Vref 0.4 Iref CVOS prot VOSC COSC Low V(Pin 13) – 1.4 V 1.6 V 3 RS COSC High 10 The Current Sense Comparator threshold is internally clamped to 1.0 V. Therefore, the maximum peak switch current is: Ipk(max) [ VOSC prot 1.0 V CT CT < 1.6 V Discharge R Q Disch S R Q LOSC S Synchro 3.6 V VDemag Out COSC Regul 1.0 V RS 0 1 1 0 IRegul Vin IDischarge VC UVLO Figure 35. Oscillator 14 VOSC prot R2 VDemag Out Thermal Protection Q1 Vref 3 S R Q R PWM Latch Current Sense Comparator D 1N5819 ICharge 0.4 Iref Current Substrate Sense 7 R3 1.6 V 10 R C COSC Regul 0 RS CT 1 0: Discharge Phase 1: Charge Phase IDischarge Figure 34. Output Totem Pole IRegul Series gate resistor, R2, will dampen any high frequency oscillations caused by the MOSFET input capacitance and any series wiring inductance in the gate−source circuit. Diode D is required if the negative current into the output drive pin exceeds 15 mA. Figure 36. Simplified Block Oscillator Two comparators are used to generate the sawtooth. They compare the CT voltage to the oscillator valley (1.6 V) and peak reference (3.6 V) values. A latch (Ldisch) memorizes the oscillator state. In addition to the charge and discharge cycles, a third state can exist. This phase can be produced when, at the end of the discharge phase, the oscillator has to wait for a synchronization or demagnetization pulse before restarting. During this delay, the CT voltage must remain equal to the oscillator valley value (]1.6 V). So, a third regulated current source IRegul controlled by COSC Regul, is connected to CT in order to perfectly compensate the (0.4 Iref) current source that permanently supplies CT. The maximum duty cycle is 80%. Indeed, the on−time is allowed only during the oscillator capacitor charge. Oscillator The oscillator is a very accurate sawtooth generator that can work either in free mode or in synchronization mode. In this second mode, the oscillator stops in the low state and waits for a demagnetization or a synchronization pulse to start a new charging cycle. • The Sawtooth Generation: In the steady state, the oscillator voltage varies between about 1.6 V and 3.6 V. The sawtooth is obtained by charging and discharging an external capacitor CT (Pin 10), using two distinct current sources = Icharge and Idischarge. In fact, CT is permanently connected to the charging current source (0.4 Iref) and so, http://onsemi.com 16 MC44603A That is why, the MC44603A demagnetization detection consists of a comparator that can compare the auxiliary winding voltage to a reference that is typically equal to 65 mV. Consequently: Tcharge = CT x V/Icharge Tdischarge = CT x V/Idischarge where: Tcharge is the oscillator charge time V is the oscillator peak−to−peak value Icharge is the oscillator charge current and Tdischarge is the oscillator discharge time Idischarge is the oscillator discharge current 0.75 V Zero Current Detection VPin 8 So, as fS = 1 /(Tcharge + Tdischarge) when the Regul arrangement is not activated, the operating frequency can be obtained from the graph in Figure 2. NOTE: The output is disabled by the signal VOSC prot when VCT is lower than 1.0 V (refer to Figure 31). 65 mV -0.33 V On-Time Off-Time Dead-Time Synchronization and Demagnetization Blocks To enable the output, the LOSC latch complementary output must be low. Reset is activated by the Ldisch output during the discharge phase. To restart, the LOSC has to be set (refer to Figure 35). To perform this, the demagnetization signal and the synchronization must be low. • Synchronization: The synchronization block consists of two comparators that compare the synchronization signal (external) to 0.7 and 3.7 V (typical values). The comparators’ outputs are connected to the input of an AND gate so that the final output of the block should be: − high when 0.7 < SYNC < 3.7 V − low in the other cases. As a low level is necessary to enable the output, synchronized low level pulses have to be generated on the output of the synchronization block. If synchronization is not required, the Pin 9 must be connected to the ground. Figure 38. Demagnetization Detection A diode D has been incorporated to clamp the positive applied voltages while an active clamping system limits the negative voltages to typically −0.33 V. This negative clamp level is sufficient to avoid the substrate diode switching on. In addition to the comparator, a latch system has been incorporated in order to keep the demagnetization block output level low as soon as a voltage lower than 65 mV is detected and as long as a new restart is produced (high level on the output) (refer to Figure 39). This process prevents ringing on the signal at Pin 8 from disrupting the demagnetization detection. This results in a very accurate demagnetization detection. The demagnetization block output is also directly connected to the output, disabling it during the demagnetization phase (refer to Figure 34). NOTE: The demagnetization detection can be inhibited by connecting Pin 8 to the ground. 3.7 V Oscillator Sync Oscillator 9 Output Buffer Output Buffer 0.7 V R Q Demag S VCC Figure 37. Synchronization Negative Active Clamping System VDemag Out • Demagnetization: 8 C Dem In flyback applications, a good means to detect magnetic saturation of the transformer core, or demagnetization, consists in using the auxiliary winding voltage. This voltage is: 65 mV D Figure 39. Demagnetization Block − negative during the on−time, − positive during the off−time, − equal to zero for the dead−time with generally some − ringing (refer to Figure 38). Standby • Power Losses in a Classical Flyback Structure http://onsemi.com 17 MC44603A RICL AC Line Also, Clamping Network Vin + V Ipk + CS RS + where RS is the resistor used to measure the power switch current. Thus, the input power is proportional to VCS2 (VCS being the internal current sense comparator input). That is why the standby detection is performed by creating a VCS threshold. An internal current source (0.4 x Iref) sets the threshold level by connecting a resistor to Pin 12. As depicted in Figure 41, the standby comparator noninverting input voltage is typically equal to (3.0 x VCS + VF) while the inverter input value is (VR P Stby + VF). Rstartup VCC MC44603A RS Snubber Figure 40. Power Losses in a Classical Flyback Structure Vref Vref In a classical flyback (as depicted in Figure 40), the standby losses mainly consist of the energy waste due to: − the startup resistor Rstartup − the consumption of the IC and the power − switch control − the inrush current limitation resistor RICL − the switching losses in the power switch − the snubber and clamping network 0.6 Iref 0.4 Iref → Pstartup RP Stby Vref Vref 0 0.25 IF Stby CStby 1 13 0.2 Iref 0 IDischarge IDischarge/2 ERAmpOut 2R Pstartup is nearly constant and is equal to: C. S. Comparator Current Mirror X2 1R ǒ(Vin–VCC)2ńRstartupǓ Vref 1 12 → Pcontrol → PICL → PSW → PSN−CLN 0.8 Iref Oscillator Discharge Current Figure 41. Standby PICL only depends on the current drawn from the mains. Losses can be considered constant. This waste of energy decreases when the standby losses are reduced. Pcontrol increases when the oscillator frequency is increased (each switching requires some energy to turn on the power switch). PSW and PSN−CLN are proportional to the switching frequency. Consequently, standby losses can be minimized by decreasing the switching frequency as much as possible. The MC44603A was designed to operate at a standby frequency lower than the normal working one. • Standby Power Calculations with MC44603A During a switching period, the energy drawn by the transformer during the on−time to be transferred to the output during the off−time, is equal to: The VCS threshold level is typically equal to [(VR P Stby)/3] and if the corresponding power threshold is labelled PthL: PthL + 0.5 x L x 2 ǒVR3.0P RStby Ǔ x fS S And as: VR P Stby + RP Stby x 0.4 x Iref + RR P Stby x 0.4 x RP Stby + 10.6 x RS x Rref Vref x Vref Rref ǸLPxthLfS Thus, when the power drawn by the converter decreases, VCS decreases and when VCS becomes lower than [VCS−th x (VR P Stby)/3], the standby mode is activated. This results in an oscillator discharge current reduction in order to increase the oscillator period and to diminish the switching frequency. As it is represented in Figure 41, the (0.8 x Iref) current source is disconnected and is replaced by a lower value one (0.25 x IF Stby). Where: IF Stby = Vref/RF Stby E + 1 x L x Ipk2 2 where: − L is the transformer primary inductor, − lpk is the inductor peak current. Input power is labelled Pin: Pin + 0.5 x L x Ipk2 x fS where fS is the normal working switching frequency. http://onsemi.com 18 MC44603A In order to prevent undesired mode switching when power is close to the threshold value, a hysteresis that is proportional to VR P Stby is incorporated creating a second VCS threshold level that is equal to [2.5 x (VR P Stby)/3]. When the standby comparator output is high, a second current source (0.6 x Iref) is connected to Pin 12. Finally, the standby mode function can be shown graphically in Figure 42. VCT (Pin 10) Dmax Figure 44. Maximum Duty Cycle Control Using the internal current source (0.4 Iref), the Pin 11 voltage can easily be set by connecting a resistor to this pin. If a capacitor is connected to Pin 11, the voltage increases from 0 to its maximum value progressively (refer to Figure 45), thereby, implementing a soft−start. The soft−start capacitor is discharged internally when the VCC (Pin 1) voltage drops below 9.0 V. Pin fS Normal Working Pin 11 Voltage Pin 11 fStby R Connected to Pin 11 I = 0.4 Iref VZ RI PthH C C // R VZ RI = RC Standby PthL [(VR P Stby)/3] VCS 2.5 x [(VR P Stby)/3] Figure 45. Different Possible Uses of Pin 11 1 Figure 42. Dynamic Mode Change If no external component is connected to Pin 11, an internal zener diode clamps the Pin 11 voltage to a value VZ that is higher than the oscillator peak value, disabling soft−start and maximum duty cycle limitation. This curve shows that there are two power threshold levels: − the low one: PthL fixed by VR P Stby − the high one: Foldback As depicted in Figures 33 and 49, the foldback input (Pin 5) can be used to reduce the maximum VCS value, providing foldback protection. The foldback arrangement is a programmable peak current limitation. If the output load is increased, the required converter peak current becomes higher and VCS increases until it reaches its maximum value (normally, VCS max = 1.0 V). Then, if the output load keeps on increasing, the system is unable to supply enough energy to maintain the output voltages in regulation. Consequently, the decreasing output can be applied to Pin 5, in order to limit the maximum peak current. In this way, the well known foldback characteristic can be obtained (refer to Figure 46). fStby PthH + (2.5)2 x PthL x fS PthH + 6.25 x PthL x fStby fS Maximum Duty Cycle and Soft−Start Control Maximum duty cycle can be limited to values less than 80% by utilizing the Dmax and soft−start control. As depicted in Figure 43, the Pin 11 voltage is compared to the oscillator sawtooth. Vref Output Control 0.4 Iref 11 DZ Soft-Start Capacitor 2.4 V CDmax Dmax Output Drive VOSC Oscillator Figure 43. Dmax and Soft−Start http://onsemi.com 19 MC44603A Vref Ipk max Vout VCC VO Nominal Out Delay T New Startup Sequence Initiated 0 VOVP VCC Vdisable2 External Resistor Iout Overload 5.0 s In 2.5 V 11.6 k Enable 2.0 k COVLO 2.5 V (Vref) Figure 46. Foldback Characteristic In τ Overvoltage Protection The overvoltage arrangement consists of a comparator that compares the Pin 6 voltage to Vref (2.5 V) (refer to Figure 47). If no external component is connected to Pin 6, the comparator noninverting input voltage is nearly equal to: ǒ11.6 k2.0)k2.0 k Ǔ x VCC The comparator output is high when: 2.0 k x VCC w 2.5 V 11.6 k ) 2.0 k Ǔ à VCC w 17 V A delay latch (2.0 s) is incorporated in order to sense overvoltages that last at least 2.0 s. If this condition is achieved, VOVP out, the delay latch output, becomes high. As this level is brought back to the input through an OR gate, VOVP out remains high (disabling the IC output) until Vref is disabled. Consequently, when an overvoltage longer than 2.0 s is detected, the output is disabled until VCC is removed and then re−applied. The VCC is connected after Vref has reached steady state in order to limit the circuit startup consumption. The overvoltage section is enabled 5.0 s after the regulator has started to allow the reference Vref to stabilize. By connecting an external resistor to Pin 6, the threshold VCC level can be changed. http://onsemi.com 20 VOVP out Out Delay 2.0 s (If VOVP out = 1.0, the Output is Disabled) Figure 47. Overvoltage Protection NOTE: Foldback is disabled by connecting Pin 5 to VCC. ǒ 6 τ MC44603A Undervoltage Lockout Section RF Stby VCC Rref Pin 15 Vref enable This block particularly, produces Vref (Pin 16 voltage) and Iref that is determined by the resistor Rref connected between Pin 16 and the ground: V Iref + ref where Vref + 2.5 V (typically) Rref Pin 16 Another resistor is connected to the Reference Block: RF Stby that is used to fix the standby frequency. In addition to this, VCC is compared to a second threshold level that is nearly equal to 9.0 V (Vdisable1). UVLO1 is generated to reset the maximum duty cycle and soft−start block disabling the output stage as soon as VCC becomes lower than Vdisable1. In this way, the circuit is reset and made ready for the next startup, before the reference block is disabled (refer to Figure 30). Finally, the upper limit for the minimum normal operating voltage is 9.4 V (maximum value of Vdisable1) and so the minimum hysteresis is 4.2 V. ((Vstup−th) min = 13.6 V). The large hysteresis and the low startup current of the MC44603A make it ideally suited for off−line converter applications where efficient bootstrap startup techniques are required. Cstartup 1 1 1 0 Vdisable2 7.5 V CUVLO1 0 Reference Block: Voltage and Current Sources Generator (Vref, Iref, ...) Startup 14.5 V UVLO1 (to Soft-Start) Vdisable1 9.0 V Figure 48. VCC Management As depicted in Figure 48, an undervoltage lockout has been incorporated to guarantee that the IC is fully functional before allowing system operation. http://onsemi.com 21 MC44603A 185 VAC to 270 VAC RFI Filter R1 1.0/5.0 W C3 1.0 nF/1.0 kV C4 ... C7 1.0 nF/1000 V R3 4.7 M D1 ... D4 1N4007 C1 220 F C2 220 F Sync C16 100 pF 9 R12 27 k 8 C9 1.0 nF 10 7 11 6 12 R15 5.6 k C11 1.0 nF R15 22 k 13 MC44603AP C10 1.0 F 5 R9 1.0 k C15 1.0 nF D8 MR856 D7 M856 L1 1.0 H 15 2 D6 1N4148 R5 1.2 k Laux D9 MR852 Lp C27 1000 F 16 D10 MR852 MTP6N60E R26 1.0 k C18 2.2 nF D12 MR856 C25 1000 F R19 10 k C24 0.1 F C23 220 pF 7.0 V/2.0 A 1 R12 22 R18 27 k C28 0.1 F 14 V/2.0 A R6 150 R8 15 k R11 39 R17 22 k C31 0.1 F C26 220 pF R7 180 k R10 10 C33 100 F 30 V/2.0 A C14 4.7 nF *D15 1N5819 3 C30 100 F 150 V/0.6 A C29 220 pF 4 14 L2 22.5 H C32 220 pF C17 47 nF D5 1N4934 R2 68 k/2.0 W C8 2.2 nF R20 22 k 5.0 W R14 0.2 C13 100 nF D11 MR852 R13 1.0 k C21 1000 F C22 0.1 F R24 270 R23 147.5 k MOC8101 R21 10 k C19 100 nF D14 1N4733 C20 33 nF R25 1.0 k TL431 C12 6.8 nF R22 2.5 k * Diode D15 is required if the negative current into the output pin exceeds 15 mA. Figure 49. 250 W Input Power Off−Line Flyback Converter with MOSFET Switch http://onsemi.com 22 MC44603A 250 W Input Power Fly−Back Converter 185 V − 270 V Mains Range MC44603AP & MTP6N60E Tests Conditions Line Regulation Results Vin = 185 VAC to 270 VAC Fmains = 50 Hz Iout = 0.6 A Iout = 2.0 A Iout = 2.0 A Iout = 2.0 A 10 mV 10 mV 10 mV 20 mV Load Regulation 150 V Vin = 220 VAC Iout = 0.3 A to 0.6 A 50 mV Cross Regulation Vin = 220 VAC Iout (150 V) = 0.6 A Iout (30 V) = 0 A to 2.0 A Iout (14 V) = 2.0 A Iout (7.0 V) = 2.0 A 150 V 130 V 114 V 7.0 V 150 V < 1.0 mV Efficiency Vin = 220 VAC, Pin = 250 W 81% Standby Mode P input Vin = 220 VAC, Pout = 0 W 3.3 W Switching Frequency 20 kHz fully stable Output Short Circuit Pout (max) = 270 W Safe on all outputs Startup Pin = 250 W VAC = 160 V DEVICE ORDERING INFORMATION Device MC44603ADWR2G Operating Temperature Range Package Shipping† TA = −25°C to +85°C SOIC−16 (Pb−Free) 1000 / Tape & Reel †For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specifications Brochure, BRD8011/D. http://onsemi.com 23 MC44603A PACKAGE DIMENSIONS PDIP−16 CASE 648−08 ISSUE T NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: INCH. 3. DIMENSION L TO CENTER OF LEADS WHEN FORMED PARALLEL. 4. DIMENSION B DOES NOT INCLUDE MOLD FLASH. 5. ROUNDED CORNERS OPTIONAL. −A− 16 9 1 8 B F C DIM A B C D F G H J K L M S L S −T− H SEATING PLANE K G D M J 16 PL 0.25 (0.010) T A M M INCHES MIN MAX 0.740 0.770 0.250 0.270 0.145 0.175 0.015 0.021 0.040 0.70 0.100 BSC 0.050 BSC 0.008 0.015 0.110 0.130 0.295 0.305 0_ 10 _ 0.020 0.040 MILLIMETERS MIN MAX 18.80 19.55 6.35 6.85 3.69 4.44 0.39 0.53 1.02 1.77 2.54 BSC 1.27 BSC 0.21 0.38 2.80 3.30 7.50 7.74 0_ 10 _ 0.51 1.01 SOIC−16WB CASE 751G−03 ISSUE C A D 9 h X 45 _ E 0.25 H 8X M B M 16 q 1 NOTES: 1. DIMENSIONS ARE IN MILLIMETERS. 2. INTERPRET DIMENSIONS AND TOLERANCES PER ASME Y14.5M, 1994. 3. DIMENSIONS D AND E DO NOT INLCUDE MOLD PROTRUSION. 4. MAXIMUM MOLD PROTRUSION 0.15 PER SIDE. 5. DIMENSION B DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLE DAMBAR PROTRUSION SHALL BE 0.13 TOTAL IN EXCESS OF THE B DIMENSION AT MAXIMUM MATERIAL CONDITION. MILLIMETERS DIM MIN MAX A 2.35 2.65 A1 0.10 0.25 B 0.35 0.49 C 0.23 0.32 D 10.15 10.45 E 7.40 7.60 e 1.27 BSC H 10.05 10.55 h 0.25 0.75 L 0.50 0.90 q 0_ 7_ 8 16X M 14X e T A S B S A1 L A 0.25 B B SEATING PLANE T C GreenLine is a trademark of Motorola, Inc. ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC 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. “Typical” parameters which may be provided in SCILLC 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. SCILLC does not convey any license under its patent rights nor the rights of others. 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This literature is subject to all applicable copyright laws and is not for resale in any manner. PUBLICATION ORDERING INFORMATION LITERATURE FULFILLMENT: Literature Distribution Center for ON Semiconductor P.O. Box 5163, Denver, Colorado 80217 USA Phone: 303−675−2175 or 800−344−3860 Toll Free USA/Canada Fax: 303−675−2176 or 800−344−3867 Toll Free USA/Canada Email: [email protected] N. American Technical Support: 800−282−9855 Toll Free USA/Canada Europe, Middle East and Africa Technical Support: Phone: 421 33 790 2910 Japan Customer Focus Center Phone: 81−3−5773−3850 http://onsemi.com 24 ON Semiconductor Website: www.onsemi.com Order Literature: http://www.onsemi.com/orderlit For additional information, please contact your local Sales Representative MC44603A/D