- :
`y`=**poly**`(`

¶`A`) - :
`y`=**poly**`(`

¶`x`) If

`A`is a square*N*-by-*N*matrix,`poly (`

is the row vector of the coefficients of`A`)`det (z * eye (N) - A)`

, the characteristic polynomial of`A`.For example, the following code finds the eigenvalues of

`A`which are the roots of`poly (`

.`A`)roots (poly (eye (3))) ⇒ 1.00001 + 0.00001i 1.00001 - 0.00001i 0.99999 + 0.00000i

In fact, all three eigenvalues are exactly 1 which emphasizes that for numerical performance the

`eig`

function should be used to compute eigenvalues.If

`x`is a vector,`poly (`

is a vector of the coefficients of the polynomial whose roots are the elements of`x`)`x`. That is, if`c`is a polynomial, then the elements of

are contained in`d`= roots (poly (`c`))`c`. The vectors`c`and`d`are not identical, however, due to sorting and numerical errors.

- :
**polyout**`(`

¶`c`) - :
**polyout**`(`

¶`c`,`x`) - :
`str`=**polyout**`(…)`

¶ Display a formatted version of the polynomial

`c`.The formatted polynomial

c(x) = c(1) * x^n + ... + c(n) x + c(n+1)

is returned as a string or written to the screen if

`nargout`

is zero.The second argument

`x`specifies the variable name to use for each term and defaults to the string`"s"`

.**See also:**polyreduce.