5

Consider a situation where you have data in a list of the form

data = {{x1, x2, x3, ..., xn, y}, {...}, ..., {...}}

For example,

data = {{0, 2, 3, 2}, {0, 0, 1, 4}, {7, 6, 8, 3}}

I'd like to fit the data to a multivariate polynomial of order, say, 2. So, the 3-variable function values are:

{2, 4, 3}

in respective points

{{0, 2, 3}, {0, 0, 1}, {7, 6, 8}}

I'd say something like

Fit[data, {1, x, y, z, x^2, y^2, z^2, x y , x z, y z}, {x, y, z}]

This is all very nice, but i may not have only 3-variate data, there may be an arbitrary number of variables, and I don't know how to programmatically generate all the linear, quadratic or even higher-order terms, to insert them as the second argument of Fit[].

For 4-variate date do second order, it would be something like:

{1, x1, x2, x3, x4, x1^2, x2^2, x3^2, x4^2, x1 x2, x1 x3, x1 x4, x2 x3, x2 x4, x3 x4}

Is there any way I can generate such a list for n variables, to m-th order? Like terms (without coefficients) in a m-order power series expansion of an n-variable function.

1
  • Should those be x y instead of xy?
    – kennytm
    Dec 20, 2011 at 9:37

4 Answers 4

8

Does this do what you want?

Union[Times @@@ Tuples[{1, x, y, z}, 2]]
1
  • This does exactly what I want. :) Thank you!
    – vedran
    Dec 20, 2011 at 9:41
6

While the solution of @ruebenko is perfectly correct, I'd like to mention that it will be quite slow for higher powers / larger number of variables, because of the complexity of Tuples and lots of duplicates for higher powers. Here is an algebraic method with a much better performance for those cases (both run-time and memory-wise):

List @@ Expand[(1 + x + y + z + t)^2] /. a_Integer*b_ :> b

Here is a comparison for large number of variables:

In[257]:= (res1=Union[Times@@@Tuples[{1,x,y,z,t},9]])//Short//Timing
Out[257]= {19.345,{1,t,t^2,t^3,t^4,t^5,t^6,t^7,t^8,t^9,x,<<694>>,x^2 z^7,y z^7,
      t y z^7,x y z^7,y^2 z^7,z^8,t z^8,x z^8,y z^8,z^9}}

In[259]:= (res2=List@@Expand[(1+x+y+z+t)^9]/. a_Integer*b_:>b)//Short//Timing
Out[259]= {0.016,{1,t,t^2,t^3,t^4,t^5,t^6,t^7,t^8,t^9,x,<<694>>,x^2 z^7,y z^7,
      t y z^7,x y z^7,y^2 z^7,z^8,t z^8,x z^8,y z^8,z^9}}

In[260]:= res1===res2
Out[260]= True

In this case, we observe a 1000x speedup, but generally the two methods just have different computational complexities. The above code is an application of a general and nice method, called Algebraic Programming. For an interesting discussion of it in the context of Mathematica, see this Mathematica Journal paper by Andrzej Kozlowski.

4
  • 1
    +1, good stuff! But you know, if you FindFit with 700 vars, the 20 sec. for the vars are most likely the least of your concern ;-)
    – user1054186
    Dec 20, 2011 at 15:10
  • @ruebenko Sure, this is not to detract from your solution (which I upvoted) ! Conceptually, your method is more natural. This is just for the background information - and who knows, some people may need to solve the same problem for something else. Dec 20, 2011 at 15:13
  • 1
    I was going to include a more efficient method in my answer, but I didn't because it would vex WReach to optimize the fastest part of a operation. However, I am glad you posted this, because mine used implicit loops, and I like this better.
    – Mr.Wizard
    Dec 20, 2011 at 17:20
  • @Mr.Wizard Well, I agree, we certainly should not annoy WReach. Thanks for the upvote. Dec 20, 2011 at 17:40
3

Using @ruebenko's neat solution,

varsList[y_, n_?IntegerQ, k_?IntegerQ] := 
Union[Times @@@ 
 Tuples[Prepend[Table[Subscript[y, i], {i, 1, n}], 1], k]]

you can generate desired list via varsList[x, 4, 2].

2

Here is another method that I believe is worth knowing:

set = {1, x, y, z};

Union @@ Outer[Times, set, set]

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