The capacitors C1 (of 220 nanoFarad

The capacitors C1 (of 220 nanoFarad) and C2 (of 100 nanoFarad) smooth out the input and output voltages. This is important because the L200 has a feedback loop where it takes voltage readings that depend on its output and then changes its output in responce. This can induce some oscillations in its output. The size of the capacitors is appropriate for smoothing out this frequency.

R2 should be an 820 Ohm resistor. R1 should be a variable resistor, with maximum value somewhat larger than the computed ideal resulting from the second equation. It's best if it can be adjusted very finely, as you want to be precise about the output voltage of your charger. The value of R3 sets the maximum current the circuit will produce (up to about 2A). The relevant equations are:

Vout (in volts) = 2.77 * (1 + R1 / R2)

R1 = (Vout/2.77 - 1) * R2

R3 (in Ohms) = 0.45 / Imax (in amps)

where Vout is the voltage drop across the output (between + OUT and - OUT, this is the voltage applied to your battery), and Imax is the maximum charging current. To determine what Imax should be, find the manufactorer's charging recommendations for your battery. Some batteries, like my Hawker Cyclon don't need to have the current limited when they are being charged with constant voltage. Still, you have to pick some value, and you'll want it to be less than than the 2A max that the L200 will deliver and less than the max current your AC/DC converter is rated for (which is clearly written on the converter). I used a resistance of about 0.5 Ohms to limit it to about 1A, as the AC/DC converter I used (see below) is rated for 1A.

You can see that with this circuit you'll get an output voltage anywhere between about 3V and 33V. Thus, practically speaking, it can be used as a charger for either a 6V or 12V battery depending on how you set the resistor R1, and which AC/DC converter you use.