Force Mathematica to interpolate on non-structured tensor grid

This list is a simple function that maps a 2D point to a number, if you regard each `{{x,y},z}` as `f[x,y]=z`

``````{
{{1,3},9}, {{1,4},16},
{{2,4},8}, {{2,5},10}
}
``````

I now want a function that interpolates/extrapolates `f[x,y]` for any `{x,y}`.

Mathematica refuses to do this:

``````Interpolation[{{{1,3},9}, {{1,4},16},{{2,4},8}, {{2,5},10}},
InterpolationOrder->1]
``````

Interpolation::indim: The coordinates do not lie on a structured tensor product grid.

I understand why (Mathematica wants a "rectangular" domain), but what's the easiest way to force Mathematica to create an interpolation?

This doesn't work:

``````f[1,3]=9; f[1,4]=16; f[2,4]=8; f[2,5]=10;
g=FunctionInterpolation[f[x,y],{x,1,2},{y,3,5}]
``````

FunctionInterpolation::nreal:
16 Near {x, y} = {1, --}, the function did not evaluate to a real number. 5 FunctionInterpolation::nreal:
17 Near {x, y} = {1, --}, the function did not evaluate to a real number. 5 FunctionInterpolation::nreal:
18 Near {x, y} = {1, --}, the function did not evaluate to a real number. 5 General::stop: Further output of FunctionInterpolation::nreal will be suppressed during this calculation.

Even if you ignore the warnings above, evaluating g gives errors

``````g[1.5,4] // FortranForm

f(1.5,4) + 0.*(-9.999999999999991*(f(1.4,4) - f(1.5,4)) +
-      0.10000000000000009*
-       (9.999999999999991*
-          (9.999999999999991*(f(1.4,4) - f(1.5,4)) +
-            4.999999999999996*(-f(1.4,4) + f(1.6,4))) +
-         0.5000000000000006*
-          (-10.000000000000014*
-             (-3.333333333333333*(f(1.3,4) - f(1.6,4)) -
-               4.999999999999996*(-f(1.4,4) + f(1.6,4))) -
-            9.999999999999991*
-             (9.999999999999991*(f(1.4,4) - f(1.5,4)) +
-               4.999999999999996*(-f(1.4,4) + f(1.6,4))))))
``````

The other "obvious" idea (interpolating interpolating functions themselves) doesn't work either.

-

If polynomial interpolation is acceptable, `InterpolatingPolynomial` does what you want (where `data` is your list of points above):

``````In[63]:= InterpolatingPolynomial[data, {x, y}]

Out[63]= -24 + x (12 - 5 y) + 12 y

In[64]:= f[2, 3]

Out[64]= 6
``````

You could also use `Fit` to do least-squares fitting on the linear combination of functions specified in the second argument:

``````In[65]:= Fit[Flatten /@ data, {1, x, y}, {x, y}]

Out[65]= 4.75 - 8. x + 4.5 y
``````

Of course, a fitted function may not exactly interpolate your data points. If such fitting is acceptable though, `FindFit` can fit to any (linear or non-linear) model function you specify:

``````In[72]:= FindFit[Flatten/@data, x y (a Sin[x] + b Cos[y]) + c, {a,b,c}, {x,y}]

Out[72]= {a -> -0.683697, b -> 0.414257, c -> 15.3805}
``````

HTH!

-

http://library.wolfram.com/infocenter/MathSource/7760/

-
Yasushi Iwasaki, welcome to the StackOverflow Mathematica community, and thank you for contributing. –  Mr.Wizard May 7 '11 at 6:35

Unfortunately, polynomials are too wiggly, but linear functions aren't wiggly enough. I believe the correct model is several line segments, but they'll all have different slopes.

Here's a hideous workaround that does what I want.

``````
(* data in format {{x,y},z} *)
data = {{{1,3},9}, {{1,4},16}, {{2,4},8}, {{2,5},10}}

(* find the ranges of x and y *)
datax = DeleteDuplicates[Transpose[Transpose[data][[1]]][[1]]]
datay = DeleteDuplicates[Transpose[Transpose[data][[1]]][[2]]]

(* extract the values of y and z for each x *)
datamap[t_]:=Map[{#[[1,2]], #[[2]]} &, Select[data, #[[1,1]] == t &]]

(* interpolate for each value of x, create a rectangular array, and then
interpolate in y *)
Map[(f[#]=Interpolation[datamap[#],InterpolationOrder->1])&, datax]

(* and now apply f to the expanded grid I've created *)

datatab = Flatten[Table[
{{datax[[i]], datay[[j]]}, f[datax[[i]]][datay[[j]]]},
{i,1,Length[datax]}, {j,1,Length[datay]}], 1]

(* now mathematica will let me interpolate *)
dataint = Interpolation[datatab, InterpolationOrder->1]

(* The resulting function agrees with my original*)

Flatten[Table[{{x,y},dataint[x,y]},{x,1,2},{y,3,5}],1]

Out[29]= {{{1, 3}, 9}, {{1, 4}, 16}, {{1, 5}, 23}, {{2, 3}, 6}, {{2, 4}, 8},
{{2, 5}, 10}}

(* above contains all my original points [plus a few extra] *)

(* and does a reasonable job of interpolating *)

dataint[1.5,3.5]

9.75

which is the average of the four corner values:

{dataint[1,3], dataint[1,4], dataint[2,3], dataint[2,4]}

{9, 16, 6, 8}
``````
-