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I am working with Чебышёв-polynomials at the moment, recursive defined polynomials. For the very likely case you never saw them before:

f[0,x_]  := 1;
f[1,x_]  := x;
f[n_,x_] := 2 * x * f[n-1, x] - f[n-2, x];
Plot[{f[9, x],f[3, x]},{x, -1, 1}]

And I found myself asking, since I usually work with python, if there is a way to build an array of functions in wolfram-cloud, to ease the process.

Thus I have to calculate every f[n] only once, allowing me to improve the run-time quite a bit and also allowing me to extend the range of n.

  • The typical way to solve this problem in Mathematica is memoization. reference.wolfram.com/language/tutorial/… – Szabolcs Jan 22 '17 at 13:52
  • Is there some reason you're not using the inbuilt function ChebyshevT ? My naive expectation is that using this will improve run-time quite a bit, with very little effort on your part. – High Performance Mark Jan 22 '17 at 13:53
  • @HighPerformanceMark It's fair to ask, so I wanted to a) learn something about the syntax and b) actually wanted to play around with the polynomial myself, so I get a better grasp of it. – Patrick Abraham Jan 22 '17 at 14:03
  • @Szabolcs Does this also hold for functions or does this only hold for specific values. Also is there a way to pre-run some part of it, so it won't time out. So can I break it down in multiple calculations? – Patrick Abraham Jan 22 '17 at 14:15
  • @Szabolcs I have to falsify myself. It actually doesn't. I tried to make a working sample and tried to calculate the run-time without any output or simplifying the polynomial. So I suppressed the output of the polynomial f[27,x] and tried to calculate it once and access it afterwards without outputing it. Both times I checked the time before minus the time after the calculation. And each time it took 3.1 seconds. Either implying that looking it up takes ages and that it was pre-calculated (in a fresh book) or that it actually calculated it both times. – Patrick Abraham Jan 22 '17 at 14:56
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Use memoization.

In this case memoization is trickier than usual because we work with functions, not function values.

Clear[cheb]
cheb[0] = 1 &;
cheb[1] = # &;
cheb[n_] := cheb[n] = Evaluate@Expand[2 # cheb[n - 1][#] - cheb[n - 2][#]] &

The Evaluate makes sure that the insides of the Function get evaluated even before supplying and argument.

  • Might I ask why you are using &; instead of ; – Patrick Abraham Jan 24 '17 at 20:28
  • And where is actually # defined. Just tried it, and it spit some # Formula as output. – Patrick Abraham Jan 24 '17 at 20:36
  • @PatrickAbraham Look up Function and see reference.wolfram.com/language/tutorial/PureFunctions.html You can enter # or & into the documentation search box and you will be taken to the relevant page. When learning Mathematica, always check the documentation first (before googling, etc.). It is better than that of most other systems. – Szabolcs Jan 24 '17 at 20:48
  • Still the code you wrote isn't working, at least in the cloud version. And I have somewhat a hard time figuring out how I can make it work. – Patrick Abraham Jan 24 '17 at 21:06
  • @PatrickAbraham It is working perfectly fine. If you have trouble with it, show what you did, what you got as a result and what you expected. Remember that cheb[10] is a function, not a number. – Szabolcs Jan 24 '17 at 21:11

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