Designing a Buck-Boost LED Driver Using the MAX16834
- Buck-Boost LED drivers allow LED bias when the input voltage is either above or below the LED voltage. This is ideal in cases such as a single cell Li-Ion battery.
- Abstract: This reference design is for a buck-boost LED driver. The MAX16834 current-mode high-brightness LED driver is featured, and the MAX16834 EV evaluation kit.
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- High Voltage High Current LED Driver Controller for Buck Boost or Buck-Boost Topology.
Abstract: This reference design is for a buck-boost LED driver. The MAX16834 current-mode high-brightness LED driver is featured, and the MAX16834 EV (evaluation) kit is used to implement the design. The application note shows the design specifications, schematic, bill of materials (BOM), and performance data. In this reference design a buck-boost converter (input-voltage referenced) drives 350mA through 4 white LEDs (WLEDs) from a 7V to 18V DC supply. The MAX16834 current-mode high-brightness (HB) LED driver is featured. Input voltage: 7V to 18V Input voltage ripple: 100mVP-P LED current: 350mA LED current ripple: 5% (max) LED forward voltage: 3.5V at 350mA Number of LEDs: 4 (max) Output overvoltage protection: 17.2V Detailed Description Connecting the negative terminal of a boost converter's output to the input-positive supply results in a buck-boost converter (input-voltage referenced). In this design a buck-boost converter (input-voltage referenced) drives 350mA through 4 white LEDs (WLEDs) from a 7V to 18V DC supply. (Each WLED has a forward voltage drop of 3.5V at 350mA.) The MAX16834 HB LED driver with integrated peak current-mode controller is used to design the converter, which operates in CCM (continuous conduction mode) at 495kHz switching frequency. The switching frequency is configured with the 11kΩ R15 resistor. The MAX16834 controls the peak of the inductor current to achieve 350mA LED current under different input-output voltage conditions. The voltage across the LED current-sense resistor is sensed and then amplified by a factor of 9.9 internally. This results in a smaller value of sense resistor, thereby increasing the efficiency. This amplified voltage is then compared with the reference voltage set by resistors R16 and R17. The error is then amplified by the transconductance amplifier with GM = 500µS. This results in a control voltage across the COMP pin; this voltage sets the reference to the current loop. The peak of the voltage across the inductor current-sense resistor, R9, is tracked to this voltage. Input supply-voltage range: 7V to 18V Input voltage ripple: 100mVP-P Maximum LED forward voltage: 14V (which is 4 x 3.5V) LED current: 350mA LED current ripple: 5% (max) Switching frequency: 455kHz Calculate the maximum duty cycle for N2 from Equation 1: Where VLEDMAX is the maximum LED voltage; VINMIN is the minimum input voltage; VD is the diode voltage drop; and VDS is the average voltage across the FET when it is turned on. In this application, DMAX is 0.69. Selecting the Inductor (L1) To choose an inductor, both the inductor value and its peak current value must be known. Calculate the peak inductor current with Equation 2: Where ILAVG is the average inductor current. ΔIL is the inductor current ripple, specified as the percentage of average inductor current: Allow 30% ΔIL. After substituting the known values, we get: Calculate the minimum inductance with Equation 5: Where fSW is the switching frequency. Allowing 20% tolerance results in LMIN = 17µH. Here a 22µH inductor is chosen. Switch Current-Sense Resistor (R9) Under normal operating conditions the maximum voltage across the switch current-sense resistor must not be more than 250mV. If the sense-resistor voltage reaches 300mV (typ), then the converter is turned off. The voltage across R9 determines the ON pulse width of the switching cycle. Internal leading-edge blanking is provided to prevent premature turn-off of the switching MOSFET in a switching cycle. Calculate R9 with Equation 6: Therefore, R9 = 0.133Ω. Here a 0.15Ω resistor is chosen for R9. Slope Compensation Capacitor (C13) Peak current-mode control is known to be unstable at duty ratios more than 50% in a CCM boost-converter design. Proper slope compensation is, therefore, required to eliminate the instability caused by the subharmonic oscillations. The MAX16834 uses an internal ramp generator for slope compensation. The ramp resets at the beginning of each switching cycle and slews at the rate programmed by the external capacitor, C13. An internal 100µA current source charges this capacitor. This voltage is added to the voltage across R9 internally. Calculate the value of C13 with the Equation 7: Where VSLOPE is: Therefore from Equations 7 and 8, C13 = 1.57nF. Here a 1.5nF capacitor is chosen. LED Current-Sense Resistor (R5) Calculate R5 with the Equation 9: For this application VREFI is selected as 1.94V. Therefore, R5 = 0.56Ω. Filter Capacitors Calculate the value of output capacitor COUT (the parallel combination of C7 and C8) with Equation 10: Where ΔVLED is the maximum peak-to-peak boost output-voltage ripple. This value depends on the maximum current ripple and the dynamic impedance of LEDs at the rated current. To prolong LED life and preserve chromaticity, the LED current ripple should be kept below 5% of the average current. In this application, COUT is calculated to be 3µF. Accordingly, two capacitors of 2.2µF/50V each are chosen for C7 and C8. Calculate the input capacitor value (the parallel combination of C1, C2) with Equation 11: Where ΔVIN is the peak-to-peak input voltage ripple. For a 100mV ΔVIN, CIN is 1.9µF. Therefore, C1 is selected as 2.2µF/25V and C2 as 1.1µF/25V. Feedback Compensation A buck-boost converter, power-circuit transfer function has a right-half-plane zero calculated with Equation 12: For this application, fRHPZ occurs at 37.8kHz. To keep the feedback stable with sufficient phase margin, the total loop gain should cross 0dB before one-fifth of the RHP zero frequency at -20dB/decade. Thus the crossover frequency, fC, is calculated to be 7.56kHz. The output capacitor and effective output impedance offered by the load create a pole at: Where RO is the effective impedance contributed by the load, and is calculated as: From Equation 14, fP1 = 4.7kHz. Now the compensation components, R10 and C12, must be selected. They must contribute a zero at the pole frequency fP1, and set the loop gain at fP1 so that loop gain crosses 0dB at fC. Calculate R10 with Equation 15: From Equation 15, R10 = 341Ω. Here a 301Ω resistor is chosen for R10; GM is the gain of the internal transconductance amplifier. Accordingly, C12 is calculated as: From Equation 16, C12 = 0.11µF. Here a 0.1µF capacitor is chosen. Digital PWM Dimming The MAX16834 has an internal PWM dimming MOSFET driver. PWM dimming is achieved by applying a 1.5V to 5V logic-high PWM signal with a frequency ranging from DC to 20kHz. The brightness of the LED can be varied by changing the duty ratio of the PWM signal. The NDRV driver and the output of the transconductance amplifier are controlled by the PWM signal. When the PWM signal is high, then NDRV is enabled and the output of the transconductance amplifier is connected to the COMP pin. When the signal is low, NDRV is disabled and the output of the amplifier is disconnected. The COMP pin is connected to the negative input of the PWM comparator with CMOS inputs which draw negligible current from the compensation capacitor, C12. Thus the charge on C12 is preserved, thereby retaining the state when PWM was on. Once the signal becomes high, NDRV is enabled and the output of the amplifier is connected to the COMP pin. This establishes a steady-state operation quickly. Open-LED Protection The output of the boost converter can increase to high voltages, if it is operated without any load or if there is an open-LED fault. The converter can be disabled at a desired output voltage, which can be configured with the help of R11 and R12. The midpoint of R11 and R12 is connected to the OVP pin of the IC. The converter is disabled if the voltage across this pin reaches 1.435V (typ). In this application, R11 and R12 are configured to activate open-LED protection once the output voltage reaches 17.2V. Implementation of the Buck Boost Converter on the MAX16834 EV Kit The MAX16834 EV kit is assembled as a boost converter. The kit board can be reconfigured in buck-boost mode by removing and adding the following components: Remove resistors R4 and R8. Install a 0Ω resistor in place of R3. Install the components mentioned in the BOM.
Application Note AN874, Buck Configuration High-Power LED Driver Buck-Boost LED Driver Using the PIC16F785 MCU Author: Microchip Technology Inc. Subject.
Buck-Boost LED Drivers
Buck-Boost LED drivers allow LED bias when the input voltage is either above or below the LED voltage. This is ideal in cases such as a single cell Li-Ion battery driving a single LED where the input voltage can vary from 4.2V fully charged down to 2.7V fully depleted while the LED forward voltage can vary from 2V to 4V depending on brightness and temperature. These LED drivers offer the highest efficiency, lowest noise, and the smallest footprints. Other features include integrated Schottky diodes, accurate LED current matching and multiple output capability. Quick LED Driver Search Input Vin (Min) V Vin (Max) V LED Strings # LEDs In Each String # Strings String Current A LED Voltage Min LED Voltage V Max LED Voltage V
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