In numerical analysis, Chebyshev nodes are specific real algebraic numbers, namely the roots of the Chebyshev polynomials of the first kind. They are often used as nodes in polynomial interpolation because the resulting interpolation polynomial minimizes the effect of Runge's phenomenon. In numerical analysis, Chebyshev nodes are specific real algebraic numbers, namely the roots of the Chebyshev polynomials of the first kind. They are often used as nodes in polynomial interpolation because the resulting interpolation polynomial minimizes the effect of Runge's phenomenon. For a given positive integer n the Chebyshev nodes in the interval (−1, 1) are These are the roots of the Chebyshev polynomial of the first kind of degree n. For nodes over an arbitrary interval an affine transformation can be used: The Chebyshev nodes are important in approximation theory because they form a particularly good set of nodes for polynomial interpolation. Given a function ƒ on the interval [ − 1 , + 1 ] {displaystyle } and n {displaystyle n} points x 1 , x 2 , … , x n , {displaystyle x_{1},x_{2},ldots ,x_{n},} in that interval, the interpolation polynomial is that unique polynomial P n − 1 {displaystyle P_{n-1}} of degree at most n − 1 {displaystyle n-1} which has value f ( x i ) {displaystyle f(x_{i})} at each point x i {displaystyle x_{i}} . The interpolation error at x {displaystyle x} is for some ξ {displaystyle xi } (depending on x) in . So it is logical to try to minimize This product is a monic polynomial of degree n. It may be shown that the maximum absolute value (maximum norm) of any such polynomial is bounded from below by 21−n. This bound is attained by the scaled Chebyshev polynomials 21−n Tn, which are also monic. (Recall that |Tn(x)| ≤ 1 for x ∈ .) Therefore, when the interpolation nodes xi are the roots of Tn, the error satisfies For an arbitrary interval a change of variable shows that