Addition Formulas of Leaf Functions and Hyperbolic Leaf Functions

Addition formulas exist in trigonometric functions. Double-angle and half-angle formulas can be derived from these formulas. Moreover, the relation equation between the trigonometric function and the hyperbolic function can be derived using an imaginary number. The inverse hyperbolic function arsinh...

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Veröffentlicht in:	Computer modeling in engineering & sciences 2020-01, Vol.123 (2), p.441-473
1. Verfasser:	Shinohara, Kazunori
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Sprache:	eng
Schlagworte:	Hyperbolic functions Hyperbolic Leaf Functions Jacobi Elliptic Functions Leaf Functions Lemniscate Functions Mathematical analysis Nonlinear Equations Ordinary Differential Equations Polynomials Trigonometric functions
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description	Addition formulas exist in trigonometric functions. Double-angle and half-angle formulas can be derived from these formulas. Moreover, the relation equation between the trigonometric function and the hyperbolic function can be derived using an imaginary number. The inverse hyperbolic function arsinh(r) - ∫r0 1/√1+t2dt is similar to the inverse trigonometric function arsinh(r) - ∫r0 1/√1-t2dt, such as the second degree of a polynomial and the constant term 1, except for the sign - and +. Such an analogy holds not only when the degree of the polynomial is 2, but also for higher degrees. As such, a function exists with respect to the leaf function through the imaginary number i, such that the hyperbolic function exists with respect to the trigonometric function through this imaginary number. In this study, we refer to this function as the hyperbolic leaf function. By making such a defi nition, the relation equation between the leaf function and the hyperbolic leaf function makes it possible to easily derive various formulas, such as addition formulas of hyperbolic leaf functions based on the addition formulas of leaf functions. Using the addition formulas, we can also derive the double-angle and half-angle formulas. We then verify the consistency of these formulas by constructing graphs and numerical data.
doi_str_mv	10.32604/cmes.2020.08656
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Double-angle and half-angle formulas can be derived from these formulas. Moreover, the relation equation between the trigonometric function and the hyperbolic function can be derived using an imaginary number. The inverse hyperbolic function arsinh(r) - ∫r0 1/√1+t2dt is similar to the inverse trigonometric function arsinh(r) - ∫r0 1/√1-t2dt, such as the second degree of a polynomial and the constant term 1, except for the sign - and +. Such an analogy holds not only when the degree of the polynomial is 2, but also for higher degrees. As such, a function exists with respect to the leaf function through the imaginary number i, such that the hyperbolic function exists with respect to the trigonometric function through this imaginary number. In this study, we refer to this function as the hyperbolic leaf function. By making such a defi nition, the relation equation between the leaf function and the hyperbolic leaf function makes it possible to easily derive various formulas, such as addition formulas of hyperbolic leaf functions based on the addition formulas of leaf functions. Using the addition formulas, we can also derive the double-angle and half-angle formulas. 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Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.</rights><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c370t-299a6b01e2b43e3eabb31a3fec846899b865db21c8d72753bc411ff031f358e83</citedby></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27924,27925</link.rule.ids></links><search><creatorcontrib>Shinohara, Kazunori</creatorcontrib><title>Addition Formulas of Leaf Functions and Hyperbolic Leaf Functions</title><title>Computer modeling in engineering & sciences</title><description>Addition formulas exist in trigonometric functions. Double-angle and half-angle formulas can be derived from these formulas. Moreover, the relation equation between the trigonometric function and the hyperbolic function can be derived using an imaginary number. The inverse hyperbolic function arsinh(r) - ∫r0 1/√1+t2dt is similar to the inverse trigonometric function arsinh(r) - ∫r0 1/√1-t2dt, such as the second degree of a polynomial and the constant term 1, except for the sign - and +. Such an analogy holds not only when the degree of the polynomial is 2, but also for higher degrees. As such, a function exists with respect to the leaf function through the imaginary number i, such that the hyperbolic function exists with respect to the trigonometric function through this imaginary number. In this study, we refer to this function as the hyperbolic leaf function. 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By making such a defi nition, the relation equation between the leaf function and the hyperbolic leaf function makes it possible to easily derive various formulas, such as addition formulas of hyperbolic leaf functions based on the addition formulas of leaf functions. Using the addition formulas, we can also derive the double-angle and half-angle formulas. We then verify the consistency of these formulas by constructing graphs and numerical data.</abstract><cop>Henderson</cop><pub>Tech Science Press</pub><doi>10.32604/cmes.2020.08656</doi><tpages>33</tpages><oa>free_for_read</oa></addata></record>
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source	Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; Tech Science Press
subjects	Hyperbolic functions Hyperbolic Leaf Functions Jacobi Elliptic Functions Leaf Functions Lemniscate Functions Mathematical analysis Nonlinear Equations Ordinary Differential Equations Polynomials Trigonometric functions
title	Addition Formulas of Leaf Functions and Hyperbolic Leaf Functions
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