Partial Variable Stability for a Class of Nonlinear Systems with Time Delay

This article first gives a new class of integral inequalities. Then, as an application, the nonlinear neutral differential system with multiple delays is considered, and the trivial solution of the nonlinear neutral system with multiple delays is obtained. Uniform asymptotic Lipschitz stability. Obviously, the above system is a generalization of the traditional differential system. The purpose of this paper is to study the dual stability of neutral differential equations with delays, including equal asymptotically Lipschitz stability and uniformly asymptotic Lipschitz stability. The author uses the method of integral inequality to establish a double stability criterion. As a result, the local stability of differential equations is widely used in theory and practice, such as dynamic systems and control systems.


Introduction
In 1892, Lyapunov, a Russian mathematician, mechanician and physicist, proposed the notion of the stability of motion. He gave the general research methods in his doctoral dissertation "The general problem of the stability of motion" [1], in which he established the foundation of the stability theory. When studying nonlinear systems, especially studying dynamic systems or control systems, we cannot study the stability of all variables because of the technology difficulties, the limitation of practical conditions, or it is not necessary to study all variables considering the actual need. As a result, studying the partial stability of differential equations becomes more important. In addition, the partial stability is widely In 2009, the author discussed a new class of inequalities in [4].
Vorotnikov, V.I. [5] [6] considered the following system In 2002, Wang Feng used the differential inequality of delay in article [7] to study the following delay system:

, d y A t y B t z Y t y z t z C t y D t z Z t y z t
In 2006, Siligeng used the integral inequality extended in [3] in [8] to discuss the double stability of the following system to some variables: In this paper the author consider a new class of the nonlinearly perturbed differential systems with time-delay It is obvious that the above system is a generalization of the systems in [5] [6] [7] [8].
The aim of this paper is to investigate the double stability of neutural differential equations, including Uniform stability and Uniform Lipschitz stability. The author uses the method of differential inequalities with time-delay and integral inequalities to establish double stability criteria.

Preliminaries
Consider the following system: Definition 1 [9] [10] [11] The trivial solution of system (1) has uniform stability and exponential asymptotic stability with respect to y if, for [11] The trivial solution of system (1) has Lipschitz stability with respect to y if, there exists constants  [9] [10] [11] The trivial solution of system (1) has uniform exponential Lipschitz asymptotic stability with respect to y if, K and 0 δ > in definition 3 are ndependent of 0 t .
Lemma 1 [4] The following conditions are established on  are non-negative continuous function on R + , and:  are all constants greater than 1, and

y B t y C t z t Y s y s z s h s y s z s y s z s s z D t y E t z t Z s y s z s h s y s z s y s z s s
where 0 τ ≥ is a constant, initial condition is:

t a t b t b t c t c t d t d t i I
1) when λ ε > , the trivial solution of (2) is LS , q GE ELAS with respect to y; 2) when λ ε = , the trivial solution of (2) is, GUELAS with respect to.
Proof Apply constant variation method to system (2), it can be deduced that:   Note: The differential system discussed in this paper is the time-differential form of the ordinary differential system in [5] [6]. The time-differential system in [7] is generalized to a neutral system, and the Lipschitz stability in [8] is further extended to equi-exponential Lipschitz asymptotic stability and uniform exponential Lipschitz asymptotic stability and added global results

Conclusion
In this paper, we use the method of integral inequalities to establish double stability criteria. As a result, studying the partial stability of differential equations becomes more important. In addition, the partial stability of differential equations is widely used in science and technology.