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I am trying to evaluate a function that I have defined piecewise. I need to integrate it with respect to one variable and then take the derivative with respect to another (variables are independent). However, something in the way I am defining the functions is causing mathematica to throw errors or infinitely evaluate. I believe that the derivative function does not like the format of the output of the integrate function, and vice versa when I tired reversing the order of the steps. The integrand is not analytical by hand, so I need to pipe the output of one into the other. Can anyone tell me what is going wrong?

\[Theta] = 30 Degree; 
d = 50.8*10^-3 ;
reo = (150/2)*10^-3; 
rei = ((reo/Tan[\[Theta]]) - 
    d) Tan[\[Theta]] 

B = 24.4*10^-3; 
\[CapitalGamma] = 10*10^-3; 
l = .2*10^-3; 
\[CurlyPhi] = 20 Degree;

Pe = 101325; 
Ps = 1.1* Pe ;

\[Gamma] = (\[CurlyPhi]*Sin[\[Theta]])/(B*\[CapitalGamma]^3);
Pd[h_] := 
 Sqrt[((Ps^2 + Pe^2*\[Gamma]*h^3*(l + h) + 
      Log[rei/reo])/(1 + \[Gamma]*h^3*(l + h) + Log[rei/reo]))]

rd = Sqrt[reo*rei]
P [r_, h_] := 
  Piecewise[{{Sqrt[
      Pd[h]^2 + .5*(Pe^2 - Pd[h]^2)*Log[rei/reo]*Log[rd/r]], 
     r > rd}, {Sqrt[
      Pd[h]^2 + .5*(Pe^2 - Pd[h]^2)*Log[rei/reo]*Log[r/rd]], r < rd}}];
W[h_] := Integrate[2*Pi*r*P[r, h]/9.8, {r, rei, reo}]
S[h_] := D[W[h], h]

Plot[{P[r, 10*10^-6], P[r, 8*10^-6], P[r, 6*10^-6], P[r, 4*10^-6], 
  P[r, 2*10^-6], P[r, 1*10^-6]}, {r, rei, reo}]
Plot[W[h], {h, 1*10^-6, 10*10^-6}]
Plot[S[h], {h, 1*10^-6, 10*10^-6}]
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1 Answer

up vote 1 down vote accepted

You're trying to do a very complicated calculation a very large number of times in that integral and then a very very large number of times to make that plot. On my system, it takes 10s just to get one point. So you need to make it a lot faster. I recommend compiling P like so:

P = Compile[{{r, _Real}, {h, _Real}}, 
  Module[{Pdh = Sqrt[(
     Ps^2 + Pe^2 \[Gamma] h^3 (l + h) + Log[rei/reo])/(
     1 + \[Gamma] h^3 (l + h) + 
      Log[rei/reo])]}, \[Sqrt](Pdh^2 + .5 (Pe^2 - Pdh^2) Log[rei/
        reo] Log[Min[rd, r]/Max[rd, r]])]]

That will make things a lot faster, but now we need to make sure we're always using numerical expressions, not symbolic ones. That means the integral needs to become

W[h_] := NIntegrate[(2 \[Pi] r P[r, h])/9.8, {r, rei, reo}]

and the derivative needs to become

Needs["NumericalCalculus`"]
S[h_] := ND[W[hh], hh, h]

This makes things about 100 times faster, and the plots come out. You may still see some warning messages, but they can be ignored. Throw a Quiet around the definitions of W and S if it bothers you.

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Not really relevant. The issue is that trying to take a derivative of P either before or after the integral seems to be causing issues since the h dependance is inside of Pd, rather than directly in P. –  Elliot Feb 12 '13 at 19:18
    
Trivial counterexample: Pd[h_]:=Sin[h^2];P[r_,h_]:=r^2+8 Pd[h];W[h_]:=Integrate[\[Pi] P[r,h],{r,0,1}];S[h_]:=(D[W[hh],hh]/.hh->h);Plot[S[h],{h,0,2 \[Pi]}]. Did you try the given solution? It works for me; if it does not work for you, can you say why it failed? –  Xerxes Feb 12 '13 at 20:01
    
S[h_]:=(D[W[hh],hh]/.hh->h) As soon as I did this instead of S[h_]:=D[W[h],h], it started working. I am not sure what this means, though, or why the first version is wrong. –  Elliot Feb 12 '13 at 20:30
    
Ah, I kind of glossed over that. When you use S inside of a Plot, the h is the dependent variable of the plot; that is, it's a real number. You can't take a derivative with respect to a real number. So instead, you use a dummy variable hh and substitute h in after the derivative. –  Xerxes Feb 12 '13 at 20:34
    
I take that back I am still getting errors it is just producing a graph now instead of nothing. NIntegrate::inumr: The integrand 0.641141 r ([Piecewise] Sqrt[Power[<<2>>] Plus[<<2>>]-0.420686 Plus[<<2>>] Log[<<1>>]] r>0.0491988 Sqrt[Power[<<2>>] Plus[<<2>>]-0.420686 Plus[<<2>>] Log[<<1>>]] r<0.0491988 0 True ) has evaluated to non-numerical values for all sampling points in the region with boundaries {{0.0323037,0.07493}}. >> –  Elliot Feb 12 '13 at 20:41
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