A Color object contains a color in ARGB. A is for Alpha, which you don't need right now. The others are values for Red, Green and Blue. Each of them is an 8 bit value. Together, ARG and B form a 32 bit color.

16 bit colors are weird to begin with, because Red and Blue have 5 bits and Green has 6 bits.

To convert these to 8 bits, you can bit shift them (or multiply them).

```
int input = Your16BitColorValue;
var color = new Color;
color.R = input & 0x1F; /* Isolate 5 least significant bits */
color.G = (input & 0x7E0) >> 5; /* Isolate 6 middle bits and shift them 5 right */
color.B = (input & 0xF800) >> 11; /* Isolate left 5 bits and shift them right */
```

This is pretty accurate. For instance, for green, a 6 bit number, the highest value (all 6 bits set) is 63. The lower half of the bits set, results in 7 (1/9th of the max). When you shift that two places to convert to an 8 bit number, you get 28, which is also exactly 1/9th of 255. If you try a couple of other examples, you'll find that every example is pretty close. The biggest rounding errors, you find in the end of the spectrum. For instance 63, which is the brightest green in 16bit, will result in 252, which is *almost* the brightest green in 32 bit, but not exactly.

To solve that, you might use a factor, like this:

```
Value32 = Value16 * 255 / Max16Value
```

where Max16Value is either 31 (for red and blue) or 63 (for green). For instance:

```
Color.B = ((input >> 11) & 0x1F) * 255 / 31;
```

That way, a red of 31 in input will actually result in a red of 255 in the 32 bit color, which is the brightest value in both cases.