7

I'm trying to calculate new velocities for 2 colliding balls, but can't really do that before I solve another problem.

Since in digital world a real collision almost never happens, we will always have a situation where the "colliding" balls overlap.

Imagine there is a 100 balls moving randomly so, if I understand it correctly, the procedure should be as follows:

  • Move the balls (x += vx; y+= vy;)
  • Get the lest overlapping (or perfectly colliding) balls
  • Move the balls "back in time" to that moment
  • Perform collision calculations

If the above is correct, then, how could I move the balls "back in time" to the point of first collision? Known data:

  • All coordinates of the balls (b[i].x, b[i].y)
  • Ball X and Y velocities (b[i].vx, b[i].vy)
  • Distance between lest overlapping balls (dist)

Should I just calculate how many percent the dist is of the perfect distance to the collision and then simply move back x and y coordinates by the same amount of percent of vx and vy?

3

For collisions like these, it's usually easiest to look at it from the reference frame of one of the balls.

Let's say you have ball1 and ball2. These balls have positions p1 and p2 respectively, and velocities v1 and v2. Let the relative velocity of ball1 with respect to ball2 be v1-v2=v.

We want to know when ||p1-p2|| is less than ||r1||+||r2||, where r1 is the vector with a length of the radius of the first ball in the direction towards the second ball, and r2 is vice-versa.

From ball2's perspective, ball1 is moving with velocity v1+v2. At time t, ball2 is at position p2+(v1+v2)*t.

The balls collide when:

(p1-(p2+vt)) = (r1+r2)
-(p2+vt) = (r1+r2)-p1
-p2-vt = (r1+r2)-p1
-vt = (r1+r2)-p1+p2
vt = (p1-p2)-(r1+r2)

Now since ||a|| = ||b||+||c|| when a = b+c, we know that

||v||t = ||p1-p2|| - ||r1+r2||
t = (||p1-p2|| - ||r1+r2||)/||v||

For example: p1 = (7,5) and p2=(4,1), ||r1||=1 and ||r1||=2, and v1=(1,2) and v2=(-2,-2) then v=(3,4). The collision happens at:

t = (||(3,4)|| - 3)/||(3,4)||
t = (5-3)/(5) = 2/5 = 0.4

Now that you have the time of the collision, figuring out where the balls are is easy :-)

edit to put the vectormath into pseudocode:

p = p1-p2
v = v1-v2
t = (sqrt(p.x*p.x + p.y*p.y) - (r1+r2)) / sqrt(v.x*v.x + v.y*v.y)
|improve this answer|||||
  • Wow there is way too much math for this late hour. Thank you, i'll have to remember vector math before trying to understand any of this. I'll come back with questions if something goes terribly wrong ;] – Marius Jun 23 '11 at 20:09
  • ok, i added pseudocode so you don't have to worry about vector math so much! – hughes Jun 23 '11 at 20:18
  • Thank you, i'll try it out as soon as i can. – Marius Jun 25 '11 at 8:42
  • Thanks i've managed to adapt your math, but unfortunately, as the other posters said, it's not that easy. I thought i could limit myself by low speeds so that the balls would never fly through each other in one frame but it seems i can't. Your equasions, however, answer my original question so thank you. – Marius Jun 27 '11 at 17:46
3

Whether your strategy of move-then-collide makes sense depends on what kind of thing you are trying to simulate, and on the trade-off between accuracy and speed. If you are, say, writing a snooker simulator, or Super Monkey Ball, then move-then-collide is probably not good enough, for three reasons.

First, the balls will have the wrong velocities after collision. The differences will be subtle, but will feel wrong to players:

enter image description here see text

On the left, velocities at the end of a time-step when balls are allowed to intersect before collision is detected. On the right: velocities immediately after a collision at the correct time and place.

Second, objects moving fast enough may pass through each other without colliding. Or even if you detect the collision, you may eject the objects in the wrong way, causing some kind of illegal motion. (See tasvideos.org for a collection of collision bugs in the Super Mario Bros games that are caused by this move-then-eject strategy.)

Third, objects may end up intersecting at the end of your time step, with no room to move them apart (because other objects get in the way). So you end up having to draw the objects in intersecting position, which looks wrong.

In applications where these issues matter, then it's better to determine the point of collision before moving the balls. See this article of mine for a basic introduction to this collide-then-move approach.

|improve this answer|||||
  • The graphic isn't right, since the balls on the left are shown before the collision has been calculated (don't confuse sim time with real time). Your second point is sound, but your third seems to ignore the fact that the sim will rewind time. – Beta Jun 23 '11 at 22:49
  • If you're going to rewind time, you have to rewind time for all the balls, otherwise you may find that there's a third ball sitting in the spot where you are expecting the first two balls to collide. (And if you're going to rewind time for all the balls, why bother to wind it forwards in the first place?) – Gareth Rees Jun 23 '11 at 23:25
  • In general, yes, you have to rewind time for all balls -- although you could probably save some work by rewinding it only for balls involved in conflicts like that. (I assume you're only joking about the "why bother...".) – Beta Jun 23 '11 at 23:36
  • No, quite serious. I don't see what it gains you. – Gareth Rees Jun 24 '11 at 0:19
  • If you take out that step, the simulation goes nowhere. Remember, we're discussing move-then-collide. – Beta Jun 24 '11 at 1:00
1

Consider the case of one circle centered at the origin and stationary, and the other moving toward it in, say, the -x direction. (You can transform any collision case into this with some simple vector algebra.)

So the position of the center of the second circle is (x,y), where y is constant and x is decreasing. The collision occurs when x2 + y2 = (r1 + r2)2, call that xcrit. But in the simulation we've gone past that, to some x < xcrit. So we have to rewind enough time to bring it back to xcrit, which we can calculate easily since we know x, xcrit and v.

|improve this answer|||||
0

EDIT: nevermind, my algorithm for finding the point of collision is incorrect. I'll think about this a bit more.

EDIT2: Ok, sorry about that. Try this:

  1. Find out when they collided. Let's call this T seconds ago. This would be T such that the distance between the two balls is equal to the sum of their radii. The equation is ((x1 - v_x1*T)-(x2 - v_x2*T))^2 = r1 + r2
  2. Move the balls back time T
  3. Continue with the your collision

I'm sorry, I don't know how to format math equations on SO. :S

After going back to the time of collision, you can calculate their new velocities fairly easily using elementary physics. See http://en.wikipedia.org/wiki/Elastic_collision#Two-_and_three-dimensional

|improve this answer|||||

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for?Browse other questions tagged or ask your own question.