4D integral with exponential value

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Mümin ÖZPOLAT
Mümin ÖZPOLAT il 20 Mar 2017
Commentato: Torsten il 23 Mar 2017
Hi,
I am trying to calculate this integral using indefinite integral functions.
1 1 / 1 1
/ / | / /
| | | | | 1
| | exp| | | ----------------------------------------------------------------------- dx dy
/ / | / / / 1 \ / 2 / 1 \2 \2
0 0 | 0 0 | ------------------------------ + 160 | | (w - z) + | y - x + - | |
| | / 2 / 1 \2 \2 | \ \ 2 / /
| | | (w - z) + | y - x + - | | |
\ \ \ \ 2 / / /
\
|
|
| dz dw
|
|
|
|
/
It is 4D integral. When I try to use indefinite integral function int Matlab cant calculate it.
int(int(exp(int(int(1/((1/((w - z)^2 + (y - x + 1/2)^2)^2 + 160)*((w - z)^2 + (y - x + 1/2)^2)^2), x, 0, 1), y, 0, 1)), z, 0, 1), w, 0, 1)
When I try to use integral2 function to calculate numerically, the z and w parameters are obstacles.
I cannot use 4D user defined integral function because there exp{} block between integrals.
Do you know how to solve that integral?

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Risposte (2)

Torsten
Torsten il 21 Mar 2017
Modificato: Torsten il 21 Mar 2017
Brute-force method:
delta=0.01;
w=0:delta:1;
z=0:delta:1;
x=0:delta:1;
y=0:delta:1;
func=@(x,y,w,z)1/(1+160*(((w-z)^2+(y-x+0.5)^2)^2));
for i=1:numel(w)
wloc = w(i);
for j=1:numel(z)
zloc = z(j);
f = 0;
for k=1:numel(x)-1
xloc_l = x(k);
xloc_r = x(k+1);
for l=1:numel(y)-1
yloc_l = y(l);
yloc_r = y(l+1);
f = f + 0.25*(func(xloc_l,yloc_l,wloc,zloc)+func(xloc_l,yloc_r,wloc,zloc)+func(xloc_r,yloc_l,wloc,zloc)+func(xloc_r,yloc_r,wloc,zloc))*delta^2;
end
end
fxy(i,j) = exp(f);
end
end
integral = 0.0;
for i=1:numel(w)-1
for j=1:numel(z)-1
integral = integral + 0.25*(fxy(i,j)+fxy(i,j+1)+fxy(i+1,j)+fxy(i+1,j+1))*delta^2;
end
end
"integral" should be the value of the integral you are looking for.
You may want to choose a smaller value for "delta" to get a better approximation.
With delta=1/300 I get a value of 1,166618 for your integral.
Best wishes
Torsten.
Mümin ÖZPOLAT
Mümin ÖZPOLAT il 22 Mar 2017
Modificato: Mümin ÖZPOLAT il 22 Mar 2017
Thanks !
Seems like it is an implementation of Riemann Sum.
You use delta^2 because the integration is 2 layered and multiplicate it by 0.25 because you get average of 4 different result.
  1 Commento
Torsten
Torsten il 23 Mar 2017
It's the two-dimensional trapezoidal rule, applied twice: once to the double inner integral, then to the double outer intergral.
Best wishes
Torsten.

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