E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Headlight LED
Transcription
E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Headlight LED
E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Dec 1, 2015 Headlight LED Demo Application using Elmos E522.32 Dual LED Controller (2 x Boost-to-Battery Topology) for Low-Beam, High-Beam and Daytime Running Light Figure 1. Demoboard 1 What you get: 1. Demonstrator for dual constant current LED application using E522.32 Dual LED controller to drive 1A LED arrays (1st channel High- and Low-Beam) and 750mA LED arrays (2nd channel Daytime Running Light) and output power up to approx. 45W. 2 Advantages of E522.32 dual Boost-to-Battery Applications: The Headlight LED Demo application is build using a single Elmos E522.32 Dual LED controller to drive three light functions Low-Beam, High-Beam and Daytime Running Light. Both converters operate in Boost-to-Battery topology with spread-spectrum to improve electromagnetic compatibility. Small ceramic input and output capacitors are used to save space and cost. This demoboard is designed for an input voltage range from 5.5V up to 18V. The 1st channel is optimized to drive 1A LED arrays for Low- and High-Beam with a LED output voltage between 5V and 50V (dependent on the input voltage and externally configured over-voltage protection). The 2nd channel is optimized to drive 750mA LED arrays for Daytime Running Light with a LED output voltage between 5V and 40V (dependent on the input voltage and externally configured over-voltage protection). 3 Features Demoboard: LED over voltage protection, power-stage current limitation short-circuit and open load proof application status LED on each Channel reverse polarity protection Low- and High-Beam can be toggled “on” and “off” Digital PWM Dimming to control the LED brightness of Daytime Running Light Derating Mechanisms for either low V(VIN) or high temperatures via NTC reading The maximum LED string length at both channels results from the LED forward voltage, the input voltage and the maximum output voltage defined by the over voltage protection. n (V OUT (max) V VIN )/(V LED(max) ) Elmos Semiconductor AG Application Note 1/12 QM-No.: 25AN0158E.00 AN 0158 E522.32 Demoboard 2 x Boost-to-Battery Dec 1, 2015 The LED string is protected against over voltage by the over OVP voltage divider for each channel. The OVP threshold is adjusted to approx. 60V on the 1st channel ( Low- and High-Beam) and approx. 50V on the 2nd channel (Daytime Running Light). That means, an output voltage of > 60V at the 1st channel’s output will turn off the channel. Note that the OVP threshold is an absolute value, so the usable output voltage is limited to (VOUT(max)-VIN ) in Boost-to-Battery configuration. Both channels operate with the same switching frequency in phase shift of 180° to reduce EMI. The switching frequency is generated by the internal oscillator of the E522.32. The switching frequency is set to 480kHz by the resistor R5 (62 kOhms) at pin RT. 4 Low- and High Beam control: Low- and High Beam can be toggled on and off via the pins DIS_LB and DIS_HB on the CON3 connector. The Low and High Beam are connected in series. To switch both functions off, set PWDIM1 low via pin DIS_LB. By toggling the pin DIS_HB the switch Q3 is opened and closed. This switches the High Beam on and off. Table 1.Truth Table DIS_LB 0V 3V3 0V 3V3 DIS_HB 0V 0V 3V3 3V3 Low-Beam OFF ON OFF ON High-Beam OFF OFF OFF ON 5 Daytime Running Light control The DRL_DIM pin on CON3 connector can be used to control the LED brightness of the Daytime Running Light with only marginal changes in the LED color. The average LED current can be controlled by digital PWM in a range of 1000:1 at 200 Hz PWM frequency via DRL_DIM pin on the CON3. When DRL_DIM pin is Low, the 2nd channel is in sample-and-hold state, and the Daytime Running Light is switched off. 6 Voltage Derating and Temperature Derating If the input voltage is low, higher losses could occur. Therefore the output current is linearityreduced between 5.5V and 7.5V. Output Derating VS Input Voltage 100 LOAD (% ) 95 90 85 80 75 70 65 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 INPUT VOLTAGE (V) Figure 2. Output Derating VS Input Voltage The Headlight LED Demo application includes temperature derating on board for each channel (47kOhm NTC resistor). The NTC resistors measure the temperature near of the corresponding channel and reduce the output current. It is possible to use the on Board NTCs (NTC1, NTC2) or external NTC (connected via CON3 connector). Elmos Semiconductor AG Application Note 2/12 QM-No.: 25AN0158E.00 AN 0158 E522.32 Demoboard 2 x Boost-to-Battery Dec 1, 2015 Temperature Derating 100 90 LOAD (% ) 80 70 60 50 40 30 20 10 0 0 10 20 30 40 50 60 70 80 90 100 110 120 130 140 150 AMBIENT TEMP. (°C) Figure 3. Temperature Derating 7 High Voltage Option If an absolute output voltage between 60V and 75V is required the over-voltage protection, diodes and MOSFETs must be adapted. For an absolute output voltage up to 75V the value of R8 or R12 must be changed to 590kOhm. In this high voltage range, please exercise caution!. 8 Electrical Characteristics Description Input Voltage Range LED Current LB+HB LED Current DRL Recommended LED Output Voltage LB+HB Maximum LED Output Voltage LB+HB Recommended LED Output Voltage DRL Maximum LED Output Voltage DRL Efficiency OVP Threshold LB+HB OVP Threshold DRL Switching Frequency ADIM1 Input Voltage LB+HB ADIM2 Input Voltage DRL Over-Current Protection LB+HB Over-Current Protection DRL Elmos Semiconductor AG Condition Recommended R16=100mOhm R25=130mOhm Typ. VLED,HB + VLED,LB VIN<=18V VOUT(max),LB_HB-VIN Typ. VLED,DRL VIN<=18V VOUT(max),DRL-VIN VIN=13V VLED,LB_HB=32V VLED(typ),LB_HB=13V ILED,LB_HB=1A ILED,DRL=750mA R8=470kOhm R11=9,53kOhm R12=390kOhm R11=9,53kOhm R5=62kOhm Symbol VIN ILED,LB_HB ILED,DRL VLED(typ),LB_HB Value (Typical) 5.5V-18V 1A 750mA 32V VLED(max),LB_HB 42V VLED(typ),DRL 13V VLED(max),DRL 32V Eff. 88.00% VOUT(max),LB_HB 60V VOUT(max),DRL 50V fOSC,INT VADIM1,EXT VADIM2,EXT 480kHz 600mV 600mV R22=20mOhm R19=680Ohm, R21=18kOhm R31=82mOhm R29=680Ohm, R30=22kOhm IOCP,LB_HB 15.25A IOCP,DRL 3.97A Application Note 3/12 QM-No.: 25AN0158E.00 AN 0158 E522.32 Demoboard 2 x Boost-to-Battery Dec 1, 2015 E522.32 Boost to Battery (HB LB DRL Demo) Efficiency 90 88 86 84 Eff. [%] 82 80 78 76 74 72 70 5 7 9 11 13 15 17 19 21 23 25 27 29 Vin [V] Figure 4. Efficiency diagram HB+LB+DRL Iout [mA] E522.32 Boost to VBAT (HB LB DRL Demo) 1000 980 960 940 920 900 880 860 840 820 800 780 760 740 720 700 680 660 640 620 600 580 560 540 520 500 Line Regulation Iout_hb_lb [mA] Iout_drl [mA] 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 Vin [V] Figure 5. Lineregulation IOUT versus VIN (Typ. VADIM = 0.581V) Elmos Semiconductor AG Application Note 4/12 QM-No.: 25AN0158E.00 E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Dec 1, 2015 9 What you need to start: 1. An external Power supply for input voltage VIN between 5.5V and 18V, with a recommended current capability of ~10A, especially for low V VIN and high VLED operation. 10 Connectors: 1. Connector CON1 is for input supply voltage VIN and GND 2. Connector CON2 provides the output current for Low- and High-Beam. Connect the anode of the Low Beam LED arrays to pin 3 (LB+) and the cathode to pin 1 (LB-). Connect the anode of the High Beam LED arrays to pin 2 (HB+) and the cathode to pin 3 (HB-). 3. Connector CON4 provides the output current for Daytime Running Light. Connect the anode of the Daytime Running Light LED arrays to pin 2 (DRL+) and the cathode to pin 1 (DRL-). CON3 Pin No. 1 3 5 7 9 Function VSM GND GND NTC1_L NTC2_L Pin No. 2 4 6 8 10 Function DIS_HB DIS_LB DRL_DIM NTC1_H NTC2_H 4. Pin TP1 and Pin TP4 are GND pins, intended for measurement probes etc.. 5. The STATUS1 and STATUS2 LED turns on if E522.32 is active. The STATUS LEDs turn off, if a failure is detected at the corresponding channel (for failure states see data sheet E522.32 for details). 11 Start of operation: 1. Connect a LED capable of 1A to CON2 or LB+ and LB- and another to HB+ and HB- with a suitable forward voltage. 2. Connect a LED capable of 750mA to CON4 or DRL+ and DRL- with a suitable forward voltage. 3. Connect a power supply to VIN and GND. 3 a) Adjust the power supply to the desired input voltage within 5.5 and 18V, depending on LED count and forward voltage. Elmos Semiconductor AG Application Note 5/12 QM-No.: 25AN0158E.00 E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Dec 1, 2015 12 Schematic Figure 6. Demoboard Schematic Elmos Semiconductor AG Application Note 6/12 QM-No.: 25AN0158E.00 AN 0158 E522.32 Demoboard 2 x Boost-to-Battery Dec 1, 2015 13 Bill of material (BOM): Used Pos.-No. 2 R17, R28 R19, R29, 4 R41, R46 3 R6, R7, R15 1 R27 R3, R4, R23, 5 R38, R44 2 R18, R20 1 R40 1 R13 1 R11 3 R14, R39, R45 1 R21 1 R30 1 R37 2 R35, R43 2 R34, R42 2 R24, R32 1 R5 1 R36 1 R12 1 R8 2 R1, R2 1 R33 1 R26 1 R22 1 R31 1 R16 1 R25 1 R10 1 R9 1 R48 1 R47 Value 10R, 1% Order-No. 667-ERJ-3EKF10R0V Supplier MOUSER Remark 0603, 1/10W Manufacturer Panasonic 680R, 1% 667-ERJ-3EKF6800V MOUSER 0603, 1/10W Panasonic 1k2, 1% 1k8, 1% 667-ERJ-3EKF1201V 667-ERJ-3EKF1801V MOUSER MOUSER 0603, 1/10W 0603, 1/10W Panasonic Panasonic 3k3, 1% 667-ERJ-3EKF3301V MOUSER 0603, 1/10W Panasonic 4k7, 1% 5k1, 1% 5k6, 1% 9k53, 1% 10k, 1% 18k, 1% 22k, 1% 36k, 1% 42k2, 1% 47k, 1% 56k, 1% 62k, 1% 180k, 1% 390k, 1% 470k, 1% opt. 33R, 1% opt. R020, 1% R082, 1% R100, 1% R130, 1% R680, 1% 1R5, 1% 5R6 , 1% 6R8 , 1% 667-ERJ-3EKF4701V 667-ERJ-3EKF5101V 667-ERJ-3EKF5601V 667-ERJ-3EKF9531V 667-ERJ-3EKF1002V 667-ERJ-3EKF1802V 667-ERJ-3EKF2202V 667-ERJ-3EKF3602V 667-ERJ-3EKF4222V 667-ERJ-3EKF4702V 667-ERJ-3EKF5602V 667-ERJ-3EKF6202V 667-ERJ-3EKF1803V 667-ERJ-3EKF3903V 667-ERJ-3EKF4703V MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W 0603, 1/10W Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic 667-ERJ-6ENF33R0V MOUSER Panasonic 754-PRL1632-R020-FT1 754-PRL1632-R082-FT1 667-ERJ-8RSFR10V 667-ERJ-8RSFR13V 667-ERJ-8RQFR68V 667-ERJ-8RQF1R5V 667-ERJ-8BQF5R6V 667-ERJ-8BQF6R8V MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER 0805, 1/8W 0805 1206_ wide , 1W 1206_ wide , 1W 1206, 1/4W 1206, 1/4W 1206 / 1/4W 1206 / 1/4W 1206, 1/2W 1206, 1/2W 2 2 1 1 1 2 2 1 4.7nF 22nF 47nF 56nF 100nF 1uF 220pF 33nF 81-GCM188R71H472K37D 81-GCM188R71H223K37D 81-GCM188R71H473K55D 81-GRM188R71H563KA93 81-GCM188R71H104KA7D 81-GCM188R71E105KA4D 81-GCM2165C2A221JA6D 81-GCM219R71H333KA7D MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER MOUSER 0603, X7R, 50V 0603, X7R, 50V 0603, X7R, 50V 0603, X7R, 50V 0603, X7R, 50V 0603, X7R, 25V 0805,NP0, 100V 0805, X7R, 50V Murata Murata Murata Murata Murata Murata Murata Murata 47nF, 10% 81-GCM21BR71H473KA7L MOUSER 0805, X7R, 50V Murata 100nF, 10% 100nF, 10% 100nF 1uF 2,2uF 4,7uF (2uF||2uF) 100V 81-GCM21BR71H104KA37 81-GCJ21BR71H104KA1L 81-GRJ21BC72A105KE1L 81-GCM21BR7YA105KA5L 81-GCM32DR72A225K64L MOUSER MOUSER MOUSER MOUSER MOUSER 0805, X7R, 50V 0805, X7R, 50V 0805, X7S, 100V 0805, X7R, 35V 1210, X7R, 100V Murata Murata Murata Murata Murata 81-GCM32DR72A225K64L MOUSER 1210, X7R, 100V Murata 1 1 1 1 1 C2, C4 C24, C25 C3 C1 C7 C5, C6 C26, C27 C18 C10, C16, C21 C11 C8 C23 C13 C22 1 C17 3 Elmos Semiconductor AG Application Note 7/12 Susumu Susumu Panasonic Panasonic Panasonic Panasonic Panasonic Panasonic QM-No.: 25AN0158E.00 AN 0158 E522.32 Demoboard 2 x Boost-to-Battery Dec 1, 2015 Used 3 2 1 Pos.-No. C9, C15, C20 C14, C19 C12 Value 4,7uF, 10% 10uF 33uF Order-No. 81-GCM32ER71H475KA5L 81-GRM32ER71H106MA2L 667-EEE-FP1V330AP Supplier MOUSER MOUSER MOUSER Remark 1210, X7R, 50V 1210, X7R, 50V SMD 33UF 35V ELECT Manufacturer Murata Murata Panasonic 2 NTC1, NTC2 47k NTC 594-NTCS0603E3473JHT MOUSER NTC 47k 0603 VISHAY 1 L1 XAL6060472MEB XAL6060-472MEB Coilcraft 4.7 uH 20 % 11 A Coilcraft 1 L2 XAL1010103MED XAL1010-103MED Coilcraft 10 uH 20 % 15.5 A Coilcraft 1 L3 XAL1010153MED XAL1010-153MED Coilcraft 15 uH 20 % 13.8 A Coilcraft 1 1 1 2 1 D1 D2 D3 D4, D5 D6 STATUS1 STATUS2 BZX84-C10 PMEG6030 SM4T35CAY 859-LTST-C150KGKT 859-LTST-C150KGKT 78-BZX84C10-E3-08 771-PMEG6030EP-115 511-SM4T35CAY MOUSER MOUSER MOUSER MOUSER MOUSER SMD LED 1206 GREEN SMD LED 1206 GREEN 50V 0.35W 5% 60V 3A SOD128 TVS-Diode 2 D7, D8 TS4148-0805 821-TS4148-0805-RY MOUSER DIODE LITEON LITEON VISHAY NXP ST Taiwan Semiconductor 1 Z1 5,6V 621-MMSZ5232B-F MOUSER Zener-Diode 5.6V 500mW DIODES 1 Q1 SI7463DP-T1GE3 781-SI7463DP-T1-GE3 MOUSER VISHAY 5 BC846 833-BC846B-TP MOUSER 2 Q2, Q5, Q8, Q9, Q10 Q3, Q6 FDC5614 512-FDC5614P MOUSER 2 Q4, Q7 BUK9Y25-60E 771-BUK9Y25-60E115 MOUSER MOSFET 40V 18.6A 5.4W 9.2mohm @ 10V NPN 65V 100mA SOT23 MOSFET SSOT-6 P-CH MOSFET N-channel 60 V 25 mo FET 1 U1 522.32 522.32 ELMOS ELMOS 521.32 ELMOS 2 1 1 CON1, CON4 ARK130/2 CON2 ARK130/3 CON3 WSL10G ARK130/2 ARK130/3 WSL10G Schukat Schukat Reichelt ARK130/2 ARK130/3 WSL 6G PTR PTR 4 TP1, TP2, TP3, TP3 12H6164 Bürklin Solder pin Ettinger GND Elmos Semiconductor AG Application Note 8/12 MCC Fairchild NXP QM-No.: 25AN0158E.00 E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Dec 1, 2015 14 Layout Hints: Figure 7. Bottom layer Figure 8. Middle layer 2 Elmos Semiconductor AG Application Note 9/12 QM-No.: 25AN0158E.00 E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Dec 1, 2015 Figure 9. Middle layer 1 Figure 10. Top layer Elmos Semiconductor AG Application Note 10/12 QM-No.: 25AN0158E.00 E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Dec 1, 2015 Figure 11. Multilayer composite print Elmos Semiconductor AG Application Note 11/12 QM-No.: 25AN0158E.00 E522.32 Demoboard 2 x Boost-to-Battery AN 0158 Dec 1, 2015 Usage Restrictions Elmos Semiconductor AG provide the E522.32 Demonstration Board simply and solely for IC evaluation purposes in laboratory. The Kit or any part of the Kit must not be used for other purposes or within non laboratory environments. Especially the use or the integration in production systems, appliances or other installations is prohibited. The pcb´s are delivered to customer are for the temporary purpose of testing, evaluation and development of the Elmos IC´s only. Elmos will not assume any liability for additional applications of the pcb. Disclaimer Elmos Semiconductor AG shall not be liable for any damages arising out of defects resulting from (1) delivered hardware or software, (2) non observance of instructions contained in this document, or (3) misuse, abuse, use under abnormal conditions or alteration by anyone other than Elmos Semiconductor AG. To the extend permitted by law Elmos Semiconductor AG hereby expressively disclaims and user expressively waives any and all warranties of merchantability and of fitness for a particular purpose, statutory warranty of non-infringement and any other warranty or product liability that may arise by reason of usage of trade, custom or course of dealing. 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Copyright © 2015 Elmos Reproduction, in part or whole, without the prior written consent of Elmos, is prohibited. Elmos Semiconductor AG Application Note 12/12 QM-No.: 25AN0158E.00