In the paper we study the question of the solvability and unique solvability of systems of the higher order differential equations with the argument deviations \begin{equation*} u_i^{(m_i)}(t)=p_i(t)u_{i+1}(\tau _{i}(t))+ q_i(t), (i=\overline {1, n}), \text {for $t\in I:=[a, b]$}, \end{equation*} and \begin{equation*}u_i^{(m_i)} (t)=F_{i}(u)(t)+q_{0i}(t), (i = \overline {1, n}), \text {for $ t\in I$}, \end{equation*} under the conjugate $u_i^{(j_1-1)}(a)=a_{i j_1}$, $u_i^{(j_2-1)}(b)=b_{i j_2}$, $j_1=\overline {1, k_i}$, $j_2=\overline {1, m_i-k_i}$, $i=\overline {1, n}$, and the right-focal $u_i^{(j_1-1)}(a)=a_{i j_1}$, $u_i^{(j_2-1)}(b)=b_{i j_2}$, $j_1=\overline {1, k_i}$, $j_2=\overline {k_i+1,m_i}$, $i=\overline {1, n}$, boundary condi...
In this article, we study the differential equation $$ (-1)^{n-p} x^{(n)}(t)=f(t,x(t),x'(t),dots,x^{...
In the paper we study the question of solvability and unique solvability of systems of the higher-or...
We consider the problem u′(t)=H(u)(t) +Q(u)(t), u(a) = h(u), whereH,Q: C([a,b];R) → L([a,b];R) are, ...
For strongly singular higher-order linear differential equations together with two-point conjugate a...
AbstractWe gain solvability of a system of nonlinear, second-order ordinary differential equations s...
summary:Consider boundary value problems for a functional differential equation $$\begin {cases} x^{...
In this thesis the following contributions are made to the general theory of boundary value problems...
We establish sufficient conditions for the existence of positive solutions to five multi-point bou...
summary:Two point boundary value problem for the linear system of ordinary differential equations wi...
summary:We establish new efficient conditions sufficient for the unique solvability of the initial v...
AbstractUnder suitable conditions on f(t,y(t+θ)), the boundary value problem of higher-order functio...
For strongly singular higher-order linear differential equations together with two-point conjugate a...
Sharp conditions are obtained for the unique solvability of focal boundary value problems for higher...
AbstractBy means of Mawhin's continuation theorem, we study m-point boundary value problem at resona...
AbstractIn this note we prove an existence theorem for the two-point problemu(m)t=ft,ut,…,u(m−1)t+∑k...
In this article, we study the differential equation $$ (-1)^{n-p} x^{(n)}(t)=f(t,x(t),x'(t),dots,x^{...
In the paper we study the question of solvability and unique solvability of systems of the higher-or...
We consider the problem u′(t)=H(u)(t) +Q(u)(t), u(a) = h(u), whereH,Q: C([a,b];R) → L([a,b];R) are, ...
For strongly singular higher-order linear differential equations together with two-point conjugate a...
AbstractWe gain solvability of a system of nonlinear, second-order ordinary differential equations s...
summary:Consider boundary value problems for a functional differential equation $$\begin {cases} x^{...
In this thesis the following contributions are made to the general theory of boundary value problems...
We establish sufficient conditions for the existence of positive solutions to five multi-point bou...
summary:Two point boundary value problem for the linear system of ordinary differential equations wi...
summary:We establish new efficient conditions sufficient for the unique solvability of the initial v...
AbstractUnder suitable conditions on f(t,y(t+θ)), the boundary value problem of higher-order functio...
For strongly singular higher-order linear differential equations together with two-point conjugate a...
Sharp conditions are obtained for the unique solvability of focal boundary value problems for higher...
AbstractBy means of Mawhin's continuation theorem, we study m-point boundary value problem at resona...
AbstractIn this note we prove an existence theorem for the two-point problemu(m)t=ft,ut,…,u(m−1)t+∑k...
In this article, we study the differential equation $$ (-1)^{n-p} x^{(n)}(t)=f(t,x(t),x'(t),dots,x^{...
In the paper we study the question of solvability and unique solvability of systems of the higher-or...
We consider the problem u′(t)=H(u)(t) +Q(u)(t), u(a) = h(u), whereH,Q: C([a,b];R) → L([a,b];R) are, ...