fundamental theorem of calculus

(0.002 seconds)

21—30 of 146 matching pages

21: 3.12 Mathematical Constants

… ►The fundamental constant …

22: 8.24 Physical Applications

… ►With more general values of

p

E_{p}\left(x\right)

supplies fundamental auxiliary functions that are used in the computation of molecular electronic integrals in quantum chemistry (Harris (2002), Shavitt (1963)), and also wave acoustics of overlapping sound beams (Ding (2000)).

23: 16.21 Differential Equation

… ►A fundamental set of solutions of (16.21.1) is given by …For other fundamental sets see Erdélyi et al. (1953a, §5.4) and Marichev (1984).

24: Bibliography C

… ►

L. Carlitz (1961b) The Staudt-Clausen theorem. Math. Mag. 34, pp. 131–146.

ⓘ

External Links:: MathReview (K. Goldberg), ZentralBlatt
Referenced by:: §24.6.
Encodings:: BibTeX

… ►

B. C. Carlson (1971) New proof of the addition theorem for Gegenbauer polynomials. SIAM J. Math. Anal. 2, pp. 347–351.

ⓘ

External Links:: ISSN 1095-7154, Document, MathReview (Mary L. Boas), ZentralBlatt
Referenced by:: §18.18(ii).
Encodings:: BibTeX

… ►

B. C. Carlson (1978) Short proofs of three theorems on elliptic integrals. SIAM J. Math. Anal. 9 (3), pp. 524–528.

ⓘ

External Links:: Document, MathReview (Y. L. Luke), ZentralBlatt
Referenced by:: §19.26(i).
Encodings:: BibTeX

… ►

F. Clarke (1989) The universal von Staudt theorems. Trans. Amer. Math. Soc. 315 (2), pp. 591–603.

ⓘ

External Links:: ISSN 0002-9947, FullText, MathReview (T. Metsänkylä), ZentralBlatt
Referenced by:: §24.16(iii).
Encodings:: BibTeX

… ►

H. S. Cohl (2013a) Fourier, Gegenbauer and Jacobi expansions for a power-law fundamental solution of the polyharmonic equation and polyspherical addition theorems. SIGMA Symmetry Integrability Geom. Methods Appl. 9, pp. Paper 042, 26.

ⓘ

External Links:: ISSN 1815-0659, Document, MathReview (Heinrich Begehr), ZentralBlatt
Referenced by:: §14.28(ii), §14.28(ii).
Encodings:: BibTeX

…

25: Bibliography

… ►

W. A. Al-Salam (1990) Characterization theorems for orthogonal polynomials. In Orthogonal Polynomials (Columbus, OH, 1989), NATO Adv. Sci. Inst. Ser. C Math. Phys. Sci., Vol. 294, pp. 1–24.

ⓘ

External Links:: Link, MathReview (Walter Van Assche), ZentralBlatt
Referenced by:: §18.3.
Encodings:: BibTeX

… ►

H. Alzer and S. Qiu (2004) Monotonicity theorems and inequalities for the complete elliptic integrals. J. Comput. Appl. Math. 172 (2), pp. 289–312.

ⓘ

External Links:: ISSN 0377-0427, Document, MathReview (Živorad Tomovski), ZentralBlatt
Referenced by:: §19.9(i).
Encodings:: BibTeX

… ►

G. E. Andrews (2000) Umbral calculus, Bailey chains, and pentagonal number theorems. J. Combin. Theory Ser. A 91 (1-2), pp. 464–475.

ⓘ

Notes:: In memory of Gian-Carlo Rota
External Links:: ISSN 0097-3165, Document, MathReview (Alessandro Di Bucchianico), ZentralBlatt
Referenced by:: §17.12.
Encodings:: BibTeX

… ►

T. M. Apostol (1952) Theorems on generalized Dedekind sums. Pacific J. Math. 2 (1), pp. 1–9.

ⓘ

External Links:: MathReview (N. G. de Bruijn), ZentralBlatt
Referenced by:: (25.11.41), (25.11.42), §25.11(xii).
Encodings:: BibTeX

… ►

T. M. Apostol (2000) A Centennial History of the Prime Number Theorem. In Number Theory, Trends Math., pp. 1–14.

ⓘ

External Links:: MathReview (Giovanni Coppola), ZentralBlatt
Referenced by:: (25.16.2), (25.16.4), §25.16(i), §25.16.
Encodings:: BibTeX

…

26: David M. Bressoud

… ► 227, in 1980, Factorization and Primality Testing, published by Springer-Verlag in 1989, Second Year Calculus from Celestial Mechanics to Special Relativity, published by Springer-Verlag in 1992, A Radical Approach to Real Analysis, published by the Mathematical Association of America in 1994, with a second edition in 2007, Proofs and Confirmations: The Story of the Alternating Sign Matrix Conjecture, published by the Mathematical Association of America and Cambridge University Press in 1999, A Course in Computational Number Theory (with S. …

27: 30.10 Series and Integrals

… ►For an addition theorem, see Meixner and Schäfke (1954, p. 300) and King and Van Buren (1973). …

28: 10.44 Sums

… ►

§10.44(i) Multiplication Theorem

… ►

§10.44(ii) Addition Theorems

►

Neumann’s Addition Theorem

… ►

Graf’s and Gegenbauer’s Addition Theorems

…

29: 18.38 Mathematical Applications

… ►Classical OP’s play a fundamental role in Gaussian quadrature. … ►

18.38.3

\sum_{m=0}^{n}P^{(\alpha,0)}_{m}\left(x\right)=\frac{{\left(\alpha+2\right)_{n% }}}{n!}{{}_{3}F_{2}}\left({-n,n+\alpha+2,\frac{1}{2}(\alpha+1)\atop\alpha+1,% \frac{1}{2}(\alpha+3)};\tfrac{1}{2}(1-x)\right)\geq 0,

x\geq-1

\alpha\geq-2

n=0,1,\dots

ⓘ

Symbols:: ${{}_{\NVar{p}}F_{\NVar{q}}}\left(\NVar{a_{1},\dots,a_{p}};\NVar{b_{1},\dots,b_% {q}};\NVar{z}\right)$ or ${{}_{\NVar{p}}F_{\NVar{q}}}\left({\NVar{a_{1},\dots,a_{p}}\atop\NVar{b_{1},% \dots,b_{q}}};\NVar{z}\right)$ : alternatively ${{}_{\NVar{p}}F_{\NVar{q}}}\left(\NVar{\mathbf{a}};\NVar{\mathbf{b}};\NVar{z}\right)$ or ${{}_{\NVar{p}}F_{\NVar{q}}}\left({\NVar{\mathbf{a}}\atop\NVar{\mathbf{b}}};% \NVar{z}\right)$
generalized hypergeometric function, $P^{(\NVar{\alpha},\NVar{\beta})}_{\NVar{n}}\left(\NVar{x}\right)$ : Jacobi polynomial, ${\left(\NVar{a}\right)_{\NVar{n}}}$ : Pochhammer’s symbol (or shifted factorial), $!$ : factorial (as in $n!$ ), $m$ : nonnegative integer, $n$ : nonnegative integer and $x$ : real variable
Proved:: Askey and Gasper (1976, Theorem 3, p.717)(proved)
Referenced by:: §18.14(iv), §18.18(viii), Erratum (V1.2.0) for Equation (18.38.3)
Permalink:: http://dlmf.nist.gov/18.38.E3
Encodings:: pMML, png, TeX
Modification (effective with 1.2.0):: This equation was updated to include the value of the sum in terms of the ${{}_{3}F_{2}}$ function. Also the constraint was previously $\alpha>-1$ .
See also:: Annotations for §18.38(ii), §18.38(ii), §18.38 and Ch.18

…

30: 15.10 Hypergeometric Differential Equation

… ►

§15.10(i) Fundamental Solutions

… ►When none of the exponent pairs differ by an integer, that is, when none of

c

c-a-b

a-b

is an integer, we have the following pairs

f_{1}(z)

f_{2}(z)

of fundamental solutions. … ►(a) If

c

equals

n=1,2,3,\dots

, and

a=1,2,\dots,n-1

, then fundamental solutions in the neighborhood of

z=0

are given by (15.10.2) with the interpretation (15.2.5) for

f_{2}(z)

. … ► … ►The three pairs of fundamental solutions given by (15.10.2), (15.10.4), and (15.10.6) can be transformed into 18 other solutions by means of (15.8.1), leading to a total of 24 solutions known as Kummer’s solutions. …