# Calculating area of fitted function to compare with results - Mathematica

H!
I've spent a lot of time reading Mathematica's Document Center and stackoverflow (among other sites), but I haven't found any answer to my question: How in Mathematica I can compare areas (quantitatively) of function (to be precise - results) and its fit. I'd like to get some numerical estimation of my fit. The function of course is in 3D.
Cheers,
John

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i'm not sure what you mean by 'area of a function'. do you have an example? –  Thies Heidecke Jan 11 '12 at 16:29
I mean an area under the function - it's a practical question, meaning I need that answer to proceed with my analysis. Though I don't know how could I present that example here... –  John Smith Jan 11 '12 at 16:46
have you looked at Integrate or NIntegrate? –  Thies Heidecke Jan 11 '12 at 17:04
Yes - that would be a normal approach. The problem nevertheless lays within my results, they're in discrete form and I don't know how to calculate an area under my points (results). –  John Smith Jan 11 '12 at 17:39
You can use Interpolation to make a continuous function from discrete data points and NIntegrate that. –  Thies Heidecke Jan 11 '12 at 18:19

If the actual goal is to estimate how good your fit is, then you do not need to calculate any "areas" - Mathematica has built in analysis offered by LinearModelFit[...] and NonlinearModelFit[...]. Let's make up some dataset scattered around a Gaussian surface:

data = MapThread[{#1[[1]], #1[[2]],
1.2 Exp[-34 ((#1 - .56).(#1 - .56))] + #2} &, {RandomReal[
1, {100, 2}], RandomReal[{-.1, .1}, 100]}];


Introduce a Gaussian surface model to fit these data:

model = a Exp[-b ((x - x0)^2 + (y - y0)^2)];


Now, do the nonlinear regression:

    nlm = NonlinearModelFit[data,
model, {a, b, {x0, .5}, {y0, .6}}, {x, y}];


Obtain and plot the best fit:

    Show[Plot3D[nlm["BestFit"], {x, 0, 1}, {y, 0, 1}, PlotRange -> All,
PlotStyle -> Opacity[.5], MeshStyle -> Opacity[.5], Mesh -> 25],
ListPointPlot3D[data,
PlotStyle -> Directive[PointSize[Medium], Red]]]


The function nlm[…] contains a lot of information:

nlm["Properties"]


Here are few properties relevant to your request:

nlm["ParameterTable"]


nlm["ANOVATable"]


Thanks, Vitaliy

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