Instability of solutions for certain nonlinear vector differential equations of fourth order

Instability of solutions for certain nonlinear vector differential equations of fourth order

The main purpose of this paper is to give a result with an explanatory example which deals directly with the instability of the trivial solution of a certain nonlinear vector differential equation of fourth order. The result which will be established here improves and includes a well-known instabi...

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Дата:2009
Автор: Tunç, C.
Формат: Стаття
Мова:English
Опубліковано: Інститут математики НАН України 2009
Назва видання:Нелінійні коливання
Онлайн доступ:https://nasplib.isofts.kiev.ua/handle/123456789/178387
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Цитувати:Instability of solutions for certain nonlinear vector differential equations of fourth order / C. Tunç // Нелінійні коливання. — 2009. — Т. 12, № 1. — С. 120-129. — Бібліогр.: 15 назв. — англ.

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spelling nasplib_isofts_kiev_ua-123456789-1783872025-02-09T20:47:06Z Instability of solutions for certain nonlinear vector differential equations of fourth order Нестійкість розв’язків деяких нелінійних векторних рівнянь четвертого порядку Неустойчивость решений некоторых нелинейных векторных уравнений четвёртого порядка Tunç, C. The main purpose of this paper is to give a result with an explanatory example which deals directly with the instability of the trivial solution of a certain nonlinear vector differential equation of fourth order. The result which will be established here improves and includes a well-known instability result in the literature established for a scalar nonlinear differential equation of fourth order. Отримано результат iз пояснювальним прикладом про нестiйкiсть тривiального розв’язку деякого нелiнiйного векторного диференцiального рiвняння четвертого порядку, що покращує вiдомий результат про нестiйкiсть для скалярного диференцiального рiвняння четвертого порядку. 2009 Article Instability of solutions for certain nonlinear vector differential equations of fourth order / C. Tunç // Нелінійні коливання. — 2009. — Т. 12, № 1. — С. 120-129. — Бібліогр.: 15 назв. — англ. 1562-3076 https://nasplib.isofts.kiev.ua/handle/123456789/178387 517.9 en Нелінійні коливання application/pdf Інститут математики НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description The main purpose of this paper is to give a result with an explanatory example which deals directly with the instability of the trivial solution of a certain nonlinear vector differential equation of fourth order. The result which will be established here improves and includes a well-known instability result in the literature established for a scalar nonlinear differential equation of fourth order.
format Article
author Tunç, C.
spellingShingle Tunç, C.
Instability of solutions for certain nonlinear vector differential equations of fourth order
Нелінійні коливання
author_facet Tunç, C.
author_sort Tunç, C.
title Instability of solutions for certain nonlinear vector differential equations of fourth order
title_short Instability of solutions for certain nonlinear vector differential equations of fourth order
title_full Instability of solutions for certain nonlinear vector differential equations of fourth order
title_fullStr Instability of solutions for certain nonlinear vector differential equations of fourth order
title_full_unstemmed Instability of solutions for certain nonlinear vector differential equations of fourth order
title_sort instability of solutions for certain nonlinear vector differential equations of fourth order
publisher Інститут математики НАН України
publishDate 2009
url https://nasplib.isofts.kiev.ua/handle/123456789/178387
citation_txt Instability of solutions for certain nonlinear vector differential equations of fourth order / C. Tunç // Нелінійні коливання. — 2009. — Т. 12, № 1. — С. 120-129. — Бібліогр.: 15 назв. — англ.
series Нелінійні коливання
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AT tuncc neustoičivostʹrešeniinekotoryhnelineinyhvektornyhuravneniičetvertogoporâdka
first_indexed 2025-11-30T15:37:05Z
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fulltext UDC 517 . 9 INSTABILITY OF SOLUTIONS FOR CERTAIN NONLINEAR VECTOR DIFFERENTIAL EQUATIONS OF FOURTH ORDER НЕСТIЙКIСТЬ РОЗВ’ЯЗКIВ ДЕЯКИХ НЕЛIНIЙНИХ ВЕКТОРНИХ РIВНЯНЬ ЧЕТВЕРТОГО ПОРЯДКУ C. Tunç Yüzüncü Yil Univ. 65080, Van – Turkey e-mail: cemtunc@yahoo.com The main purpose of this paper is to give a result with an explanatory example which deals directly with the instability of the trivial solution of a certain nonlinear vector differential equation of fourth order. The result which will be established here improves and includes a well-known instability result in the literature established for a scalar nonlinear differential equation of fourth order. Отримано результат iз пояснювальним прикладом про нестiйкiсть тривiального розв’язку де- якого нелiнiйного векторного диференцiального рiвняння четвертого порядку, що покращує вiдомий результат про нестiйкiсть для скалярного диференцiального рiвняння четвертого по- рядку. 1. Introduction. As is well-known, the area of differential equations is an old but durable subject that remains alive and useful to a wide variety of engineers, scientists, and mathematicians. The principles of differential equations are largely about the qualitative theory of ordinary differential equations. Qualitative theory refers to the study of the behavior of solutions, for example the investigation of stability, instability, boundedness of solutions and etc., without determining explicit formulas for the solutions. It originated with Poincare at the beginning of the twentieth century and has been the most important theme of ordinary differential equati- ons in that century. During this period, very little attention is paid to techniques for finding analytic formulas for solutions. That is to say, there are actually very few equations (beyond linear equations with constant-coefficient and even there are difficulties if the order of the equation or system is high) for which we can do this. Therefore, it is very important to interpret qualitative behavior of solutions when there is no analytical expression for the solutions of any differential equation under investigation. So far, in the relevant literature, some methods have been improved to obtain information about qualitative behaviors of solutions of differential equations without solving them. Among them the Lyapunov’s [1] second (or direct) method is most well-known. Namely, Lyapunov’s second (or direct) method is one of the basic tools for investigating the qualitative behavior of solutions; stability, instability, boundedness, existence of periodic solutions and etc. of nonlinear differential equations of higher order. During the past fifty year, by using Lyapunov’s [1] second (or direct) method, throughout hundreds of the papers, qualitative behaviors of solutions, stability, instability, boundedness, existence of peri- odic solutions and etc. for various ordinary scalar or vector nonlinear differential equations of second-, third-, fourth-, fifth-, sixth-, seventh- and eighth-order have been investigated extensi- vely in the relevant literature. However, we will not discuss details of these works here. Now, c© C. Tunç, 2009 120 ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1 INSTABILITY OF SOLUTIONS FOR CERTAIN NONLINEAR VECTOR DIFFERENTIAL . . . 121 we consider the constant-coefficient fourth order scalar differential equation x(4) + a1 ... x + a2ẍ+ a3ẋ+ a4x = 0. (1) As we know from the qualitative theory of ordinary differential equations that the trivial soluti- on of the equation (1) is unstable if the associated (auxiliary) equation ψ(r) = r4 + a1r 3 + a2r 2 + a3r + a4 = 0 (2) has at the least one root with a positive real part. Naturally, the existence of such a root depends on (though not always on all of) the coefficients a1, a2, a3 and a4 of equation (2). The correspon- ding auxiliary equation (2) of equation (1) has no purely imaginary roots r = iλ (λ 6= 0) if X1 ≡ λ4 − a2λ 2 + a4 6= 0 or if X2 ≡ a1λ 2 − a3 6= 0. Note that X1 may be rearranged in the form X1 = ( λ2 − 1 2 a2 )2 + a4 − 1 2 a2 2 so that X1 6= 0 holds if, for example, a4 > 1 4 a2 2. It is also easy to see that X2 6= 0 will hold if a1a3 < 0, a4 6= 0, where the condition on a4 here being necessary in order to ensure that λ 6= 0. It should also be noted that it was shown in Ezeilo [2] that the existence of the relation a4 > 1 4 a2 2 between the coefficients a2 and a4 of the equation (1) is a sufficient condition that guarantees that the trivial solution x = 0 of the equation (1) is unstable. The above preamble is merely intended to give a background to the assumptions which play a dominant role in our treatment here and to give some indication of how these assumptions stand with respect to the Routh – Hurwitz criteria. Now, the objective of this paper is to study the instability of the trivial solution X = 0 of nonlinear vector differential equations of the form X(4) + Ψ(Ẍ) ... X +G ( X, Ẋ, Ẍ, ... X ) Ẍ + Θ(Ẋ) + F (X) = 0, (3) in which X ∈ R n; Ψ and G are continuous (n × n)-symmetric matrix-valued functions for the variables indicated explicitly; Θ : R n → R n, F : R n → R n and Θ(0) = F (0) = 0, and it is also supposed that the functions Θ and F are continuous for allX, Ẋ ∈ R n, respectively. In this case, the equation (3) can be rewritten as Ẋ = Y, Ẏ = Z, Ż = W, (4) Ẇ = −Ψ(Z)W −G(X,Y,Z,W )Z − Θ(Y ) − F (X), ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1 122 C. TUNÇ which was obtained by taking Ẋ = Y, Ẍ = Z, ... X = W in the equation (3). Now, let J(Ψ(Z)Z|Z), JΘ(Y ) and JF (X), respectively, denote the linear operators from the matrix Ψ(Z) and vectors Θ(Y ) and F (X) to the matrices J(Ψ(Z)Z|Z) = ( ∂ ∂zj n ∑ k=1 ψikzk ) = Ψ(Z) + ( n ∑ k=1 ∂ψik ∂zj zk ) , JΘ(Y ) = ( ∂θi ∂yj ) , JF (X) = ( ∂fi ∂xj ) , i, j = 1, 2, . . . , n, where (x1, x2, . . . , xn), (y1, y2, . . . , yn), (z1, z2, . . . , zn), (ψik), (θ1, θ2, . . . , θn) and (f1, f2, . . . , fn) are components ofX, Y, Z,Ψ,Θ and F, respectively. Furthermore, it is also assumed throughout this paper that F (X) and Θ(Ẋ) are gradient vector fields and the matrices JF (X), JΘ(Y ) and J(Ψ(Z)Z|Z) exist and are symmetric and continuous. It is also worth mentioning that although a substantial amount of results have been publi- shed with regard to stability of certain nonlinear differential equations of fourth order, comparati- vely only a few results have been published which deal directly with the instability of solutions of certain differential equations of fourth order. In particular, one can refer to the book of Reissig et al. [3] as a survey for some papers published on the stability of solutions of certain differential equations of fourth order and the papers of Ezeilo [2, 4, 5], Lu and Liao [6], Sadek [7], Skrapek [8], Tiryaki [9], Tunç [10 – 12], C. Tunç and E. Tunç [13] and references cited there for some investigations performed on the instability of solutions of certain fourth order linear and nonlinear differential equations. Now, to the best of our knowledge, so far in the relevant literature, the papers performed on the instability of solutions scalar differential equations of fourth order can be summarized as follows. First, in 1978, Ezeilo [2] has carried out a work on the instability of the trivial solution of the fourth-order scalar differential equation x(4) + a1 ... x + a2ẍ+ a3ẋ+ f(x) = 0. In 1979, Ezeilo [4] also extended his aforementioned instability result in [2] to a much more general scalar differential equation given by x(4) + a1 ... x + h(x, ẋ, ẍ, ... x) ẍ+ g(x) ẋ+ f(x) = 0. Later, in 1988, Tiryaki [9] interested in a fourth-order nonlinear scalar differential equation of the form x(4) + ψ(ẍ) ... x + φ(ẋ)ẍ+ θ(ẋ) + f(x) = 0. (5) Under specified conditions imposed on the functions ψ, φ, θ and f, he established sufficient conditions that guarantee the instability of the trivial solution of the equation (5). After that, in 1980, Skrapek [8] considered fourth-order scalar differential equations of the form x(4) + f(x, ẋ, ẍ, ... x) = 0. He studied hypotheses on the function f for which the zero solution of the above fourth-order differential equation is unstable. Similarly, in 1993 by help of Lyapunov’s second method, Lu ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1 INSTABILITY OF SOLUTIONS FOR CERTAIN NONLINEAR VECTOR DIFFERENTIAL . . . 123 and Liao [6] gave some sufficient conditions for the instability of solutions of a general fourth- order linear scalar differential equation with variable coefficient, at least one of the characteri- stic roots of which has positive real part. Finally, in 2000, Ezeilo [5] discussed a similar problem for the scalar differential equations x(4) + ψ(ẍ) ... x + g(x, ẋ, ẍ, ... x) ẍ+ θ(ẋ) + f(x) = 0, (6) x(4) + a1 ... x + g(x, ẋ, ẍ, ... x) ẍ+ h(x)ẋ+ f(x, ẋ, ẍ, ... x) = 0, (7) and x(4) + p( ... x, ẍ) + q(x, ẋ, ẍ, ... x) ẍ+ a3ẋ+ a4x = 0, (8) respectively, where a1, a3 and a4 are constants. Now, with respect to our observations in the literature, so far instability of solutions of nonli- near vector differential equations of the form (3) was not investigated in the relevant literature, except for its scalar version, differential equation (6). It should also be clarified that nearly throughout all of the papers just stated above it was taken into consideration Krasovskii’s cri- terion (see Krasovskii [14]) as a fundamental criterion through the proofs, and the Lyapunov’s [1] second (or direct) method has been used as a basic tool to prove the results established there. In this paper, in view of Krasovskii’s criterion [14], we use the same method to verify our main result. The motivation for the present paper has been inspired basically by the paper of Ezeilo [5] and that just mentioned above. It is worth mentioning that all the papers mentioned above do not contain an example on the topic. However, our main result includes an explanatory example. Throughout this paper, the symbol 〈X,Y 〉 is used to denote the usual scalar product in R n for given any X, Y in R n, that is, 〈X,Y 〉 = n ∑ i=1 xiyi, thus ‖X‖2 = 〈X,X〉. It is also well-known that a real symmetric matrix A = (aij), i, j = 1, 2, . . . , n, is said to be positive definite if and only if the quadratic form XT AX is positive definite, where X ∈ R n and XT denotes the transpose of X (see Bellman [15]). 2. Main result. Actually, we prove the following theorem. Theorem. Assume that the functionG and the functions Ψ,Θ and F in equation (3), respecti- vely, are continuous and continuously differentiable, and there exist constants a1 and a2 such that the following conditions are satisfied: Ψ, G, JΘ and JF are symmetric such that ∂ψij ∂zk = ∂ψik ∂zj , i, j, k = 1, 2, . . . , n; F (X) 6= 0 if X 6= 0, λi(Ψ(Z)) ≥ a1 > 0, λi(G(X,Y,Z,W )) ≤ a2 and λi(JF (X)) > 1 4 a2 2, i = 1, 2, . . . , n, ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1 124 C. TUNÇ for allX, Y, Z,W ∈ R n,where λi(JF (X)) and λi(G(X,Y,Z,W )), i = 1, 2 . . . , n, are eigenvalues of G(X,Y,Z,W ) and JF (X). Then the trivial solution X = 0 of equation (3) is unstable. Remark 1. In order to prove the above theorem, it will suffice, see Krasovskii [14], to show that there exists a continuous Lyapunov function V = V (X,Y,Z,W ) which has the following Krasovskii properties: (K1) In every neighborhood of (0, 0, 0, 0) there exists a point (ξ, η, ζ, µ) such that V (ξ, η, ζ, µ) > 0; (K2) the time derivative V̇ = d dt V (X,Y,Z,W ) along solution paths of the system (4) is positive semi-definite; (K3) the only solution (X,Y,Z,W ) = (X(t), Y (t), Z(t),W (t)) of the system (4) which sati- sfies V̇ = 0 (t ≥ 0) is the trivial solution (0, 0, 0, 0). Remark 2. It should be clarified that there is no restriction on the eigenvalues of the matrix JΘ(Y ) obtained from Θ(Y ). Remark 3. Our result includes and improves the result of Ezeilo [5], which was established on the instability of zero solution of equation (6). Proof. For the proof of the theorem, we define a Lyapunov function V = V (X,Y,Z,W ) given by V = a2〈Y,Z〉 + 〈W,Z〉 + 〈F (X), Y 〉 + 1 ∫ 0 〈Θ(σ Y ), Y 〉 dσ + 1 ∫ 0 〈Ψ(σ Z)Z,Z〉 dσ. (9) Observe that V (0, 0, 0, 0) = 0. Indeed, in view of the assumptions of the theorem, we also have that V (0, 0, ε, ε) = 〈ε, ε〉 + 1 ∫ 0 〈Ψ(σε)ε, ε〉 dσ ≥ 〈ε, ε〉 + 1 ∫ 0 〈a1ε, ε〉 dσ = = 〈ε, ε〉 1 2 a1〈ε, ε〉 = ‖ε‖2 + 1 2 a1 ‖ε‖ 2 > 0 for all arbitrary ε 6= 0, ε ∈ R n, which verifies the property (K1). Next let (X,Y,Z,W ) = = (X(t), Y (t), Z(t),W (t)) be an arbitrary solution of the system (4). In view of the function (9) and the system (4), a straightforward calculation gives that V̇ = d dt V (X,Y,Z,W ) = a2〈Z,Z〉 + 〈W,W 〉 + a2〈Y,W 〉 − 〈G(X,Y,Z,W )Z,Z〉+ + 〈JF (X)Y, Y 〉 − 〈Ψ(Z)W,Z〉 − 〈Θ(Y ), Z〉+ + d dt 1 ∫ 0 〈Θ(σ Y ), Y 〉 dσ + d dt 1 ∫ 0 〈Ψ(σ Z)Z,Z〉 dσ. (10) ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1 INSTABILITY OF SOLUTIONS FOR CERTAIN NONLINEAR VECTOR DIFFERENTIAL . . . 125 Now, recall that d dt 1 ∫ 0 〈Θ(σ Y ), Y 〉 dσ = 1 ∫ 0 σ〈JΘ(σ Y )Z, Y 〉 dσ + 1 ∫ 0 〈Θ(σ Y ), Z〉 dσ = = 1 ∫ 0 σ ∂ ∂σ 〈Θ(σ Y ), Z〉 dσ + 1 ∫ 0 〈Θ(σ Y ), Z〉 dσ = = σ 〈Θ(σ Y ), Z〉|10 = 〈Θ(Y ), Z〉 (11) and d dt 1 ∫ 0 〈Ψ(σ Z)Z,Z〉 dσ = 1 ∫ 0 〈Ψ(σ Z)Z,W 〉 dσ + 1 ∫ 0 〈σ J(Ψ(σ Z)Z|σ Z)W,Z〉 dσ = = 1 ∫ 0 〈Ψ(σ Z)Z,W 〉 dσ + 1 ∫ 0 σ〈J(Ψ(σ Z)Z|σ Z)Z,W 〉 dσ = = 1 ∫ 0 〈Ψ(σ Z)Z,W 〉 dσ + 1 ∫ 0 σ ∂ ∂σ 〈Ψ(σ Z)Z,W 〉 dσ = = σ〈Ψ(σ Z)Z,W 〉|10 = 〈Ψ(Z)Z,W 〉. (12) Collecting the estimates (11) and (12) into (10), we get V̇ = a2〈Z,Z〉 + 〈W,W 〉 + a2〈Y,W 〉 − 〈G(X,Y,Z,W )Z,Z〉 + 〈JF (X)Y, Y 〉. (13) In view of the assumption λi(G(X,Y,Z,W )) ≤ a2 of the theorem, it follows for the terms a2〈Z,Z〉 − 〈G(X,Y,Z,W )Z,Z〉, which are contained in (13), that a2〈Z,Z〉 − 〈G(X,Y,Z,W )Z,Z〉 ≥ a2〈Z,Z〉 − a2〈Z,Z〉 = 0. (14) Hence, by using (14), we have V̇ ≥ 〈W,W 〉 + 〈Y, a2W 〉 + 〈JF (X)Y, Y 〉 ≥ ≥ 〈W,W 〉 − |a2| ‖Y ‖ ‖W‖ + 〈JF (X)Y, Y 〉. (15) ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1 126 C. TUNÇ In view of (15), the assumption λi(JF (X)) > 1 4 a2 2 of the theorem, we conclude that V̇ ≥ ∥ ∥ ∥ ∥ W + 1 2 a2Y ∥ ∥ ∥ ∥ 2 + 〈JF (X)Y, Y 〉 − 1 4 a2 2〈Y, Y 〉 ≥ ≥ 〈JF (X)Y, Y 〉 − 1 4 a2 2〈Y, Y 〉 ≥ 0. Now, it is clear that V̇ (0, 0, 0,W ) = 〈W,W 〉 = ‖W‖2 ≥ 0. Hence, the above discussion shows that the function V̇ is positive semi-definite. This case veri- fies the property (K2). Next, let (X(t), Y (t), Z(t),W (t)) be an arbitrary solution of the system (3). We observe from the previous estimate of V̇ in (13) that V̇ = 0, t ≥ 0, necessarily implies that Y (t) = 0 for all t ≥ 0 and, therefore, also that X = ξ (a constant vector). In its turn this implies that X = ξ, Y = Ẋ, Z = Ẏ = 0, W = Ż = 0 for all t ≥ 0. The substitution of the estimates X = ξ, Y = Ẋ, Z = Ẏ = 0, W = Ż = 0 for all t ≥ 0 into the system (4) leads to the result F (ξ) = 0 which, by the assumption of the theorem, implies (only) that ξ = 0. Thus V̇ = 0, t ≥ 0, implies that X = Y = Z = W = 0 for all t ≥ 0. Hence the property of (K3) holds for the function V. The theorem is thereby established. Example. As a special case of the system (4), let us choose, for the case n = 4, Ψ, G, Θ and F that appeared in the system (4) to be the following: Ψ(Z) =     1 + z2 1 0 0 0 0 1 + z2 2 0 0 0 0 1 + z2 3 0 0 0 0 1 + z2 4     , G(X,Y,Z,W ) =         1 − x2 1 − y2 1 − z2 1 − w2 1 0 0 0 0 2 0 0 0 0 2 − 2 1 + x2 3 + z4 3 0 0 0 0 1 2 − 3 2 + y2 4 + z2 4 + w4 4         , ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1 INSTABILITY OF SOLUTIONS FOR CERTAIN NONLINEAR VECTOR DIFFERENTIAL . . . 127 Θ(Y ) =               2y1 + y3 1 + y5 1 y2 + 1 3 y3 2 3y3 + 1 5 y5 3 2y4 + 1 3 y3 4               , and F (X) =               3x1 + 1 3 x3 1 2x2 + 1 6 x3 2 4x3 + x3 3 5x4 + 1 3 x3 4               . Then, clearly, eigenvalues of the matrix Ψ(Z) are λ1(Ψ(Z)) = 1 + z2 1 , λ2(Ψ(Z)) = 1 + z2 2 , λ3(Ψ(Z)) = 1 + z2 3 , λ4(Ψ(Z)) = 1 + z2 4 . Trivially, λi(Ψ(Z)) ≥ 1 = a1 > 0, i = 1, 2, . . . , 4. Next, observe that λ1(G(X,Y,Z,W )) = 1 − x2 − y2 − z2 − w2 ≤ 1, λ2(G(X,Y,Z,W )) = 2, λ3(G(X,Y,Z,W )) = 2 − 2 1 + x2 + z4 ≤ 2, λ4(G(X,Y,Z,W )) = 1 2 − 3 2 + y2 + z2 + w2 ≤ 1 2 . Thus, one can choose λi(G(X,Y,Z,W )) ≤ a2 = 2, i = 1, 2, . . . , 4. Similarly, it follows that JΘ(Y ) is a symmetric matrix, namely, JΘ(Y ) =     2 + 3y2 1 + 5y4 1 0 0 0 0 1 + y2 2 0 0 0 0 3 + y4 3 0 0 0 0 2 + y2 4     , ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1 128 C. TUNÇ hence it is readily verified that JΘ(Y ) is a symmetric matrix. Now, the derivative of the function F (X) gives that JF (X) =             3 + x2 1 0 0 0 0 2 + 1 2 x2 2 0 0 0 0 4 + 3x2 3 0 0 0 0 5 + x2 4             . Hence, λ1(JF (X)) = 3 + x2 1 ≥ 3 > 0, λ2(JF (X)) = 2 + 1 2 x2 2 ≥ 2 > 0, λ3(JF (X)) = 4 + 3x2 3 ≥ 4 > 0, λ3(JF (X)) = 5 + 3x2 4 ≥ 5 > 0. Thus λi(JF (X)) ≥ 2, i = 1, 2, . . . , 4. Therefore, it can be concluded from the above discussion that λi(JF (X)) − 1 4 a2 2 = λi(JF (X)) − 1 > 0, i = 1, 2, . . . , 4. Thus all the conditions of the theorem are satisfied. Acknowledgement. I would like to express my sincere gratitude to the anonymous referee for his/her very sensitive corrections, comments and suggestions on this paper. 1. Lyapunov A. M. Stability of motion. — London: Acad. Press, 1966. 2. Ezeilo J. O. C. An instability theorem for a certain fourth order differential equation // Bull. 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Math.— 2004. — 6, № 2. — P. 127 – 134. 14. Krasovskii N. N. On conditions of inversion of A. M. Lyapunov’s theorems on instability for stationary systems of differential equations (in Russian) // Dokl. Akad. Nauk SSSR (New. Ser.). — 1955. — № 101. — P. 17 – 20. 15. Bellman R. Introduction to matrix analysis. Reprint of the second (1970) edition. With a foreword by Gene Golub // Classics in Appl. Math. — Philadelphia, PA: SIAM, 1997. — 19. Received 16.04.08, after revision — 08.02.09 ISSN 1562-3076. Нелiнiйнi коливання, 2009, т . 12, N◦ 1

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