Nonoscillation, maximum principles, and exponential stability of second order delay differential equations without damping term

Research output: Contribution to journalArticlepeer-review

22 Scopus citations

Abstract

Delays, arising in nonoscillatory and stable ordinary differential equations, can induce oscillation and instability of their solutions. That is why the traditional direction in the study of nonoscillation and stability of delay equations is to establish a smallness of delay, allowing delay differential equations to preserve these convenient properties of ordinary differential equations with the same coefficients. In this paper, we find cases in which delays, arising in oscillatory and asymptotically unstable ordinary differential equations, induce nonoscillation and stability of delay equations. We demonstrate that, although the ordinary differential equation (Formula presented.) can be oscillating and asymptotically unstable, the delay equation (Formula presented.), where (Formula presented.), can be nonoscillating and exponentially stable. Results on nonoscillation and exponential stability of delay differential equations are obtained. On the basis of these results on nonoscillation and stability, the new possibilities of non-invasive (non-evasive) control, which allow us to stabilize a motion of single mass point, are proposed. Stabilization of this sort, according to common belief, requires a damping term in the second order differential equation. Results obtained in this paper refute this delusion.

Original languageEnglish
Article number361
JournalJournal of Inequalities and Applications
Volume2014
Issue number1
DOIs
StatePublished - 22 Dec 2014

Keywords

  • Cauchy function
  • differential inequalities
  • exponential stability
  • maximum principles
  • nonoscillation
  • positivity of solutions
  • positivity of the Cauchy function
  • stabilization

Fingerprint

Dive into the research topics of 'Nonoscillation, maximum principles, and exponential stability of second order delay differential equations without damping term'. Together they form a unique fingerprint.

Cite this