# What machine learning algorithm is appropriate for shooting basketballs?

We are making a robot that shoots basketballs into hoops.

From an image and our knowledge of the camera's angle and the target's dimensions (the targets are coated with retroreflective tape), we know how far away we are, X and Y (distance being Z, more or less)

This is fed into the machine learning algorithm, which should spit out

1. Speed to be sent to the canon
2. Horizontal tilt
3. Vertical tilt

What kind of machine learning algorithm is this, and how would you train it?

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If you know your current position, target position, why do you need machine learning at all? You can just calculate speed and tilt –  Archeg Feb 13 '12 at 15:18
@Archeg: We only know our current position relative to the target. The point of the machine learning algorithm is to figure out how input relates to output (e.g, what the drag for the ball is, etc) –  Glycan Feb 13 '12 at 15:22
Machine learning is usefull when you do not know what enviroment variables will influence your result. Or if it is difficult to hardcode them. In your case I still can't see them. Do you need to check strength of wind, is it possible to have some obstacles around or maybe you should use different balls with different mass and surface? Machine learning is a great tool, but it's slow and never smart enough. So it's good to think, why do you need it at all. –  Archeg Feb 13 '12 at 15:36
I need to learn, then apply my learning to shoot accuratly. What I need to learn is roughly how much tilt hear affects landing position there, how force affects distance, etc. (However, the team suggests using bowling balls to destory competeing robots, so we may need to learn how to shoot those, too. :)) –  Glycan Feb 13 '12 at 15:44

Machine Learning is probably not appropriate for this task. At least, not by itself. Use physics. You should be able to get a rough formula for this out of a first-semester physics textbook, though you'll need to decide whether you're aiming for the middle of the hoop or the board behind it.

Your physics formulae should tell you the angle and force to use, but your model of the system will have some inaccuracies. Different balls may have different mass, and you might not want to explicitly account for air resistance, and so on. A search through the space of offsets based on how close the previous shot was could work. The choice of search methods is up to you - simulated annealing could work well, as Mencel said.

One possible use for machine learning here might be to remember and extrapolate these offsets. A function approximator (such as a neural network) could be used to learn the offsets from experience. Once your search method succeeds at putting the ball in the hoop, use this as a training example for an approximator that learns to map from what the physics model says to use to the offsets that made the shot work. Then, for the next shot (from whatever position), the function approximator would be used to guess the offsets to use. If that shot misses, repeat the search until correct offsets are found. Update the function approximator, rinse, and repeat. Also, it would probably be beneficial if your function approximator were initialized in such a way that it initially always says to apply no offsets - after all, the best first guess should be to just use what the physics model tells you to use.

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The most physics is going to give us is a very rough approximate - unless you know the the drag of a small foam basketball with burn marks on it? How exactly would a neural network work? –  Glycan Feb 13 '12 at 16:15

I would recommend a reinforcement learning approach. It'll be slow ; so maybe you could initialize the solution with your own estimate (basic physics) and refine it with reinforcement learning.

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What exactly do you suggest? Can you be more specific? (I'm sorry, I have a very basic grasp of machine learning) –  Glycan Feb 13 '12 at 15:29
Try looking up SARSA –  Chris Taylor Feb 14 '12 at 9:32

Perhaps you want to use something like Simulated Annealing. Each time you complete a trial of throws, you change the speed/tilt a bit according to a random factor. That random factor would depend on how well you performed during the last trial.

Edit:

Well I haven't really thought hard about it, but by trials I mean you could throw the ball 100 times with fixed speed and tilt, and count how many times you succeed. You can consider that whole trial of 100 throws to be one iteration, and the percentage of successes is your win rate, analagous to 'energy level' in the Simulated Annealing process.

After one trial, you would then vary the speed or tilt randomly. It could be something simple like 'add 2 to the speed', or 'increase vertical tilt a little bit'. This is a transition from your previous state to the new state. You now measure the energy of your new state (i.e. do another 100 throws with the new inputs). If this new state is worse, then scrap it, go back to the previous state and vary the inputs differently e.g. 'decrease speed by 2'.

Of course you would also need an initial guess, which is where you ought to use your physics to best calculate estimates for the first trial.

I believe that's how the simulated annealing process works, but you ought to read up on it to understand better how to apply it to your situation. I read a nice introduction to it in Steven Skiena's "The Algorithm Design Manual", which describes other machine learning techniques too.

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Could you please explain a bit more throughtly? What do you mean by 'a trail of throws'? Depend how, exactly? –  Glycan Feb 13 '12 at 15:32
We can work out tilt and speed for one given input ourselves, and we don't need 100 tries for each iteration. The problem is "what tilt and speed will sucessed /given this distance, x, and y/" –  Glycan Feb 13 '12 at 16:12
I picked 100 arbitrarily. Whatever number suits you best, but 1 would be too few for this method. I don't understand what you mean by "We can work out tilt and speed for one given input ourselves". If you can, then surely you are already done and don't need any algorithm at all? If you are trying to find the best speed and tilt for a given distance, then you would have to keep the distance fixed and vary the speed and tilt to find the best solution for that distance. You can do this for each distance, and build up a table of good speeds/tilts. –  HexTree Feb 13 '12 at 16:19
We can pick up the right tilt and speed for a given distance/location after a couple of tries. The goal is to be able to say with reasonable accuracy, on the fly, what configuration works in these conditions –  Glycan Feb 13 '12 at 20:02
Well if it only takes a couple of tries, then I don't think machine learning is relevant at all, you can quite easily work out the correct speeds and tilts by trial and error. –  HexTree Feb 13 '12 at 20:12