Since you asked about acceleration as a vector, here is an alternate solution which would compute things that way.

First, given the velocity (a `Vector2D`

value), let's suppose you can compute a direction from it. I don't know your syntax, so here's a sketch of what that might be:

```
double forwardDirection = Math.toDegrees(velocity.direction()) + 90;
```

This is the direction the car is pointing. (Cars are always pointing in the direction of their velocity.)

Then, we get the components of the acceleration. First, the front-and-back part of the acceleration, which is pretty simple:

```
double forwardAcceleration = 0;
if (up)
forwardAcceleration = 100;
if (down)
forwardAcceleration = -100;
```

The acceleration due to steering is a little more complicated. If you're going around in a circle, the magnitude of the acceleration towards the center of that circle is equal to the speed squared divided by the circle's radius. And, if you're steering left, the acceleration is to the left; if you're steering right, it's to the right. So:

```
double speed = velocity.magnitude();
double leftAcceleration = 0;
if (right)
leftAcceleration = ((speed * speed) / turningRadius);
if (left)
leftAcceleration = -((speed * speed) / turningRadius);
```

Now, you have a `forwardAcceleration`

value that contains the acceleration in the forward direction (negative for backward), and a `leftAcceleration`

value that contains the acceleration in the leftward direction (negative for rightward). Let's convert that into an acceleration vector.

First, some additional direction variables, which we use to make unit vectors (primarily to make the code easy to explain):

```
double leftDirection = forwardDirection + 90;
double fDir = Math.toRadians(forwardDirection - 90);
double ldir = Math.toRadians(leftDirection - 90);
Vector2D forwardUnitVector = new Vector2D(Math.cos(fDir), Math.sin(fDir));
Vector2D leftUnitVector = new Vector2D(Math.cos(lDir), Math.sin(lDir));
```

Then, you can create the acceleration vector by assembling the forward and leftward pieces, like so:

```
Vector2D acceleration = forwardUnitVector.scale(forwardAcceleration);
acceleration = acceleration.add(leftUnitVector.scale(leftAcceleration));
```

Okay, so that's your acceleration. You convert that to a change in velocity like so (note that the correct term for this is `deltaV`

, not `deltaA`

):

```
Vector2D deltaV = acceleration.scale(secondsElapsed);
velocity = velocity.add(deltaV).
```

Finally, you probably want to know what direction the car is headed (for purposes of drawing it on screen), so you compute that from the new velocity:

```
double forwardDirection = Math.toDegrees(velocity.direction()) + 90;
```

And there you have it -- the physics computation done with acceleration as a vector, rather than using a one-dimensional speed that rotates with the car.

(This version is closer to what you were initially trying to do, so let me analyze a bit of where you went wrong. The part of the acceleration that comes from up/down is always in a direction that is pointed the way the car is pointed; it does not turn with the steering until the car turns. Meanwhile, the part of the acceleration that comes from steering is always purely to the left or right, and its magnitude has nothing to do with the front/back acceleration -- and, in particular, its magnitude can be nonzero even when the front/back acceleration is zero. To get the total acceleration vector, you need to compute these two parts separately and add them together as vectors.)

Neither of these computations are completely precise. In this one, you compute the "forward" and "left" directions from where the car started, but the car is rotating and so those directions change over the timestep. Thus, the `deltaV = acceleration * time`

equation is only an estimate and will produce a slightly wrong answer. The other solution has similar inaccuracies -- but one of the reasons that the other solution is better is that, in this one, the small errors mean that the speed will increase if you steer the car left and right, even if you don't touch the "up" key -- whereas, in the other one, that sort of cross-error doesn't happen because we keep the speed and steering separate.

`if (speed < 1.5 && speed != 0) velocity.setLength(0);`

? Regarding the acceleration with the arrow keys: I find it awkward that your rotation velocity increases when your speed decreases. Anyways, the easiest way to get your direction fixed is to rotate the velocity vector when pressing left or right. If you want it "more physical" consider using an angular momentum, but don't get too fancy. – user694971 Sep 5 '11 at 21:22