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By Theorem 4.61.2 in Szegő's Orthogonal Polynomials, my edition, it turns out that the hypergeometric series 2F1 representation of Q_0^{(\alpha,\beta)} degenerates to 1F0 when alpha+beta+1=0, and this perfectly cancels with the powers to become constant. There is an alternative linearly independent solution to Jacobi's differential equation (à la Frobenius' method), and this issue reports that it has not been implemented yet.
The linearly independent solution is given in terms of a partial derivative with respect to beta, so perhaps this calls for an implementation by dual numbers, similar to the logkernel integrals.
This case is really a corner case, since alpha = beta = -1/2 is special anyway, and it appears to me that most exotic solutions are sought from (alpha,beta) in [-1/2,1/2]^2.
The text was updated successfully, but these errors were encountered:
By Theorem 4.61.2 in Szegő's Orthogonal Polynomials, my edition, it turns out that the hypergeometric series 2F1 representation of Q_0^{(\alpha,\beta)} degenerates to 1F0 when
alpha+beta+1=0, and this perfectly cancels with the powers to become constant. There is an alternative linearly independent solution to Jacobi's differential equation (à la Frobenius' method), and this issue reports that it has not been implemented yet.The linearly independent solution is given in terms of a partial derivative with respect to beta, so perhaps this calls for an implementation by dual numbers, similar to the
logkernelintegrals.This case is really a corner case, since alpha = beta = -1/2 is special anyway, and it appears to me that most exotic solutions are sought from (alpha,beta) in [-1/2,1/2]^2.
The text was updated successfully, but these errors were encountered: