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How does Mathematica create an InterpolatingFunction object? Example:

test1 = FunctionInterpolation[Sin[x],{x,0,2*Pi}]

The FullForm of test1 is long, but is primarily x values with the corresponding y values. However, the interpolation is not linear (since I didn't set InterpolationOrder -> 1)

I know Mathematica uses cubic splines, in part because the default InterpolationOrder is 3, but also because:

Plot[D[test1[t],t,t,t,t] /. t->x, {x,0,2*Pi}]

shows the 4th derivative is uniformly 0.

So, how does Mathematica compute this cubic spline?

My goal is to use a FunctionInterpolation object in Perl.

EDIT: Thank you, Sasha! That did exactly what I wanted, with a minor glitch. Below is my attempt to reimplement Hermite interpolation in a way that's easy to convert to Perl (also available at

The problem: the last 3 plots have small, but nonzero values. I can't tell if I implemented Hermite wrong, or this is just a numerical glitch.

(* the Hermite <h>(not Hermione)</h> polynomials *) 

h00[t_] = (1+2*t)*(1-t)^2 
h10[t_] = t*(1-t)^2 
h01[t_] = t^2*(3-2*t) 
h11[t_] = t^2*(t-1) 


This confirms my understanding of InterpolatingFunction by calculating 
the value in a different, Perl-friendly, way; this probably does NOT 
work for all InterpolatingFunction's, just the ones I'm using here. 

f = interpolating function, t = value to evaluate at 


altintfuncalc[f_, t_] := Module[ 
 {xvals, yvals, xint, tisin, tpos, m0, m1, p0, p1}, 

 (* figure out x values *) 
 xvals = Flatten[f[[3]]]; 

 (* and corresponding y values *) 
 yvals = Flatten[f[[4,3]]]; 

 (* and size of each x interval; there are many other ways to do this *) 
 (* <h>almost all of which are better than this?</h> *) 
 xint = (xvals[[-1]]-xvals[[1]])/(Length[xvals]-1); 

 (* for efficiency, all vars above this point should be cached *) 

 (* which interval is t in?; interval i = x[[i]],x[[i+1]] *) 
 tisin = Min[Max[Ceiling[(t-xvals[[1]])/xint],1],Length[xvals]-1]; 

 (* and the y values for this interval, using Hermite convention *) 
 p0 = yvals[[tisin]]; 
 p1 = yvals[[tisin+1]]; 

 (* what is t's position in this interval? *) 
 tpos = (t-xvals[[tisin]])/xint; 

 (* what are the slopes for the intervals immediately before/after this one? *) 
 (* we are assuming interval length of 1, so we do NOT divide by int *) 
 m0 = p0-yvals[[tisin-1]]; 
 m1 = yvals[[tisin+2]]-p1; 

 (* return the Hermite approximation *) 
 (* <h>Whoever wrote the wp article was thinking of w00t</h> *) 
 h00[tpos]*p0 + h10[tpos]*m0 + h01[tpos]*p1 + h11[tpos]*m1 

(* test cases *) 

f1 = FunctionInterpolation[Sin[x],{x,0,2*Pi}] 
f2 = FunctionInterpolation[x^2,{x,0,10}] 
f3 = FunctionInterpolation[Exp[x],{x,0,10}] 

Plot[{altintfuncalc[f1,t] - f1[t]},{t,0,2*Pi}] 
Plot[{altintfuncalc[f2,t] - f2[t]},{t,0,10}] 
Plot[{altintfuncalc[f3,t] - f3[t]},{t,0,10}] 
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It's probably using Hermite interpolation as default (and not Splines) , at least that is what Interpolation[ ] does – belisarius has settled Apr 16 '11 at 14:02

1 Answer 1

up vote 3 down vote accepted

Generally it uses piecewise Hermite cubic interpolation. I am not sure about the choice of nodes, though. It seems they are chosen uniformly across the interval. I am sure there are results for the lower bounds of intervals for a requested precision assuming smooth function, but I do not have details.

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