Difference between revisions of "Neutral differential equation"
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A differential equation with distributed argument (cf. [[Differential equations, ordinary, with distributed arguments|Differential equations, ordinary, with distributed arguments]]) in which the highest derivative occurs for more than one value of the argument, among them a basic (untransformed) one, and this latter value is the largest of those present in the equation. For example, the equation | A differential equation with distributed argument (cf. [[Differential equations, ordinary, with distributed arguments|Differential equations, ordinary, with distributed arguments]]) in which the highest derivative occurs for more than one value of the argument, among them a basic (untransformed) one, and this latter value is the largest of those present in the equation. For example, the equation | ||
| − | + | $$x'(t)=f(t,x(\alpha(t)),x'(\beta(t)))\tag{*}$$ | |
| − | is a neutral differential equation when | + | is a neutral differential equation when $\alpha(t)\leq t$, $\beta(t)\leq t$. |
| − | For a neutral differential equation the initial value problem is solvable; thus, if for | + | For a neutral differential equation the initial value problem is solvable; thus, if for \ref{*} with increasing $\beta(t)$ one gives |
| − | + | $$x=\phi(t),\quad t\leq t_0,$$ | |
then for | then for | ||
| − | + | $$f\in C^{m,n,n},\quad\alpha,\beta\in C^m,\quad\phi\in C^p,\quad m,n\geq0,p\geq1,$$ | |
| − | there exists a (for | + | there exists a (for $n\geq1$ unique) piecewise-smooth solution, which belongs to $C^k$ when $k=1+\min\{m,n,p-1\}$ compatibility conditions hold, that is, conditions of the type |
| − | + | $$\phi'(t_0)=f(t_0,\phi(\alpha(t_0)),\phi'(\beta(t_0))).$$ | |
Neutral differential equations are one of the most thoroughly studied classes of equations with distributed arguments. They occur naturally in applied problems that contain in their statement some recurrence property. | Neutral differential equations are one of the most thoroughly studied classes of equations with distributed arguments. They occur naturally in applied problems that contain in their statement some recurrence property. | ||
Revision as of 12:26, 7 September 2014
A differential equation with distributed argument (cf. Differential equations, ordinary, with distributed arguments) in which the highest derivative occurs for more than one value of the argument, among them a basic (untransformed) one, and this latter value is the largest of those present in the equation. For example, the equation
$$x'(t)=f(t,x(\alpha(t)),x'(\beta(t)))\tag{*}$$
is a neutral differential equation when $\alpha(t)\leq t$, $\beta(t)\leq t$.
For a neutral differential equation the initial value problem is solvable; thus, if for \ref{*} with increasing $\beta(t)$ one gives
$$x=\phi(t),\quad t\leq t_0,$$
then for
$$f\in C^{m,n,n},\quad\alpha,\beta\in C^m,\quad\phi\in C^p,\quad m,n\geq0,p\geq1,$$
there exists a (for $n\geq1$ unique) piecewise-smooth solution, which belongs to $C^k$ when $k=1+\min\{m,n,p-1\}$ compatibility conditions hold, that is, conditions of the type
$$\phi'(t_0)=f(t_0,\phi(\alpha(t_0)),\phi'(\beta(t_0))).$$
Neutral differential equations are one of the most thoroughly studied classes of equations with distributed arguments. They occur naturally in applied problems that contain in their statement some recurrence property.
Comments
References
| [a1] | J.K. Hale, "Theory of functional differential equations" , Springer (1977) pp. Chapt. 12 |
Neutral differential equation. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Neutral_differential_equation&oldid=11961