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I have two arrays, say A={1, 2, 3} and B={2, 4, 8} (array item count and numbers may vary). How do I find a bijection between the arrays.

In this case, it would be f:A->B; f(x)=2^(x)

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3  
Homework by any chance?? –  Simon Cowen Jun 6 '11 at 14:04
    
There's clearly no general method to do this, unless there are extra constraints. Are there? –  acl Jun 6 '11 at 16:28
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3 Answers

up vote 4 down vote accepted

As others have remarked, this problem is ill-defined.

Other possible functions that give the same results are (among probably infinite others): (8 x)/3 - x^2 + x^3/3, x + (37 x^2)/18 - (4 x^3)/3 + (5 x^4)/18, and (259 x^3)/54 - (31 x^4)/9 + (35 x^5)/54.

I found these solutions using:

n = 5; (* try various other values *)
A = {1, 2, 3} ; B = {2, 4, 8}
eqs = Table[
  Sum[a[i] x[[1]]^i, {i, n}] == x[[2]], {x, {A, B}\[Transpose]}]
sol = Solve[eqs, Table[a[i], {i, n}], Reals]
Sum[a[i] x^i, {i, n}] /. sol

Sometimes not all of the a[i]'s are fully determined and you may come up with values of your own.

[tip: better not use variables starting with a capital letter in Mathematica so as not to get into conflict with reserved words]

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Probably (I guess) the title should be Find ONE bijection ... in which case any interpolation could do –  belisarius Jun 6 '11 at 22:39
    
@belisarius Yeah, strange question... –  Sjoerd C. de Vries Jun 6 '11 at 22:44
    
I need an algorythm, and not one specific solution, sori if my question was not clear. –  Martynas Jun 8 '11 at 20:19
    
@martynas the code above in the blue code block can be considered as an algorithm to find some rules that connect the two series. Varying n provides various solutions. –  Sjoerd C. de Vries Jun 9 '11 at 12:41
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I don't think this problem has a general solution. You may try FindSequenceFunction, but it will not always find the solution. For the case at hand, you'd need a bit longer lists:

In[250]:= FindSequenceFunction[Transpose[{{1, 2, 3}, {2, 4, 8}}], n]

Out[250]= FindSequenceFunction[{{1, 2}, {2, 4}, {3, 8}}, n]

but

In[251]:= FindSequenceFunction[Transpose[{{1, 2, 3, 4}, {2, 4, 8, 16}}], n]

Out[251]= 2^n

You can also play with FindFit, if you have some guesses about the bijection:

In[252]:= FindFit[Transpose[{{1, 2, 3}, {2, 4, 8}}], p*q^x, {p, q}, x]

Out[252]= {p -> 1., q -> 2.}
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Is there algorithm available online of this function? I need to make and application. –  Martynas Jun 6 '11 at 14:44
2  
And NEVER forget to check oeis.org :) –  belisarius Jun 6 '11 at 15:13
    
Also check Eureqa creativemachines.cornell.edu/eureqa –  belisarius Jun 6 '11 at 15:16
    
@Martynas Unfortunately, I don't know what algorithm is used in FindSequenceFunction. Hopefully, more knowledgable people here will remark on that. –  Leonid Shifrin Jun 6 '11 at 15:59
    
yeah, those are good, but there is fact, that I need to write my own application :) its the assignment ;] –  Martynas Jun 6 '11 at 17:16
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Since you tag Mathematica, I'll use Mathematica functions as a reference.

If you are interested in an arbitrary fit of your data with a smooth function, you can use Interpolation. E.g.

a = {1, 2, 3}; b = {2, 4, 8};
f = Interpolation[Transpose[{a, b}]];

(* Graph the interpolation function *)
Show[Plot[f[x], {x, 1, 3}], Graphics[Point /@ Transpose[{a, b}]], 
   PlotRange -> {{0, 4}, {0, 9}}, Frame -> Automatic, Axes -> None]

Plot of f

Interpolation uses piecewise polynomials. You can do the same in your favorite programming language if you happen know or are willing to learn a bit about numerical methods, especially B-Splines.

If instead you know something about your data, e.g. that it is of the form c d^x, then you can do a minimization to find the unknowns (c and d in this case). If your data is in fact generated from the form c d^x, then the fit will be fairly, otherwise it's the error is minimized in the least-squares sense. So for your data:

FindFit[Transpose[{a, b}], c d^x, {c, d}, {x}]

reports:

{c -> 1., d -> 2.}

Indicating that your function is 2^x, just as you knew all along.

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1  
+1. It probably doesn't matter too much in your example, but it was pointed out to me here by Mark McClure that since version 6 you can use Point@Transpose[{a, b}] (rather than Point /@ Transpose[{a, b}]), and this syntax is much more efficient. You may already be aware of this. (I wasn't, until Mark pointed it out) –  TomD Jun 7 '11 at 11:56
    
@TomD Thanks! I didn't know that! –  Codie CodeMonkey Jun 7 '11 at 16:47
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