# Basic pathfinding with obstacle avoidance in a continuous 2D space

I'm writing a simulation in which a creature object should be able to move towards some other arbitrary object in the environment, sliding around obstacles rather than doing any intelligent pathfinding. I'm not trying to have it plan a path -- just to move in one general direction, and bounce around obstacles.

It's a 2D environment (overhead view), and every object has a bounding rectangle for collision detection. There is no grid, and I am not looking for A* solution.

I haven't been able to find any tutorials on this kind of "dumb" collision-based pathfinding, so I might not be describing this using the most common terms.

Any recommendations on how to implement this (or links to tutorials)?

-

Expanding on what Guillaume said about obstacle avoidance, a technique that would work well for you is anti-gravity movement. You treat local obstacles as point sources of antigravity, the destination as gravity, and your computer controlled character will slip (like soap!) around the obstacles to get to the destination.

-
On the minus side, you have to have a anti-gravity field that is greater than the object to avoid, so that you begin to turn before you vehicule is on the obstacle. Thus, you can have a configuration where you get a acceleration that goes directly against the desired one (two obstacle in front of you, cancelling each lateral acceleration, and overridding the forward acceleration to the goal) on the plus side, this would work well against moving obstacles. –  PATRY May 18 '09 at 11:30
While two obstacles can theoretically cancel each other, in practice that's unlikely and unstable... just a small change in position and you get pulled around the obstacle. If it's an issue, you could counter it with random noise. –  Paul May 18 '09 at 23:56
The anti-gravity solution looks like a good option in my case. It's very straightforward, and the calculations are trivial. I don't require guarantees that the agents will reach targets on the first attempt, so it's okay if they get blocked by obstacles (though occasional application of random extra forces might solve this problem as well). –  kpozin May 19 '09 at 0:42
I agree that its unstable and unlikely. I just mentionned it because i used this solution in a case where players could place "defenses" very precisely, and this was a cheat that our test showed. I didn't thought about adding random noise :( –  PATRY May 19 '09 at 10:07
Ah, that's a good point PATRY... thanks for the insight! –  Paul May 20 '09 at 2:54

Maybe you could use Pledge's algorithm

-
It's "Pledge" (from reading the wikipedia link). –  Ross May 18 '09 at 18:44

you can combine two steering algorithm :

seek : you apply a steering force in the direction which is the difference between the current velocity and the desired velocity towards the target

Obstacle Avoidance : you anticipates the vehicle's future using a box whose length is a constant time multiplied by the current velocity of the vehicle. Any obstacle that intersects this box is a potential collision threat. The nearest such threat is chosen for avoidance. To avoid an obstacle, a lateral steering force is applied opposite to the obstacle's center. In addition, a braking (deceleration) force is applied. These forces vary with urgency (the distance from the tip of the box to the point of potential collision). Steering varies linearly, braking varies quadratically.

You can find more on the website "Steering Behaviors For Autonomous Characters"

regards

Guillaume

PS : this assume you're using a point/velocity/acceleration method for the object's movement.

-

Whenever your creature, travelling in vector direction v, collides with a wall whose direction is represented by vector w, the direction that you need to "slide" is given by the vector that is the projection of v onto w. This can be found using

v . w
--------- w
|w|*|w|

where . is the vector dot product and |w| is the magnitude of vector w ( = sqrt(w . w)). If w is a unit vector, this becomes simply

(v . w) w

Using the resulting vector as your creature's speed will mean your creature travels quickly when it just "grazes" the wall, and slowly when it hits the wall nearly dead-on. (This is how most first-person shooter games manage collisions for the human player.)

If instead you want your creature to always travel at full speed, you only need the sign of v . w -- you will always be travelling either in the direction the wall faces (w) or the opposite direction (-w).

The issue that you will have is when your creature hits the wall dead-on. In that case your projected vector will be (0, 0), and you need some other technique to decide which way (w or -w) to go. The usual approach here is A*, although this may be unnecessary if your environment possesses enough structure.

-