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The integral formulas of the associated Legendre functions
Abstract A new kind of integral formulas for $${\bar{P}_{n,m} (x)}$$ is derived from the addition theorem about the Legendre Functions when n − m is an even number. Based on the newly introduced integral formulas, the fully normalized associated Legendre functions can be directly computed without using any recursion methods that currently are often used in the computations. In addition, some arithmetic examples are computed with the increasing degree recursion and the integral methods introduced in the paper respectively, in order to compare the precisions and run-times of these two methods in computing the fully normalized associated Legendre functions. The results indicate that the precisions of the integral methods are almost consistent for variant x in computing $${\bar{P}_{n,m} (x)}$$, i.e., the precisions are independent of the choice of x on the interval [0,1]. In contrast, the precisions of the increasing degree recursion change with different values on the interval [0,1], particularly, when x tends to 1, the errors of computing $${\bar{P}_{n,m} (x)}$$ by the increasing degree recursion become unacceptable when the degree becomes larger and larger. On the other hand, the integral methods cost more run-time than the increasing degree recursion. Hence, it is suggested that combinations of the integral method and the increasing degree recursion can be adopted, that is, the integral methods can be used as a replacement for the recursive initials when the recursion method become divergent.
The integral formulas of the associated Legendre functions
Abstract A new kind of integral formulas for $${\bar{P}_{n,m} (x)}$$ is derived from the addition theorem about the Legendre Functions when n − m is an even number. Based on the newly introduced integral formulas, the fully normalized associated Legendre functions can be directly computed without using any recursion methods that currently are often used in the computations. In addition, some arithmetic examples are computed with the increasing degree recursion and the integral methods introduced in the paper respectively, in order to compare the precisions and run-times of these two methods in computing the fully normalized associated Legendre functions. The results indicate that the precisions of the integral methods are almost consistent for variant x in computing $${\bar{P}_{n,m} (x)}$$, i.e., the precisions are independent of the choice of x on the interval [0,1]. In contrast, the precisions of the increasing degree recursion change with different values on the interval [0,1], particularly, when x tends to 1, the errors of computing $${\bar{P}_{n,m} (x)}$$ by the increasing degree recursion become unacceptable when the degree becomes larger and larger. On the other hand, the integral methods cost more run-time than the increasing degree recursion. Hence, it is suggested that combinations of the integral method and the increasing degree recursion can be adopted, that is, the integral methods can be used as a replacement for the recursive initials when the recursion method become divergent.
The integral formulas of the associated Legendre functions
Yu, Jinhai (author) / Wan, Xiaoyun (author) / Zeng, Yanyan (author)
Journal of Geodesy ; 86
2011
Article (Journal)
English
BKL:
38.73
Geodäsie
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