Innovative Integrals and Their Applications I

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This book develops integral identities, mostly involving multidimensional functions and infinite limits of integration, whose evaluations are intractable by common means. It exposes a methodology based on the multivariate power substitution and its variants, assisted by the software tool Mathematica. The approaches introduced comprise the generalized method of exhaustion, the multivariate power substitution and its variants, and the use of permutation symmetry to evaluate definite integrals, which are very important both in their own right, and as necessary intermediate steps towards more involved computation.

A key tenet is that such approaches work best when applied to integrals having certain characteristics as a starting point. Most integrals, if used as a starting point, will lead to no result at all, or will lead to a known result. However, there is a special class of integrals (i.e., innovative integrals) which, if used as a starting point for such approaches, will lead to new and useful results, and can also enable the reader to generate many other new results that are not in the book.

The reader will find a myriad of novel approaches for evaluating integrals, with a focus on tools such as Mathematica as a means of obtaining useful results, and also checking whether they are already known. Results presented involve the gamma function, the hypergeometric functions, the complementary error function, the exponential integral function, the Riemann zeta function, and others that will be introduced as they arise. The book concludes with selected engineering applications, e.g., involving wave propagation, antenna theory, non-Gaussian and weighted Gaussian distributions, and other areas.

The intended audience comprises junior and senior sciences majors planning to continue in the pure and applied sciences at the graduate level, graduate students in mathematics and the sciences, and junior and established researchers in mathematical physics, engineering, and mathematics. Indeed, the pedagogical inclination of the exposition will have students work out, understand, and efficiently use multidimensional integrals from first principles.


Author(s): Anthony A. Ruffa, Bourama Toni
Series: STEAM-H: Science, Technology, Engineering, Agriculture, Mathematics & Health
Publisher: Springer
Year: 2022

Language: English
Pages: 324
City: Cham

Preface
Contents
1 The Generalized Method of Exhaustion
1.1 Preliminary Concepts
1.1.1 The Residue Theorem
1.1.2 The Laplace Transform
1.2 Approximating the Area Under a Curve with Triangles
1.3 A Simple Illustration
1.4 Analytic Derivation
1.5 The Fundamental Theorem of Calculus
1.6 Infinite Products for the Logarithm and the Sine
1.7 Application to Other Functions
1.8 Improper Integrals
1.9 Summary and Further Reading
2 The Multivariate Power Substitution and Its Variants
2.1 The Multivariate Power Substitution
2.1.1 Illustrative Examples
2.1.2 Some Preliminary Results
2.2 Permutation Symmetry
2.3 The Laplace Transform
2.4 Multivariate Power Substitution Variants
2.5 More Variants
2.6 Triple Integrals
2.7 Further Reading
3 Additional Multivariate Substitution Variants
3.1 Polar Coordinates and Spherical Coordinates
3.2 The Generalized Method of Exhaustion Revisited
3.3 The Complementary Error Function
3.4 A New Variant
3.5 The Laplace Transform Revisited
3.6 Triple and Quadruple Integrals
3.7 The Owen T-Function
3.8 Further Reading
4 Miscellaneous Integral Identities
4.1 Identities Involving the Lerch Transcendent
4.2 Integrals Involving the Logarithm
4.3 Various Other Integral Identities
4.4 Summary and Further Reading
5 The Exponential Integral Function, the Sine Integral and Cosine Integrals
5.1 Integral Identities Involving E1(x)
5.2 Identities Involving Ea(x)
5.3 The Laplace Transform
5.4 Permutation Symmetry
5.5 Further Reading
6 The Riemann Zeta Function and the Hurwitz Zeta Function
6.1 The Riemann Zeta Function
6.2 Integrals Involving the Polygamma Function
6.3 The Hurwitz Zeta Function
6.4 Integrals Involving Trigonometric Functions
6.5 The Laplace Transform
6.6 Identities Involving the Polylogarithm
6.7 Identities Involving the Lerch Transcendent
6.8 Summary and Further Reading
7 Engineering Applications
7.1 Plane Waves and Spherical Waves
7.1.1 Plane Waves
7.1.2 The Angular Spectrum of Plane Waves
7.1.3 Spherical Waves
7.1.4 The Sommerfeld Identity
7.1.5 An Alternative Identity
7.2 The Sommerfeld Integral
7.3 Bessel Functions and Frequency Modulation
7.4 Non-Gaussian and Weighted Gaussian Distributions
7.5 Further Reading
References
Index