Linear algebra is also important in many algorithms in computer algebra, as you might have guessed. For example, if you can reduce a problem to saying that a polynomial is zero, where the coefficients of the polynomial are linear in the variables `x1, …, xn`

, then you can solve for what values of `x1, …, xn`

make the polynomial equal to 0 by equating the coefficient of each `x^n`

term to 0 and solving the linear system. This is called the method of undetermined coefficients, and is used for example in computing partial fraction decompositions or in integrating rational functions.

For the graph theory, the coolest thing about an adjacency matrix is that if you take the nth power of an adjacency Matrix for an unweighted graph (each entry is either 0 or 1), `M^n`

, then each entry `i,j`

will be the number of paths from vertex `i`

to vertex `j`

of length `n`

. And if that isn't just cool, then I don't know what is.