HB (high-brightness) LEDs require a large amount of current to operate. When driving HB LEDs from a voltage source, you can set the required current with a suitable series resistor. If the voltage source is a battery, then, as the battery drains, the LED’s intensity decreases. Also, a series resistance has the disadvantage of power loss through the resistor. A better option is to use a suitable dc/dc converter. If the LED’s turn-on voltage is lower than the battery voltage, as would be the case with a 6V sealed-lead-acid battery, then you can use a buck converter (reference 1 and reference 2). You can build a simple buck converter using only discrete components. It requires two bipolar transistors, a P-channel MOSFET, an inductor, a Schottky diode, and a few resistors (Figure 1).

When you switch on the battery voltage, the voltage across R₁, the resistor in series with the HB LED, is 0V. Thus, transistor Q₂ is off, and Q₁ is in saturation. The saturated state of Q₁ switches on the MOSFET, thereby applying the battery voltage to the LED through the inductor. As the current through resistor R₁ increases, it turns on Q₂, which turns off Q₁ and thus turns off the MOSFET. During the MOSFET’s off state, the inductor continues to supply current to the LED through Schottky diode D₂. The HB LED is a 1W, white Lumiled LED. Resistor R₁ helps control the LED’s intensity. Using a larger value for R₁ reduces the intensity.

The SwitchCAD-III software, which is available as a free download from Linear Technology, simulated the circuit; the simulated MOSFET was an International Rectifier IRF9Z24S instead of an IRF9540 because the model for IRF9540 is not available in SwitchCAD-III. Figure 2 plots the MOSFET-drain waveform and the voltage at Q₁’s base. The circuit was wired on a prototyping board and tested for various supply voltages. Figure 3 shows oscilloscope screenshots for the MOSFET-drain voltage and the voltage at the base of Q₁. They fairly well match the simulated waveform. Conversion efficiencies were 60 to 95% for supply voltages of 6 to 10V.