The Least Possible Impulse for Oscillating All Nontrivial Solutions of Second-Order Nonoscillatory Differential Equations
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Jitsuro Sugie [1]
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[1] Shimane University
Shimane University
Japón
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- Localización: Qualitative theory of dynamical systems, ISSN 1575-5460, Vol. 21, Nº 2, 2022
- Idioma: inglés
- Enlaces
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Resumen
Nonoscillatory solutions of second-order linear differential equations with a parameter may become oscillatory with variations in the parameter. Such equations are termed as conditionally oscillatory equations and are classified according to the result established by Einar Hille, wherein Euler-type differential equations are used as scale marks for classification. Moreover, nonoscillatory solutions can be converted into oscillatory solutions by introducing impulse. Thus, this research determines the least possible amount of impulse required to oscillate all nonoscillatory solutions for each classified group of conditionally oscillatory equations without altering the parameter. Presumably, nonoscillatory solutions can be expected to oscillate when a large amount of impulse is added. Therefore, the focus of this paper is to calculate the least possible amount of impulse required for the stated change. A result derived from a Philos-type oscillation theorem for impulsive differential equations is used to establish the proofs.
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