Generally you want to bring in time to the equation, so that you can smoothly change the angle over `time`

. Most setups have a way to get a time it took to render the previous frame and the typical way to do this is to say..

```
int touchAngle;
float angle;
float deltaTime; //Time it took to render last frame, typically in miliseconds
float amountToTurnPerSecond;
public void update()
{
if((int)angle != touchAngle) angle += (deltaTime * amountToTurnPerSecond);
}
```

This will make it so that each second, your angle is changed by `amountToTurnPerSecond`

, but changed slowly over each frame the correct amount of change so that it is smooth. Something to note about this is that you wont evenly end up at `touchAngle`

most of the time, so checking to see if you go over and instead setting to `touchAngle`

would be a good idea.

Edit to follow up on comment:

I think the easiest way to attain the correct direction for turn is actually not to use angles at all. You need to get the relative direction from your touch to your character in a 2d space. Typically you take the touch from screen space to world space, then do the calculations there (at least this is what I've done in the past). Start out by getting your touch into world space, then use the vector cross product to determine direction. This looks kind of like the following...

```
character position = cx, cy
target position = tx, ty
current facing direction of character = rx, ry
```

First we take the distance between the character and the target position:

```
dx = tx - cx
dy = ty - cy
```

This not only gives us how far it is from us, but essentially tells us that if we were at 0, 0, which quadrant in 2d space would the target be?

Next we do a cross product:

```
cross_product = dx * ry - dy * rx
```

If this is positive you go one way, if it's negative you go the other. The reason this works out is that if the distance is for instance `(-5, 2)`

then we know that if we are facing directly north, the point is to our left 5 and forward 2. So we turn left.