| 品牌:ALLEGRO MICROSYSTEMS | 型号:NCP1631DR2G | 功率:10W |
PWM Current?Mode Controller for Free Running Quasi?Resonant Operation TheNCP1337 combines a true current mode modulator and a demagnetization detector which ensures full Borderline/Critical Conduction Mode in any load/line conditions together with minimum drain voltage switching (Quasi?Resonant operation). The transformer core reset detection is done internally, without using any external signal, due to the Soxyless concept. The frequency is internally limited to 130 kHz, preventing the controller to operate above the 150 kHz CISPR?22 EMI starting limit. By monitoring the feedback pin activity, the controller enters ripple mode as soon as the power demand falls below a predetermined level. As each restart is softened by an internal soft?start, and as the frequency cannot go below 25 kHz, no audible noise can be heard. The NCP1337 also features an efficient protective circuitry which, in presence of an overcurrent condition, disables the output pulses and enters a safe burst mode, trying to restart. Once the default has gone, the device auto?recovers. Also included is a bulk voltage monitoring function (known as brown?out protection), an adjustable overpower compensation, and a VCC OVP. Finally, an internal 4.0 ms soft?start eliminates the traditional startup stress. Features MARKING DIAGRAM PDIP?7 P SUFFIX CASE 626B 1 8 SOIC?7 D SUFFIX CASE 751U P1337 AYWW G 1 NCP1337P AWL YYWWG ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? Free?Running Borderline/Critical Mode Quasi?Resonant Operation Current?Mode Soft Ripple Mode with Minimum Switching Frequency for Standby Auto?Recovery Short?Circuit Protection Independent of Auxiliary Voltage Overvoltage Protection Brown?Out Protection Two Externally Triggerable Fault Comparators (one for a disable function, and the other for a permanent latch) Internal 4.0 ms Soft?Start 500 mA Peak Current Drive Sink Capability 130 kHz Max Frequency Internal Leading Edge Blanking Internal Temperature Shutdown Direct Optocoupler Connection Dynamic Self?Supply with Levels of 12 V (On) and 10 V (Off) SPICE Models Available for TRANsient and AC Analysis These are Pb?Free Devices* AC?DC Adapters for Notebooks, etc. Offline Battery Chargers Consumer Electronics (DVD Players, Set?Top Boxes, TVs, etc.) Auxiliary Power Supplies (USB, Appliances, TVs, etc.) A WL Y, YY WW G G = Assembly Location = Wafer Lot = Year = Work Week = Pb?Free Package = Pb?Free Package PIN CONNECTIONS BO FB CS GND 4 (Top View) 5 1 2 3 6 VCC DRV 8 HV ORDERING INFORMATION Device NCP1337PG NCP1337DR2GPackage PDIP?7 (Pb?Free) SOIC?7 (Pb?Free) Shipping? 50 Units/Tube 2500 Tape & Reel Typical Applications ?For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specification Brochure, BRD8011/D. *For additional information on our Pb?Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. ? Semiconductor Components Industries, LLC, 2006 1 July, 2006 ? Rev. 2 Publication Order Number: NCP1337/D 元器件交易网 NCP1337 PIN FUNCTION DESCRIPTION Pin No. 1 Symbol BO Function Brown?out and external triggering Description ? ? ? By connecting this pin to the input voltage through a resistor divider, the controller ensures operation at a safe mains level. If an external event brings this pin above 3.0 V, the controller’s output is disabled. If an external event brings this pin above 5.0 V, the controller is permanently latched?off. By connecting an optocoupler or an auxiliary winding to this pin, the peak current setpoint is adjusted accordingly to the output power demand. When the requested peak current setpoint is below the internal standby level, the device enters soft ripple mode. This pin senses the primary current and routes it to the internal comparator via an L.E.B. Inserting a resistor in series with the pin allows to control the overpower compensation level. 2 FB Sets the peak current setpoint ? ? 3 CS Current sense input and overpower compensation adjustment ? ? ? ? ? ? 4 5 6 GND DRV VCC IC ground Output driver IC supply To be connected to an external MOSFET. Connected to a tank capacitor (and possibly an auxiliary winding). When VCC reaches 18.6 V, an internal OVP stops the output pulses. Connected to the high?voltage rail, this pin injects a constant current into the VCC bulk capacitor and ensures a clean lossless startup sequence. 8 HV High?voltage pin VOUT NCP1337 BO 1 + Cbulk 2 3 4 6 5 VCC Rcomp 8 + VCC + Figure 1. Typical Application Schematic 2 元器件交易网 NCP1337 ? + + 3V BO + 5V S R Q PERM. LATCH Vdd VCC < 4 V TSD 8 ms timeout 35 ms max Toff Toff 5.5 ms blanking Ton VCC Q Q Toff R1 R2 Inhib Soxyless demag detection + ? DISABLE Vdd 10 mA TSD S Startup Soxyless Ton 7.5 ms min period SStart Clk D VBO + 500 mV + ? BOK DRV OVP Vdd 130 mV FB 3V 20 kHz Low?pass filter 100 mV + ? + Skip SSkip Ton 67 ms max Ton Soxyless Setpoint ? + TSD CS comp. PERM. LATCH SSkip 12 V 10 V 5V HV + + ? 9.5 mA or 600 mA VCC 500 mV Vdd VBO FAULT if Zener activated 300 ms Soft?Skip t FAULT Management* 70 mA x VBO ? 35 mA 4 ms soft?start SStart OVP ? + + 18.6 V CS Ton 4k 350 ns LEB 2p FAULT (*If FAULT duration > 80 ms = > STOP Restart when 2nd time VCC = VCCon) GND Figure 2. Internal Circuit Architecture 3 元器件交易网 NCP1337 MAXIMUM RATINGS Rating Voltage on Pin 8 (HV) when Pin 6 (VCC) is Decoupled to Ground with 10 mF Maximum Current in Pin 8 (HV) Power Supply Voltage, Pin 6 (VCC) and Pin 5 (DRV) Maximum Current in Pin 6 (VCC) Maximum Voltage on all Pins except Pin 8 (HV), Pin 6 (VCC) and Pin 5 (DRV) Maximum Current into all Pins except Pin 8 (HV), Pin 6 (VCC) and Pin 5 (DRV) Maximum Current into Pin 6 (DRV) during ON Time and TBLANK Maximum Current into Pin 6 (DRV) after TBLANK during OFF Time Thermal Resistance, Junction?to?Case Thermal Resistance, Junction?to?Air, SOIC Version Thermal Resistance, Junction?to?Air, DIP Version Maximum Junction Temperature Operating Temperature Range Storage Temperature Range ESD Capability, HBM Model per Mil?std?883, Method 3015 (All Pins except HV) ESD Capability, Machine Model Symbol VHV ? VCCmax ? ? ? ? ? RqJC RqJA RqJA TJMAX ? ? ? ? Value ?0.3 to 500 20 ?0.3 to 20 "30 ?0.3 to 10 "10 "1.0 "15 57 178 100 150 ?40 to +125 ?60 to +150 2.0 200 Unit V mA V mA V mA A mA °C/W °C/W °C/W °C °C °C kV V 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. This device contains latchup protection and exceeds 100 mA per JEDEC standard JESD78. 4 元器件交易网 NCP1337 ELECTRICAL CHARACTERISTICS (For typical values TJ = 25°C, for min/max values TJ = 0°C to +125°C, Max TJ = 150°C, VCC = 11 V, unless otherwise noted.) Characteristic SUPPLY SECTION VCC Increasing Level at which the Controller Starts VCC Decreasing Level at which the Controller Stops Protection Mode is Activated if VCC reaches this Level whereas the HV Current Source is ON VCC Decreasing Level at which the Latch?Off Phase Ends Margin between VCC Level at which Latch Fault is Released and VCCLATCH VCC Increasing Level at which the Controller Enters Protection Mode VCC Level below which HV Current Source is Reduced Internal IC Consumption, No Output Load on Pin 5, FSW = 60 kHz Internal IC Consumption, 1.0 nF Output Load on Pin 5, FSW = 60 kHz Internal IC Consumption, Latch?Off Phase, VCC = 8.0 V Internal IC Consumption in Skip INTERNAL STARTUP CURRENT SOURCE Minimum Guaranteed Startup Voltage on HV Pin High?Voltage Current Source when VCC > VCCINHIB (VCC = 10.5 V, VHV = 60 V) High?Voltage Current Source when VCC < VCCINHIB (VCC = 0 V, VHV = 60 V) Leakage Current Flowing when the HV Current Source is OFF (VCC = 17 V, VHV = 500 V) DRIVE OUTPUT Output Voltage Rise?Time @ CL = 1.0 nF, 10?90% of Output Signal Output Voltage Fall?Time @ CL = 1.0 nF, 10?90% of Output Signal Source Resistance Sink Resistance TEMPERATURE SHUTDOWN Temperature Shutdown Hysteresis on Temperature Shutdown CURRENT COMPARATOR Maximum Internal Current Setpoint (@ IFB = IFB***) Minimum Internal Current Setpoint (@ IFB = IFBrippleIN) Internal Current Setpoint for IFB = IFBrippleOUT Propagation Delay from Current Detection to Gate OFF State Leading Edge Blanking Duration Internal Current Offset Injected on the CS Pin during ON Time (Over Power Compensation) @ 1.0 V on Pin 1 and Vpin3 = 0.5 V @ 2.0 V on Pin 1 and Vpin3 = 0.5 V Maximum ON Time 3 3 3 3 3 3 VCSLimit VCSrippleIN VCSrippleOUT TDEL TLEB IOPC ? ? 5 MaxTON 52 35 105 67 ? ? 82 ms 475 ? ? ? ? 500 100 130 120 350 525 ? ? 150 ? mV mV mV ns ns mA ? ? TSD ? 130 ? ? 30 ? ? °C °C 5 5 5 5 TR TF ROH ROL ? ? ? ? 50 20 20 8.0 ? ? ? ? ns ns W W 8 8 8 8 VHVmin IC1 IC2 IHVLeak ? 5.5 0.3 ? ? 9.5 0.6 ? 55 15 1.1 90 V mA mA mA 6 6 6 6 ? 6 6 6 6 6 6 VCCON VCCMIN VCCOFF VCCLATCH VMARGIN VCCOVP VCCINHIB ICC1 ICC2 ICC3 ICCLOW 11 9.0 ? 3.6 0.3 17.6 ? ? ? ? ? 12 10 9.0 5.0 ? 18.6 1.5 1.2 2.0 600 600 13 11 ? 6.0 ? 19.6 ? ? ? ? ? V V V V V V V mA mA mA mA Pin Symbol Min Typ Max Unit 5 元器件交易网 NCP1337 ELECTRICAL CHARACTERISTICS (continued) (For typical values TJ = 25°C, for min/max values TJ = 0°C to +125°C, Max TJ = 150°C, VCC = 11 V, unless otherwise noted.) Characteristic FEEDBACK SECTION FB Current under which FAULT is Detected FB Current for which Internal Setpoint is *** FB Current above which DRV Pulses are Stopped FB Current under which DRV Pulses are Reauthorized after having reached IFBrippleIN FB Current above which FB Pin Voltage is not Regulated anymore FB Pin Voltage when IFBopen < IFB < IFBregMax Duration before Entering Protection Mode after FAULT Detection Internal Soft?Start Duration (Up to VCSLimit) Internal Soft?Skip Duration (Up to VCSLimit) BROWN?OUT AND LATCH SECTION Brown?Out Detection Level Current Flowing out of Pin 1 when Brown?Out Comparator has Toggled Vpin1 Threshold that Disables the Output Vpin1 Threshold that Activates the Permanent Latch DEMAGNETIZATION DETECTION BLOCK Current Threshold for Demagnetization Detection Max Voltage on DRV Pin During OFF Time after TBLANK (when Sinking 15 mA) Min Voltage on DRV Pin During OFF Time after TBLANK (when Sourcing 15 mA) Propagation Delay from Demag Detection to Gate ON State (IGATE Slope of 500 A/s) Blanking Window after Gate OFF State before Detecting Demagnetization Timeout on Demag Signal Maximum OFF Time Minimum Switching Period 5 5 5 5 5 5 5 5 ISOXYth VDRVlowMAX VDRVlowMIN TDMG TBLANK TOUT MaxTOFF MinPeriod ? ? ?0.6 ? ? ? ? 6.8 210 ? ? 180 5.5 8.0 35 7.7 ? 1.5 ? 220 ? ? 42 8.5 mA V V ns ms ms ms ms 1 1 1 1 VBO IBO VDISABLE VLATCH 460 ? 2.8 4.75 500 10 3.0 5.0 540 ? 3.3 5.25 mV mA V V 2 2 2 2 2 2 ? ? ? IFBopen IFB*** IFBrippleIN IFBrippleOUT IFBregMax VFB TFAULT TSS TSSkip ? ? ? ? ? 2.8 ? ? ? 40 50 220 205 500 3.0 80 4.0 300 ? ? ? ? ? 3.2 ? ? ? mA mA mA mA mA V ms ms ms Pin Symbol Min Typ Max Unit 6 元器件交易网 NCP1337 APPLICATION INFORMATION INTRODUCTION TheNCP1337 implements a standard current mode architecture where the switch?off time is dictated by the peak current setpoint, whereas the core?reset detection triggers the turn?on event. This component represents the ideal candidate where low part?count is the key parameter, particularly in low?cost AC?DC adapters, consumer electronics, auxiliary supplies, etc. Due to its high?performance, high?voltage technology, the NCP1337 incorporates all the necessary features needed to build a rugged and reliable Switch?Mode Power Supply (SMPS): ? Quasi?Resonant Operation: Valley?switching operation is ensured whatever the operating conditions are, due to the internal soxyless circuitry. As a result, there are virtually no primary switch turn?on losses, and no secondary diode recovery losses, and EMI and video noise perturbations are reduced. The converter also stays a first?order system and accordingly eases the feedback loop design. ? Dynamic Self?Supply (DSS): Due to its Very High Voltage Integrated Circuit (VHVIC) technology, ON Semiconductor’s NCP1337 allows for a direct pin connection to the high?voltage DC rail. A dynamic current source charges up a capacitor and thus provides a fully independent VCC level. As a result, low power applications will not require any auxiliary winding to supply the controller. In applications where this winding is anyway required (see “Power Dissipation” section in the application note), the DSS will simplify the VCC capacitor selection. ? Overcurrent Protection (OCP): When the feedback current is below minimum value, a fault is detected. If this fault is present for more than 80 ms, NCP1337 enters an auto?recovery soft burst mode. All pulses are stopped and the VCC capacitor discharges down to 5.0 V. Then, by monitoring the VCC level, the startup current source is activated ON and OFF to create a burst mode. After the current source being activated twice, the controller tries to restart, with a 4.0 ms soft?start. If the fault has gone, the SMPS resumes operation. If the fault is still there, the burst sequence starts again. The soft?start, together with a minimum frequency clamp, allow to reduce the noise generated in the transformer in short?circuit conditions. Overvoltage Protection (OVP): By continuously monitoring the VCC voltage level, the NCP1337 stops switching whenever an overvoltage condition is detected. Brown?Out Detection (BO): By monitoring the level on Pin 1 during normal operation, the controller protects the SMPS against low mains condition. When Pin 1 level falls below 500 mV, the controller stops pulsing until this level goes back and resumes operation. By adjusting the resistor divider connected between the high input voltage and this pin, start and stop levels are programmable. Over Power Compensation (OPC): An internal current source injects out of Pin 3 (CS pin) a current proportional to the voltage applied on Pin 1. As this voltage is an image of the input voltage, by inserting a resistor in series with Pin 3, it is possible to create an offset on the current sense signal that will compensate the effect of the input voltage variation. External Latch Trip Point: By externally forcing a level on Pin 1 (e.g., with a signal coming from a temperature sensor) greater than 3.0 V (but below 5.0 V),
