NCP43080 Product Preview Synchronous Rectifier Controller The NCP43080 is a synchronous rectifier controller for switch mode power supplies. The controller enables high efficiency designs for flyback and quasi resonant flyback topologies. Externally adjustable minimum off−time and on−time blanking periods provides flexibility to drive various MOSFET package types and PCB layout. A reliable and noise less operation of the SR system is insured due to the Self Synchronization feature. The NCP43080 also utilizes Kelvin connection of the driver to the MOSFET to achieve high efficiency operation at full load and utilizes a light load detection architecture to achieve high efficiency at light load. The precise turn−off threshold, extremely low turn−off delay time and high sink current capability of the driver allow the maximum synchronous rectification MOSFET conduction time. The high accuracy driver and 5 V gate clamp make it ideally suited for directly driving GaN devices. Features www.onsemi.com 8 1 SOIC−8 D SUFFIX CASE 751 MARKING DIAGRAMS 8 43080x ALYW G G 1 1 DFN8 MN SUFFIX CASE 488AF 43080x ALYWG G • Self−Contained Control of Synchronous Rectifier in CCM, DCM and • • • • • • • • • • • • • • • QR for Flyback, Forward or LLC Applications Precise True Secondary Zero Current Detection Rugged Current Sense Pin (up to 150 V) Adjustable Minimum ON−Time Adjustable Minimum OFF-Time with Ringing Detection Adjustable Maximum ON−Time for CCM Controlling of Primary QR Controller Improved Robust Self Synchronization Capability 8 A / 4 A Peak Current Sink / Source Drive Capability Operating Voltage Range up to VCC = 35 V Automatic Light−load & Disable Mode Adaptive Gate Drive Clamp GaN Transistor Driving Capability (options A and C) Low Startup and Disable Current Consumption Maximum Operation Frequency up to 1 MHz SOIC-8 and DFN−8 (4x4) and WDFN8 (2x2) Packages These are Pb−Free Devices 1 WDFN8 MT SUFFIX CASE 511AT FxMG G 43080x = Specific Device Code x = A, B, C, D or Q Fx = Specific Device Code x = A, 2, C, D or Q A = Assembly Location L = Wafer Lot Y = Year W = Work Week M = Date Code G = Pb−Free Package (Note: Microdot may be in either location) ORDERING INFORMATION See detailed ordering and shipping information on page 33 of this data sheet. Typical Applications • • • • Notebook Adapters High Power Density AC/DC Power Supplies (Cell Phone Chargers) LCD TVs All SMPS with High Efficiency Requirements This document contains information on a product under development. ON Semiconductor reserves the right to change or discontinue this product without notice. © Semiconductor Components Industries, LLC, 2015 November, 2015 − Rev. P0 1 Publication Order Number: NCP43080/D MIN_TON MIN_TOFF NCP43080 RTN D1 MIN_TON MIN_TOFF OK1 Figure 1. Typical Application Example − LLC Converter with Optional LLD +Vout + Vbulk TR1 R1 C1 C6 R7 C7 + C2 C5 R6 D3 R5 + VCC FLYBACK M2 D4 D6 C3 CONTROL GND CIRCUITRY FB C4 DRV M1 CS R2 R3 R4 D5 R8 OK1 Figure 2. Typical Application Example − DCM, CCM or QR Flyback Converter with optional LLD www.onsemi.com 2 NCP43080 +Vout + Vbulk TR1 R1 C1 + R3 R4 R9 VCC SIDE M2 D4 + PRIMARY C4 C10 R10 D3 ZCD C9 R11 C8 C2 D6 C3 GND FLYBACK CONTROLLER C7 DRV M1 R7 COMP CS R2 R6 R5 C5 R8 C6 Figure 3. Typical Application Example − Primary Side Flyback Converter with optional LLD + Vbulk R18 TR1 R5 C1 C8 R13 R14 C2 C9 + R17 D3 D8 R12 C7 + VCC QR CONTROL CIRCUITRY ZCD C4 DRV FB CS M3 D4 D7 GND D1 R1 +Vout C5 M1 R15 R9 R10 R6 R7 R19 OK1 C3 M2 NCP43080Q D5 R16 R11 D6 TR2 C6 Figure 4. Typical Application Example − QR Converter − Capability to Force Primary into CCM Under Heavy Loads utilizing MAX−TON www.onsemi.com 3 NCP43080 PIN FUNCTION DESCRIPTION ver. A, B, C, D ver. Q Pin Name 1 1 VCC 2 2 MIN_TOFF Adjust the minimum off time period by connecting resistor to ground. 3 3 MIN_TON Adjust the minimum on time period by connecting resistor to ground. 4 4 LLD This input modulates the driver clamp level and/or turns the driver off during light load conditions. 5 − NC Leave this pin opened or tie it to ground. 6 6 CS Current sense pin detects if the current flows through the SR MOSFET and/or its body diode. Basic turn−off detection threshold is 0 mV. A resistor in series with this pin can decrease the turn off threshold if needed. 7 7 GND Ground connection for the SR MOSFET driver, VCC decoupling capacitor and for minimum on and off time adjust resistors and LLD input. GND pin should be wired directly to the SR MOSFET source terminal/soldering point using Kelvin connection. DFN8 exposed flag should be connected to GND 8 8 DRV Driver output for the SR MOSFET − 5 MAX_TON MIN_TON Description Supply voltage pin Adjust the maximum on time period by connecting resistor to ground. ELAPSED ADJ DISABLE Minimum ON time generator EN Disable detection & V DRV clamp modulation LLD V_DRV control VDD 100μA CS CS_ON CS detection DRIVER DRV Out DRV CS_OFF Control logic CS_RESET VDD RESET MIN_TOFF ADJ Minimum OFF time generator ELAPSED DISABLE EN VCC managment UVLO VCC GND NC Figure 5. Internal Circuit Architecture − NCP43080A, B, C, D www.onsemi.com 4 NCP43080 ELAPSED MIN_TON ADJ DISABLE Minimum ON time generator EN Disable detection & V DRV clamp modulation LLD V_DRV control VDD 100mA CS CS_ON CS detection DRIVER DRV Out DRV CS_OFF Control logic CS_RESET VDD RESET MIN_TOFF ADJ Minimum OFF time generator ELAPSED EN DISABLE VCC managment UVLO VCC ELAPSED MAX_TON ADJ Maximum ON time generator GND EN Figure 6. Internal Circuit Architecture − NCP43080Q (CCM QR) with MAX_TON www.onsemi.com 5 NCP43080 ABSOLUTE MAXIMUM RATINGS Rating Symbol Value Unit VCC −0.3 to 37.0 V VMIN_TON, VMIN_TOFF, VMAX_TON, VLLD −0.3 to VCC V VDRV −0.3 to 17.0 V Supply Voltage MIN_TON, MIN_TOFF, MAX_TON, LLD Input Voltage Driver Output Voltage Current Sense Input Voltage VCS −4 to 150 V Current Sense Dynamic Input Voltage (tPW = 200 ns) VCS_DYN −10 to 150 V MIN_TON, MIN_TOFF, MAX_TON, LLD Input Current IMIN_TON, IMIN_TOFF, IMAX_TON, ILLD −10 to 10 mA Junction to Air Thermal Resistance, 1 oz 1 in2 Copper Area, SOIC8 RqJ−A_SOIC8 160 °C/W Junction to Air Thermal Resistance, 1 oz 1 in2 Copper Area, DFN8 RqJ−A_DFN8 80 °C/W RqJ−A_WDFN8 160 °C/W Maximum Junction Temperature TJMAX 150 °C Storage Temperature TSTG −60 to 150 °C ESD Capability, Human Body Model, Except Pin 6, per JESD22−A114E ESDHBM 2000 V ESD Capability, Human Body Model, Pin 6, per JESD22−A114E ESDHBM 1000 V ESD Capability, Machine Model, per JESD22−A115−A ESDMM 200 V ESD Capability, Charged Device Model, Except Pin 6, per JESD22−C101F ESDCDM 750 V ESD Capability, Charged Device Model, Pin 6, per JESD22−C101F ESDCDM 250 V Junction to Air Thermal Resistance, 1 oz 1 in2 Copper Area, WDFN8 Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality should not be assumed, damage may occur and reliability may be affected. 1. This device meets latch−up tests defined by JEDEC Standard JESD78D Class I. RECOMMENDED OPERATING CONDITIONS Parameter Symbol Maximum Operating Input Voltage Min VCC Operating Junction Temperature TJ −40 Max Unit 35 V 125 °C Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond the Recommended Operating Ranges limits may affect device reliability. ELECTRICAL CHARACTERISTICS −40°C ≤ TJ ≤ 125°C; VCC = 12 V; CDRV = 0 nF; RMIN_TON = RMIN_TOFF = 10 kW; VLLD = 0 V; VCS = −1 to +4 V; fCS = 100 kHz, DCCS = 50%, unless otherwise noted. Typical values are at TJ = +25°C Parameter Test Conditions Symbol Min Typ Max Unit VCC rising VCCON 8.3 8.8 9.3 V VCC falling VCCOFF 7.3 7.8 8.3 SUPPLY SECTION VCC UVLO (ver. B & C) VCC UVLO Hysteresis (ver. B & C) VCC UVLO (ver. A, D & Q) VCCHYS V VCCON 4.20 4.45 4.80 VCC falling VCCOFF 3.70 3.95 4.20 VCC UVLO Hysteresis (ver. A, D & Q) Start−up Delay 1.0 VCC rising VCC rising from 0 to VCCON + 1 V @ tr = 10 ms www.onsemi.com 6 VCCHYS 0.5 tSTART_DEL 75 V V 125 ms NCP43080 ELECTRICAL CHARACTERISTICS −40°C ≤ TJ ≤ 125°C; VCC = 12 V; CDRV = 0 nF; RMIN_TON = RMIN_TOFF = 10 kW; VLLD = 0 V; VCS = −1 to +4 V; fCS = 100 kHz, DCCS = 50%, unless otherwise noted. Typical values are at TJ = +25°C Parameter Test Conditions Symbol Min Typ Max Unit ICC 3.3 4.0 5.6 mA B, D, Q 3.8 4.5 6.0 A, C 4.5 6.0 7.5 B, D, Q 7.7 9.0 10.7 A, C 20 25 30 SUPPLY SECTION Current Consumption, RMIN_TON = RMIN_TOFF = 0 kW CDRV = 0 nF, fSW = 500 kHz A, C CDRV = 1 nF, fSW = 500 kHz CDRV = 10 nF, fSW = 500 kHz B, D, Q Current Consumption No switching, VCS = 0 V, RMIN_TON = RMIN_TOFF = 0 kW ICC Current Consumption below UVLO No switching, VCC = VCCOFF – 0.1 V, VCS = 0 V ICC_UVLO Current Consumption in Disable Mode VLLD = VCC − 0.1 V, VCS = 0 V ICC_DIS 40 50 60 1.5 2.0 2.5 mA 75 125 mA 55 70 mA 40 55 ns 35 ns 40 DRIVER OUTPUT Output Voltage Rise−Time CDRV = 10 nF, 10% to 90% VDRVMAX Output Voltage Fall−Time CDRV = 10 nF, 90% to 10% VDRVMAX Driver Source Resistance Driver Sink Resistance Output Peak Source Current Output Peak Sink Current Maximum Driver Output Voltage VCC = 35 V, CDRV > 1 nF, VLLD = 0 V, (ver. B, D and Q) tr tf 20 RDRV_SOURCE 1.2 W RDRV_SINK 0.5 W IDRV_SOURCE 4 A IDRV_SINK 8 A VDRVMAX VCC = 35 V, CDRV > 1 nF, VLLD = 0 V, (ver. A, C) Minimum Driver Output Voltage VCC = VCCOFF + 200 mV, VLLD = 0 V, (ver. B) VDRVMIN VCC = VCCOFF + 200 mV, VLLD = 0 V, (ver. C) VCC = VCCOFF + 200 mV, VLLD = 0 V Minimum Driver Output Voltage VLLD = VCC − VLLDREC V VDRVLLDMIN V 9.0 9.5 10.5 4.3 4.7 5.5 7.2 7.8 8.5 4.2 4.7 5.3 3.6 4.0 4.4 0.0 0.4 1.2 V V CS INPUT Total Propagation Delay From CS to DRV Output On VCS goes down from 4 to −1 V, tf_CS = 5 ns tPD_ON 35 60 ns Total Propagation Delay From CS to DRV Output Off VCS goes up from −1 to 4 V, tr_CS = 5 ns tPD_OFF 12 23 ns CS Bias Current VCS = −20 mV Turn On CS Threshold Voltage Turn Off CS Threshold Voltage Guaranteed by Design Turn Off Timer Reset Threshold Voltage CS Leakage Current VCS = 150 V ICS −105 −100 −95 mA −75 −40 mV 0 mV 0.6 V 0.4 mA VTH_CS_ON −120 VTH_CS_OFF −1 VTH_CS_RESET 0.4 0.5 ICS_LEAKAGE MINIMUM tON and tOFF ADJUST Minimum tON time RMIN_TON = 0 W tON_MIN 35 55 75 ns Minimum tOFF time RMIN_TOFF = 0 W tOFF_MIN 190 245 290 ns Minimum tON time RMIN_TON = 10 kW tON_MIN 0.92 1.00 1.08 ms Minimum tOFF time RMIN_TOFF = 10 kW tOFF_MIN 0.92 1.00 1.08 ms Minimum tON time RMIN_TON = 50 kW tON_MIN 4.62 5.00 5.38 ms Minimum tOFF time RMIN_TOFF = 50 kW tOFF_MIN 4.62 5.00 5.38 ms www.onsemi.com 7 NCP43080 ELECTRICAL CHARACTERISTICS −40°C ≤ TJ ≤ 125°C; VCC = 12 V; CDRV = 0 nF; RMIN_TON = RMIN_TOFF = 10 kW; VLLD = 0 V; VCS = −1 to +4 V; fCS = 100 kHz, DCCS = 50%, unless otherwise noted. Typical values are at TJ = +25°C Parameter Test Conditions Symbol Min Typ Max Unit MAXIMUM tON ADJUST Maximum tON Time VMAX_TON = 3 V tON_MAX 4.3 4.8 5.3 ms Maximum tON Time VMAX_TON = 0.3 V tON_MAX 41 48 55 ms Maximum tON Output Current VMAX_TON = 0.3 V, VCS = 0 V IMAX_TON −105 −100 −95 mA Disable Threshold VLLD_DIS = VCC − VLLD VLLD_DIS 0.8 0.9 1.0 V Recovery Threshold VLLD_REC = VCC − VLLD VLLD_REC 0.9 1.0 1.1 V LLD INPUT Disable Hysteresis Disable Time Hysteresis Disable to Normal, Normal to Disable Disable Recovery Time 0.1 V tLLD_DISH 45 ms tLLD_DIS_REC 7.0 fLPLLD 6 Low Pass Filter Frequency Driver Voltage Clamp Threshold VLLD_DISH VDRV = VDRVMAX, VLLDMAX = VCC − VLLD VLLDMAX 12.5 16.0 ms 10 13 kHz 2.0 V Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product performance may not be indicated by the Electrical Characteristics if operated under different conditions. TYPICAL CHARACTERISTICS 4.7 9.3 4.6 9.1 VCCON 4.4 8.7 4.3 8.5 4.2 4.1 VCCOFF 4.0 VCCON 8.9 VCC (V) VCC (V) 4.5 8.3 8.1 VCCOFF 7.9 3.9 7.7 3.8 7.5 7.3 −40 −20 3.7 −40 −20 0 20 40 60 TJ (°C) 80 100 120 Figure 7. VCCON and VCCOFF Levels, ver. A, D, Q 0 20 40 60 TJ (°C) 80 100 Figure 8. VCCON and VCCOFF Levels, ver. B, C www.onsemi.com 8 120 NCP43080 TYPICAL CHARACTERISTICS 6 TJ = 55°C TJ = 25°C 120 TJ = 85°C TJ = 125°C 5 100 ICC_UVLO (mA) ICC (mA) 4 TJ = 0°C 3 TJ = −20°C TJ = −40°C 2 1 80 60 40 20 0 0 5 10 15 20 25 30 0 −40 35 −20 0 20 60 80 100 VCC (V) TJ (°C) Figure 9. Current Consumption, CDRV = 0 nF, fCS = 500 kHz, ver. D Figure 10. Current Consumption, VCC = VCCOFF − 0.1 V, VCS = 0 V, ver. D 30 120 60 CDRV = 10 nF CDRV = 10 nF 50 20 40 ICC (mA) 25 15 10 30 20 CDRV = 1 nF 5 CDRV = 1 nF 10 CDRV = 0 nF CDRV = 0 nF 0 −40 −20 0 20 40 60 80 100 0 −40 −20 120 0 20 40 60 80 100 120 TJ (°C) TJ (°C) Figure 11. Current Consumption, VCC = 12 V, VCS = −1 to 4 V, fCS = 500 kHz, ver. A Figure 12. Current Consumption, VCC = 12 V, VCS = −1 to 4 V, fCS = 500 kHz, ver. D 70 65 ICC_DIS (mA) ICC (mA) 40 60 55 50 45 40 −40 −20 0 20 40 60 80 100 120 TJ (°C) Figure 13. Current Consumption in Disable, VCC = 12 V, VCS = 0 V, VLLD = VCC − 0.1 V www.onsemi.com 9 NCP43080 TYPICAL CHARACTERISTICS 0 −90 −92 −0.2 −94 −0.4 −98 ICS (mA) ICS (mA) −96 −100 −102 −104 TJ = 125°C TJ = 85°C TJ = 55°C TJ = 25°C TJ = 0°C TJ = −20°C TJ = −40°C −0.6 −0.8 −1.0 −106 −108 −110 −40 −1.2 −20 0 20 40 60 80 100 −1.4 −1.0 −0.8 −0.6 −0.4 −0.2 120 0.4 0.6 VCS (V) Figure 14. CS Current, VCS = −20 mV Figure 15. CS Current, VCC = 12 V 2.5 −50 VTH_CS_ON (mV) −30 2.0 ICC (mA) 0.2 TJ (°C) 3.0 TJ = 125°C TJ = 85°C TJ = 55°C TJ = 25°C TJ = 0°C TJ = −20°C TJ = −40°C 1.5 1.0 0.5 0 −4 0 −3 −2 0.8 1.0 −70 −90 −110 −130 −1 0 1 2 3 −150 −40 −20 4 0 20 40 60 80 100 VCS (V) TJ (°C) Figure 16. Supply Current vs. CS Voltage, VCC = 12 V Figure 17. CS Turn−on Threshold 1.0 120 0.60 VTH_CS_RESET (V) VTH_CS_OFF (mV) 0.5 0 −0.5 −1.0 0.55 0.50 0.45 −1.5 −2.0 −40 −20 0 20 40 60 80 100 0.40 −40 120 −20 0 20 40 60 80 TJ (°C) TJ (°C) Figure 18. CS Turn−off Threshold Figure 19. CS Reset Threshold www.onsemi.com 10 100 120 NCP43080 0.80 200 0.75 180 0.70 160 0.65 140 ICS_LEAKAGE (nA) VTH_CS_RESET (V) TYPICAL CHARACTERISTICS 0.60 0.55 0.50 0.45 TBD 100 80 60 0.40 40 0.35 0.30 20 0 −40 0 5 10 15 20 25 30 35 −20 0 20 40 60 80 100 VCC (V) TJ (°C) Figure 20. CS Reset Threshold Figure 21. CS Leakage, VCS = 150 V 60 24 55 22 120 20 50 18 tPD_OFF (ns) tPD_ON (ns) 120 45 40 35 16 14 12 10 30 8 25 6 −20 0 20 40 60 80 100 4 −40 120 −20 0 20 40 60 80 100 120 TJ (°C) TJ (°C) Figure 22. Propagation Delay from CS to DRV Output On Figure 23. Propagation Delay from CS to DRV Output Off 75 1.08 70 1.06 65 1.04 tMIN_TON (ms) tMIN_TON (ns) 20 −40 60 55 50 1.02 1.00 0.98 45 0.96 40 0.94 35 −40 −20 0 20 40 60 80 100 0.92 −40 120 −20 0 20 40 60 80 100 120 TJ (°C) TJ (°C) Figure 24. Minimum On−time RMIN_TON = 0 W Figure 25. Minimum On−time RMIN_TON = 10 kW www.onsemi.com 11 NCP43080 TYPICAL CHARACTERISTICS 5.4 290 5.3 280 270 tMIN_TOFF (ns) tMIN_TON (ms) 5.2 5.1 5.0 4.9 240 230 210 4.7 4.6 −40 −20 0 20 40 60 80 100 200 190 −40 120 −20 0 20 40 60 80 100 120 TJ (°C) TJ (°C) Figure 26. Minimum On−time RMIN_TON = 50 kW Figure 27. Minimum Off−time RMIN_TOFF = 0 W 1.08 5.4 1.06 5.3 1.04 5.2 tMIN_TOFF (ms) tMIN_TOFF (ms) 250 220 4.8 1.02 1.00 0.98 5.1 5.0 4.9 0.96 4.8 0.94 4.7 0.92 −40 −20 0 20 40 60 80 100 4.6 −40 120 −20 0 20 40 60 80 100 TJ (°C) TJ (°C) Figure 28. Minimum Off−time RMIN_TOFF = 10 kW Figure 29. Minimum Off−time RMIN_TOFF = 50 kW 1.04 1.08 1.03 1.06 1.02 1.04 tMIN_TOFF (ms) tMIN_TON (ms) 260 1.01 1.00 0.98 120 1.02 1.00 0.98 0.96 0.96 0.94 0.94 092 0.92 0 5 10 15 20 25 30 0 35 5 10 15 20 25 30 VCC (V) VCC (V) Figure 30. Minimum On−time RMIN_TON = 10 kW Figure 31. Minimum Off−time RMIN_TOFF = 10 kW www.onsemi.com 12 35 NCP43080 TYPICAL CHARACTERISTICS 5.5 10.4 VCC = 12 V, CDRV = 0 nF VCC = 12 V, CDRV = 1 nF VCC = 12 V, CDRV = 10 nF VCC = 35 V, CDRV = 0 nF VCC = 35 V, CDRV = 1 nF VCC = 35 V, CDRV = 10 nF VDRV (V) 10.0 9.8 5.1 VDRV (V) 10.2 VCC = 12 V, CDRV = 0 nF VCC = 12 V, CDRV = 1 nF VCC = 12 V, CDRV = 10 nF VCC = 35 V, CDRV = 0 nF VCC = 35 V, CDRV = 1 nF VCC = 35 V, CDRV = 10 nF 5.3 9.6 4.9 4.7 9.4 4.5 9.2 9.0 −40 −20 0 20 40 60 80 4.3 −40 −20 120 100 20 40 60 80 100 120 TJ (°C) TJ (°C) Figure 32. Driver and Output Voltage, ver. B, D and Q Figure 33. Driver Output Voltage, ver. A and C 50 5.3 TJ = 125°C TJ = 85°C TJ = 55°C TJ = 25°C 45 40 TJ = 0°C TJ = −20°C TJ = −40°C 5.2 5.1 tMAX_TON (ms) 35 30 25 20 5.0 4.9 4.8 4.7 15 4.6 10 4.5 5 0 4.4 0 0.5 1.0 1.5 2.0 2.5 4.3 −40 3.0 −20 0 20 40 60 80 100 120 VMAX_TON (V) TJ (°C) Figure 34. Maximum On−time, ver. Q Figure 35. Maximum On−time, VMAX_TON = 3 V, ver. Q 55 53 51 tMAX_TON (ms) tMAX_TON (ms) 0 49 47 45 43 41 −40 −20 0 20 40 60 80 100 TJ (°C) Figure 36. Maximum On−time, VMAX_TON = 0.3 V, ver. Q www.onsemi.com 13 120 NCP43080 APPLICATION INFORMATION General description An extremely fast turn−off comparator, implemented on the current sense pin, allows for NCP43080 implementation in CCM applications without any additional components or external triggering. An output driver features capability to keep SR transistor closed even when there is no supply voltage for NCP43080. SR transistor drain voltage goes up and down during SMPS operation and this is transferred through drain gate capacitance to gate and may turn on transistor. NCP43080 uses this pulsing voltage at SR transistor gate (DRV pin) and uses it internally to provide enough supply to activate internal driver sink transistor. DRV voltage is pulled low (not to zero) thanks to this feature and eliminate the risk of turned on SR transistor before enough VCC is applied to NCP43080. Some IC versions include a MAX_TON circuit that helps a quasi resonant (QR) controller to work in CCM mode when a heavy load is present like in the example of a printer’s motor starting up. Finally, the NCP43080 features a special pin (LLD) that can be used to reduce gate driver voltage clamp according to application load conditions. This feature helps to reduce issues with transition from disabled driver to full driver output voltage and back. Disable state can be also activated through this pin to decrease power consumption in no load conditions. If the LLD feature is not wanted then the LLD pin can be tied to GND. The NCP43080 is designed to operate either as a standalone IC or as a companion IC to a primary side controller to help achieve efficient synchronous rectification in switch mode power supplies. This controller features a high current gate driver along with high−speed logic circuitry to provide appropriately timed drive signals to a synchronous rectification MOSFET. With its novel architecture, the NCP43080 has enough versatility to keep the synchronous rectification system efficient under any operating mode. The NCP43080 works from an available voltage with range from 4 V (A, D & Q options) or 8 V (B & C options) to 35 V (typical). The wide VCC range allows direct connection to the SMPS output voltage of most adapters such as notebooks, cell phone chargers and LCD TV adapters. Precise turn-off threshold of the current sense comparator together with an accurate offset current source allows the user to adjust for any required turn-off current threshold of the SR MOSFET switch using a single resistor. Compared to other SR controllers that provide turn-off thresholds in the range of −10 mV to −5 mV, the NCP43080 offers a turn-off threshold of 0 mV. When using a low RDS(on) SR (1 mW) MOSFET our competition, with a −10 mV turn off, will turn off with 10 A still flowing through the SR FET, while our 0 mV turn off turns off the FET at 0 A; significantly reducing the turn-off current threshold and improving efficiency. Many of the competitor parts maintain a drain source voltage across the MOSFET causing the SR MOSFET to operate in the linear region to reduce turn−off time. Thanks to the 8 A sink current of the NCP43080 significantly reduces turn off time allowing for a minimal drain source voltage to be utilized and efficiency maximized. To overcome false triggering issues after turn-on and turn−off events, the NCP43080 provides adjustable minimum on-time and off-time blanking periods. Blanking times can be adjusted independently of IC VCC using external resistors connected to GND. If needed, blanking periods can be modulated using additional components. Current Sense Input Figure 37 shows the internal connection of the CS circuitry on the current sense input. When the voltage on the secondary winding of the SMPS reverses, the body diode of M1 starts to conduct current and the voltage of M1’s drain drops approximately to −1 V. The CS pin sources current of 100 mA that creates a voltage drop on the RSHIFT_CS resistor (resistor is optional, we recommend shorting this resistor). Once the voltage on the CS pin is lower than VTH_CS_ON threshold, M1 is turned−on. Because of parasitic impedances, significant ringing can occur in the application. To overcome false sudden turn−off due to mentioned ringing, the minimum conduction time of the SR MOSFET is activated. Minimum conduction time can be adjusted using the RMIN_TON resistor. www.onsemi.com 14 NCP43080 Figure 37. Current Sensing Circuitry Functionality Figure 38). Therefore the turn−off current depends on MOSFET RDSON. The −0.5 mV threshold provides an optimum switching period usage while keeping enough time margin for the gate turn-off. The RSHIFT_CS resistor provides the designer with the possibility to modify (increase) the actual turn−on and turn−off secondary current thresholds. To ensure proper switching, the min_tOFF timer is reset, when the VDS of the MOSFET rings and falls down past the VTH_CS_RESET. The minimum off−time needs to expire before another drive pulse can be initiated. Minimum off−time timer is started again when VDS rises above VTH_CS_RESET. The SR MOSFET is turned-off as soon as the voltage on the CS pin is higher than VTH_CS_OFF (typically −0.5 mV minus any voltage dropped on the optional RSHIFT_CS). For the same ringing reason, a minimum off-time timer is asserted once the VCS goes above VTH_CS_RESET. The minimum off-time can be externally adjusted using RMIN_TOFF resistor. The minimum off−time generator can be re−triggered by MIN_TOFF reset comparator if some spurious ringing occurs on the CS input after SR MOSFET turn−off event. This feature significantly simplifies SR system implementation in flyback converters. In an LLC converter the SR MOSFET M1 channel conducts while secondary side current is decreasing (refer to www.onsemi.com 15 NCP43080 VDS = VCS ISEC V TH_CS _RESET – (RSHIFT _CS*ICS ) VTH_CS_OFF – (RSHIFT _CS*ICS ) VTH_CS _ON – (RSHIFT _CS*ICS ) VDRV Turn−on delay Turn −off delay Min ON−time tMIN_TON Min t OFF timer was stopped here because of VCS<VTH_CS_RESET Min OFF−time tMIN_TOFF t The tMIN_TON and t MIN_TOFF are adjustable by R MIN_TON and RMIN_TOFF resistors Figure 38. CS Input Comparators Thresholds and Blanking Periods Timing in LLC VDS = VCS ISEC VTH_CS_RESET – (RSHIFT_CS*ICS ) VTH_CS_OFF – (RSHIFT_CS*ICS ) VTH_CS _ON – (RSHIFT_CS*ICS ) VDRV Turn−on delay Turn −off delay Min ON−time Min t OFF timer was stopped here because of VCS<VTH_CS_RESET tMIN_TON Min OFF−time tMIN_TOFF t The tMIN_TON and tMIN_TOFF are adjustable by RMIN_TON and RMIN_TOFF resistors Figure 39. CS Input Comparators Thresholds and Blanking Periods Timing in Flyback www.onsemi.com 16 NCP43080 If no RSHIFT_CS resistor is used, the turn-on, turn-off and VTH_CS_RESET thresholds are fully given by the CS input specification (please refer to electrical characteristics table). The CS pin offset current causes a voltage drop that is equal to: V RSHIFT_CS + R SHIFT_CS * I CS Note that RSHIFT_CS impact on turn-on and VTH_CS_RESET thresholds is less critical than its effect on the turn−off threshold. It should be noted that when using a SR MOSFET in a through hole package the parasitic inductance of the MOSFET package leads (refer to Figure 40) causes a turn−off current threshold increase. The current that flows through the SR MOSFET experiences a high Di(t)/Dt that induces an error voltage on the SR MOSFET leads due to their parasitic inductance. This error voltage is proportional to the derivative of the SR MOSFET current; and shifts the CS input voltage to zero when significant current still flows through the MOSFET channel. As a result, the SR MOSFET is turned−off prematurely and the efficiency of the SMPS is not optimized − refer to Figure 41 for a better understanding. (eq. 1) Final turn−on and turn off thresholds can be then calculated as: V CS_TURN_ON + V TH_CS_ON * ǒR SHIFT_CS * I CSǓ (eq. 2) V CS_TURN_OFF + V TH_CS_OFF * ǒR SHIFT_CS * I CSǓ (eq. 3) V CS_RESET + V TH_CS_RESET * ǒR SHIFT_CS * I CSǓ (eq. 4) Figure 40. SR System Connection Including MOSFET and Layout Parasitic Inductances in LLC Application www.onsemi.com 17 NCP43080 Figure 41. Waveforms From SR System Implemented in LLC Application and Using MOSFET in TO220 Package With Long Leads − SR MOSFET channel Conduction Time is Reduced current Di/Dt and high operating frequency is to use lead−less SR MOSFET i.e. SR MOSFET in SMT package. The parasitic inductance of a SMT package is negligible causing insignificant CS turn−off threshold shift and thus minimum impact to efficiency (refer to Figure 42). Note that the efficiency impact caused by the error voltage due to the parasitic inductance increases with lower MOSFETs RDS(on) and/or higher operating frequency. It is thus beneficial to minimize SR MOSFET package leads length in order to maximize application efficiency. The optimum solution for applications with high secondary www.onsemi.com 18 NCP43080 Figure 42. Waveforms from SR System Implemented in LLC Application and Using MOSFET in SMT Package with Minimized Parasitic Inductance − SR MOSFET Channel Conduction Time is Optimized It can be deduced from the above paragraphs on the induced error voltage and parameter tables that turn−off threshold precision is quite critical. If we consider a SR MOSFET with RDS(on) of 1 mW, the 1 mV error voltage on the CS pin results in a 1 A turn-off current threshold difference; thus the PCB layout is very critical when implementing the SR system. Note that the CS turn-off comparator is referred to the GND pin. Any parasitic impedance (resistive or inductive − even on the magnitude of mW and nH values) can cause a high error voltage that is then evaluated by the CS comparator. Ideally the CS turn−off comparator should detect voltage that is caused by secondary current directly on the SR MOSFET channel resistance. In reality there will be small parasitic impedance on the CS path due to the bonding wires, leads and soldering. To assure the best efficiency results, a Kelvin connection of the SR controller to the power circuitry should be implemented. The GND pin should be connected to the SR MOSFET source soldering point and current sense pin should be connected to the SR MOSFET drain soldering point − refer to Figure 40. Using a Kelvin connection will avoid any impact of PCB layout parasitic elements on the SR controller functionality; SR MOSFET parasitic elements will still play a role in attaining an error voltage. Figure 44 and Figure 43 show examples of SR system layouts using MOSFETs in TO220 and SMT packages. It is evident that the MOSFET leads should be as short as possible to minimize parasitic inductances when using packages with leads (like TO220). Figure 43 shows how to layout design with two SR MOSFETs in parallel. It has to be noted that it is not easy task and designer has to paid lot of attention to do symmetric Kelvin connection. Figure 44. Recommended Layout When Using SR MOSFET in TO220 Package Figure 43. Recommended Layout When Using SR MOSFET in SMT Package (2x SO8 FL) www.onsemi.com 19 NCP43080 VDS = VCS VTH_CS_RESET VTH_CS_OFF VTH_CS_ON t MIN_TOFF Not complete t MIN_TOFF −> IC is not activated Min OFF− time t MIN_TOFF Complete t MIN_TOFF activates IC t MIN_TOFF is stopped due to VDS drops below VTH_CS_RESET t MIN_TON Min ON−time VDRV VCC VCCON t1 t3 t2 t4 t5 t7 t6 t9 t8 t10 t11 t13 t15 t12 t14 Figure 45. NCP43080 Operation after Start−Up Event Self Synchronization complete minimum off−time period elapses between times t7 and t8 allowing the IC to activate a driver output after time t8. Self synchronization feature during start−up can be seen at Figure 45. Figure 45 shows how the minimum off−time timer is reset when CS voltage is oscillating through VTH_CS_RESET level. The NCP43080 starts operation at time t1 (time t1 can be seen as a wake−up event from the disable mode through LLD pin). Internal logic waits for one complete minimum off−time period to expire before the NCP43080 can activate the driver after a start−up or wake−up event. The minimum off−time timer starts to run at time t1, because VCS is higher than VTH_CS_RESET. The timer is then reset, before its set minimum off−time period expires, at time t2 thanks to CS voltage lower than VTH_CS_RESET threshold. The aforementioned reset situation can be seen again at time t3, t4, t5 and t6. A Minimum tON and tOFF Adjustment The NCP43080 offers an adjustable minimum on−time and off−time blanking periods that ease the implementation of a synchronous rectification system in any SMPS topology. These timers avoid false triggering on the CS input after the MOSFET is turned on or off. The adjustment of minimum tON and tOFF periods are done based on an internal timing capacitance and external resistors connected to the GND pin − refer to Figure 46 for a better understanding. www.onsemi.com 20 NCP43080 Figure 46. Internal Connection of the MIN_TON Generator (the MIN_TOFF Works in the Same Way) Current through the MIN_TON adjust resistor can be calculated as: I R_MIN_TON + V ref R Ton_min The internal capacitor size would be too large if IR_MIN_TON was used. The internal current mirror uses a proportional current, given by the internal current mirror ratio. One can then calculate the MIN_TON and MIN_TOFF blanking periods using below equations: (eq. 5) If the internal current mirror creates the same current through RMIN_TON as used the internal timing capacitor (Ct) charging, then the minimum on−time duration can be calculated using this equation. t MIN_TON + C t V ref I R_MIN_TON + Ct V ref Vref t MIN_TON + 1.00 * 10 −4 * R MIN_TON [ms] (eq. 7) t MIN_TOFF + 1.00 * 10 −4 * R MIN_TOFF [ms] (eq. 8) Note that the internal timing comparator delay affects the accuracy of Equations 7 and 8 when MIN_TON/ MIN_TOFF times are selected near to their minimum possible values. Please refer to Figures 47 and 48 for measured minimum on and off time charts. (eq. 6) + C t @ R MIN_TON RMIN_TON www.onsemi.com 21 NCP43080 10 The absolute minimum tON duration is internally clamped to 55 ns and minimum tOFF duration to 245 ns in order to prevent any potential issues with the MIN_TON and/or MIN_TOFF pins being shorted to GND. The NCP43080 features dedicated anti−ringing protection system that is implemented with a MIN_TOFF blank generator. The minimum off−time one−shot generator is restarted in the case when the CS pin voltage crosses VTH_CS_RESET threshold and MIN_TOFF period is active. The total off-time blanking period is prolonged due to the ringing in the application (refer to Figure 38). Some applications may require adaptive minimum on and off time blanking periods. With NCP43080 it is possible to modulate blanking periods by using an external NPN transistor − refer to Figure 49. The modulation signal can be derived based on the load current, feedback regulator voltage or other application parameter. 9 8 tMIN_TON (ms) 7 6 5 4 3 2 1 0 0 10 20 30 40 50 60 70 80 90 100 RMIN_TON (kW) Figure 47. MIN_TON Adjust Characteristics 10 9 tMIN_TOFF (ms) 8 7 6 5 4 3 2 1 0 0 10 20 30 40 50 60 70 80 90 100 RMIN_TOFF (kW) Figure 48. MIN_TOFF Adjust Characteristics Figure 49. Possible Connection for MIN_TON and MIN_TOFF Modulation www.onsemi.com 22 NCP43080 Maximum tON adjustment The Internal connection of the MAX_TON feature is shown in Figure 50. Figure 50 shows a method that allows for a modification of the maximum on−time according to output voltage. At a lower VOUT, caused by hard overload or at startup, the maximum on−time should be longer than at nominal voltage. Resistor RA can be used to modulate maximum on−time according to VOUT or any other parameter. The operational waveforms at heavy load in QR type SMPS are shown in Figure 51. After tMAX_TON time is exceeded, the synchronous switch is turned off and the secondary current is conducted by the diode. Information about turned off SR MOSFET is transferred by the DRV pin through a small pulse transformer to the primary side where it acts on the ZCD detection circuit to allow the primary switch to be turned on. Secondary side current disappears before the primary switch is turned on without a possibility of cross current condition. The NCP43080Q offers an adjustable maximum on−time (like the min_tON and min_tOFF settings shown above) that can be very useful for QR controllers at high loads. Under high load conditions the QR controller can operate in CCM thanks to this feature. The NCP43080Q version has the ability to turn−off the DRV signal to the SR MOSFET before the secondary side current reaches zero. The DRV signal from the NCP43080Q can be fed to the primary side through a pulse transformer (see Figure 4 for detail) to a transistor on the primary side to emulate a ZCD event before an actual ZCD event occurs. This feature helps to keep the minimum switching frequency up so that there is better energy transfer through the transformer (a smaller transformer core can be used). Also another advantage is that the IC controls the SR MOSFET and turns off from secondary side before the primary side is turned on in CCM to ensure no cross conduction. By controlling the SR MOSFET’s turn off before the primary side turn off, producing a zero cross conduction operation, this will improve efficiency. Figure 50. Internal Connection of the MAX_TON Generator, NCP43080Q www.onsemi.com 23 NCP43080 VDS = VCS ISEC V TH_CS _RESET – (RSHIFT _CS*ICS ) VTH_CS_OFF – (RSHIFT _CS*ICS ) VTH_CS _ON – (RSHIFT _CS*ICS ) Primary virtual ZCD detection delay V DRV Turn−on delay Turn −off delay Min ON−time t MIN _TON Min OFF−time tMIN _TOFF Max ON−time tMAX _TON t The tMIN _TON and tMIN _TOFF are adjustable by R MIN _TON and R MIN _TOFF resistors, t MAX_TON is adjustable by R MAX_TON Figure 51. Function of MAX_TON Generator in Heavy Load Condition Adaptive Gate Driver Clamp and automatic Light Load Turn−off and drop at MOSFET’s RDS(on) only improves stability during load transients. 2nd − In extremely low load conditions or no load conditions the NCP43080 fully disables driver output and reduces the internal power consumption when output load drops below the level where skip−mode takes place. Both features are controlled by voltage at LLD pin. The LLD pin voltage characteristic is shown in Figure 52. Driver voltage clamp is a linear function of the voltage difference between the VCC and LLD pins from VLLD_REC point up to VLLD_MAX. A disable mode is available, where the IC current consumption is dramatically reduced, when the difference of VCC − VLLD voltage drops below VLLD_DIS. When the voltage difference between the VCC − VLLD pins increase above VLLC_REC the disable mode ends and the IC regains normal operation. It should be noted that there are also some time delays to enter and exit from the disable mode. Time waveforms are shown at Figure 53. There is a time, tLLD_DISH, that the logic ignores changes from disable mode to normal or reversely. There is also some time tLLD_DIS_R that is needed after an exit from the disable mode to assure proper internal block biasing before SR controller starts work normally. As synchronous rectification system significantly improves efficiency in most of SMPS applications during medium or full load conditions. However, as the load reduces into light or no−load conditions the SR MOSFET driving losses and SR controller consumption become more critical. The NCP43080 offers two key features that help to optimize application efficiency under light load and no load conditions: 1st − The driver clamp voltage is modulated and follows the output load condition. When the output load decreases the driver clamp voltage decreases as well. Under heavy load conditions the SR MOSFET’s gate needs to be driven very hard to optimize the performance and reduce conduction losses. During light load conditions it is not as critical to drive the SR MOSFET’s channel into such a low RDSON state. This adaptive gate clamp technique helps to optimize efficiency during light load conditions especially in LLC applications where the SR MOSFETs with high input capacitance are used. Driver voltage modulation improves the system behavior when SR controller state is changed in and out of normal or disable modes. Soft transient between drop at body diode www.onsemi.com 24 NCP43080 VDRVCLAMP ICC VDRVMAX VLLD_DIS VLLD_REC VCC −VLLD VLLD_MAX Figure 52. LLD Voltage to Driver Clamp and Current Consumption Characteristic (DRV Unloaded) VCC−VLLD tLLD_DISH tLLD_DISH tLLD_DISH tLLD_DISH VLLD_REC DISABLE MODE NORMAL DISABLE MODE tLLD_DIS_R tLLD_DIS_R NORMAL ICC NORMAL VLLD_DIS t Figure 53. LLD Pin Disable Behavior in Time Domain through R3 and capacitors C2 and C3, the load level can be sensed. Output voltage of this detector on the LLD pin is referenced to controller VCC with an internal differential amplifier in NCP43080. The output of the differential amplifier is then used in two places. First the output is used in the driver block for gate drive clamp voltage adjustment. Next, the output signal is evaluated by a no−load detection comparator that activates IC disable mode in case the load is disconnected from the application output. The two main SMPS applications that are using synchronous rectification systems today are flyback and LLC topologies. Different light load detection techniques are used in NCP43080 controller to reflect differences in operation of both mentioned applications. Detail of the light load detection implementation technique used in NCP43080 in flyback topologies is displayed at Figure 54. Using a simple and cost effective peak detector implemented with a diode D1, resistors R1 www.onsemi.com 25 NCP43080 RTN Vmodul To DRV clamp VCC LLD GND To disable logic NCP43080 Figure 54. NCP43080 Light Load and No Load Detection Principle in Flyback Topologies directly reduces DRV clamp voltage down from its maximum level. The DRV is then fully disabled when IC enters disable mode. The IC exits from disable mode when difference between LLD voltage and VCC increases over VLLD_REC. Resistors R2 and R3 are also used for voltage level adjustment and with capacitor C3 form low pass filter that filters relatively high speed ripple at C2. This low pass filter also reduces speed of state change of the SR controller from normal to disable mode or reversely. Time constant should be higher than feedback loop time constant to keep whole system stable. Operational waveforms related to the flyback LLD circuitry are provided in Figure 55. The SR MOSFET drain voltage drops to ~ 0 V when ISEC current is flowing. When the SR MOSFET is conducting the capacitor C2 charges−up, causing the difference between the LLD pin and VCC pin to increase, and drop the LLD pin voltage. As the load decreases the secondary side currents flows for a shorter a shorter time. C2 has less time to accumulate charge and the voltage on the C2 decreases, because it is discharged by R2 and R3. This smaller voltage on C2 will cause the LLD pin voltage to increase towards VCC and the difference between LLD and VCC will go to zero. The output voltage then ISEC VC2 VC3 VLLD_REC VLLDMAX VLLD_DIS VDRV VDRVMAX IC enters disable mode t Figure 55. NCP43080 Driver Clamp Modulation Waveforms in Flyback Application Entering into Light/No Load Condition www.onsemi.com 26 NCP43080 IOUT VCC−VLLD VLLD_REC VLLDMAX VLLD_DIS VDRVMAX IC enters disable mode VDRV t Figure 56. NCP43080 Driver Clamp Modulation Circuitry Transfer Characteristic in Flyback Application The technique used for LLD detection in LLC is similar to the LLD detection method used in a flyback with the exception the D1 and D2 OR−ing diodes are used to measure the total duty cycle to see if it is operating in skip mode. Vmodul To DRV clamp VCC LLD GND To disable logic NCP43080 RTN Vmodul To DRV clamp VCC LLD GND To disable logic NCP43080 Figure 57. NCP43080 Light Load Detection in LLC Topology The driver clamp modulation waveforms of NCP43080 in LLC are provided in Figure 58. The driver clamp voltage clips to its maximum level when LLC operates in normal mode. When the LLC starts to operate in skip mode the driver clamp voltage begins to decrease. The specific output current level is determined by skip duty cycle and detection circuit consists of R1, R2, R3, C2, C3 and diodes D1, D2. The NCP43080 enters disable mode in low load condition, when VCC−VLLD drops below VLLD_DIS (0.9 V). Disable mode ends when this voltage increase above VLLD_REC (1.0 V) Figure 59 shows how LLD voltage modulates the driver output voltage clamp. www.onsemi.com 27 NCP43080 Normal operation Skip operation VCS 1 VCS 2 VC2 V LLDMAX V CC −V LLD (V C3) V LLD_REC V LLD_DIS V DRVMAX DRV clamp IC enters disable mode t Figure 58. NCP43080 Driver Clamp Modulation Waveforms in LLC Application VCC−VLLD IC enters disable mode VLLDMAX VLLD_REC VLLD_DIS VDRVMAX DRV clamp IOUT t Figure 59. NCP43080 Driver Clamp Modulation Circuitry Characteristic in LLC Application www.onsemi.com 28 NCP43080 behavior is shown in Figure 60. Operation waveforms for this option are provided in Figure 61. Capacitor C2 is charged to maximum voltage when LLC is switching. When there is no switching in skip, capacitor C2 is discharged by R2 and when LLD voltage referenced to VCC falls below VLLD_DIS IC enters disable mode. Disable mode is ended when LLC starts switching. There exist some LLC applications where behavior described above is not the best choice. These applications transfer significant portion of energy in a few first pulses in skip burst. It is good to keep SR fully working during skip mode to improve efficiency. There can be still saved some energy using LLD function by activation disable mode between skip bursts. Simplified schematic for this LLD Vmodul To DRV clamp VCC LLD GND To disable logic NCP43080 RTN Vmodul To DRV clamp VCC LLD GND To disable logic NCP43080 Figure 60. NCP43080 Light Load Detection in LLC Application − Other Option www.onsemi.com 29 NCP43080 Normal operation Skip operation VCS1 VCS2 VC2 VLLDMAX VCC−VLLD VLLD_DIS DRV clamp VLLD_REC IC enters disable mode VDRVMAX t Figure 61. NCP43080 Light Load Detection Behavior in LLC Application – Other Option Power Dissipation Calculation significantly. Therefore, the MOSFET switch always operates under Zero Voltage Switching (ZVS) conditions when in a synchronous rectification system. The following steps show how to approximately calculate the power dissipation and DIE temperature of the NCP43080 controller. Note that real results can vary due to the effects of the PCB layout on the thermal resistance. It is important to consider the power dissipation in the MOSFET driver of a SR system. If no external gate resistor is used and the internal gate resistance of the MOSFET is very low, nearly all energy losses related to gate charge are dissipated in the driver. Thus it is necessary to check the SR driver power losses in the target application to avoid over temperature and to optimize efficiency. In SR systems the body diode of the SR MOSFET starts conducting before SR MOSFET is turned−on, because there is some delay from VTH_CS_ON detect to turn−on the driver. On the other hand, the SR MOSFET turn off process always starts before the drain to source voltage rises up Step 1 − MOSFET Gate−to Source Capacitance: During ZVS operation the gate to drain capacitance does not have a Miller effect like in hard switching systems because the drain to source voltage does not change (or its change is negligible). www.onsemi.com 30 NCP43080 it will need to be measured. Please note that the input capacitance is not linear (as shown Figure 62) and it needs to be characterized for a given gate voltage clamp level. Step 2 − Gate Drive Losses Calculation: Gate drive losses are affected by the gate driver clamp voltage. Gate driver clamp voltage selection depends on the type of MOSFET used (threshold voltage versus channel resistance). The total power losses (driving loses and conduction losses) should be considered when selecting the gate driver clamp voltage. Most of today’s MOSFETs for SR systems feature low RDS(on) for 5 V VGS voltage. The NCP43080 offers both a 5 V gate clamp and a 10 V gate clamp for those MOSFET that require higher gate to source voltage. The total driving loss can be calculated using the selected gate driver clamp voltage and the input capacitance of the MOSFET: P DRV_total + V CC @ V CLAMP @ C g_ZVS @ f SW Where: VCC VCLAMP Cg_ZVS C iss + C gs ) C gd (eq. 9) is the NCP43080 supply voltage is the driver clamp voltage is the gate to source capacitance of the MOSFET in ZVS mode fsw is the switching frequency of the target application The total driving power loss won’t only be dissipated in the IC, but also in external resistances like the external gate resistor (if used) and the MOSFET internal gate resistance (Figure 44). Because NCP43080 features a clamped driver, it’s high side portion can be modeled as a regular driver switch with equivalent resistance and a series voltage source. The low side driver switch resistance does not drop immediately at turn−off, thus it is necessary to use an equivalent value (RDRV_SIN_EQ) for calculations. This method simplifies power losses calculations and still provides acceptable accuracy. Internal driver power dissipation can then be calculated using Equation 10: C rss + C gd C oss + C ds ) C gd Figure 62. Typical MOSFET Capacitances Dependency on VDS and VGS Voltages Therefore, the input capacitance of a MOSFET operating in ZVS mode is given by the parallel combination of the gate to source and gate to drain capacitances (i.e. Ciss capacitance for given gate to source voltage). The total gate charge, Qg_total, of most MOSFETs on the market is defined for hard switching conditions. In order to accurately calculate the driving losses in a SR system, it is necessary to determine the gate charge of the MOSFET for operation specifically in a ZVS system. Some manufacturers define this parameter as Qg_ZVS. Unfortunately, most datasheets do not provide this data. If the Ciss (or Qg_ZVS) parameter is not available then www.onsemi.com 31 NCP43080 Figure 63. Equivalent Schematic of Gate Drive Circuitry P DRV_IC + 1 @ C g_ZVS @ V CLAMP 2 @ f SW @ 2 ǒ R DRV_SINK_EQ 1 ) @ C g_ZVS @ V CLAMP 2 @ f SW @ 2 Where: RDRV_SINK_EQ Ǔ R DRV_SINK_EQ ) R G_EXT ) R g_int ǒ R DRV_SOURCE_EQ ) C g_ZVS @ V CLAMP @ f SW @ ǒV CC * V CLAMPǓ Ǔ (eq. 10) R DRV_SOURCE_EQ ) R G_EXT ) R g_int Step 4 − IC Die Temperature Arise Calculation: The die temperature can be calculated now that the total internal power losses have been determined (driver losses plus internal IC consumption losses). The package thermal resistance is specified in the maximum ratings table for a 35 mm thin copper layer with no extra copper plates on any pin (i.e. just 0.5 mm trace to each pin with standard soldering points are used). The DIE temperature is calculated as: is the NCP43080x driver low side switch equivalent resistance (0.5 W) RDRV_SOURCE_EQ is the NCP43080x driver high side switch equivalent resistance (1.2 W) is the external gate resistor (if used) RG_EXT Rg_int is the internal gate resistance of the MOSFET T DIE + ǒP DRV_IC ) P CCǓ @ R qJ−A ) T A Step 3 − IC Consumption Calculation: In this step, power dissipation related to the internal IC consumption is calculated. This power loss is given by the ICC current and the IC supply voltage. The ICC current depends on switching frequency and also on the selected min tON and tOFF periods because there is current flowing out from the min tON and tOFF pins. The most accurate method for calculating these losses is to measure the ICC current when CDRV = 0 nF and the IC is switching at the target frequency with given MIN_TON and MIN_TOFF adjust resistors. IC consumption losses can be calculated as: P CC + V CC @ I CC Where: PDRV_IC PCC RqJA TA (eq. 11) www.onsemi.com 32 (eq. 12) is the IC driver internal power dissipation is the IC control internal power dissipation is the thermal resistance from junction to ambient is the ambient temperature NCP43080 PRODUCT OPTIONS OPN Package UVLO [V] DRV clamp [V] Pin 5 function NCP43080ADR2G SOIC8 4.5 4.7 NC NCP43080AMTTWG WDFN8 4.5 4.7 NC NCP43080DDR2G SOIC8 4.5 9.5 NC NCP43080DMNTWG DFN8 4.5 9.5 NC NCP43080DMTTWG WDFN8 4.5 9.5 NC NCP43080QDR2G SOIC8 4.5 9.5 MAX_TON Usage LLC, CCM flyback, DCM flyback, forward, QR, QR with primary side CCM control QR with forced CCM from secondary side ORDERING INFORMATION Device NCP43080ADR2G Package Package marking Packing Shipping† SOIC8 43080A SOIC−8 (Pb−Free) 2500 /Tape & Reel WDFN−8 (Pb−Free) 3000 /Tape & Reel DFN−8 (Pb−Free) 4000 /Tape & Reel NCP43080DDR2G 43080D NCP43080QDR2G 43080Q NCP43080AMTTWG WDFN8 NCP43080DMTTWG NCP43080DMNTWG FA FD DFN8 43080D †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. www.onsemi.com 33 NCP43080 PACKAGE DIMENSIONS SOIC−8 NB CASE 751−07 ISSUE AK NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: MILLIMETER. 3. DIMENSION A AND B DO NOT INCLUDE MOLD PROTRUSION. 4. MAXIMUM MOLD PROTRUSION 0.15 (0.006) PER SIDE. 5. DIMENSION D DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLE DAMBAR PROTRUSION SHALL BE 0.127 (0.005) TOTAL IN EXCESS OF THE D DIMENSION AT MAXIMUM MATERIAL CONDITION. 6. 751−01 THRU 751−06 ARE OBSOLETE. NEW STANDARD IS 751−07. −X− A 8 5 S B 0.25 (0.010) M Y M 1 4 K −Y− G C N DIM A B C D G H J K M N S X 45 _ SEATING PLANE −Z− 0.10 (0.004) H M D 0.25 (0.010) M Z Y S X J S SOLDERING FOOTPRINT* 1.52 0.060 7.0 0.275 4.0 0.155 0.6 0.024 1.270 0.050 SCALE 6:1 mm Ǔ ǒinches *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. www.onsemi.com 34 MILLIMETERS MIN MAX 4.80 5.00 3.80 4.00 1.35 1.75 0.33 0.51 1.27 BSC 0.10 0.25 0.19 0.25 0.40 1.27 0_ 8_ 0.25 0.50 5.80 6.20 INCHES MIN MAX 0.189 0.197 0.150 0.157 0.053 0.069 0.013 0.020 0.050 BSC 0.004 0.010 0.007 0.010 0.016 0.050 0 _ 8 _ 0.010 0.020 0.228 0.244 NCP43080 PACKAGE DIMENSIONS DFN8 4x4 CASE 488AF ISSUE C A B D PIN ONE REFERENCE 0.15 C 2X 0.15 C 2X 0.10 C 8X ÉÉ ÉÉ ÉÉ 0.08 C L1 DETAIL A E OPTIONAL CONSTRUCTIONS ÇÇ ÇÇ ÉÉ TOP VIEW EXPOSED Cu ÇÇÇÇ DETAIL B A A1 C SIDE VIEW ÇÇ MOLD CMPD ÉÉÉ ÉÉÉ ÇÇÇ A3 A1 DETAIL B (A3) NOTE 4 ALTERNATE CONSTRUCTIONS SEATING PLANE D2 DETAIL A 1 ÇÇ 8 K e NOTES: 1. DIMENSIONS AND TOLERANCING PER ASME Y14.5M, 1994. 2. CONTROLLING DIMENSION: MILLIMETERS. 3. DIMENSION b APPLIES TO PLATED TERMINAL AND IS MEASURED BETWEEN 0.15 AND 0.30MM FROM TERMINAL TIP. 4. COPLANARITY APPLIES TO THE EXPOSED PAD AS WELL AS THE TERMINALS. 5. DETAILS A AND B SHOW OPTIONAL CONSTRUCTIONS FOR TERMINALS. L L 8X DIM A A1 A3 b D D2 E E2 e K L L1 MILLIMETERS MIN MAX 0.80 1.00 0.00 0.05 0.20 REF 0.25 0.35 4.00 BSC 1.91 2.21 4.00 BSC 2.09 2.39 0.80 BSC 0.20 −−− 0.30 0.50 −−− 0.15 SOLDERING FOOTPRINT* L 8X 2.21 4 0.63 E2 5 8X 4.30 2.39 b 0.10 C A B 0.05 C PACKAGE OUTLINE NOTE 3 BOTTOM VIEW 8X 0.80 PITCH 0.35 DIMENSIONS: MILLIMETERS *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. www.onsemi.com 35 NCP43080 PACKAGE DIMENSIONS WDFN8 2x2, 0.5P CASE 511AT ISSUE O D L A B L NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1994. 2. CONTROLLING DIMENSION: MILLIMETERS. 3. DIMENSION b APPLIES TO PLATED TERMINAL AND IS MEASURED BETWEEN 0.15 AND 0.30 MM FROM TERMINAL TIP. L1 PIN ONE REFERENCE 0.10 C 2X 2X ÍÍÍ ÍÍÍ ÍÍÍ 0.10 C DETAIL A E ALTERNATE TERMINAL CONSTRUCTIONS ÉÉ ÉÉ TOP VIEW EXPOSED Cu DETAIL B 0.05 C 0.05 C A1 A3 SIDE VIEW e/2 MOLD CMPD DETAIL B A 8X MILLIMETERS MIN MAX 0.70 0.80 0.00 0.05 0.20 REF 0.20 0.30 2.00 BSC 2.00 BSC 0.50 BSC 0.40 0.60 --0.15 0.50 0.70 ALTERNATE CONSTRUCTIONS C SEATING PLANE RECOMMENDED SOLDERING FOOTPRINT* DETAIL A e 7X 1 DIM A A1 A3 b D E e L L1 L2 7X PACKAGE OUTLINE 0.78 L 4 L2 2.30 8 5 8X BOTTOM VIEW b 0.10 C A 0.05 C 0.88 1 B 8X NOTE 3 0.30 0.50 PITCH DIMENSIONS: MILLIMETERS *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. 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