Difference between revisions of "Linear Systems in Matlab"
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In this example, <tt>solution</tt> is a column vector whose elements are <tt>x</tt> and <tt>y</tt>: | In this example, <tt>solution</tt> is a column vector whose elements are <tt>x</tt> and <tt>y</tt>: | ||
<center><math> | <center><math> | ||
| − | \mathrm{solution} = \left[ \begin{ | + | \mathrm{solution} = \left[ \begin{smallmatrix}-2.3077 \\1.9231 \end{smallmatrix} \right], |
</math></center> | </math></center> | ||
which is consistent with the answer we obtained by hand above. | which is consistent with the answer we obtained by hand above. | ||
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Ainv = inv(A); % entirely equivalent to A^-1. | Ainv = inv(A); % entirely equivalent to A^-1. | ||
</source> | </source> | ||
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=== Sparse Systems === | === Sparse Systems === | ||
Revision as of 15:49, 4 August 2009
Contents
Solving Linear Systems of Equations in MATLAB
This section discusses how to solve a set of linear equations =(b)](/wiki/images/math/b/3/a/b3ae30ff4dcdb54b97d86d814ca503d6.png)
in MATLAB.
See the discussion of linear algebra for help on writing a linear system of equations in matrix-vector format. There is also help on creating matrices and vectors in MATLAB.
The simplest way of solving a system of equations in MATLAB is by using the \ operator. Given a matrix A and a vector b, we may solve the system using the following MATLAB commands:
x = A\b;
Example
Consider the following set of equations:
These can be easily solved by hand to obtain
. These equations and their solution (intersection) are plotted in the figure to the right.
To solve the system of equations using MATLAB, first rewrite these in a matrix-vector form as
![\begin{align}
5x + 6y &= 0 \\
3x + 1y &= -5 \\
\end{align}
\quad \Leftrightarrow \quad
\left[ \begin{array}{cc} 5 & 6 \\ 3 & 1 \end{array} \right]
\left( \begin{array}{c} x \\ y \end{array} \right) =
\left( \begin{array}{c} 0 \\ -5 \end{array} \right) .](/wiki/images/math/1/7/4/174e63aeefd5db446681be987bdadb7e.png)
Once in matrix-vector form, the solution is obtained in MATLAB by using the following commands (see here for help on creating matrices and vectors):
A = [ 5 6; 3 1 ]; % define the matrix
b = [ 0; -5 ]; % define the vector
solution = A\b; % solve the system of equations.
In this example, solution is a column vector whose elements are x and y:
![\mathrm{solution} = \left[ \begin{smallmatrix}-2.3077 \\1.9231 \end{smallmatrix} \right],](/wiki/images/math/d/3/c/d3c5261fb7a5b071957c0d2e6109bc9b.png)
which is consistent with the answer we obtained by hand above.
Matrix Inverse
Note that we can also form the inverse of a matrix,
![[A] (x)=(b) \quad \Leftrightarrow \quad (x)=[A]^{-1}(b).](/wiki/images/math/9/6/0/96008bab47a724a093e8ed6374cec8f5.png)
This can be done in MATLAB as illustrated by the following:
A = [ 5 6; 3 1 ];
b = [ 0; -5 ];
Ainv = A^-1; % calculate the inverse of A
solution = Ainv*b; % calculate the solution
We could also calculate A-1 by
Ainv = inv(A); % entirely equivalent to A^-1.
Sparse Systems
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Linear Systems using the Symbolic Toolbox
Occasionally we may want to find the symbolic (general) solution to a system of equations rather than a specific numerical solution. The symbolic toolbox provides a way to do this.
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