Example 7.  Use the composite Simpson's rule for multiple integrals to numerically approximate the iterated integral  [Graphics:Images/SimpsonsRule2DMod_gr_193.gif].

Solution 7.

We use  n = 20 and  m = 5 in our computations.
The integrand is:










The curves bounding the region are:



The region of integration in the xy-plane can be seen in the
following graphical plot.



[Graphics:../Images/SimpsonsRule2DMod_gr_196.gif]





[Graphics:../Images/SimpsonsRule2DMod_gr_197.gif]



[Graphics:../Images/SimpsonsRule2DMod_gr_198.gif]
[Graphics:../Images/SimpsonsRule2DMod_gr_199.gif]





Before we carry out the quadrature, we must fix "m" the number of
vertical subdivisions to be used along each of the vertical segments
[Graphics:../Images/SimpsonsRule2DMod_gr_200.gif]
between the curves y = c[x] and y =
d[x].  



The variable "m" is global and is used in the numerical quadrature
subroutine to define the function  [Graphics:../Images/SimpsonsRule2DMod_gr_201.gif].  



Now, fix  m  and perform numerical multiple
integration.



[Graphics:../Images/SimpsonsRule2DMod_gr_202.gif]


[Graphics:../Images/SimpsonsRule2DMod_gr_203.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_204.gif]


[Graphics:../Images/SimpsonsRule2DMod_gr_205.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_206.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_207.gif]





How good was numerical quadrature ?  

Usually the special functions involved in the analytic solution
of  [Graphics:../Images/SimpsonsRule2DMod_gr_208.gif]  are
not usually covered in the standard calculus
sequence.  

For your information,. the solution using Mathematica is found
as follows:



Integrate  [Graphics:../Images/SimpsonsRule2DMod_gr_209.gif]  with
respect to the variable y.  



 



[Graphics:../Images/SimpsonsRule2DMod_gr_210.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_211.gif]





Compute the definite integral  [Graphics:../Images/SimpsonsRule2DMod_gr_212.gif].



[Graphics:../Images/SimpsonsRule2DMod_gr_213.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_214.gif]





Integrate  [Graphics:../Images/SimpsonsRule2DMod_gr_215.gif]  with
respect to the variable x.  



[Graphics:../Images/SimpsonsRule2DMod_gr_216.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_217.gif]


[Graphics:../Images/SimpsonsRule2DMod_gr_218.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_219.gif]





Compute the definite integral  [Graphics:../Images/SimpsonsRule2DMod_gr_220.gif]



[Graphics:../Images/SimpsonsRule2DMod_gr_221.gif]


[Graphics:../Images/SimpsonsRule2DMod_gr_222.gif]





We have found the value of the iterated integral



[Graphics:../Images/SimpsonsRule2DMod_gr_223.gif]



[Graphics:../Images/SimpsonsRule2DMod_gr_224.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_225.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_226.gif]


[Graphics:../Images/SimpsonsRule2DMod_gr_227.gif]



[Graphics:../Images/SimpsonsRule2DMod_gr_228.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_229.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_230.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_231.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_232.gif]

[Graphics:../Images/SimpsonsRule2DMod_gr_233.gif]



 



 



 



 



 



 



 



 



 



 



 



 



 



 



 



 



 



 



 



 



 



 



(c) John
H. Mathews 2004