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AP3029KTR-E1

AP3029KTR-E1

  • 厂商:

    BCDSEMI(美台)

  • 封装:

  • 描述:

    AP3029KTR-E1 - WHITE LED STEP-UP CONVERTER - BCD Semiconductor Manufacturing Limited

  • 数据手册
  • 价格&库存
AP3029KTR-E1 数据手册
Data Sheet WHITE LED STEP-UP CONVERTER General Description The AP3029 is an inductor-based DC/DC converter designed to drive up to six white LEDs in series or 2 rows of LEDs with 5 for each in parallel for backlight. Only one feedback resistor is needed to control the LED current and obtain required brightness. A constant frequency 1.2MHz PWM control scheme is employed in this IC, which means tiny external components can be used. In fact, 1mm tall inductor and 0.22µF output capacitor for a typical application is sufficient. Additionally, the schottky diode in boost circuit is integrated on this chip. AP3029 also provides a disable pin to ease its use for different systems. The over output voltage protection is equipped in AP3029. When any LED is broken or in other abnormal conditions, the output voltage will be clamped. The AP3029 is available in standard SOT-23-6 and TSOT-23-6 packages. AP3029 Features · · · · · · · Inherently Uniform LED Current High Efficiency up to 83.5% No Need for External Schottky Diode Over Output Voltage Protection Fast 1.2MHz Switching Frequency Uses Tiny 1mm Tall Inductor Requires Only 0.22µF Output Capacitor Applications · · · · · Cellular Phones Digital Cameras LCD modules GPS Receivers PDAs, Handheld Computers SOT-23-6 TSOT-23-6 Figure 1. Package Types of AP3029 Oct. 2009 Rev. 1. 8 1 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Pin Configuration K/KT Package (SOT-23-6/TSOT-23-6) Pin 1 Dot by Marking AP3029 SW GND FB 1 2 3 6 5 4 VIN VOUT CTRL Figure 2. Pin Configuration of AP3029 (Top View) Pin Description Pin Number 1 2 3 4 5 6 Pin Name SW GND FB CTRL VOUT VIN Switch Pin. Connect external inductor Ground Pin Voltage Feedback. Reference voltage is 200mV Shutdown and Dimming Pin. Connect to 1.8V or higher to enable device; Connect to 50mV or less to disable device; Connect to a voltage between 1.8V and 50mV to achieve linear dimming Output Pin. Connected to the cathode of internal schottky diode Input Supply Pin. Must be locally bypassed Function Oct. 2009 Rev. 1. 8 2 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Functional Block Diagram FB 3 SOFT START AP3029 SW 1 5 OVP Q1 VOUT VIN 6 VREF 1.25 V 200 mV A1 A2 COMPARATOR DRIVER R S Q Σ 2 CTRL 4 RAMP GENERATOR GND 1.2 MHz OSCILLATOR Figure 3. Functional Block Diagram of AP3029 Ordering Information AP3029 Circuit Type Package K: SOT-23-6 KT: TSOT-23-6 Package SOT-23-6 TSOT-23-6 E1: RoHS TR: Tape and Reel Temperature Range -40 to 85 C -40 to 85 C o o Part Number AP3029KTR-E1 AP3029KTTR-E1 Marking ID E8S S9F Packing Type Tape & Reel Tape & Reel BCD Semiconductor's products as designated with "E1" suffix in the part number are RoHS compliant. Oct. 2009 Rev. 1. 8 3 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Absolute Maximum Ratings (Note 1) Parameter Input Voltage SW Voltage FB Voltage CTRL Voltage Thermal Resistance (Junction to Atmosphere, no Heat sink) Operating Junction Temperature Storage Temperature Range Lead Temperature (Soldering, 10sec) ESD (Machine Model) ESD (Human Body Model) TSTG TLEAD θJA Symbol VIN Value 20 38 20 20 265 150 -65 to 150 260 250 2000 Unit V V V V oC/W oC o o AP3029 C C V V Note 1: Stresses greater than those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under "Recommended Operating Conditions" is not implied. Exposure to "Absolute Maximum Ratings" for extended periods may affect device reliability. Recommended Operating Conditions Parameter Operating Temperature Range Input Voltage CTRL Voltage Symbol TOP VIN VCTRL Min -40 2.5 Max 85 16 16 Unit o C V V Oct. 2009 Rev. 1. 8 4 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Electrical Characteristics (VIN=3V, VCTRL =3V, TA=25oC, unless otherwise specified.) Parameter Minimum Operating Voltage Maximum Operating Voltage Feedback Voltage FB Pin Bias Current Supply Current Shutdown Quiescent Current Switching Frequency Maximum Duty Cycle Switch Current Limit (Note 2) Switch VCE Saturation Voltage Switch Leakage Current CTRL Pin Voltage VCTRL Symbol VIN(min) VIN(max) VFB IFB ICC IQ f DMAX ILIMIT VCESAT TA=25oC, D=40% TA=25oC, D=80% ISW=250mA VSW=5V High Low 40 CTRL Pin Bias Current ICTRL TA=85oC TA=-40oC OVP Voltage Schottky Forward Drop Schottky Leakage Current Soft Start Time Thermal Resistance (Junction to Case) t θJC SOT-23-6 TSOT-23-6 VOV VDROP ID=150mA Reverse Voltage VR=23V Reverse Voltage VR=27V 300 60 60 55 50 75 29 0.7 0.1 4 150 µS oC/W AP3029 Conditions Min 2.5 Typ Max Unit V 16 IOUT=20mA, 4 LEDs, TA=-40oC to 85oC 188 200 35 VFB=VIN, No Switching VCTRL=0V 2.0 2.5 3.2 1.2 90 93 550 550 360 0.01 1.8 0.05 72 µA 5 mV µA V 212 100 3.2 5.0 mV nA mA µA MHz % mA V V µA Note 2: The Switch Current Limit is related to Duty Cycle. Please refer to Figure 15 for detail. Oct. 2009 Rev. 1. 8 5 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Typical Performance Characteristics (VF of WLED is 3.45V @ IF=20mA, unless otherwise noted ) AP3029 85 84 83 85 84 83 82 81 80 79 78 77 2.5 Efficiency (%) 82 81 80 79 78 77 -50 VIN=3.6V, IOUT=20mA, 4 LEDs CIN=1µF, COUT=0.22µF, L=22µH Efficiency (%) IOUT=20mA, 4 LEDs, TA=25 C CIN=1µF, COUT=0.22µF, L=22µH O -25 0 25 50 o 75 100 3.0 3.5 4.0 4.5 5.0 Junction Temperature ( C) Input Voltage (V) Figure 4. Efficiency vs. Junction Temperature Figure 5. Efficiency vs. Input Voltage 85 84 83 350 300 Schottky Forward Current (mA) 250 Efficiency (%) 82 81 80 79 78 77 200 150 VIN=3.6V, IOUT=20mA, TA=25 C CIN=1µF, COUT=0.22µF, L=22µH O 100 50 0 2 3 4 5 6 0 200 400 600 800 1000 LEDs (PCS) Schottky Forward Drop (mV) Figure 6. Efficiency vs. LED's Number Figure 7. Schottky Forward Current vs. Schottky Forward Drop Oct. 2009 Rev. 1. 8 6 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Typical Performance Characteristics (Continued) (VF of WLED is 3.45V @ IF=20mA, unless otherwise noted ) AP3029 30 3.0 25 2.5 Quiescent Current (µA) Supply Current (mA) 20 2.0 15 1.5 10 1.0 5 0.5 0 -50 C O 25 C O 100 C 0 2 4 6 8 10 12 14 16 O 2 4 6 8 10 12 14 16 0.0 Input Voltage (V) Input Voltage (V) Figure 8. Shutdown Quiescent Current vs. Input Voltage Figure 9. Supply Current vs. Input Voltage 4.0 3.8 3.6 1.40 1.35 1.30 1.25 Input Current (mA) Frequency (MHz) 3.0 3.5 4.0 4.5 5.0 3.4 3.2 3.0 2.8 2.6 2.4 2.2 2.0 2.5 1.20 1.15 1.10 1.05 1.00 0.95 0.90 -50 -25 0 25 50 o 75 100 Input Voltage (V) Junction Temperature ( C) Figure 10. Input Current in Output Open Circuit vs. Input Voltage Figure 11. Switching Frequency vs. Junction Temperature Oct. 2009 Rev. 1. 8 7 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Typical Performance Characteristics (Continued) (VF of WLED is 3.45V @ IF=20mA, unless otherwise noted ) AP3029 210 208 0.80 0.78 0.76 Schottky Forward Drop (V) 206 Feedback Voltage (mV) 204 202 200 198 196 194 192 190 -50 -25 0 25 50 o 0.74 0.72 0.70 0.68 0.66 0.64 0.62 0.60 -50 75 100 -25 0 25 50 o 75 100 Junction Temperature ( C) Junction Temperature ( C) Figure 12. Feedback Voltage vs. Junction Temperature Figure 13. Schottky Forward Drop vs. Junction Temperature 0.50 0.45 0.40 700 Schottky Leakage Current (µA) VR=10V VR=16V VR=23V Current Limit (mA) 600 0.35 0.30 0.25 0.20 0.15 0.10 0.05 0.00 -50 -25 0 25 50 o 500 400 300 200 -50 C O 25 C O 100 C 40 50 60 70 80 90 O 75 100 100 30 Junction Temperature ( C) Duty Cycle (%) Figure 14. Schottky Leakage Current vs. Junction Temperature Figure 15. Switch Current Limit vs. Duty Cycle Oct. 2009 Rev. 1. 8 8 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Typical Performance Characteristics (Continued) (VF of WLED is 3.45V @ IF=20mA, unless otherwise noted ) AP3029 450 400 350 300 250 200 150 100 50 50 250 Feedback Voltage VFB (mV) 100 150 200 250 300 200 Saturation Voltage (mV) 150 100 50 0 0.0 0.5 1.0 1.5 2.0 2.5 Switch Current (mA) CTRL Voltage (V) Figure 16. Switch Saturation Voltage vs. Switch Current Figure 17. Feedback Voltage vs. CTRL Pin Voltage Oct. 2009 Rev. 1. 8 9 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Application Information Operation The AP3029 is a boost DC-DC converter which uses a constant frequency, current mode control scheme to provide excellent line and load regulation. Operation can be best understood by referring to the Figure 3. At the start of each oscillator cycle, the SR latch is set and switch Q1 turns on. The switch current will increase linearly. The voltage on sense resistor is proportional to the switch current. The output of the current sense amplifier is added to a stabilizing ramp and the result is fed into the non-inversion input of the PWM comparator A2. When this voltage exceeds the output voltage level of the error amplifier A1, the SR latch is reset and the switch is turned off. It is clear that the voltage level at inversion input of A2 sets the peak current level to keep the output in regulation. This voltage level is the output signal of error amplifier A1, and is the amplified signal of the voltage difference between feedback voltage and reference voltage of 200mV. So, a constant output current can be provided by this operation mode. VIN ≥ 3V L1 AP3029 R1 = 200mV I LED Over Voltage Protection The AP3029 has an internal open-circuit protection circuit. When the LEDs are disconnected from circuit or fail open, the output voltage is clamped. The AP3029 will switch at a low frequency, and minimize input current. Soft Start The AP3029 has an internal soft start circuit to limit the inrush current during startup. The time of startup is controlled by internal soft start capacitor. Please refer to Figure 19. IIN 100mA/div VOUT 5V/div VFB 100mV/div VCTRL 2V/div Time 100µs/div VIN Control Signal SW VOUT AP3029 CTRL GND FB C2 Figure 19. Soft Start Waveform VIN=3.6V, 5 LEDs, ILED=20mA C1 R1 Dimming Control Figure 18. Typical Application circuit to Decide R1 LED Current Control Refer to Figure 18, the LED current is controlled by the feedback resistor R1. LEDs' current accuracy is determined by the regulator's feedback threshold accuracy and is independent of the LED's forward voltage variation. So the precise resistors are preferred. The resistance of R1 is in inverse proportion to the LED current since the feedback reference is fixed at 200mV. The relation for R1 and LED current can be expressed as below: Oct. 2009 Rev. 1. 8 10 Two typical types of dimming control circuit are present as below. First, controlling CTRL Pin voltage to change operation state is a good choice. Second, changing the feedback voltage to get appropriate duty and luminous intensity is also useful. (1). Adding a Control Signal to CTRL Pin There are three methods to control CTRL pin signal First, adding a PWM Signal to CTRL pin directly. The AP3029 is turned on or off by the PWM signal when it is applied on the CTRL pin. The typical frequency of BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Application Information (Continued) this PWM signal can be up to 2KHz. Please refer to Figure 20. AP3029 First, adding a constant DC voltage through a resistor divider to FB pin can control the dimming. Changing the DC voltage or resistor between the FB Pin and the DC voltage can get appropriate luminous intensity. Comparing with all kinds of PWM signal control, this method features a stable output voltage and LEDs current. Please refer Figure 23. AP3029 CTRL up to 2kHz Figure 20. Dimming Control Using a PWM Signal in CTRL Pin Secondly, adding a constant DC voltage through a resistor divider to CTRL pin can control the dimming. The FB voltage is indirectly adjusted when the CTRL pin voltage is between 50mV to 1.8V, which can be used as dimming control. Please refer Figure 21. AP3029 FB VDC R3 90K R2 5K R1 10Ω Effective Feedback Voltage Figure 23. Dimming Control Using DC Voltage VDC R1 10k R2 10k AP3029 CTRL 0.1 to 3.6 V Second, using a filtered PWM signal can do it. The filtered PWM signal can be considered as a varying and adjustable DC voltage. Figure 21. Dimming Control Using a DC Voltage in CTRL Pin Thirdly, using a filtered PWM signal adding to CTRL pin can achieve dimming control. The filtered PWM signal can be considered as an adjustable DC voltage. It will change the FB voltage indirectly and achieve dimming control. The circuit is shown in Figure 22. AP3029 FB PWM R4 10K C R3 90K 0.1µF R2 5K R1 10Ω Effective Feedback Voltage PWM Signal R1 5k C1 100nF AP3029 CTRL Figure 24. Dimming Control Using a Filtered PWM Voltage Figure 22. Dimming Control Using a Filtered PWM Signal Voltage in CTRL Pin Third, using a logic signal to change the feedback voltage. For example, the FB pin is connected to the GND through a mosFET and a resistor. And this mosFET is controlled a logic signal. The luminous intensity of LEDs will be changed when the mosFET turns on or off. (2). Changing the Effective Feedback Voltage There are three methods to change the effective feedback voltage. Oct. 2009 Rev. 1. 8 11 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Application Information (Continued) AP3029 AP3029 FB Logic Signal R2 2N7002 R1 Effective Feedback Voltage Figure 25. Dimming Control Using Logic Signal Typical Application VIN ≥ 3V 10µΗ VIN Control Signal 1µ F CTRL SW VOUT 0.22µF FB 10Ω AP3029 GND C: X5R or X7R Dielectric L: SUMIDA CDRH5D28R-100NC or Equivalent This circuit can work in full temperature A. Four White LEDs Driver Oct. 2009 Rev. 1. 8 12 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Typical Application (Continued) VIN ≥ 3V 22µΗ AP3029 Control Signal 1µF VIN CTRL SW VOUT 0.22µF FB 10Ω AP3029 GND C: X5R or X7R Dielectric L: SUMIDA CDRH5D28R-220NC or Equivalent This circuit can work in full temperature B. Six White LEDs Driver VIN ≥ 3V 22µΗ Control Signal 1µF VIN CTRL SW VOUT 0.22µF FB 10Ω 10Ω AP3029 GND C: X5R or X7R Dielectric L: SUMIDA CDRH5D28R-220NC or Equivalent Two transistors are recommended to use Dual Matched transistor pairs This circuit can work in full temperature C. Ten White LEDs Driver Figure 26. Typical Application of LED Drivers Oct. 2009 Rev. 1. 8 13 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Mechanical Dimensions SOT-23-6 Unit: mm(inch) AP3029 2.820(0.111) 3.020(0.119) 0.300(0.012) 0.400(0.016) 0° 8° 0.200(0.008) 6 2.650(0.104) 2.950(0.116) 5 4 0.300(0.012) 0.600(0.024) Pin 1 Dot by Marking 1 2 3 0.700(0.028)REF 0.950(0.037)TYP 1.800(0.071) 2.000(0.079) 1.500(0.059) 1.700(0.067) 0.000(0.000) 0.100(0.004) 0.100(0.004) 0.200(0.008) 0.900(0.035) 1.450(0.057) MAX 1.300(0.051) Oct. 2009 Rev. 1. 8 14 BCD Semiconductor Manufacturing Limited Data Sheet WHITE LED STEP-UP CONVERTER Mechanical Dimensions TSOT-23-6 Unit: mm(inch) AP3029 2.800(0.110) 3.000(0.118) R0.100(0.004) MIN 0° 8° 1.500(0.059) 1.700(0.067) Pin 1 Dot by Marking 2.600(0.102) 3.000(0.118) 0.370(0.015) MIN 0.950(0.037) BSC 1.900(0.075) BSC GAUGE PLANE 0.100(0.004) 0.250(0.010) 0.250(0.010) BSC 0.700(0.028) 0.900(0.035) 1.000(0.039) MAX 0.000(0.000) 0.100(0.004) 0.350(0.014) 0.510(0.020) Oct. 2009 Rev. 1. 8 15 BCD Semiconductor Manufacturing Limited BCD Semiconductor Manufacturing Limited http://www.bcdsemi.com IMPORTANT NOTICE IMPORTANT NOTICE BCD Semiconductor Manufacturing Limited reserves the right to make changes without further notice to any products or specifiBCD Semiconductor Manufacturing Limited reserves the right to make changes without further notice to any products or specifications herein. BCD Semiconductor Manufacturing Limited does not assume any responsibility for use of any its products for any cations herein. BCD Semiconductor Manufacturing Limited does not assume any responsibility for use of any its products for any particular purpose, nor does BCD Semiconductor Manufacturing Limited assume any liability arising out of the application or use particular purpose, nor does BCD Semiconductor Manufacturing Limited assume any liability arising out of the application or use of any its products or circuits. BCD Semiconductor Manufacturing Limited does not convey any license under its patent rights or of any its products or circuits. BCD Semiconductor Manufacturing Limited does not convey any license under its patent rights or other rights nor the rights of others. other rights nor the rights of others. MAIN SITE MAIN SITE - Headquarters BCD Semiconductor Manufacturing Limited - Wafer Fab BCD Semiconductor Manufacturing Limited Shanghai Design Group - IC SIM-BCD Semiconductor Manufacturing Co., Ltd. 800 Yi Shan Road, Shanghai 200233, China Corporation Advanced Analog Circuits (Shanghai) Tel: +86-21-6485 900, Yi Shan Road, Shanghai 200233, China 8F, Zone B, 1491, Fax: +86-21-5450 0008 Tel: +86-21-6495 9539, Fax: +86-21-6485 9673 USA Office BCD Semiconductor Corp. USA Office 30920 Huntwood Ave. Hayward, BCD Semiconductor Corporation CA 94544, USA 30920 Huntwood Ave. Hayward, Tel 94544, U.S.A CA : +1-510-324-2988 Fax: +1-510-324-2788 Tel : +1-510-324-2988 Fax: +1-510-324-2788 REGIONAL SALES OFFICE Shenzhen Office REGIONAL SALES OFFICE BCD Semiconductor Manufacturing Limited - Wafer Fab No. 1600, Zi Xing Road, Shanghai ZiZhu Science-based Industrial Park, 200241, China Shanghai SIM-BCD Semiconductor Manufacturing Limited Tel: +86-21-24162266, Fax: +86-21-24162277 800, Yi Shan Road, Shanghai 200233, China Tel: +86-21-6485 1491, Fax: +86-21-5450 0008 Taiwan Office Shanghai SIM-BCD Semiconductor Manufacturing Co., Ltd., Shenzhen Office BCD Taiwan Office (Taiwan) Company Limited Semiconductor Shenzhen Office Room E, SIM-BCD Semiconductor 3rd Fuzhong Road, Futian District, Shenzhen, 4F, 298-1, Rui Guang Road,(Taiwan) Company Limited Shanghai 5F, Noble Center, No.1006,Manufacturing Co., Ltd. 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