I'm working on a game where on each update of the game loop, the AI is run. During this update, I have the chance to turn the AI-controlled entity and/or make it accelerate *in the direction it is facing*. I want it to reach a final location (within reasonable range) and at that location have a specific velocity and direction (again it doesn't need to be exact) That is, given a current:

**P**= Current position vector_{0}(x, y)**V**= Current velocity vector (units/second)_{0}(x, y)**θ**= Current direction (radians)_{0}**τ**= Max turn speed (radians/second)_{max}**α**= Max acceleration (units/second^2)_{max}**|V|**= Absolute max speed (units/second)_{max}**P**= Target position vector_{f}(x, y)**V**= Target velocity vector (units/second)_{f}(x, y)**θ**= Target rotation (radians)_{f}

Select an *immediate*:

**τ**= A turn speed within [-τ_{max}, τ_{max}]**α**= An acceleration scalar within [0, α_{max}] (must accelerate in direction it's currently facing)

Such that these are minimized:

**t**= Total time to move to the destination**|P**= Distance from target position at end_{t}-P_{f}|**|V**= Deviation from target velocity at end_{t}-V_{f}|**|θ**= Deviation from target rotation at end (wrapped to (-π,π))_{t}-θ_{f}|

The parameters can be re-computed during each iteration of the game loop. A picture says 1000 words so *for example* given the current state as the blue dude, reach *approximately* the state of the red dude within as short a time as possible (arrows are velocity):

Assuming a constant α and τ for Δt (Δt → 0 for an ideal solution) and splitting position/velocity into components, this gives (I *think*, my math is probably off):

_{(EDIT: that last one should be θ = θ0 + τΔt)}

So, how do I select an immediate α and τ (remember these will be recomputed every iteration of the game loop, usually > 100 fps)? The simplest, most naieve way I can think of is:

- Select a Δt equal to the average of the last few Δts between updates of the game loop (i.e. very small)
- Compute the above 5 equations of the next step for all combinations of (α, τ) = {0, α
_{max}} x {-τ_{max}, 0, τ_{max}} (only 6 combonations and 5 equations for each, so shouldn't take too long, and since they are run so often, the rather restrictive ranges will be amortized in the end) - Assign weights to position, velocity and rotation. Perhaps these weights could be dynamic (i.e. the further from position the entity is, the more position is weighted).
- Greedily choose the one that minimizes these for the location Δt from now.

Its potentially fast & simple, however, there are a few glaring problems with this:

- Arbitrary selection of weights
- It's a greedy algorithm that (by its very nature) can't backtrack
- It doesn't really take into account the problem space
- If it frequently changes acceleration or turns, the animation could look "jerky".

Note that while the algorithm can (and probably should) save state between iterations, but P_{f}, V_{f} and θ_{f} can change every iteration (i.e. if the entity is trying to follow/position itself near another), so the algorithm needs to be able to adapt to changing conditions.

Any ideas? Is there a simple solution for this I'm missing?

Thanks, Robert