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In mathematics, Jacobi polynomials (occasionally called hypergeometric polynomials) are a class of classical orthogonal polynomials. They are orthogonal with respect to the weight on the interval . The Gegenbauer polynomials, and thus also the Legendre, Zernike and Chebyshev polynomials, are special cases of the Jacobi polynomials. The Jacobi polynomials were introduced by Carl Gustav Jacob Jacobi. The Jacobi polynomials are defined via the hypergeometric function as follows: where is Pochhammer's symbol (for the rising factorial). In this case, the series for the hypergeometric function is finite, therefore one obtains the following equivalent expression: An equivalent definition is given by Rodrigues' formula: If , then it reduces to the Legendre polynomials: For real the Jacobi polynomial can alternatively be written as and for integer where is the gamma function. In the special case that the four quantities , , , are nonnegative integers, the Jacobi polynomial can be written as The sum extends over all integer values of for which the arguments of the factorials are nonnegative. The Jacobi polynomials satisfy the orthogonality condition As defined, they do not have unit norm with respect to the weight. This can be corrected by dividing by the square root of the right hand side of the equation above, when . Although it does not yield an orthonormal basis, an alternative normalization is sometimes preferred due to its simplicity: The polynomials have the symmetry relation thus the other terminal value is The th derivative of the explicit expression leads to The Jacobi polynomial is a solution of the second order linear homogeneous differential equation The recurrence relation for the Jacobi polynomials of fixed , is: for . Writing for brevity , and , this becomes in terms of Since the Jacobi polynomials can be described in terms of the hypergeometric function, recurrences of the hypergeometric function give equivalent recurrences of the Jacobi polynomials.

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