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14.5: Symbolic Integration

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Integration is the reverse process of differentiation. In engineering, integrals are used to calculate quantities such as area, accumulated mass, total charge, displacement from velocity, and work from force.

In MATLAB symbolic math, the int function is used for integration.

`Indefinite Integrals`

An indefinite integral finds an antiderivative. For example, let \(f(x) = 3x^2 - 1\).

syms x
f = 3*x^2 - 1;
F = int(f)

MATLAB returns a symbolic expression for the antiderivative:

F = x^3 - x

Note

Note: MATLAB may not always display the + C constant of integration. In calculus, indefinite integrals include an arbitrary constant, but symbolic software often omits it unless requested.

Definite Integrals

A definite integral calculates the accumulated value over an interval.

For example, to compute the integral of \(3x^2 - 1\) from \(x = 2\) to \(x = 4\), include the lower and upper limits in the int command.

syms x
f = 3*x^2 - 1;
area = int(f, 2, 4)
area_numeric = double(area)

whos area   area_numeric

The symbolic result is exact. The numeric result is a decimal version of the same value:

area = 54

area_numeric = 54

Name             Size        Bytes       Class       

area             1x1              8      sym
area_numeric     1x1              8      double

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