This is one of these places where a little theory is helpful. You need to think about several things:

- what is the resolution of your measurements: 0.1° or 0.001°? 1 second or one microsecond?
- are the measurements associated and in some order, or tossed together randomly?

Let's say, just for example, that the resolution is 0.01°. Them you know that your values range from -180° to +180°, or 35900 different values. Lg(35900) ≈ 16 so you need 16 bits; 14 bits for -90°–+90°. Clearly, if you're storing this kind of value as floating-point, you can compress the data by half immediately.

Similarly with date time, what's the range; how many bits must you have?

Now, if the data is in some order (like, samples taken sequentially aboard a single ship) then all you need is a start value and a delta; that can make a *big* difference. With a ship traveling at 30 knots, the position can't change any more that about 0.03 degrees an hour or about 0.0000083 degrees a second. Those deltas are going to be very small values, so you can store them in a very few bits.

The point is that there are a number of things you can do, but you have to know more about the data than we do to make a recommendation.

Update: Oh, wait, fixed point *strings*?!

Okay, this is (relatively) easy. Just to start with, yes, you want to convert your strings into some binary representation. Just making up a data item, you might have

```
040.00105.0020090518212100Z
```

which you could convert to

| 4000 | short int, 16 bits |
| 10500 | short int, 16 bits |
| 20090518212100Z | 64 bits |

So that's 96 bits, 12 bytes versus 26 bytes.