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Not sure if what i'm trying to do makes sense. I am prototyping some code in mathematica, I one day hope to write in C++. An environment in which I only can compute in double precision (as I'm using the MS VC++ compiler).

I have a polynomial which approximates a function f and I want to plot the error curve. The coefficients of the polynomial have been computed to machine precision (as would be the case in C++). But when I plot the relative error I just obtain a plot of numerical noise. I would expect the error to be a smooth curve since the polynomial is a Taylor polynomial. How can I obtain a more sensible plot? The code below demonstrates what I am trying to do, with the Cos function as a test case. The result of the plot is just numerical noise.

f[x_] = Cos[x]
a[k_] := N[(-1)^k/(2*k)!]
approx[x_] := Sum[a[k]*x^(2*k), {k, 0, 12}]
Plot[approx[x]/f[x] - 1, {x, -Pi, Pi}, WorkingPrecision -> 30]

I could increase the precision in which the coefficients a[k] are calculated.

a[k_] := N[(-1)^k/(2*k)!,30]

to obtain a more sensible plot but this defeats the purpose of my prototype code. Because eventually I want to graph the error plots of the approximants which I create in C++. And in that environment the coefficients will only be computed in double precision.

I think this test makes sense?? I expect my approximation to be accurate to about machine precision, but how can I plot the error curve?

Thanks for reading.

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1 Answer 1

up vote 6 down vote accepted

First of all, plotting approx[x]/Cos[x] - 1 over a range that includes either Pi/2 or -Pi/2 is only going to cause problems as Cos[x] goes to zero at those points. At those points, approx is very nearly zero, but not exactly so. Also, Cos[x] is evaluated algebraically to be zero prior to being converted to a numerical zero when dividing, so you see spikes at those points.

Second, when plotting over a more sensible region,

Plot[approx[x]/f[x] - 1, {x, 0, 0.5}, WorkingPrecision -> 30, PlotRange -> All]

I get

enter image description here

which is exactly what I expect when operating near machine precision. Each spike is roughly equivalent to a single bit.

Lastly, if you want a good approximation across the entire domain of interest, I would not use a Taylor expansion which is good only in a neighborhood around the point of expansion. Instead, I would look at a min-max approximation using Chebyshev polynomials. For instance, taking the Chebyshev series and the Taylor series out to 14 terms gives

enter image description here

where I'm plotting the absolute difference between each series and Cos. As you can see from the plot on the left, the Chebyshev series performs much better overall than the Taylor series on the right.

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