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♦ 31—40 of 113 matching pages ♦

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31—40 of 113 matching pages

31: Tom M. Apostol

… ►Apostol was born on August 20, 1923. …

32: 22.3 Graphics

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See accompanying text — Figure 22.3.13: $\operatorname{sn}\left(x,k\right)$ for $k=1-e^{-n}$ , $n=0$ to 20, $-5\pi\leq x\leq 5\pi$ . Magnify 3D Help

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33: 26.4 Lattice Paths: Multinomial Coefficients and Set Partitions

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Table 26.4.1: Multinomials and partitions.

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$n$	$m$	$\lambda$	$M_{1}$	$M_{2}$	$M_{3}$
…
$5$	$2$	$2^{1},3^{1}$	$10$	$20$	$10$
$5$	$3$	$1^{2},3^{1}$	$20$	$20$	$10$
…

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34: 3.4 Differentiation

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B_{-2}^{5}=\tfrac{1}{120}(6-10t-15t^{2}+20t^{3}-5t^{4}),

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B_{-3}^{6}=-\tfrac{1}{720}(12-8t-45t^{2}+20t^{3}+15t^{4}-6t^{5}),

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B_{-2}^{6}=\tfrac{1}{60}(9-9t-30t^{2}+20t^{3}+5t^{4}-3t^{5}),

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B_{2}^{6}=-\tfrac{1}{60}(9+9t-30t^{2}-20t^{3}+5t^{4}+3t^{5}),

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B_{3}^{6}=\tfrac{1}{720}(12+8t-45t^{2}-20t^{3}+15t^{4}+6t^{5}).

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35: 6.16 Mathematical Applications

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36: 26.3 Lattice Paths: Binomial Coefficients

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Table 26.3.1: Binomial coefficients

\genfrac{(}{)}{0.0pt}{}{m}{n}

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$m$	$n$
$m$	…
6	1	6	15	20	15	6	1
…

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Table 26.3.2: Binomial coefficients

\genfrac{(}{)}{0.0pt}{}{m+n}{m}

for lattice paths.

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$m$	$n$
$m$	…
3	1	4	10	20	35	56	84	120	165
…

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37: 5.22 Tables

… ►Abramowitz and Stegun (1964, Chapter 6) tabulates

\Gamma\left(x\right)

\ln\Gamma\left(x\right)

\psi\left(x\right)

, and

\psi'\left(x\right)

for

x=1(.005)2

to 10D;

\psi''\left(x\right)

and

\psi^{(3)}\left(x\right)

for

x=1(.01)2

to 10D;

\Gamma\left(n\right)

\ifrac{1}{\Gamma\left(n\right)}

\Gamma\left(n+\tfrac{1}{2}\right)

\psi\left(n\right)

\operatorname{log}_{10}\Gamma\left(n\right)

\operatorname{log}_{10}\Gamma\left(n+\tfrac{1}{3}\right)

\operatorname{log}_{10}\Gamma\left(n+\tfrac{1}{2}\right)

, and

\operatorname{log}_{10}\Gamma\left(n+\tfrac{2}{3}\right)

for

n=1(1)101

to 8–11S;

\Gamma\left(n+1\right)

for

n=100(100)1000

to 20S. …

38: 10.3 Graphics

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39: 12.19 Tables

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•

Murzewski and Sowa (1972) includes $D_{-n}\left(x\right)$ $\left(=U\left(n-\tfrac{1}{2},x\right)\right)$ for $n=1(1)20$ , $x=0(.05)3$ , 7S.

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40: 23.14 Integrals

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23.14.3

\int{\wp}^{3}\left(z\right)\,\mathrm{d}z=\frac{1}{120}\wp'''\left(z\right)-% \frac{3}{20}g_{2}\zeta\left(z\right)+\frac{1}{10}g_{3}z.

ⓘ

Symbols:: $\wp\left(\NVar{z}\right)$ (= $\wp\left(z|\mathbb{L}\right)$ = $\wp\left(z;g_{2},g_{3}\right)$ ): Weierstrass $\wp$ -function, $g_{\NVar{j}}$ : Weierstrass lattice invariants $g_{2}$ , $g_{3}$ , $\zeta\left(\NVar{z}\right)$ (= $\zeta\left(z|\mathbb{L}\right)$ = $\zeta\left(z;g_{2},g_{3}\right)$ ): Weierstrass zeta function, $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral, $\mathbb{L}$ : lattice and $z$ : complex
A&S Ref:: 18.7.2
Permalink:: http://dlmf.nist.gov/23.14.E3
Encodings:: pMML, png, TeX
See also:: Annotations for §23.14 and Ch.23

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