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I am having some slight difficulty with the following code:

Lagrange[list_] := 
  Module[{points = list, length, k, j, m, x, g}, 
    length = Length[points]; 
    k = length - 1; 
    f = Sum[points[[j + 1,2]]*Product[If[j != m, (x - points[[m + 1,1]])/
          (points[[j + 1,1]] - points[[m + 1,1]]), 1], {m, 0, k}], {j, 0, k}]; 
    g = FullSimplify[Expand[f]]; 
    Return[f]]

The output I get is:

Out[101]= 0. -1.85698 (-1.5+x$26810) (-0.75+x$26810) (0. +x$26810) (0.75+x$26810)
         +0.490717 (-1.5+x$26810) (-0.75+x$26810) (0. +x$26810) (1.5 +x$26810)
         -0.490717 (-1.5+x$26810) (0. +x$26810) (0.75 +x$26810) (1.5 +x$26810)
         +1.85698 (-0.75+x$26810) (0. +x$26810) (0.75 +x$26810) (1.5 +x$26810)

My concern is with these "$" symbols. I don't know what they mean, I can't find documentation on them, and they are preventing the plotting of this polynomial.

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2 Answers 2

up vote 6 down vote accepted

The $ in your output is from the unique variable generated by the lexical scoping of Module (see the More Information part of mathematica/ref/Module). This is why I made my LagrangePoly function accept the symbol that the polynomial is meant to be in. I used LagrangePoly[list_, var_:x], which defaults to the global symbol x.

A simple example of the problem is

In[1]:= Module[{x}, x]    
Out[1]= x$583

The number in the "local" variable x$nnn comes from the global $ModuleNumber.

If you don't understand this, then you should probably read the tutorial Blocks Compared with Modules.

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if I want to put this function in a package to be used in another notebook, do you see a need for the use of module in my case? –  Matthew Kemnetz Dec 7 '11 at 6:05
2  
@Matthew: If this code is going to be moved into a package, you probably want the flexibility to choose the symbol used in the polynomial. So a symbol x should be passed to the function like I suggested. You also don't need j or m in the Module, since they're already scoped by the sum and product. Finally, why did you calculate g, but return f in your code? –  Simon Dec 7 '11 at 6:09
    
I removed g from the calculation. "g" was unnecessary and was from an old version. Thank you for catching it for me. –  Matthew Kemnetz Dec 7 '11 at 6:11
    
I thought I should let you know...it works perfectly now; just as I hoped. Thanks for all your help! On to Hermite Interpolating Polynomials! –  Matthew Kemnetz Dec 7 '11 at 6:15
1  
Simon, better than x would be \[FormalX] to avoid most collisions. –  Mr.Wizard Dec 7 '11 at 7:03

In your code, x is a local variable. However you are returning an expression containing x. The purpose of localized variables is that they shouldn't appear outside their context, which is the Module in this case.

Consider this simple example:

adder[x_] := Module[{y}, Return[x + y]]

adder[2] gives: 2 + y$1048

A good practice is to recognize that our function adder should actually itself return a function.

adder[x_] := Function[{y}, x + y]

twoAdder = adder[2];

twoAdder[3] gives: 5

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