www.fairchildsemi.com AN-9745 Design Guide for TRIAC Dimmable LED Driver Using FL7730 Introduction An LED has become a promising light source for replacing conventional lighting systems, such as fluorescent and incandescent lights. Especially in the conventional TRIAC dimmer infrastructure, there has been much research into development of an LED bulb compatible with TRIAC dimmers. Because the incandescent light source consumes a hundred watt with short life time, an LED bulb can be the excellent substitute with considerably less power dissipation and longer life. The biggest recent issue of TRIAC dimmable LED bulb is dimmer compatibility. The conventional TRIAC dimmer was originally designed to handle hundreds of watts induced by incandescent bulbs. An LED bulb consuming less than 20 W should interact with those dimmers composed of high-power devices. If the interaction between dimmer and LED bulb is not stabilized, visible flicker is perceptible. To manage the interaction without flicker, some requirements for dimmer operation need to be considered. TRIAC dimmer needs latching current at firing and holding current during TRIAC turn-on after firing. If those two currents are not met, TRIAC dimmer misfires and LED light flickers. Figure 1 shows the connection of TRIAC dimmer and LED bulb. As shown in Figure 2, the TRIAC dimmer blocks input line in the beginning of line cycle, then connects input line and LED bulb after firing. The TRIAC dimmer turns off if latching or holding current flowing through the dimmer is inadequate, as shown in Figure 3. Figure 1. TRIAC Dimmer and LED Bulb Figure 2. Dimmer Operation with Adequate Latching / Holding Current The latching and holding currents are different from dimmer models. The typical range of latching and holding currents is around 5 ~ 50 mA. Those operating requirement do not cause problems using incandescent bulbs due to high power consumption. An LED bulb with less than 20 W output power cannot maintain this amount of current over the whole line cycle. This application note provides a practical guideline of TRIAC dimmable LED bulb board design. Passive and active bleeder design guides detail how to maintain latching and holding current without visible flicker. Active damper design improves efficiency by minimizing the count of external components. The input filter design section covers the effect of filter components on PF, THD, and EMI. © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 Figure 3. Dimmer Operation with Inadequate Latching / Holding Current www.fairchildsemi.com AN-9745 APPLICATION NOTE 1. Passive Bleeder Design The passive bleeder is designed to supply latching and holding current to eliminate misfire and flicker. Figure 4 shows a board schematic using a passive bleeder. Figure 5. Line Current, Small Bleeder Capacitor (CB) Figure 4. LED Driver Schematic with Passive Bleeder A passive bleeder is composed of a resistor (RB) and a capacitor (CB). LF1 and LF2 are input filter inductors. CIN is input filter capacitor and RD is damper resistor. In dimmable board design, a resistor (ex. RB, RD) needs to be connected in series with a capacitor (ex. CB, CIN) in case that the capacitor is located in between input lines. Without the series resistor, a large voltage and current spike occurs due to the quickly charged energy in the capacitor at dimmer firing. The current spike can damage the TRIAC dimmer, especially when LED bulbs are connected in parallel with the dimmer because the sum of the current spike from each LED bulb can be over the rated current of the TRIAC dimmer. Current ringing after the current spike can also cause the TRIAC dimmer to misfire due to negative current of less than the holding current in the oscillation. The voltage spike can destroy external components if it is over the rated breakdown voltage. Figure 6. Line Current, Large Bleeder Capacitor (CB) ILINE should be higher than latching and holding current because ILINE directly flows through the TRIAC dimmer. In Figure 5, ILINE at firing is not large enough due to the small CB. The TRIAC dimmer can misfire right after firing, as shown in Figure 3. In Figure 6, ILINE is higher at dimmer firing with the large CB, which can maintain normal turn-on state of TRIAC, as shown in Figure 2. Therefore, a large CB maintains dimmer firing better than a small CB by supplying higher IB. However, a large CB has a drawback in PF, THD, and efficiency. Table 1 shows the system performance comparison between 100 nF and 220 nF CB. CB has a significant influence on PF and power dissipation in RB. Compared to 100 nF CB, the 220 nF CB seriously drops PF and increases power dissipation of RB due to the larger charging and discharging current of CB. The passive bleeder includes a hundreds-of-nF capacitor (CB) to provide latching and holding current. To remove the voltage and current spike described above, a bleeder resistor (RB) is necessary to dampen the spike. 1.1 Passive Bleeder Capacitor (CB) Selection Table 1. The capacity of CB determines the bleeder current to retain TRIAC turn-on. In terms of TRIAC dimming, bigger CB has better stability in dimming control due to large bleeder current. Figure 5 and Figure 6 show the line current of small and large bleeder capacitors. The input current (IIN) is the current from the flyback converter behind the bridge diode. IIN is in-phase with line voltage by power factor correction controlled by FL7730. IB is bleeder current and line current (ILINE) is the sum of IIN and IB. © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 CB Effect on System Performance TEST CONDITION: VIN = 230 VAC, POUT = 8 W, RB = 2 kΩ PF THD PD in RB CB [100 nF] 0.93 13% 162 mW CB [220 nF] 0.85 11% 684 mW Therefore, TRIAC dimming control and PF require balanced trade-off when selecting CB in the passive bleeder. Especially in high-line bulb with high PF requirements; these two factors can make finding the proper CB a challenge. In the CB selection, the first step is to see IB during dimmer firing by changing CB to check if there is any misfire at dimmer firing due to inadequate IB. In the range of CB without abnormal operation in dimmer firing, choose the minimum CB for higher PF and efficiency. The EMI is not affected by CB because RB is connected in series and interrupts noise filtering by CB. www.fairchildsemi.com 2 AN-9745 APPLICATION NOTE 1.2 Passive Bleeder Resistor (RB) Selection 2. Active Bleeder Design RB is the damper for reducing the spike current caused by quick charging of CB at firing. Figure 7 shows line current with excessively large RB. Too large RB dampens IB too much and limits IB less than latching current at firing. Then, the TRIAC dimmer can misfire right after firing so that visible flicker is appears. Another method to maintain TRIAC holding current is active bleeding technique. The active bleeder can cover a wider range of TRIAC turn-on in a line input cycle compared to passive bleeder. The proposed active bleeder retains TRIAC holding current by regulating input current, which minimizes power loss in the bleeder circuit. Figure 7. Line Current with Excessively Large RB Figure 8 shows ILINE with excessively small RB. If RB is too small, RB doesn’t fully dampen the spike current and ringing current occurs. The ringing current fluctuates under the negative IB, which causes misfire of the TRIAC dimmer and visible flicker. Figure 9. Active Bleeder Schematic In Figure 9, ILINE is the sum of IB (active bleeder current) and IIN (flyback input current). RSENSE is sensing resistor detecting line current, ILINE. CFILTER is the filter capacitor to filter switching noise at RSENSE voltage. QREG is a shunt regulator, such as KA431. At dimmer firing, a large current spike causes a large voltage drop at RSENSE. ZDLIM limits RSENSE voltage to protect reference block of QREG. Biasing current to drive QBLEED (bleeder MOSFET) as a linear regulator is supplied by auxiliary winding. The biasing circuit consists of DBIAS and CBIAS. The gate of QBLEED is controlled by the CBIAS biasing voltage and cathode of QREG. The amount of driving current is limited by RSOURCE and RSINK. CCOMP reduces response of the regulation loop. RCOMP compensates control loop as a negative feedback resistor. Figure 8. Line Current with Excessively Small RB IB Another consideration in RB selection is power loss. Table 2 compares system performance using two different bleeder resistors. In the system specification, RB doesn’t affect PF and THD; however, large RB makes increases power dissipation in RB. Table 2. ILINE regulation Set holding current ILINE (IIN+IB) RB Effect on System Performance TEST CONDITION: Vin = 230 VAC, POUT = 8 W, CB = 100 nF PF THD PD IN RB RB [1 kΩ] 0.93 13% 100 mW RB [2 kΩ] 0.93 13% 162 mW = VREF(QREG) / RSENSE IIN Figure 10. Line Current Using Active Bleeder In RB selection, the excessively large and small RB values should be found first. Then, the minimum RB can be selected in the proper range of RB for better efficiency. © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 www.fairchildsemi.com 3 AN-9745 APPLICATION NOTE The functional operation is shown in Figure 10. In this active bleeder, VGS (gate-source voltage) of QBLEED is increased and IB becomes higher when RSENSE voltage is less than VREF of QREG. The holding current is given as: I HOLD VREF (QREG ) RSENSE (1) In the selection of the IHOLD, there is a trade-off between dimmer compatibility and system efficiency. If IHOLD is set high, the active bleeder is more compatible with more dimmers; but the amount of IB increases with more power dissipation in the active bleeder. Figure 12. Measured Waveform at High Dimming Angle RSOURCE, RSINK, CCOMP, RCOMP, and CFILTER have a close relationship with the feedback response of the active bleeder. Smaller resistance (RSOURCE, RSINK, RCOMP) and capacitance (CCOMP, CFILTER) increase the speed of the feedback loop. If feedback loop is too fast, IB oscillates with a large current ripple. The operation of the active bleeder should be synchronized with the normal IC operation period. When the IC is in an abnormal condition, such as an LED short and open, there is no IIN due to shutdown gate signal. If active bleeder is still activated in this abnormal condition, the active bleeder should maintain holding current without IIN and the power dissipation in the active bleeder is very high and QBLEED is thermally destroyed. Therefore, the biasing current should come from the auxiliary winding. Then, the active bleeder can be disabled when switching is shut down. Figure 13. Measured Waveform at Low Dimming Angle Figure 12 and Figure 13 show the waveforms of the active bleeder at high and low dimming angle. At low dimming angle, output current is reduced by the dimming function in FL7730. The active bleeder should compensate more IB current due to the reduced IIN (C3). That is why the power dissipation in the active bleeder is in the middle dimming angle range. To check the maximum bleeder temperature, the test condition should be a middle dimming angle and maximum line input voltage. Figure 11 is a design example of an active bleeder. Probe ground is connected to VREF of the shunt regulator (KA431). C1 is the RSENSE voltage and C2 is the input voltage. C3 is the bleeder MOSFET source voltage, which is proportional to bleeder current. C4 is current probed line current. C4(ILINE) 1N4003 C2(VIN) 3. Active Damper Design Aux. winding 3k A resistive damper is necessary in series with input filter capacitor (CIN) when TRIAC dimmer is fired. At dimmer firing, a large current spike is induced through input line to quickly charge CIN. Without the resistive damper, the large spike creates line current oscillation, causing dimmer misfire and damage to the TRIAC dimmer with the excessive current. While the damper resistor suppresses the spike current, the power loss in the damper resistor is very high. The damper resistor not only dampens the spike current, but also handles the input current from the flyback. FQPF2N50 1k 680n 100n C3(QBLEED SOURCE) 100/0.5W KA431 C1(V_RSENSE) 100/0.5W Probe GND 100n Therefore, Fairchild’s proprietary active damper is proposed to reduce the power loss with minimized external components. In Figure 14, RAD is the active damper resistor and QAD is damper MOSFET to reduce power loss of RAD. RD and CD are delay circuit components and DD is reset diode to discharge CD. 3V Figure 11. Example of Active Bleeder in 8 W Bulb © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 www.fairchildsemi.com 4 AN-9745 APPLICATION NOTE RD current. Therefore, the active recommended at low line model. CD DD VGATE Table 3. QAD VAD IIN is strongly Passive vs. Active Damper Power Loss POUT = 8W Damper Power Dissipation [mW] VIN: 110 VAC VIN: 220 VAC RAD VIN damper CIN Single-Stage Flyback Figure 14. Active Damper Schematic PASSIVE DAMPER, 200 Ω 1200 290 ACTIVE DAMPER, 200 Ω + FQN1N50C (VTH: 2~4 V) 278 161 ACTIVE DAMPER, 200 Ω + FDD10N20LZ (VTH: 1~2.5 V) 171 113 3.1 Active Damper Resistor (RAD) Selection A voltage and current spike should be checked first when selecting RAD. Voltage spikes can damage the MOSFET and filter capacitor over the rated voltage. Current spikes create current ringing at dimmer firing. As shown in Figure 16, IIN ringing occurs at firing with small RAD. This ringing current drops IIN and the lowered IIN can lead to misfire of the dimmer and visible flicker. Also, a large peak current spike by using small RAD might damage the TRIAC dimmer, especially when the dimming LED bulbs are connected in parallel. Therefore, check points when selecting RAD are: Voltage spike (should be less than the part’s breakdown voltage.) Current spike (should be less than the TRIAC dimmer’s rated current. If considering connecting bulbs in parallel, the current spike should be lower inversely proportional to the number of LED bulbs.) Current ringing (check the dropped IIN at firing if it is enough higher than TRIAC holding current.) After checking the above considerations, choose the minimum RAD to maximize efficiency. Figure 15. Active Damper Waveforms Figure 15 shows the operational waveforms of the active damper. Mode analysis is as according to the sequence: M1: M2: M3: M4: Dimmer turn-off period; QAD turns off. Dimmer is fired and spike current occurs. VGATE is gradually increased by the delay circuit (RD and CD) QAD turns on by the charged VGATE. VAD is regulated as VTH of QAD. CD is discharged by DD and VGATE is reset for the next line cycle. The discharging current path is DD - RAD - CD. During M3 period, QAD can considerably reduce power loss in RAD by regulating VAD as its threshold voltage (VTH). Table 3 shows power dissipation of passive and active dampers. The power loss of active damper is much lower than passive damper resistor. At low line (110 VAC), input current is high and the damper resistor handles the large Figure 16. VIN and IIN with Small Damper Resistor (RAD) 3.2 Active Damper MOSFET (QAD) Selection The maximum VAD should be less than the breakdown voltage of QAD. After selecting RAD, maximum VAD can be checked at 90º dimming angle and the highest input line © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 www.fairchildsemi.com 5 AN-9745 APPLICATION NOTE voltage. Then, choose proper QAD with breakdown voltage margin. 1~2 A current rating is enough in the 8W LED bulb. As shown in Table 3, logic-level MOSFET with low threshold voltage can additionally reduce power loss because the regulated VAD is QAD threshold voltage. Design Example Figure 17 shows the design example of the active damper in an 8W LED bulb system. As shown in Figure 18 and Figure 19, the delay by 80 kΩ RD and 100 nF CD is around 1ms. During the delay, 220 Ω RAD dampens voltage and current spike without current ringing or dimmer misfire. 3.3 Active Damper Diode (DD) Selection 80k The active damper diode discharges CD to reset VGATE. Diode with 1A rated forward current is enough to discharge CD. Same as the QAD selection, maximum VAD at 90° dimming angle and the highest input line voltage should be checked first to select DD reverse voltage specification. ES1J 3.4 Active Damper Delay Circuit (RD, CD) Selection VGATE FQN1N50C VAD IIN The delay circuit (RD, CD) should create a long enough delay time before QAD turns on to let RAD dampen the current spike. The worst case for the spike current is 90° dimming angle. Spike current ringing needs to be checked first at 90° dimming angle to determine how long the spike current is dampened. Then, adjust RD and CD to guarantee the dampened period. The recommended CD and RD values are hundreds of nF and tens of kΩ. If CD is too large and RD is very small, DD cannot fully discharge CD in M4, as shown in Figure 15. 100nF 220/1W VIN CIN Figure 17. Design Example: Active Damper in 8W Bulb Figure 18. Measured Waveform at High Dimming Angle Figure 19. Measured Waveform at Low Dimming Angle © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 www.fairchildsemi.com 6 AN-9745 APPLICATION NOTE 4. Features of FL7730 The FL7730 is an active power factor correction (PFC) controller using single-stage flyback topology. Dimming control with no flicker is implemented by the analog sensing method. Primary-side regulation and single-stage topology reduce external components, such as input bulk capacitor and feedback circuitry to minimize cost. To improve power factor and THD, constant on-time control is utilized with an internal error amplifier and low bandwidth compensator. Precise constant-current control regulates accurate output current, independent of input voltage and output voltage. Operating frequency is proportionally adjusted by output voltage to guarantee DCM operation with higher efficiency and simpler design. FL7730 provides protections such as open-LED, short-LED, and overtemperature protection. Table 4. Figure 20. Package Diagram Pin Definitions Pin # Name Description 1 CS 2 GATE PWM Signal Output. This pin uses the internal totem-pole output driver to drive the power MOSFET. 3 GND Ground 4 VDD Power Supply. IC operating current and MOSFET driving current are supplied using this pin. 5 DIM Dimming. This pin controls the dimming operation of the LED lighting. 6 VS Voltage Sense. This pin detects the output voltage information and discharge time for linear frequency control and constant-current regulation. This pin connects divider resistors from the auxiliary winding. 7 COMI Constant-Current Loop Compensation. This pin is the output of the transconductance error amplifier. 8 GND Ground Current Sense. This pin connects a current-sense resistor to detect the MOSFET current for the output-current regulation in constant-current regulation. Figure 21. Functional Block Diagram © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 www.fairchildsemi.com 7 AN-9745 APPLICATION NOTE Design Summary Figure 22 shows the schematic of the TRIAC dimmable LED driver using FL7730. This schematic is dedicated to low-line voltage (90~140 VAC). Q1 MB8S L1 4.7mH C3 R3 100nF 20k R1 560/0.5W C1 330n D5 ES3D L2 4.7mH R11 510k D1 C2 ES1J 330n Q2 FQN1N50C R4 1M R2 100/0.5W F1 1A/250V R12 510k R10 100kΩ 0.5W C8 10n N1 N3 C10 35V/330uF VO C11 35V/1000uF R17 51k D4 RS1M D2 11V R6 62k R8 150k R5 75k D3 1N4003 R7 0 Q3 FL7730 5 C4 3.3u R9 20k Dim VDD VS GND 6 7 C5 10p C6 2.2u 8 COMI N.C GATE CS C7 47u 4 3 N2 R13 10Ω 2 Q4 FQU5N60C C9 4.7nF 1 R16 200Ω R14 1.2Ω R15 1.0Ω Figure 22. Schematic of TRIAC Dimmable LED Driver Using FL7730 (Low Line: 90~140 VAC) NP2(3 4) NA(2 6) NS (NS- NS+) NP1(5 3) Figure 23. Transformer Structure Table 5. Winding Specifications No Winding Pin (S → F) Wire Turns Winding Method 1 NP1 53 0.13φ 38 Ts Solenoid Winding NS NS- NS+ 2 Insulation: Polyester Tape t = 0.025 mm, 2-Layer 3 4 0.3φ (TIW) 24 Ts Solenoid Winding Insulation: Polyester Tape t = 0.025 mm, 2-Layer 5 NA 26 6 0.13φ 18 Ts Solenoid Winding Insulation: Polyester Tape t = 0.025 mm, 2-Layer 7 NP2 34 8 0.13φ 38 Ts Solenoid Winding Insulation: Polyester Tape t = 0.025 mm, 6-Layer Table 6. Electrical Characteristics Pin Specification Inductance 1–2 1 mH ±10% 50 kHz, 1 V Leakage 1–2 8 µH 50kHz, 1 V Short All Output Pins © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 Remark www.fairchildsemi.com 8 AN-9745 APPLICATION NOTE Experimental Verification The design example with passive bleeder and active damper was experimentally verified in an 8 W LED lighting system. Figure 24 shows constant current regulation at input voltage and output voltage change. Constant-current deviation in the wide output voltage range from 10 V to 28 V is less than 2.1% at each line input voltage. Line regulation at the rated output voltage (22 V) is less than 3.9%. Operation waveforms are shown in Figure 25, Figure 26, and Figure 27. In this dimmable board, TRIAC dimmer firing is stabilized without any misfire. FL7730 keeps constant tON so VCS is in phase with VIN. The maximum spike current of IIN is 1.2 A. Figure 28 shows the dimming curve. RMS input voltage indicates TRIAC dimming angle. LED current is smoothly controlled by the FL7730 dimming function and external circuits, such as the passive bleeder and active damper. Table 7 provides compatibility with common dimmers for a design without visible flicker. Maximum and minimum current vary because each dimmer’s maximum and minimum angles are different. Figure 25. Waveforms at Maximum Dimming Angle IIN VIN System efficiency is from 80.7% to 82.9% at low line input voltage (90 ~ 140 VAC). The active damper helps improve the efficiency with a compact and inexpensive design solution. Table 8 shows PF and THD in a low line input voltage range of 90~140 VAC. PF is over 0.9 and THD is much less than 30% by constant tON and linear frequency control in the FL7730. VCS The performances obtained in the design example show a powerful LED lighting solution with accurate constant current regulation, stable dimming control, high efficiency, high PF, and low THD with low BOM cost. Figure 26. Waveforms at Half Dimming Angle IIN OVP VIN VCS Figure 27. Waveforms at Minimum Dimming Angle IOUT [mA] Figure 24. CC Regulation, Measured by CR-Load © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 www.fairchildsemi.com 9 AN-9745 APPLICATION NOTE Table 7. Dimmer Compatibility Manufacturer Dimmer Maximum Current Minimum Current Flicker LUTRON S-600P-WH 330 mA 40 mA (12%) No LUTRON CN-600P-WH 328 mA 11 mA (3.4%) No LUTRON GL-600H 365 mA 8 mA (2.2%) No LUTRON TG-603PGH-WH 252 mA 12 mA (4.8%) No LUTRON TG-600PH-WH 333 mA 14 mA (4.2%) No LUTRON LG-600P 327 mA 3 mA (0.9%) No LUTRON CTCL-153PD 320 mA 58 mA (18%) No LEVITON IP106 380 mA 36 mA (9.5%) No LEVITON 1C4005 344 mA 0 mA (0%) No LEVITON 6631-LW 340 mA 0 mA (0%) No Legrand F 165H 344 mA 3 mA (0.9%) No Figure 29. Efficiency Figure 28. Dimming Curve (Input Voltage vs. LED Current) Table 8. Power Factor (PF) and Total Harmonic Distortion (THD) Input Voltage Output Current Output Voltage PF THD 90 VAC 360 mA 21.70 V 0.98 7.4% 110 VAC 376 mA 21.77 V 0.96 9.5% 120 VAC 380 mA 21.77 V 0.95 10.4% 140 VAC 386 mA 21.79 V 0.91 12.4% © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 www.fairchildsemi.com 10 AN-9745 APPLICATION NOTE Related Datasheets FL7730MY — Single-Stage Primary-Side-Regulation PWM Controller for PFC and LED Dimmable Driving KA431 — Programmable Shunt Regulator DISCLAIMER FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION, OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS. LIFE SUPPORT POLICY FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR CORPORATION. As used herein: 1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, or (c) whose failure to perform when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in significant injury to the user. © 2011 Fairchild Semiconductor Corporation Rev. 1.0.2 • 10/11/12 2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness. www.fairchildsemi.com 11