The way you problem is described, the algorithm is straightforward and requires only two simple steps: 1) move forward while turning (left or right) until the car is pointed directly at B, 2) move straight forward until you hit B. Done.

The only relatively tricky part is the first step. If B lies to the left from the longitudinal axis of the car in its initial position, the natural approach would be to start by turning *left*. This will work, unless point B lies inside the circular trajectory produced by such a left turn (of radius `turningRadius`

). In the latter case the car will run in circles, but will never be able to aim directly at B. In such cases the proper strategy is actually to start with a *right* turn and keep turning until you aim the car at B.

So, if you don't have any optimality requirements for your trajectory, the simplest algorithm for the first step would be to unconditionally turn "away" from the point: turn *right* if B lies to the *left* of the longitudinal axis of the car, and turn *left* if B lies to the *right*. Keep turning until the car is aimed directly at B. This sounds a bit unnatural, but it always works, i.e. you will always be able to eventually aim the car.

If you care for a more optimal (shorter) trajectory, then you need to analyze the location of B with respect to the initial position/orientation of the car ("Is B inside the turning circle or outside?") and choose the direction of the first turn accordingly.