Some Transcendental Equations with Trigonometric and Hyperbolic Functions

A system of transcendental equations (SoTE) is a set of simultaneous equations containing at least a transcendental function. Solutions involving transcendental equations are often problematic, particularly in the form of a system of equations. This challenge has limited the number of equations, with inter-related multi-functions and multi-variables, often included in the mathematical modelling of physical systems during problem formulation. Here, we presented detailed steps for using a code-based modelling approach for solving SoTEs that may be encountered in science and engineering problems. A SoTE comprising six functions, including Sine-Gordon wave functions, was used to illustrate the steps. Parametric studies were performed to visualize how a change in the variables affected the superposition of the waves as the independent variable varies from x1 = 1:0.0005:100 to x1 = 1:5:100. The application of the proposed approach in modelling and simulation of photovoltaic and thermophotovoltaic systems were also highlighted. Overall, solutions to SoTEs present new opportunities for including more functions and variables in numerical models of systems, which will ultimately lead to a more robust representation of physical systems.

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On the improvement of q-deformed hyperbolic functions

Journal of Mathematical Chemistry ◽

10.1007/s10910-020-01200-8 ◽

2021 ◽

Author(s):

J. Morales ◽

J. J. Peña ◽

J. García-Ravelo

Keyword(s):

Hyperbolic Functions

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Application of the Efros Theorem to the Function Represented by the Inverse Laplace Transform of s−μ exp(−sν)

Symmetry ◽

10.3390/sym13020354 ◽

2021 ◽

Vol 13 (2) ◽

pp. 354

Author(s):

Alexander Apelblat ◽

Francesco Mainardi

Keyword(s):

Laplace Transform ◽

Operational Calculus ◽

Inverse Laplace Transform ◽

Elementary Functions ◽

Hyperbolic Functions ◽

Error Functions ◽

Convolution Integrals ◽

Special Case ◽

Integral Identities ◽

Finite Integrals

Using a special case of the Efros theorem which was derived by Wlodarski, and operational calculus, it was possible to derive many infinite integrals, finite integrals and integral identities for the function represented by the inverse Laplace transform. The integral identities are mainly in terms of convolution integrals with the Mittag–Leffler and Volterra functions. The integrands of determined integrals include elementary functions (power, exponential, logarithmic, trigonometric and hyperbolic functions) and the error functions, the Mittag–Leffler functions and the Volterra functions. Some properties of the inverse Laplace transform of s−μexp(−sν) with μ≥0 and 0<ν<1 are presented.

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Applications of a duality between generalized trigonometric and hyperbolic functions

Journal of Mathematical Analysis and Applications ◽

10.1016/j.jmaa.2021.125241 ◽

2021 ◽

Vol 502 (1) ◽

pp. 125241

Author(s):

Hiroki Miyakawa ◽

Shingo Takeuchi

Keyword(s):

Hyperbolic Functions

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Comment on ’’Simple iterative procedures for solving transcendental equations with the ’electronic slide rule’ ’’

American Journal of Physics ◽

10.1119/1.10181 ◽

1976 ◽

Vol 44 (5) ◽

pp. 488-490

Author(s):

John A. Ball

Keyword(s):

Slide Rule ◽

Transcendental Equations ◽

Iterative Procedures

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The use of Riemann problems in solving a class of transcendental equations

Mathematical Proceedings of the Cambridge Philosophical Society ◽

10.1017/s0305004100047526 ◽

1973 ◽

Vol 73 (1) ◽

pp. 111-118 ◽

Cited By ~ 55

Author(s):

E. E. Burniston ◽

C. E. Siewert

Keyword(s):

Boundary Value Problem ◽

Closed Form ◽

Boundary Value ◽

Explicit Solutions ◽

Riemann Boundary Value Problem ◽

Riemann Problems ◽

Riemann Boundary ◽

Canonical Solution ◽

Transcendental Equations ◽

Explicit Expressions

AbstractA method of finding explicit expressions for the roots of a certain class of transcendental equations is discussed. In particular it is shown by determining a canonical solution of an associated Riemann boundary-value problem that expressions for the roots may be derived in closed form. The explicit solutions to two transcendental equations, tan β = ωβ and β tan β = ω, are discussed in detail, and additional specific results are given.

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