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Lets say that I have a math function that is defined recursively. Like so:

T(1)(x) = 1
T(n)(x) = 2x*T(n-1)(x)-1


T(1)(x) = 1
T(2)(x) = 2x*1-1 = 2x-1
T(3)(x) = 2x*(2x-1)-1 = 4x^2 - 2x - 1
/* and so on... */

Basically, I know how to write a program that will count T(15)(x) if the x is given. Thats not a problem. What I wonder, however is - how to write a program that will give me a polynomial for like T(10)(x) (one looking something like: 16x^4 + 3x^3 ...).

In the nutshell: How can I recursively count the math expression, but using x as a variable (not set).

Any help would be greatly appreciated,


share|improve this question
When you say "count" do you mean "produce" or "create"? As it stands, I'm not entirely sure what you're asking. – rcollyer Nov 15 '10 at 20:00
do you want the program in Mathematica programming language? – Yaroslav Bulatov Nov 15 '10 at 20:01
@Yaroslav Just use RSolve ... I think the tag is wrong – Dr. belisarius Nov 15 '10 at 20:03
wow, You guys are right, I made a mistake with the tag, didn't know something like Mathematica existed. I would like to eventually write this program in something like C/Java/PHP/C#, not in a Derive, Matlab, Maxima, Mathematica kind of thing. – PawelMysior Nov 15 '10 at 20:33
@PawelMysior, that changes things a bit. Most optimizing compilers can "unroll" a tail-recursive (en.wikipedia.org/wiki/Tail_recursion) process, so it may not be necessary to do anything more than adapt what you have already to whatever language you wish to use. That said, do you want a specific polynomial to use in your code? – rcollyer Nov 15 '10 at 20:47
up vote 0 down vote accepted

Based upon the comments, I believe that there are four options, in order of complexity.

First, you could just implement an explicit formula for the given polynomial that you are looking for, if it exist. In the case of the Chebyshev polynomials, an explicit formula (3rd sum from the top) fitting your needs does exist.

If, however, you are looking for something more general, i.e. more than one type of polynomial, you could create an explicit list of the polynomials up to some absurd order and do a string replace using the user supplied variable name. In most systems, this won't take up a lot of memory.

Thirdly, if you wish to remain general and still recursively produce the polynomials, you could tap into a computer algebra system, like Mathematica. For instance, you can access Mathematica through MathLink, or use an instance of webMathematica, or even scrape the output from WolframAlpha. Although, I think you'd run into copyright issues with the last one.

Lastly, the most complex and most general would be to create an abstract syntax tree. If you can use c++, I'd look at boost.proto which essentially does this for you. But, if you create it yourself, you'd have three types of binary ops, add, multiply, and power and two types of leaf nodes, coefficient and variable. Now, to massage the tree into a form where you can use it you have to move through the tree and apply transformation rules: replace a subtree and interchange parent and child. Replace would alter the tree by applying standard math rules, such as 2 + 2 becomes 4 and x * x becomes x2. But, the real work would be in interchanging the parent and child nodes, as this would be used to apply the distributive law (mult -> add becoming add -> mult) and providing opportunities to use replace.

The first two options are by far the easiest, and I'd go with the first if it is available. That said, I'd find implementing either the MathLink interface or the syntax tree much more interesting to do.

Edit: to clarify what I mean by interchanging a parent with its child, consider the case of n = 2.

Graphic showing a basic transformation of a expression tree.

which effects 4 nodes: "Plus", both "Times", and the coefficient 1. But, it is easy to see that this will reduce the overall number of nodes by eliminating the second "Times."

share|improve this answer
Note: I deleted my first answer as it had nothing to do with what the OP wanted answered. – rcollyer Nov 16 '10 at 16:07

Here's one way:

t[1, x_Symbol] = 1;
t[n_Integer, x_Symbol] := 2 x (t[n - 1, x]) - 1;

Note that this will return t[4,x] (etc) 'unexpanded', that is like this:

-1 + 2 x (-1 + 2 x (-1 + 2 x))

You can either Expand[] the result or modify the function to Expand before returning.

Does that answer your question ?

share|improve this answer

I think your Mathematica tag may be wrong, but anyway. Mathematica has an embedded function RSolve to cope with this:

   RSolve[{a[n] == 2  x a[n - 1] - 1, a[1] == 1}, a[n], n]  

The result is:

   a[n] = (x + 2^n (-1 + x) x^n)/(x (-1 + 2 x))    

As expected

   a[3] = -1 - 2 x + 4 x^2


share|improve this answer
I'm not sure he's asking for it to be solved, although, I'm not really sure what he's asking for. But, I think it is just to generate the nth polynomial. – rcollyer Nov 15 '10 at 20:23
rcollyer - generating the nth polynomial - exactly what I want to achieve. – PawelMysior Nov 15 '10 at 20:38
@PawelMysior the a[n] in the answer is the polynomial – Dr. belisarius Nov 15 '10 at 20:51

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