Chaplygin's theorem

Consider an initial value problem: differential equation

${\displaystyle y'\left(t\right)=f\left(t,y\left(t\right)\right)}$  in ${\displaystyle t\in \left[t_{0};\alpha \right]}$ , ${\displaystyle \alpha >t_{0}}$ 

with an initial condition

${\displaystyle y\left(t_{0}\right)=y_{0}}$ .

For the initial value problem described above the upper boundary solution and the lower boundary solution are the functions ${\displaystyle {\overline {z}}\left(t\right)}$  and ${\displaystyle {\underline {z}}\left(t\right)}$  respectively, both of which are smooth in ${\displaystyle t\in \left(t_{0};\alpha \right]}$  and continous in ${\displaystyle t\in \left[t_{0};\alpha \right]}$ , such as the following inequalities are true:

1. ${\displaystyle {\underline {z}}\left(t_{0}\right)<y\left(t_{0}\right)<{\overline {z}}\left(t_{0}\right)}$ ;
2. ${\displaystyle {\underline {z}}'\left(t\right)<f(t,{\underline {z}}\left(t\right))}$  and ${\displaystyle {\overline {z}}\ '\left(t\right)>f(t,{\overline {z}}\left(t\right))}$  for ${\displaystyle t\in \left(t_{0};\alpha \right]}$ .

Given the aforementioned initial value problem and respective upper boundary solution ${\displaystyle {\overline {z}}\left(t\right)}$  and lower boundary solution ${\displaystyle {\underline {z}}\left(t\right)}$  for ${\displaystyle t\in \left[t_{0};\alpha \right]}$ . If the right part ${\displaystyle f\left(t,y\left(t\right)\right)}$ 

1. is continous in ${\displaystyle t\in \left[t_{0};\alpha \right]}$ , ${\displaystyle y\left(t\right)\in \left[{\underline {z}}\left(t\right);{\overline {z}}\left(t\right)\right]}$ ;
2. satisfies the Lipschitz condition over variable ${\displaystyle y}$  between functions ${\displaystyle {\overline {z}}\left(t\right)}$  and ${\displaystyle {\underline {z}}\left(t\right)}$ : there exists constant ${\displaystyle K>0}$  such as for every ${\displaystyle t\in \left[t_{0};\alpha \right]}$ , ${\displaystyle y_{1}\left(t\right)\in \left[{\underline {z}}\left(t\right);{\overline {z}}\left(t\right)\right]}$ , ${\displaystyle y_{2}\left(t\right)\in \left[{\underline {z}}\left(t\right);{\overline {z}}\left(t\right)\right]}$  the inequality

${\displaystyle \left\vert f\left(t,y_{1}\left(t\right)\right)-f\left(t,y_{2}\left(t\right)\right)\right\vert \leq K\left\vert y_{1}\left(t\right)-y_{2}\left(t\right)\right\vert }$  holds,

then in ${\displaystyle t\in \left[t_{0};\alpha \right]}$  there exists one and only one solution ${\displaystyle y\left(t\right)}$  for the given initial value problem and moreover for all ${\displaystyle t\in \left[t_{0};\alpha \right]}$ 

${\displaystyle {\underline {z}}\left(t\right)<y\left(t\right)<{\overline {z}}\left(t\right)}$ .

Inside inequalities within both of definitions of the upper boundary solution and the lower boundary solution signs of inequalities (all at once) can be altered to unstrict. As a result, inequalities sings at Chaplygin's theorem concusion would change to unstrict by ${\displaystyle {\overline {z}}\left(t\right)}$  and ${\displaystyle {\underline {z}}\left(t\right)}$  respectively. In particular, any of ${\displaystyle {\overline {z}}\left(t\right)=y\left(t\right)}$ , ${\displaystyle {\underline {z}}\left(t\right)=y\left(t\right)}$  could be chosen.

If ${\displaystyle y\left(t\right)}$  is already known to be an existent soltion for the initial value problem in ${\displaystyle t\in \left[t_{0};\alpha \right]}$ , the Lipschitz condition requirement can be omitted entirely for proving the resulting inequality. There exists applications for this method while researching whether the solution is stable or not (^[2], pp. 7–9). This is often called "Differential inequality method" in literature^[4][5] and, for example, Grönwall's inequality can be proven using this technique.^[5]

Chaplygin's theorem answers the question about existence and uniqueness of the solution in ${\displaystyle t\in \left[t_{0};\alpha \right]}$  and the constant ${\displaystyle K}$  from the Lipschitz condition is, generally speaking, dependent on ${\displaystyle \alpha }$ : ${\displaystyle K=K\left(\alpha \right)}$ . If for ${\displaystyle t\in \left[t_{0};+\infty \right)}$  both functions ${\displaystyle {\overline {z}}\left(t\right)}$  and ${\displaystyle {\underline {z}}\left(t\right)}$  retain their smoothness and for ${\displaystyle \alpha \in \left(t_{0};+\infty \right)}$  a set ${\displaystyle \left\{K\left(\alpha \right)\right\}}$  is bounded, the theorem holds for all ${\displaystyle t\in \left[t_{0};+\infty \right)}$ .

• Komlenko, Yuriy. (1967-09-01). "Chaplygin's theorem for a second-order linear differential equation with lagging argument". p. 666–669.^[1]