Example of a differential system with complete Perron and upper-limit instability but massive partial stability (Q2135097)

In this paper, the author coniders the following system: \[ \dot{x} = f(t,x),~~~t\in\mathbb{R}_+\equiv [0,\infty),~~~x\in G, \] with right-hand side \(f:\mathbb{R}_+\times G\rightarrow \mathbb{R}^n\) satisfying the conditions \(f, f'_x\in C(\mathbb{R}_+\times G, \mathbb{R}^n)\) and \(f(t,0)=0\), \(t\in\mathbb{R}^+\), so that the system has a zero solution. Here \(G \subset \mathbb{R}^n\) (with the norm \(|\cdot|\)) contains the origin. Firstly, some of the results on Perron stability that are available in the literature are briefly mentioned. Then, the author strengthens these results for the system given above. Indeed, in this paper, one theorem is established, and its complete proof is also given. The main idea of the theorem is that to prove the existence of a differential system such that, first, all solutions starting sufficiently close to the origin tend to infinity in the norm as t tends to infinity, so that the system above has complete instability (both Perron and upper-limit); second, all other solutions tend to zero, so that the system, nevertheless, does not have global instability (Perron or upperlimit), or, which is the same, the system has partial stability, which is not only partial but even massive.