We give an explicit formula for the general solution of a one dimensional linear delay differential equation with multiple delays, which are integer multiples of the smallest delay. For an equation of this class with two delays, we derive two equations with single delays, whose stability is sufficient for the stability of the equation with two delays. This presents a new approach to the study of the stability of such systems. This approach avoids requirement of the knowledge of the location of the characteristic roots of the equation with multiple delays which are generally more difficult to determine, compared to the location of the characteristic roots of equations with a single delay
summary:We propose a new method for studying stability of second order delay differential equations....
We provide explicit conditions for uniform stability, global asymptotic stability and uniform expone...
This note is concerned with stability properties of linear time-invariant delay systems. We consider...
We give an explicit formula for the general solution of a one dimensional linear delay differential ...
AbstractNew explicit conditions of exponential stability are obtained for the nonautonomous equation...
AbstractThis paper deals with the stability analysis of numerical methods for the solution of delay ...
In this paper, we consider the asymptotic stability for the system of linear delay differential equa...
AbstractFor linear delay differential and difference equations with one coefficient matrix A, we giv...
AbstractA formula is given that counts the number of roots in the positive half plane of the charact...
Consider the linear differential equation x(t)= Σi=1npi(t)x(t-ti)=0, t≥t0where p C([t0∞), R) and ti\...
AbstractConsider the following two-dimensional delay differential equation (DDE) u′(t)=a1u(t)+b1v(t–...
AbstractNew explicit conditions of exponential stability are obtained for the nonautonomous linear e...
The paper investigates the exponential stability and exponential estimate of the norms of solutions ...
We study a linear delay differential equation with a single positive and a single negative term. We ...
The method and the formula of variation of constants for ordinary differential equations (ODEs) is a...
summary:We propose a new method for studying stability of second order delay differential equations....
We provide explicit conditions for uniform stability, global asymptotic stability and uniform expone...
This note is concerned with stability properties of linear time-invariant delay systems. We consider...
We give an explicit formula for the general solution of a one dimensional linear delay differential ...
AbstractNew explicit conditions of exponential stability are obtained for the nonautonomous equation...
AbstractThis paper deals with the stability analysis of numerical methods for the solution of delay ...
In this paper, we consider the asymptotic stability for the system of linear delay differential equa...
AbstractFor linear delay differential and difference equations with one coefficient matrix A, we giv...
AbstractA formula is given that counts the number of roots in the positive half plane of the charact...
Consider the linear differential equation x(t)= Σi=1npi(t)x(t-ti)=0, t≥t0where p C([t0∞), R) and ti\...
AbstractConsider the following two-dimensional delay differential equation (DDE) u′(t)=a1u(t)+b1v(t–...
AbstractNew explicit conditions of exponential stability are obtained for the nonautonomous linear e...
The paper investigates the exponential stability and exponential estimate of the norms of solutions ...
We study a linear delay differential equation with a single positive and a single negative term. We ...
The method and the formula of variation of constants for ordinary differential equations (ODEs) is a...
summary:We propose a new method for studying stability of second order delay differential equations....
We provide explicit conditions for uniform stability, global asymptotic stability and uniform expone...
This note is concerned with stability properties of linear time-invariant delay systems. We consider...