Numerical differentiation and integration
Revision as of 13:29, 10 November 2010 by Kevindunn (talk | contribs) (→Source code used in slides)
Part A: Numerical differentiation
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Part B: Numerical integration
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Source code used in slides
Composite trapezoidal integration
MATLAB | Python |
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function In = trapezcomp(f, a, b, n)
% Composite trapezoidal function integration
%
% INPUTS:
% f: the function to integrate
% a: lower bound of integration
% b: upper bound
% n: number of panels to create between ``a`` and ``b``
% Initialization
h = (b-a)/n;
x = a;
% Composite rule
In =f(a);
for k=2:n
x = x + h;
In = In + 2. * f(x);
end
In = (In + f(b)) * h * 0.5;
% end of function
Then use this function as follows: >> f = @(x)sin(x);
>> I1 = trapezcomp( f, 0, pi/2, 1 ) % 0.7854
>> I2 = trapezcomp( f, 0, pi/2, 2 ) % 0.9481
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import numpy as np
def trapezcomp(f, a, b, n):
"""
Composite trapezoidal function integration
INPUTS:
f: the function to integrate
a: lower bound of integration
b: upper bound
n: number of panels to create between ``a`` and ``b``
"""
# Initialization
h = (b - a) / n
x = a
# Composite rule
In = f(a)
for k in range(1, n):
x = x + h
In += 2*f(x)
return (In + f(b))*h*0.5
if __name__ == '__main__':
def func(x):
return np.sin(x)
print(trapezcomp(func, 0, np.pi/2, 1)) # 0.785398163397
print(trapezcomp(func, 0, np.pi/2, 2)) # 0.948059448969
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Romberg integration
MATLAB | Python |
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Then use this function as follows: >> f = @(x)sin(x);
>> format long
>>
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