Power function and binomial series on T(q-h)
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Date
2023
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TAYLOR & FRANCIS LTD
Open Access Color
GOLD
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Abstract
This article is devoted to present (q h) -analogue of power function which satisfies additivity and derivative properties similar to the ordinary power function. In the light of nabla (q h) -power function we present (q h)-analogue of binomial series and conclude that such power function is (q h)-analytic. We prove the analyticity by showing that both the power function and its absolutely convergent Taylor series solve the same IVP. Finally we present the reductions of (q h)-binomial series to classical binomial series Gauss' binomial and Newton's binomial formulas.
Description
Keywords
Nabla generalized quantum binomial, nabla (q h)-power function, (q h)-analytic functions, nabla (q h)-binomial series, Newton's binomial formula, Gauss' binomial formula, Nabla -Binomial Series, Nabla (q, h)-Binomial Series, (Q, h)-Analytic Functions, Newton’s Binomial Formula, Nabla -Power Function, Gauss’ Binomial Formula, Nabla Generalized Quantum Binomial, -Analytic Functions, Nabla (q, h)-Power Function, nabla generalized quantum binomial, Engineering (General). Civil engineering (General), nabla $ (q, h) $ -power function, nabla $ (q, h) $ -binomial series, QA1-939, newton's binomial formula, gauss' binomial formula, TA1-2040, $ (q, h) $ -analytic functions, Mathematics
Fields of Science
02 engineering and technology, 01 natural sciences, 0101 mathematics, 0210 nano-technology
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OpenCitations Citation Count
1
Source
Applied Mathematics in Science and Engineering
Volume
31
Issue
1
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