multiplication formulas

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1: 5.5 Functional Relations

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§5.5(iii) Multiplication

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Gauss’s Multiplication Formula

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5.5.7

\prod_{k=1}^{n-1}\Gamma\left(\frac{k}{n}\right)=(2\pi)^{(n-1)/2}n^{-1/2}.

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Symbols:: $\Gamma\left(\NVar{z}\right)$ : gamma function, $\pi$ : the ratio of the circumference of a circle to its diameter, $n$ : nonnegative integer and $k$ : nonnegative integer
Permalink:: http://dlmf.nist.gov/5.5.E7
Encodings:: pMML, png, TeX
See also:: Annotations for §5.5(iii), §5.5(iii), §5.5 and Ch.5

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4: Bibliography O

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F. W. J. Olver (1977a) Connection formulas for second-order differential equations with multiple turning points. SIAM J. Math. Anal. 8 (1), pp. 127–154.

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External Links:: Document, MathReview (Anthony Leung), ZentralBlatt
Referenced by:: §2.8(v), (9.13.13), (9.13.17), §9.13(i), §9.13(i).
Encodings:: BibTeX

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F. W. J. Olver (1977b) Connection formulas for second-order differential equations having an arbitrary number of turning points of arbitrary multiplicities. SIAM J. Math. Anal. 8 (4), pp. 673–700.

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External Links:: Document, MathReview (W. Wasow), ZentralBlatt
Referenced by:: §2.8(v).
Encodings:: BibTeX

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5: 27.20 Methods of Computation: Other Number-Theoretic Functions

… ►To calculate a multiplicative function it suffices to determine its values at the prime powers and then use (27.3.2). For a completely multiplicative function we use the values at the primes together with (27.3.10). ►The recursion formulas (27.14.6) and (27.14.7) can be used to calculate the partition function

p\left(n\right)

for

n<N

. … ►A recursion formula obtained by differentiating (27.14.18) can be used to calculate Ramanujan’s function

\tau\left(n\right)

, and the values can be checked by the congruence (27.14.20). …

6: 2.8 Differential Equations with a Parameter

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§2.8(v) Multiple and Fractional Turning Points

►The approach used in preceding subsections for equation (2.8.1) also succeeds when

z_{0}

is a multiple or fractional turning point. For the former

f(z)

has a zero of multiplicity

\lambda=2,3,4,\dots

and

g(z)

is analytic. …For results, including error bounds, see Olver (1977c). ►For connection formulas for Liouville–Green approximations across these transition points see Olver (1977b, a, 1978). …

7: Bibliography S

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D. M. Smith (1998) Algorithm 786: Multiple-precision complex arithmetic and functions. ACM Trans. Math. Software 24 (4), pp. 359–367.

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External Links:: ISSN 0098-3500, Document, GAMS (module 786; package TOMS), ZentralBlatt
Referenced by:: 4th item.
Encodings:: BibTeX

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D. M. Smith (1989) Efficient multiple-precision evaluation of elementary functions. Math. Comp. 52 (185), pp. 131–134.

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External Links:: ISSN 0025-5718, FullText, MathReview (Menachem Dishon), ZentralBlatt
Referenced by:: §4.45(i).
Encodings:: BibTeX

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D. M. Smith (1991) Algorithm 693: A FORTRAN package for floating-point multiple-precision arithmetic. ACM Trans. Math. Software 17 (2), pp. 273–283.

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Notes:: Multiple-precision Fortran.
External Links:: ISSN 0098-3500, Document, GAMS (module 693; package TOMS), ZentralBlatt
Referenced by:: 2nd item.
Encodings:: BibTeX

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D. Sornette (1998) Multiplicative processes and power laws. Phys. Rev. E 57 (4), pp. 4811–4813.

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External Links:: Document
Referenced by:: §8.24(i).
Encodings:: BibTeX

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A. H. Stroud (1971) Approximate Calculation of Multiple Integrals. Prentice-Hall Inc., Englewood Cliffs, N.J..

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External Links:: ISBN 0130438936;978-0130438935, MathReview (R. D. Riess), ZentralBlatt
Referenced by:: §3.5(x).
Encodings:: BibTeX

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8: 18.18 Sums

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§18.18(iii) Multiplication Theorems

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§18.18(v) Linearization Formulas

… ►Formula (18.18.27) is known as the Hille–Hardy formula. … ►Formula (18.18.28) is known as the Mehler formula. …

9: 18.28 Askey–Wilson Class

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18.28.26

\lim_{\lambda\to 0}r_{n}\left(\ifrac{x}{(2\lambda)};\lambda,qa\lambda^{-1},qc% \lambda^{-1},bc^{-1}\lambda\,|\,q\right)=P_{n}\left(x;a,b,c;q\right).

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Symbols:: $P_{\NVar{n}}\left(\NVar{x};\NVar{a},\NVar{b},\NVar{c};\NVar{q}\right)$ : big $q$ -Jacobi polynomial, $\left(\NVar{a_{1},a_{2},\dots,a_{r}};\NVar{q}\right)_{\NVar{n}}$ : multiple $q$ -Pochhammer symbol, $z$ : complex variable, $q$ : real variable, $\ell$ : nonnegative integer, $n$ : nonnegative integer and $x$ : real variable
Source:: Koekoek et al. (2010, (14.1.18))
Proof sketch:: In the terminating $q$ -hypergeometric series which defines the ${}_{4}\phi_{3}$ in (18.28.1_5), with $\left(azq^{\ell},az^{-1}q^{\ell};q\right)_{\ell}$ written as $\prod_{j=0}^{\ell-1}(1-2aq^{j}x+a^{2}q^{2j})$ , substitute for $x$ and the parameters according to the left-hand side of the present formula, take the limit, and obtain the ${}_{3}\phi_{2}$ as in (18.27.5).
Referenced by:: (18.28.27), (18.28.28), §18.28(x)
Permalink:: http://dlmf.nist.gov/18.28.E26
Encodings:: pMML, png, TeX
See also:: Annotations for §18.28(x), §18.28(x), §18.28 and Ch.18

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10: 27.5 Inversion Formulas

§27.5 Inversion Formulas

… ►The multiplicative functions are a subgroup of this group. …which, in turn, is the basis for the Möbius inversion formula relating sums over divisors: … ►Special cases of Möbius inversion pairs are: … ►Other types of Möbius inversion formulas include: …