NCP1406 25 V/25 mA PFM Step−Up DC−DC Converter The NCP1406 is a monolithic PFM step−up DC−DC converter. This device is designed to boost single Lithium or two cells AA/AAA battery voltage up to 25 V (with internal MOSFET) output for handheld applications. A pullup Chip Enable feature is built−in with this device to extend battery−operating life. In addition to standard boost converter topologies, this device can be configured for voltage−inverting and step−down applications. This device is available in space−saving TSOP−5 package. With its small footprint, the device is also ideal for generating a boosted voltage from a 3.3 V or 5.0 V power rail. Features • • • • • • • • • • • • • • 85% Efficiency at VOUT = 25 V, IOUT = 25 mA, VIN = 5.0 V Low Operating Current of 15 mA (Not Switching) Low Shutdown Current of 0.3 mA Low Startup Voltage of 1.8 V Typical at 0 mA Output Voltage up to 25 V with Built−in 26 V MOSFET Switch PFM Switching Frequency up to 1.0 MHz Chip Enable Output Voltage Soft−Start Feedback Pin Open/Short Circuit Protection Input Undervoltage Lockout Thermal Shutdown Low Profile and Minimum External Parts Micro Miniature TSOP−5 Package Pb−Free Package is Available http://onsemi.com MARKING DIAGRAM 5 5 1 DAMAYWG G TSOP−5/SOT23−5/SC59−5 SN SUFFIX CASE 483 1 DAM = Device Marking A = Assembly Location Y = Year W = Work Week G = Pb−Free Package (Note: Microdot may be in either location) PIN CONNECTIONS CE 1 FB 2 VDD 3 5 LX 4 GND (Top View) Typical Applications • • • • • • • • LCD Bias White LED Driver OLED Driver Personal Digital Assistants (PDA) Digital Still Camera Cellular Telephone Hand−Held Games Hand−Held Instrument © Semiconductor Components Industries, LLC, 2006 February, 2006 − Rev. 2 ORDERING INFORMATION Device Package Shipping† NCP1406SNT1 TSOP−5 3000 Tape & Reel NCP1406SNT1G TSOP−5 (Pb−Free) 3000 Tape & Reel †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. 1 Publication Order Number: NCP1406/D NCP1406 L1 8.2 mH D1 MBR0530T1 VOUT 25 V VIN 2.0 V to 5.5 V CE 1 LX 5 FB 2 Enable VDD 3 NCP1406 C1 10 mF C2 3.3 mF C3 82 pF R1 2.2 MW GND 4 R2 110 kW ǒ Ǔ ǒ Ǔ ǒ Ǔ R VOUT + 1.19 1 ) 1 R2 Figure 1. Typical 25 V Step−Up Application Circuit L1 8.2 mH D1 MBR0520LT1 VOUT 15 V VIN 2.0 V to 5.5 V CE 1 LX 5 FB 2 Enable VDD 3 NCP1406 C1 10 mF C2 4.7 mF C3 68 pF R1 1.3 MW GND 4 R2 110 kW R VOUT + 1.19 1 ) 1 R2 Figure 2. Typical 15 V Step−Up Application Circuit L1 8.2 mH D1 MBR0520LT1 VOUT 8V VIN 2.0 V to 5.5 V CE 1 FB 2 Enable VDD 3 LX 5 NCP1406 C1 10 mF C2 4.7 mF C3 12 pF GND 4 R1 620 kW R2 110 kW R VOUT + 1.19 1 ) 1 R2 Figure 3. Typical 8.0 V Step−Up Application Circuit http://onsemi.com 2 NCP1406 LX VDD FB Fault Protection TSD UVLO PFM Comparator Driver PFM ON/OFF Timing Control − FB + + − Vref CE Soft−Start GND Figure 4. Representative Block Diagram PIN FUNCTION DESCRIPTION Pin Symbol Description 1 CE Chip Enable Pin (1) The chip is enabled if a voltage which is equal to or greater than 0.9 V is applied. (2) The chip is disabled if a voltage which is less than 0.3 V is applied. (3) The chip will be enabled if it is left floating. 2 FB PFM comparator inverting input, and is connected to off−chip resistor divider which sets output voltage. 3 VDD Power supply pin for internal circuit. 4 GND Ground pin. 5 LX External inductor connection pin. MAXIMUM RATINGS Rating Symbol Value Unit Power Supply Voltage (Pin 3) VDD −0.3 to 6.0 V Input/Output Pin LX (Pin 5) LX Peak Sink Current FB (Pin 2) VLX ILX VFB −0.3 to 27 1.5 −0.3 to 6.0 V A V CE (Pin 1) Input Voltage Range VCE −0.3 to 6.0 V Power Dissipation and Thermal Characteristics Maximum Power Dissipation @ TA = 25_C Thermal Resistance, Junction−to−Air PD RqJA 500 250 mW _C/W Operating Ambient Temperature Range TA −40 to +85 _C Operating Junction Temperature Range TJ −40 to +150 _C Tstg −55 to +150 _C Storage Temperature Range 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 series contains ESD protection and exceeds the following tests: Human Body Model (HBM) "2.0 kV per JEDEC standard: JESD22−A114 for all pins. Machine Model (MM) "200 V per JEDEC standard: JESD22−A115 for all pins. 2. Latchup Current Maximum Rating: "150 mA per JEDEC standard: JESD78. 3. Moisture Sensitivity Level (MSL): 1 per IPC/JEDEC standard: J−STD−020A. http://onsemi.com 3 NCP1406 DISSIPATION RATINGS Package Power Rating @TA 255C Derating Factor @TA 255C Power Rating @TA = 705C Power Rating @TA = 855C TSOP−5 500 mW 4.0 mW/°C 320 mW 260 mW ELECTRICAL CHARACTERISTICS (VOUT = 25 V, TA = −40_C to +85_C for min/max values, typical values are at TA = 25_C, unless otherwise noted.) Characteristic Symbol Min Typ Max Unit Minimum Off Time (VDD = 3.0 V, VFB = 0 V) toff 0.08 0.13 0.20 ms Maximum On Time (Current Not Asserted) ton 0.58 0.90 1.40 ms Maximum Duty Cycle DMAX 84 90 96 % Minimum Startup Voltage (IOUT = 0 mA) Vstart − 1.8 2.0 V DVstart − 1.6 − mV/°C Vhold − 1.7 1.9 V tSS − 3.0 8.0 ms VLX − − 26 V Rsw(on) − 0.7 − W Current Limit (When ILX reaches ILIM, the LX switch is turned off by the LX switch protection circuit) (Note 5) ILIM − 0.80 − A Off−State Leakage Current (VLX = 26 V) ILKG − 0.1 1.0 mA CE Input Voltage (VDD = 3.0 V, VFB = 0 V) High State, Device Enabled Low State, Device Disabled VCE(high) VCE(low) 0.9 − − − − 0.3 V V CE Input Current High State, Device Enabled (VDD = VCE = 5.5 V) Low State, Device Disabled (VDD = 5.5 V, VCE = VFB = 0 V) ICE(high) ICE(low) − −500 10 −150 500 − nA nA ON/OFF TIMING CONTROL Minimum Startup Voltage Temperature Coefficient (TA = −40 to +85°C) Minimum Hold Voltage (IOUT = 0 mA) Soft−Start Time LX (PIN 5) Internal Switch Voltage (Note 4) (Note 5) LX Pin On−State Resistance (VLX = 0.4 V, VDD = 5.0 V) CE (PIN 1) TOTAL DEVICE Supply Voltage VDD 1.4 − 5.5 V VUVLO − 1.0 1.3 V VFB 1.178 1.170 1.190 1.190 1.202 1.210 V IFB − 15 45 nA Operating Current 1 (VFB = 0 V, VDD = VCE = 3.0 V, Maximum Duty Cycle) IDD1 − 0.7 1.5 mA Operating Current 2 (VDD = VCE = VFB = 3.0 V, Not Switching) IDD2 − 15 25 mA Off−State Current (VDD = 5.0 V, VCE = 0 V) IOFF − 0.3 1.3 mA Thermal Shutdown (Note 5) TSD − 140 − °C TSDHYS − 10 − °C Undervoltage Lockout (VDD Falling) Feedback Voltage TA = 25°C TA = −40 to +85°C Feedback Pin Bias Current (VFB = 1.19 V) Thermal Shutdown Hysteresis (Note 5) 4. Recommended maximum VOUT up to 25 V. 5. Guaranteed by design, not tested. http://onsemi.com 4 NCP1406 TYPICAL CHARACTERISTICS 100 4.2 V 5.0 V 4.2 V 25.0 3.0 V VIN = 2.4 V VOUT = 25 V L1 = 8.2 mH, Sumida CR43−8R2MC C1 = 10 mF C2 = 3.3 mF C3 = 82 pF TA = 25°C Figure 1 3.7 V 24.5 24.0 0 10 20 30 VOUT, OUTPUT VOLTAGE (V) 40 VIN = 2.4 V 70 60 0 50 10 20 30 40 50 Figure 5. Output Voltage versus Output Current (VOUT = 25 V, L = 8.2 H) Figure 6. Efficiency versus Output Current (VOUT = 25 V, L = 8.2 H) 100 VOUT = 15 V L1 = 8.2 mH, Sumida CR43−8R2MC C1 = 10 mF C2 = 4.7 mF C3 = 68 pF TA = 25°C Figure 2 3.7 V VIN = 2.0 V 2.4 V 5.0 V 3.0 V 4.2 V 14.5 14.0 0 20 90 3.0 V 80 VOUT = 15 V L1 = 8.2 mH, Sumida CR43−8R2MC C1 = 10 mF C2 = 4.7 mF C3 = 68 pF TA = 25°C Figure 2 2.4 V VIN = 2.0 V 70 40 60 60 0 80 5.0 V 4.2 V 3.7 V 15.0 20 40 60 80 IOUT, OUTPUT CURRENT (mA) IOUT, OUTPUT CURRENT (mA) Figure 7. Output Voltage versus Output Current (VOUT = 15 V, L = 8.2 H) Figure 8. Efficiency versus Output Current (VOUT = 15 V, L = 8.2 H) 9.0 100 90 3.7 V 4.2 V EFFICIENCY (%) VOUT = 8.0 V L1 = 8.2 mH, Sumida CR43−8R2MC C1 = 10 mF C2 = 4.7 mF C3 = 12 pF TA = 25°C Figure 3 5.0 V 8.0 VIN = 2.0 V 2.4 V 3.0 V 7.5 7.0 0 VOUT = 25 V L1 = 8.2 mH, Sumida CR43−8R2MC C1 = 10 mF C2 = 3.3 mF C3 = 82 pF TA = 25°C Figure 1 3.7 V 3.0 V IOUT, OUTPUT CURRENT (mA) 15.5 8.5 80 IOUT, OUTPUT CURRENT (mA) 16.0 VOUT, OUTPUT VOLTAGE (V) 5.0 V 90 EFFICIENCY (%) 25.5 EFFICIENCY (%) VOUT, OUTPUT VOLTAGE (V) 26.0 2.4 V 80 3.7 V 3.0 V VIN = 2.0 V VOUT = 8.0 V L1 = 8.2 mH, Sumida CR43−8R2MC C1 = 10 mF C2 = 4.7 mF C3 = 12 pF TA = 25°C Figure 3 70 25 50 75 100 125 150 60 0 25 5.0 V 4.2 V 50 75 100 125 IOUT, OUTPUT CURRENT (mA) IOUT, OUTPUT CURRENT (mA) Figure 9. Output Voltage versus Output Current (VOUT = 8.0 V, L = 8.2 H) Figure 10. Efficiency versus Output Current (VOUT = 8.0 V, L = 8.2 H) http://onsemi.com 5 150 NCP1406 TYPICAL CHARACTERISTICS 100 VOUT = 25 V L1 = 10 mH, Sumida CMD4D11−100MC C1 = 10 mF C2 = 3.3 mF C3 = 150 pF TA = 25°C Figure 1 25.5 25.0 2.4 V 3.7 V 3.0 V 4.2 V 90 EFFICIENCY (%) V VOUT, OUTPUT VOLTAGE (V) 26.0 5.0 V VIN = 2.0 V 24.5 24.0 5 10 15 20 25 2.4 V VIN = 2.0 V 5 10 15 20 25 IOUT, OUTPUT CURRENT (mA) IOUT, OUTPUT CURRENT (mA) Figure 11. Output Voltage versus Output Current (VOUT = 25 V, L = 10 H) Figure 12. Efficiency versus Output Current (VOUT = 25 V, L = 10 H) 30 100 VOUT = 15 V L1 = 10 mH, Sumida CMD4D11−100MC C1 = 10 mF C2 = 4.7 mF C3 = 120 pF TA = 25°C Figure 2 15.5 3.7 V 90 15.0 4.2 V 2.4 V VIN = 2.0 V 5.0 V 3.0 V 14.5 3.7 V 3.0 V VOUT = 15 V L1 = 10 mH, Sumida CMD4D11−100MC C1 = 10 mF C2 = 4.7 mF C3 = 120 pF TA = 25°C Figure 2 2.4 V 80 VIN = 2.0 V 70 14.0 0 10 20 30 40 50 5.0 V 4.2 V EFFICIENCY (%) VOUT, OUTPUT VOLTAGE (V) VOUT = 25 V L1 = 10 mH, Sumida CMD4D11−100MC C1 = 10 mF C2 = 3.3 mF C3 = 150 pF TA = 25°C Figure 1 3.7 V 3.0 V 60 0 30 16.0 60 0 60 10 20 30 40 50 IOUT, OUTPUT CURRENT (mA) IOUT, OUTPUT CURRENT (mA) Figure 13. Output Voltage versus Output Current (VOUT = 15 V, L = 10 H) Figure 14. Efficiency versus Output Current (VOUT = 15 V, L = 10 H) 9.0 60 100 VOUT = 8.0 V L1 = 10 mH, Sumida CMD4D11−100MC C1 = 10 mF C2 = 4.7 mF C3 = 20 pF TA = 25°C Figure 3 8.5 5.0 V 90 3.7 V EFFICIENCY (%) VOUT, OUTPUT VOLTAGE (V) 80 70 0 5.0 V 4.2 V 4.2 V 5.0 V 8.0 2.4 V VIN = 2.0 V 7.5 7.0 0 3.0 V 2.4 V 80 3.0 V VIN = 2.0 V VOUT = 8.0 V L1 = 10 mH, Sumida CMD4D11−100MC C1 = 10 mF C2 = 4.7 mF C3 = 20 pF TA = 25°C Figure 3 70 25 50 75 100 60 0 25 4.2 V 3.7 V 50 75 IOUT, OUTPUT CURRENT (mA) IOUT, OUTPUT CURRENT (mA) Figure 15. Output Voltage versus Output Current (VOUT = 8.0 V, L = 10 H) Figure 16. Efficiency versus Output Current (VOUT = 8.0 V, L = 10 H) http://onsemi.com 6 100 NCP1406 TYPICAL CHARACTERISTICS 100 DMAX, MAXIMUM CYCLE (%) VFB, FEEDBACK VOLTAGE (V) 1.22 1.20 1.18 1.16 90 80 70 VDD = 3.0 V VFB = 0 V VDD = 3.0 V 1.14 −50 −25 0 25 50 75 60 −50 100 0 25 50 TA, AMBIENT TEMPERATURE (°C) Figure 17. Feedback Voltage versus Ambient Temperature Figure 18. Maximum Duty Cycle versus Ambient Temperature toff, MINIMUM OFF TIME (ms) 1.0 0.9 0.8 0.7 0.16 0.14 0.12 0.10 VDD = 3.0 V −25 0 25 50 75 VDD = 3.0 V 0.08 −50 100 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) Figure 19. Maximum On Time versus Ambient Temperature Figure 20. Minimum Off Time versus Ambient Temperature 100 25 IDD2, OPERATING CURRENT 2 (mA) IDD1, OPERATING CURRENT 1 (mA) −25 TA, AMBIENT TEMPERATURE (°C) 1000 900 800 700 600 500 −50 100 0.18 1.1 0.6 −50 75 TA, AMBIENT TEMPERATURE (°C) 1.2 ton, MAXIMUM ON TIME (ms) −25 VDD = VCE = 3.0 V VFB = 0 V −25 0 25 50 75 100 20 15 10 5 VDD = VCE = VFB = 3.0 V 0 −50 −25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) TA, AMBIENT TEMPERATURE (°C) Figure 21. Operating Current 1 versus Ambient Temperature Figure 22. Operating Current 2 versus Ambient Temperature http://onsemi.com 7 100 NCP1406 800 600 400 200 VDD = 5.0 V VCE = 0 V −25 0 25 50 75 100 40 30 20 10 VDD = VCE = 5.5 V 0 −50 −25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) Figure 23. Off−State Current versus Ambient Temperature Figure 24. CE “High” Input Current versus Ambient Temperature −500 −400 −300 −200 −100 VDD = 5.5 V VCE = 0 V 0 −50 50 TA, AMBIENT TEMPERATURE (°C) −25 0 25 50 75 100 2.2 2.0 1.8 1.6 IOUT = 0 mA 1.4 −50 −25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) Figure 25. CE “Low” Input Current versus Ambient Temperature Figure 26. Minimum Startup Voltage versus Ambient Temperature 1.3 100 2.4 TA, AMBIENT TEMPERATURE (°C) 100 6 tss, SOFT−START TIME (ms) VUVLO, UNDERVOLTAGE LOCKOUT VOLTAGE (V) ICE(low), CE “LOW” INPUT CURRENT (nA) 0 −50 VSTART, MINIMUM STARTUP VOLTAGE (V) IOFF, OFF−STATE CURRENT (nA) 1000 ICE(high), CE “HIGH” INPUT CURRENT (nA) TYPICAL CHARACTERISTICS 1.2 1.1 1.0 0.9 0.8 −50 −25 0 25 50 75 100 5 4 3 2 1 0 −50 −25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) TA, AMBIENT TEMPERATURE (°C) Figure 27. Undervoltage Lockout Voltage versus Ambient Temperature Figure 28. Soft−start Time versus Ambient Temperature http://onsemi.com 8 100 NCP1406 TYPICAL CHARACTERISTICS 1.1 0.4 0.3 0.2 ILIMIT, CURRENT LIMIT (A) VOUT = 25 V L1 = 8.2 mH D1 = MBR0530LT1 C1 = 10 mF C2 = 3.3 mF C3 = 82 pF R1 = 2.2 MW R2 = 110 kW TA = 25°C 0.1 0 1 2 3 4 5 −25 0 25 50 75 Figure 30. Current Limit versus Ambient Temperature RSW(on), SWITCH−ON RESISTANCE (W) TA = 85°C 0.8 TA = 25°C 0.6 TA = −40°C 2 3 4 5 6 100 1.4 1.8 V 2.0 V 1.2 2.4 V 1.0 3.0 V 3.7 V 0.8 VDD = 5.0 V 0.6 0.4 −50 −25 0 25 50 75 VIN, INPUT VOLTAGE (V) TA, AMBIENT TEMPERATURE (°C) Figure 31. Switch−ON Resistance versus Input Voltage Figure 32. Switch−ON Resistance versus Ambient Temperature 1000 VDD = 3.0 V VLX = 26 V VCE = 0 V 600 400 200 0 −50 0.7 Figure 29. No Load Input Current versus Input Voltage 1.0 800 0.8 TA, AMBIENT TEMPERATURE (°C) 1.2 1 0.9 VIN, INPUT VOLTAGE (V) 1.4 0.4 1.0 0.6 −50 6 −25 0 25 50 75 100 IFB, FEEDBACK PIN BIAS CURRENT (nA) ILKG, LX PIN OFF−STATE LEAKAGE CURRENT (nA) RSW(on), SWITCH−ON RESISTANCE (W) IIN, NO LOAD INPUT CURRENT (mA) 0.5 50 VDD = 3.0 V VFB = 1.19 V 40 30 20 10 0 −50 −25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) TA, AMBIENT TEMPERATURE (°C) Figure 33. LX Pin OFF−State Leakage Current versus Ambient Temperature Figure 34. Feedback Pin Bias Current versus Ambient Temperature http://onsemi.com 9 100 100 NCP1406 TYPICAL CHARACTERISTICS L1 = 8.2 mH, C1 = 10 mF, C2 = 3.3 mF, VIN = 3.7 V 1. VOUT = 25 V (AC Coupled), 100 mV/div 2. IOUT = 1.0 mA to 15 mA, 20 mA/div L1 = 8.2 mH, C1 = 10 mF, C2 = 4.7 mF, VIN = 3.7 V 1. VOUT = 15 V (AC Coupled), 100 mV/div 2. IOUT = 1.0 mA to 20 mA, 20 mA/div Figure 35. Load Transient Response (VOUT = 25 V) Figure 36. Load Transient Response (VOUT = 15 V) L1 = 8.2 mH, C1 = 10 mF, C2 = 3.3 mF, IOUT = 15 mA 1. VOUT = 25 V (AC Coupled), 100 mV/div 2. VIN = 3.0 V to 4.0 V, 2.0 V/div L1 = 8.2 mH, C1 = 10 mF, C2 = 4.7 mF, IOUT = 15 mA 1. VOUT = 15 V (AC Coupled), 100 mV/div 2. VIN = 3.0 V to 4.0 V, 2.0 V/div Figure 37. Line Transient Response (VOUT = 25 V) Figure 38. Line Transient Response (VOUT = 15 V) L1 = 8.2 mH, C1 = 10 mF, C2 = 3.3 mF, VIN = 4.2 V, VOUT = 25 V, IOUT = 5.0 mA 1. VLX, 10 V/div 2. IL, 200 mA/div 3. Vripple, 50 mV/div L1 = 8.2 mH, C1 = 10 mF, C2 = 3.3 mF, VIN = 4.2 V, VOUT = 25 V, IOUT = 30 mA 1. VLX, 10 V/div 2. IL, 200 mA/div 3. Vripple, 50 mV/div Figure 39. Operating Waveforms (Light Load) Figure 40. Operating Waveforms (Heavy Load) http://onsemi.com 10 NCP1406 TYPICAL CHARACTERISTICS L1 = 8.2 mH, C1 = 10 mF, C2 = 3.3 mF, VIN = 4.2 V, IOUT = 20 mA 1. VCE, 0 V to 1.0 V to 0 V, 1.0 V/div 2. IL, 500 mA/div 3. VOUT, 10 mV/div L1 = 8.2 mH, C1 = 10 mF, C2 = 4.7 mF, VIN = 4.2 V, IOUT = 25 mA 1. VCE, 0 V to 1.0 V to 0 V, 1.0 V/div 2. IL, 500 mA/div 3. VOUT, 10 mV/div Figure 41. Startup/Shutdown Waveforms (VOUT = 25 V) Figure 42. Startup/Shutdown Waveforms (VOUT = 15 V) 5.0 VSTART, STARTUP VOLTAGE (V) VSTART, STARTUP VOLTAGE (V) 5.0 4.0 VOUT = 25 V L1 = 10 mH, Sumida CMD4D11−100MC C1 = 10 mF C2 = 3.3 mF D1 = MBR0530LT1 Figure 1 TA = 25°C 3.0 2.0 1.0 0 0 5 10 15 20 25 4.0 3.0 2.0 1.0 0 30 VOUT = 15 V L1 = 10 mH, Sumida CMD4D11−100MC C1 = 10 mF C2 = 4.7 mF D1 = MBR0520LT1 Figure 2 TA = 25°C 0 5 10 15 20 25 IOUT, OUTPUT CURRENT (mA) IOUT, OUTPUT CURRENT (mA) Figure 43. Startup Voltage versus Output Current (VOUT = 25 V) Figure 44. Startup Voltage versus Output Current (VOUT = 15 V) http://onsemi.com 11 NCP1406 DETAILED OPERATING DESCRIPTION Operation Current Limit The NCP1406 is a monolithic DC−DC switching converter optimized for single Lithium or two cells AA/AAA size batteries powered portable products. The NCP1406 device consists of soft−start circuit, chip enable circuit, PFM comparator, voltage reference, PFM on/off timing control circuit, driver, current limit circuit, open−drain MOSFET switch, input voltage UVLO, thermal shutdown, and feedback pin short−circuit/ open−circuit protection. The device operating current is typically 15 mA, and can be further reduced to about 0.3 mA when the chip is disabled (VCE < 0.3 V). The operation of NCP1406 can be best understood by referring to the block diagram and typical application circuit in Figures 1 and 4. The PFM comparator monitors the output voltage via the external feedback resistor divider by comparing the feedback voltage with the reference voltage. When the feedback voltage is lower than the reference voltage, the PFM control and driver circuit turns on the N−Channel MOSFET switch and the current ramps up in the inductor. The switch will remain on for the maximum on−time, 0.90 ms, or until the current limit is reached, whichever occurs first. The MOSFET switch is then turned off and energy stored in the inductor will be discharged to the output capacitor and load through the Schottky diode. The MOSFET switch will be turned off for at least the minimum off−time, 0.13 ms, and will remain off if the feedback voltage is higher than the reference voltage and output capacitor will be discharged to sustain the output current, until the feedback voltage is again lower than reference voltage. This switching cycle is then repeated to attain voltage regulation. The current limit circuit limits the maximum current flowing through the LX pin to typical 0.80 A during the MOSFET switch turn−on period. When the current limit is exceeded, the switch will be turned off. With the current limit circuit, the peak inductor current is limited to the current limit, saturation of inductor is prevented and output voltage over−shoot during startup can also be minimized. N−Channel MOSFET Switch The NCP1406 is built−in with a 26 V open drain N−Channel MOSFET switch which allows high output voltage up to 25 V to be generated from simple step−up topology. Input Voltage Undervoltage Lockout There is an undervoltage lockout circuit continuously monitoring the voltage at the VDD pin. The device will be disabled if the VDD pin voltage drops below the UVLO threshold voltage. FB Pin Short−Circuit/Open−Circuit Protection With the FB protection circuit, the drain−to−source leakage current of the N−Ch MOSFET is sensed. When the FB pin connection is shorted or opened, the converter switches at maximum duty cycle, the peak of VLX and the VOUT will build up, and the leakage current will increase. When the leakage current increases to a certain level, the converter will stop switching with the protection circuit. Therefore, the peak of VLX will stop increasing at a certain level before the N−Ch MOSFET is damaged immediately. However, the sensing of the leakage current is not very accurate and cannot be too close to the normal 26 V maximum operating condition. Therefore, the VLX is around 30 V to 40 V during a FB pin protection fault. Soft−Start Thermal Shutdown There is a soft−start circuit in NCP1406. When power is applied to the device, the soft−start circuit limits the device to switch at a small duty cycle initially, the duty cycle is then increased gradually until the output voltage is in regulation. With the soft−start circuit, the output voltage over−shoot is minimized and the startup capability with heavy loads is also improved. When the chip junction temperature exceeds 140°C, the entire IC is shutdown. The IC will resume operation when the junction temperature drops below 130°C. Enable/Disable Operation The NCP1406 offers IC shutdown mode by the chip enable pin (CE pin) to reduce current consumption. An internal 150 nA pullup current source ties the CE pin to the VDD pin by default. Therefore, the user can float the CE pin for permanent “ON”. When the voltage at the CE pin is equal to or greater than 0.9 V, the chip will be enabled, which means the device is in normal operation. When the voltage at the CE pin is less than 0.3 V, the chip is disabled, which means IC is shutdown. During shutdown, the IC supply current reduces to 0.3 mA and the LX pin enters high impedance state. However, the input remains connected to the output through the inductor and the Schottky diode, keeping the output voltage one diode forward voltage drop below the input voltage. ON/OFF Timing Control The maximum on−time is typically 0.90 ms, whereas, the minimum off−time is typically 0.13 ms. The switching frequency can be up to 1.0 MHz. Voltage Reference and Output Voltage The internal bandgap voltage reference is trimmed to 1.19 V at an accuracy of "1.0% at 25°C. The voltage reference is connected to the non−inverting input of the PFM comparator and the inverting input of the PFM comparator is connected to the FB pin. The output voltage can be set by connected an external resistor voltage divider from the VOUT to the FB pin. With the internal 26 V MOSFET switch, the output voltage can be set between VIN to 25 V. http://onsemi.com 12 NCP1406 APPLICATIONS CIRCUIT INFORMATION External Component Selection increases above the maximum output current in DCM mode. However, stable operation in continuous conduction mode is hard to achieve, and double pulsing or group pulsing will occur which will lead to much larger inductor current ripple and result in larger output ripple voltage. If the current limit is used to turn off the MOSFET in order to maximize the output current, it is critical to make sure that the current limit has been reached before the maximum on−time is met. To ensure this condition is met, the inductance L should be selected according the following inequality: Inductor The NCP1406 is designed to work well with a range of inductance values; the actual inductance value depends on the specific application, output current, efficiency, and output ripple voltage. For step−up conversion, the device works well with inductance ranging from 1.0 mH to 47 mH. In general, an inductor with small DCR, usually less than 1.0 W, should be used to minimize loss. It is necessary to choose an inductor with saturation current greater than the peak switching current in the application. NCP1406 is designed to operate in discontinuous conduction mode (DCM). Stable operation in continuous conduction mode is not guaranteed. For each switching cycle, if the internal MOSFET is switched on, it will be switched off only when either the maximum on−time, ton, of typical 0.9 ms is reached or the inductor current limit of 0.8 A is met, whichever is earlier. Therefore, the designer can choose to use either the maximum on−time or the current limit to turn off the MOSFET switch. If the goal is targeted to minimize output ripple voltage, the maximum on−time of 0.9 ms should be used to turn off the MOSFET; however, the maximum output current will be reduced. If we target to maximize the output current, the current limit should be chosen to turn off the MOSFET, but this method will result in a larger output ripple voltage. If the maximum on−time is used to turn off the MOSFET in order to achieve a smaller output ripple voltage, it is critical to ensure that the maximum on−time has been reached before the current limit is met. To ensure this condition is met, the inductance L should be selected according to the following inequality: Lu VIN ILIM Lt ton(max) Since there is 100 ns internal propagation delay between the time the current limit is reached and the time the MOSFET is switched off, the actual peak inductor current can be obtained from the equation below: V IPK + ILIM ) IN L 100 ns Where ILIM is the current limit which is typically 0.8 A, VIN is the input voltage, L is the selected inductance. Then the maximum output current under the current limit control can be calculated by the equation below: VIN IPK IOUT(max) + 2(VOUT ) VD) h This method can achieve larger maximum output current in DCM mode. Since the current limit is reached in each switching cycle, the inductor current ripple is larger resulting in larger output voltage ripple. Two ceramic capacitors in parallel can be used at the output to keep the output ripple small. Diode ton(max) The diode is the main source of loss in DC–DC converters. The key parameters which affect their efficiency are the forward voltage drop, VD, and the reverse recovery time, trr. The forward voltage drop creates a loss just by having a voltage across the device while a current flowing through it. The reverse recovery time generates a loss when the diode is reverse biased, and the current appears to actually flow backwards through the diode due to the minority carriers being swept from the P–N junction. A Schottky diode with the following characteristics is recommended: 1. Small forward voltage, VD < 0.3 V. 2. Small reverse leakage current. 3. Fast reverse recovery time/switching speed. 4. Rated current larger than peak inductor current, Irated > IPK. 5. Reverse voltage larger than output voltage, Vreverse > VOUT. Where VIN is the input voltage, ILIM is the current limit which is typically 0.8 A, and ton(max) is the maximum on−time which is typically 0.9 ms. The maximum output current under this maximum on−time control can be calculated from the equation below: 2 V IN ton(max) IOUT(max) + 2L(VOUT ) VD) VIN ILIM h Where VIN is the input voltage, ton(max) is the maximum on−time which is typically 0.9 ms, L is the selected inductance, VOUT is the desired output voltage, VD is the Schottky diode forward voltage, and h is the conversion efficiency which can be assumed typically 80% for better margin for estimation. The above equation for calculating IOUT(max) is for DCM mode operation only. In fact, the operation can go beyond the critical conduction mode if the current loading further http://onsemi.com 13 NCP1406 Input Capacitor 1% tolerance resistors should be used for both R1 and R2 for better VOUT accuracy. The input capacitor stabilizes the input voltage and minimizes peak current ripple from the power source. The capacitor should be connected directly to the inductor pin where the input voltage is applied in order to effectively smooth the input current ripple and voltage due to the inductor current ripple. The input capacitor is also used to decouple the high frequency noise from the VDD supply to the internal control circuit; therefore, the capacitor should be placed close to the VDD pin. For some particular applications, separate decoupling capacitors should be provided and connected directly to the VDD pin for better decoupling effect. A larger input capacitor can better reduce ripple current at the input. By reducing the ripple current at the input, the converter efficiency can be improved. In general, a 4.7 mF to 22 mF ceramic input capacitor is sufficient for most applications. X5R and X7R type ceramic capacitors are recommended due to their good capacitance tolerance and stable temperature behavior. Feedforward Capacitor A feedforward capacitor is required to add across the upper feedback resistor to avoid double pulsing or group pulsing at the switching node which will cause larger inductor ripple current and higher output voltage ripple. With adequate feedforward capacitance, evenly distributed single pulses at the switching node can be achieved. The range of the capacitor value is from 5.0 pF to 200 pF for most applications. For NCP1406, the lower the switching frequency, the larger the feedforward capacitance is needed; besides, the higher the output voltage, the larger the feedforward capacitance is required. For the initial trial value of the feedforward capacitor, the following equation can be used; however, the actual value needs fine tuning: 2 Ǔ I IPK L 1 Vripple + OUT * COUT fSW(Load) VOUT ) VD−VIN * (IPK−IOUT) ESR 2IOUT(VOUT ) VD−VIN) 2 I PK L Where IOUT is the nominal load current, COUT is the selected output capacitance, IPK is the peak inductor current, L is the selected inductance, VOUT is the output voltage, VD is the Schottky diode forward voltage, VIN is the input voltage, ESR is the ESR of the output capacitor. The NCP1406 can be used to produce a negative voltage output by adding a diode−capacitor charge−pump circuit (D2, D3, and C1) to the LX pin as shown in Figure 50. The feedback voltage resistor divider is still connected to the positive output to monitor the positive output voltage and a small value capacitor is used at C2. When the internal MOSFET switches off, the voltage at the LX pin charges up the capacitor through diode D2. When the MOSFET To achieve better efficiency at light load, a high impedance feedback resistor divider should be used. Choose the lower resistor R2 value from the range of 10 kW to 200 kW. The value of the upper resistor R1 can then be calculated from the equation below: ǒ R1 Negative Voltage Generation Feedback Resistors V R1 + R2 OUT * 1 1.19 20 The NCP1406 can be used to generate output voltage higher than 25 V by adding an external high voltage N−Ch MOSFET in series with the internal MOSFET switch as shown in Figure 51. The drain−to−source breakdown voltage of the external MOSFET must be at least 1.0 V higher than the output voltage. The diode D2 connected across the gate and the source of the external MOSFET helps the external MOSFET to turn off and ensures that most of the voltage drops across the external MOSFET during the switch−off period. Since the high voltage external MOSFET is in series with the internal MOSFET, higher break down voltage is achieved but the current capability is not increased. There is an alternative application circuit shown in Figure 53 which can output voltage up to 30 V. For this circuit, a diode−capacitor charge−pump voltage doubler constructed by D2, D3 and C1 is added. During the internal MOSFET switch−on time, the LX pin is shorted to ground and D2 will charge up C1 to the stepped up voltage at the cathode of D1. During the MOSFET switch−off time, the voltage at VOUT will be almost equal to the double of the voltage at the cathode of D1. The VOUT is monitored by the FB pin via the resistor divider and can be set by the resistor values. Since the maximum voltage at the cathode of D1 is 15 V, the maximum VOUT is 30 V. The value of C1 can be in the range of 0.47 mF to 2.2 mF. The output capacitor is used for sustaining the output voltage when no current is delivering from the input, and smoothing the ripple voltage. Ceramic capacitors should be used for the output capacitor due to their low ESR at high switching frequency and low profile in physical size. In general, a 3.3 mF to 22 mF ceramic capacitor should be appropriate for most applications. X5R and X7R type ceramic capacitors are recommended due to their good capacitance tolerance and temperature coefficient, while Y5V type ceramic capacitors are not recommended since both their capacitance tolerance and temperature coefficient are too large. The output voltage ripple and switching frequency at nominal load current can be calculated by the following equations: fSW(Load) + p fSW(Load) Output Voltage Higher than 25 V Output Capacitor ǒ 1 CFF [ Ǔ http://onsemi.com 14 NCP1406 switches on, the capacitor C1 is effectively connected like a reversed battery and C1 discharges the stored charge through the RDS(on) of the internal MOSFET and D3 to charge up COUT and builds up a negative voltage at VOUT. Since the negative voltage output is not directly monitored by the NCP1406, the output load regulation of the negative output is not as good as the standard positive output circuit. The resistance values of the resistors of the voltage divider can be one−tenth of those used in the positive output circuit in order to improve the regulation at light load. The application circuit in Figure 54, is actually the combination of the application circuits in Figures 50 and 51. Moreover, the brightness of the LEDs can be adjusted by a DC voltage or a PWM signal with an additional circuit illustrated below: To FB Pin To LED R2 DC/ PWM Signal D2 R1 100 kW C1 0.1 mF 680 pF GND Step−Down Converter RS C2 Figure 45. NCP1406 can be configured as a simple step−down converter by using the open−drain LX pin to drive an external P−Ch MOSFET as shown in Figure 52. The resistor RGS is used to switch off the P−Ch MOSFET during the switch−off period. Too small a resistance value should not be used for RGS, otherwise, the efficiency will be reduced. RGS should be in the range of 510 W to 5.1 kW. With this additional circuit, the maximum LED current is set by the above equation. The value of R2 can be obtained by the following equation: R2 + White LED Driver The NCP1406 can be used as a constant current LED driver which can drive up to 6 white LEDs in series as shown in Figure 57. The LED current can be set by the resistance value of RS. The desired LED current can be calculated by the equation below: VMAX DCTL(MAX) * VD * 1.19 (ILED(MAX)*ILED(MIN)) RS R1 ǒ Ǔ VMAX is the maximum voltage of the control signal, DCTL(MAX) is the maximum duty cycle of the control signal, VD is the diode forward voltage, ILED(MAX) is the maximum LED current and ILED(MIN) is the minimum LED current. If a PWM control signal is used, the signal frequency can be in the range of 5.0 kHz to 30 kHz. It is recommended to keep the input PWM frequency about 15 kHz to avoid generating audio noise. ILED + 1.19 RS http://onsemi.com 15 NCP1406 PCB Layout Guidelines PCB layout is very important for switching converter performance. All the converter’s external components should be placed closed to the IC. The schematic, PCB trace layout, and component placement of the step−up DC−DC converter demonstration board are shown in Figure 46 to Figure 49 for PCB layout design reference. The following guidelines should be observed: 1. Grounding Single−point grounding should be used for the output power return ground, the input power return ground, and the device switch ground to reduce noise. The input ground and output ground traces must be thick and short enough for current to flow through. A ground plane should be used to reduce ground bounce. 2. Power Traces Low resistance conducting paths (short and thick traces) should be used for the power carrying traces to reduce power loss so as to improve efficiency (short and thick traces for connecting the inductor L can also reduce stray inductance). The path between C1, L1, D1, and C2 should be kept short. The trace from L to LX pin of the IC should also be kept short. 3. External Feedback Components Feedback resistors R1 and R2, and feedforward capacitor C3 should be located as close to the FB pin as possible to minimize noise picked up by the FB pin. The ground connection of the feedback resistor divider should be connected directly to the GND pin. 4. Input Capacitor The input capacitor should be located close to both the input to the inductor and the VDD pin of the IC. 5. Output Capacitor The output capacitor should be placed close to the output terminals to obtain better smoothing effect on output ripple voltage. L1 8.2 mH C3 R1 CE 1 FB 2 C1 10 mF VDD 3 Enable D1 LX 5 NCP1406 TP1 VIN 1.8 V to 5.0 V MBR0530T1 TP3 VOUT 25 V C2 3.3 mF GND 4 R2 TP4 GND TP2 GND Figure 46. Step−Up Converter Demonstration Board Schematic http://onsemi.com 16 NCP1406 Figure 47. Step−Up Converter Demonstration Board Top Layer Component Silkscreen Figure 48. Step−Up Converter Demonstration Board Top Layer Copper Figure 49. Step−Up Converter Demonstration Board Bottom Layer Copper http://onsemi.com 17 NCP1406 Components Supplier Output Voltage Parts Supplier Part Number Description C1 Panasonic ECJ2FB0J106M Ceramic Capacitor 0805 10 mF/6.3 V www.panasonic.com C2 Panasonic ECJ3YB1E475M Ceramic Capacitor 1206 4.7 mF/25 V www.panasonic.com C3 Panasonic ECJ1VC1H560K Ceramic Capacitor 0603 56 pF/50 V www.panasonic.com D1 ON Semiconductor L1 Sumida Electric Co. Ltd R1 Panasonic ERJ3GEYJ135V Resistor 0603 1.3 MW www.panasonic.com R2 Panasonic ERJ3GEYJ114V Resistor 0603 110 kW www.panasonic.com U1 ON Semiconductor NCP1406SNT1 25 V Step−up DC−DC Converter C1 Panasonic ECJ2FB0J106M Ceramic Capacitor 0805 10 mF/6.3 V www.panasonic.com C2 Panasonic ECJ5YB1H335M Ceramic Capacitor 1812 3.3 mF/50 V www.panasonic.com C3 Panasonic ECJ1VC1H151K Ceramic Capacitor 0603 150 pF/50 V www.panasonic.com D1 ON Semiconductor L1 Sumida Electric Co. Ltd R1 Panasonic ERJ3GEYJ225V Resistor 0603 2.2 MW www.panasonic.com R2 Panasonic ERJ3GEYJ114V Resistor 0603 110 kW www.panasonic.com U1 ON Semiconductor NCP1406SNT1 25 V Step−up DC−DC Converter MBR0520LT1 15 V CMD4D11−100MC MBR0530LT1 CMD4D11−100MC Schottky Power Rectifier 20 V/500 mA www.onsemi.com Inductor 10 mH 1.2 mm Low Profile www.sumida.com www.onsemi.com Schottky Power Rectifier 30 V/500 mA www.onsemi.com Inductor 10 mH 1.2 mm Low Profile www.sumida.com www.onsemi.com OTHER APPLICATION CIRCUITS L 8.2 mH 2.2 mF C1 VIN 2.0 V to 5.5 V D3 D2 CIN 10 mF CE 1 FB 2 VDD 3 D1 LX 5 NCP1406 25 V Website VOUT −15 V COUT 4.7 mF 25 V 6.0 mA at VIN = 2.0 V 40 mA at VIN = 5.5 V C3 C2 2.2 mF 1000 pF GND 4 R1 R2 ǒ L: CR43−8R2MC, Sumida CIN: ECJ2FB0J106M, Panasonic COUT: ECJ3YB1E475M, Panasonic C1: ECJ2FB1C225K, Panasonic C2: ECJ2FB1C225K, Panasonic C3: ECJ1VC1H102J, Panasonic D1, D2: MBR0520LT1, ON Semiconductor D3: MBR0520LT1 x 2, ON Semiconductor Figure 50. Positive−to−Negative Output Converter for Negative LCD Bias http://onsemi.com 18 Ǔ R1 VOUT [ * 1.19 )1 )1 R2 NCP1406 L 8.2 mH D1 VOUT Up to 30 V VIN 3.0 V to 5.5 V Q1 CE 1 FB 2 VDD 3 LX 5 NCP1406 CIN 10 mF 10 V D2 C1 5 pF to 1000 pF R1 COUT 3.3 mF 50 V 6.0 mA at VIN = 3.0 V 35 mA at VIN = 5.5 V R2 GND 4 ǒ Ǔ R1 VOUT + 1.19 )1 R2 L: CR43−8R2MC, Sumida CIN: ECJ2FB0J106M, Panasonic COUT: ECJ5YB1H335M, Panasonic Q1: MGSF1N03T1, ON Semiconductor / NTHS5402T1, ON Semiconductor D1: MBR0530T1, ON Semiconductor D2: MMSD914T1, ON Semiconductor Figure 51. Step−Up DC−DC Converter with 30 V Output Voltage L 10 mH Q1 VIN 3.0 V to 5.5 V CE 1 FB 2 VDD 3 LX 5 NCP1406 CIN 10 mF 6.3 V RGS 1k D1 C1 1000 pF R1 39 k COUT 22 mF 6.3 V VOUT 1.6 V 200 mA R1 110 k GND 4 ǒ Ǔ R1 VOUT + 1.19 )1 R2 L: CR43−100MC, Sumida CIN: ECJ2FB0J106M, Panasonic COUT: ECJHVB0J226M, Panasonic Q1: MGSF1P02LT1, ON Semiconductor D1: MBR0530T1, ON Semiconductor Figure 52. Step−Down DC−DC Converter with 1.6 V Output Voltage for DSP Circuit http://onsemi.com 19 NCP1406 L 6.8 mH C1 1.0 mF D3 VOUT 30 V VIN 2.0 V to 5.5 V C2 7.0 pF R1 2.2 MW R2 91 kW CE 1 FB 2 VDD 3 COUT1 10 mF 16 V D2 LX 5 NCP1406 CIN 10 mF 6.3 V 2.0 mA at VIN = 2.0 V 35 mA at VIN = 5.5 V D1 COUT2 10 mF 16 V GND 4 ǒ Ǔ R1 VOUT + 1.19 )1 R2 L: CR43−6R8MC, Sumida CIN: ECJ2FB0J106M, Panasonic COUT1, COUT2: ECJ3YB1C106M, Panasonic C1: ECJ2FB1C225K, Panasonic D1, D2, D3: MBR0540T1, ON Semiconductor Figure 53. Step−Up DC−DC Converter with 30 V Output Voltage D3 L 8.2 mH D4 C2 3.3 mF 50 V C3 D2 2.2 mF/50 V VIN 3.3 V to 5.0 V C1 1 mF 50 V Q1 C4 750 pF to 2000 pF CE 1 R1 R2 FB 2 VDD 3 LX 5 U1 NCP1406 CIN 10 mF 6.3 V D1 GND 4 ǒ Ǔ R1 VOUT [ * 1.19 )1 )1 R2 L: CR43−8R2MC, Sumida CIN: ECJ2FB0J106M, Panasonic C1: ECJGVB1C105M, Panasonic C2: ECJ5YB1H335M, Panasonic C3: ECJ4YB1H105M, Panasonic Q1: MGSF1N03T1, ON Semiconductor / NTHS5402T1, ON Semiconductor D1, D2: MMSD914T1, ON Semiconductor D3: MBR0530T1, ON Semiconductor D4: MBR0530T1 x 2, ON Semiconductor Figure 54. Voltage Inverting DC−DC Converter with −28 V Output Voltage http://onsemi.com 20 VOUT −28 V 9.0 mA at VIN = 3.3 V 20 mA at VIN = 5.0 V NCP1406 D2 D3 C5 4.7 mF 25 V C4 L1 10 mH ON C1 10 mF 6.3 V 2.2 mF CE 1 JP1 R1 C3 OFF FB 2 R2 VDD 3 2.0 mA at VIN = 2.0 V 5.0 mA at VIN = 2.4 V 10 mA at VIN = 3.0 V D1 5 pF to 1000 pF VOUT1 15 V 2.0 mA at VIN = 2.0 V 5.0 mA at VIN = 2.4 V 10 mA at VIN = 3.0 V C2 4.7 mF 25 V LX 5 U1 NCP1406 VIN 2.0 V to 5.5 V VOUT2 −15 V ǒ GND 4 Ǔ R1 VOUT1 + 1.19 )1 R2 VOUT2 [ −VOUT1 ) 0.3 L: CR43−100MC, Sumida C1: ECJ2FB0J106M, Panasonic C2, C5: ECJ3YB1E475M, Panasonic C3: ECJ1VC1H102J, Panasonic C4: ECJ2FB1C225K, Panasonic D1: MBR0520LT1, ON Semiconductor D2, D3: MBR0520LT1 x 2, ON Semiconductor R1: 1.3 MW R2: 110 kW Figure 55. +15 V, −15 V Outputs Converter for LCD Bias Supply D4 D5 VOUT2 −7.5 V C7 10 mA at VIN = 3.0 V 10 mF 16 V C5 L1 10 mH 2.2 mF VIN 3.0 V to 5.5 V ON 820 pF CE 1 JP1 OFF C3 R1 FB 2 R2 VDD 3 D3 C6 10 mF 16 V D2 LX 5 U1 NCP1406 C1 10 mF 6.3 V C4 2.2 mF D1 GND 4 C9 L: CR43−100MC, Sumida C1: ECJ2FB0J106M, Panasonic C6, C7: ECJ3YB1C106M, Panasonic C3: ECJ1VC1H821J, Panasonic C2, C4, C5: ECJ2FB1C225K, Panasonic D1, D2, D3, D4, D5: MBR0520LT1, ON Semiconductor R1: 1.3 MW R2: 110 kW C2 2.2 mF 16 V ǒ Ǔ R1 VOUT1 + 1.19 )1 R2 V VOUT2 [ − OUT1 2 Figure 56. +15 V, −7.5 V Outputs Converter for CCD Supply Circuit http://onsemi.com 21 VOUT1 15 V 10 mA at VIN = 3.0 V NCP1406 TP2 GND L1 4.7 mH C1 22 mF 6.3 V Control Signal D1 JP1 ON CE CE 1 OFF FB 2 VDD 3 R2 100 kW TP3 VOUT ILED 100 mA LX 5 U1 NCP1406 TP1 VIN 3.0 V to 5.5 V U1: NCP1406, ON Semiconductor D1: MBR0520LT1, ON Semiconductor L1: CR43−4R7MC, Sumida C1: ECJHVB0J226M, Panasonic C2: ECJ3YB1C106M, Panasonic LED1, LED2, LED3: LWH1033 (Luxpia) R1: 12 W R2: 100 kW C2 White LED x 3 GND 4 ILED(DC) + 1.19 V R1 Figure 57. White LEDs Driver Circuit http://onsemi.com 22 TP4 GND 10 mF 16 V R1 12 W NCP1406 PACKAGE DIMENSIONS TSOP−5 SN SUFFIX CASE 483−02 ISSUE E NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: MILLIMETER. 3. MAXIMUM LEAD THICKNESS INCLUDES LEAD FINISH THICKNESS. MINIMUM LEAD THICKNESS IS THE MINIMUM THICKNESS OF BASE MATERIAL. 4. A AND B DIMENSIONS DO NOT INCLUDE MOLD FLASH, PROTRUSIONS, OR GATE BURRS. D S 5 4 1 2 3 B L G DIM A B C D G H J K L M S A J C 0.05 (0.002) H M K MILLIMETERS MIN MAX 2.90 3.10 1.30 1.70 0.90 1.10 0.25 0.50 0.85 1.05 0.013 0.100 0.10 0.26 0.20 0.60 1.25 1.55 0_ 10 _ 2.50 3.00 INCHES MIN MAX 0.1142 0.1220 0.0512 0.0669 0.0354 0.0433 0.0098 0.0197 0.0335 0.0413 0.0005 0.0040 0.0040 0.0102 0.0079 0.0236 0.0493 0.0610 0_ 10 _ 0.0985 0.1181 SOLDERING FOOTPRINT* 0.95 0.037 1.9 0.074 2.4 0.094 1.0 0.039 0.7 0.028 SCALE 10:1 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. 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. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner. PUBLICATION ORDERING INFORMATION LITERATURE FULFILLMENT: N. American Technical Support: 800−282−9855 Toll Free Literature Distribution Center for ON Semiconductor USA/Canada P.O. Box 61312, Phoenix, Arizona 85082−1312 USA Phone: 480−829−7710 or 800−344−3860 Toll Free USA/Canada Japan: ON Semiconductor, Japan Customer Focus Center 2−9−1 Kamimeguro, Meguro−ku, Tokyo, Japan 153−0051 Fax: 480−829−7709 or 800−344−3867 Toll Free USA/Canada Phone: 81−3−5773−3850 Email: [email protected] http://onsemi.com 23 ON Semiconductor Website: http://onsemi.com Order Literature: http://www.onsemi.com/litorder For additional information, please contact your local Sales Representative. NCP1406/D