Lyapunov approach to manifolds stability for impulsive Cohen–Grossberg-type conformable neural network models

: In this paper, motivated by the advantages of the generalized conformable derivatives, an impulsive conformable Cohen–Grossberg-type neural network model is introduced. The impulses, which can be also considered as a control strategy, are at fixed instants of time. We define the notion of practical stability with respect to manifolds. A Lyapunov-based analysis is conducted, and new criteria are proposed. The case of bidirectional associative memory (BAM) network model is also investigated. Examples are given to demonstrate the e ff ectiveness of the established results.


Introduction
The neural network modeling approach in the form of differential equations has been intensively applied by numerous researchers in different areas of science, engineering and medicine. The construction of a neuronal network model and its analysis are key goals in many practical applications. Indeed, the applications of such models include a variety of problems, such as optimization problems, associative memory, parallel processing, linear and nonlinear programming, including algorithms, computer vision, pattern recognition and many others [1,2].
The Cohen-Grossberg-type of neural networks [3] are an important class of neural network models that are widely used as a framework in the study of partial memory storage and global pattern formation phenomena [4][5][6]. Due to its important applications, the properties of different Cohen-Grossberg neural network models have been intensively studied, including some very recent results [7,8]. This the practical point of view, the concept of practical stability is more relevant [54,55].
In the past decade, the practical stability concept has been rapidly developed [56,57], and has been extended to the practical stability with respect to manifolds notion [58]. Indeed, the practical stability is useful in many applied systems when the dynamic of the model is contained within particular bounds during a fixed time interval. In such cases, the global asymptotic notion is not applicable. The practical stability strategy is also very efficient when a neuronal state is unstable in the classical sense and yet, state trajectories may oscillate sufficiently near the desired state such that its performance is admissible, which does not imply stability or convergence of trajectories. In addition, there are many applied systems that are stable or asymptotically stable in the classical sense, but actually useless in practice because of the small or inappropriate stability domain or attraction domain. The stability with respect to manifolds concepts are generalizations of the stability notions for single trajectories and are related to the study of stability properties of a manifold of states. Such concepts are of considerable interest to networks capable of approaching not only one steady state. The extended practical stability with respect to manifolds concept has been applied to integer-order Cohen-Grossberg models in [59] and to some conformable models [60]. However, there is no one existing result on practical stability with respect to manifolds for impulsive conformable Cohen-Grossberg neural networks. It is clear that this task is attractive and important in the analysis of such neural network models.
The main goal of this research is to propose an impulsive conformable Cohen-Grossberg-type neural network model. Also, the adoption of the practical stability with respect to manifolds notion is an essential motivation for our study.
The innovations of this article can be described as follows: (1) We propose a new impulsive conformable Cohen-Grossberg neural network model. The advantages of the conformable modelling approach can be used in the analysis of the properties of the introduced model. The impulsive perturbations can also be used to stabilize and control the proposed model.
(2) We introduce the practical stability with respect to manifolds notion. Using modifications of the Lyapunov technique, new criteria are proposed, which guarantee the practical stability behavior of manifolds related to the newly suggested model.
(3) The BAM generalization of the introduced model is analysed, and the corresponding sufficient conditions for practical stability with respect to manifolds are established.
(4) We verify the efficiency of the established criteria by examples. The structuring of the rest of the paper pursue the following scheme. In Section 2 some definitions and lemmas from conformable calculus are given. The conformable impulsive Cohen-Grossberg neural network model is introduced and the practical stability with respect to manifolds concept is adopted to it. Some preliminaries related to the Lyapunov functions method are also given. Section 3 is devoted to the main practical stability results established on the basis of a Lyapunov-type analysis. The case of BAM impulsive conformable Cohen-Grossberg-type neural networks is studied, and sufficient conditions for the practical exponential stability of the trajectories are proposed in Section 4. Illustrative examples are elaborated in Section 5. Some concluding comments are stated in Section 6.
Notations: R is the set of all real numbers, the set of all nonnegative real numbers will be denoted by R + = [0, ∞), R n denotes the n-dimensional real space with the norm ||y|| = n ι=1 |y ι | of an y ∈ R n , y = (y 1 , y 2 , . . . , y n ) T .

Conformable calculus definitions and lemmas
Here, we will present some basic definitions and lemmas related to the conformable calculus. Let τ 0 ∈ R + . Definition 1. [47,48] The generalized conformable derivative of order α, 0 < α ≤ 1 for a function Let the time instants τ 1 , τ 2 , . . . , are such that Any function that has an α-generalized conformable derivatives for any t ∈ (t, ∞) is called αgeneralized conformable differentiable on (t, ∞), and we will denote the set of all such functions by C α [(t, ∞), R n ] [48].

Definition 2.
[47] Let y : [t, ∞) → R n . The generalized conformable integral of order 0 < α ≤ 1 of y is given by The following properties of the generalized conformable derivatives and integrals will be applied in our future analysis [46][47][48].
Remark 6. To emphasize more advantages of the application of fractional derivatives, we note the following properties for α ∈ (0, 1] and x, y ∈ C α [(t, ∞), R] which follow directly by Definition 1 [35,36,41,48]: (e) D α t (x(t)) = 0 for any x(t) = λ, where λ is an arbitrary constant. For the classical fractional derivatives [22][23][24][25], including the Riemann-Liouville fractional derivative where 0 < α < 1 and Γ(z) = ∞ 0 e −t t z−1 dt is the Gamma function, and Caputo fractional derivative the properties (b)-(e) do not hold, except for the statement (e) for a fractional derivative of Caputo. The reason for this is the application of the integral in the known definitions of fractional derivatives.

The Gohen-Grossberg impulsive conformable neural network model
In this section we propose an impulsive Cohen-Grossberg-type neural network model with generalized conformable derivatives as follows where ι = 1, 2, . . . , n, n ≥ 2 represents the number of the units, y ι (t) is the state of the ι-th node at time t, the functions a ι , b ι , f j , U ι ∈ C[R, R + ] and c ι j ∈ R + , ι, j = 1, 2, . . . , n are the system's parameters in the continuous part, a ι denote the amplification functions, b ι are appropriate behaved functions, f j represent the activation functions, U ι denotes the external bias on the ιth node at time t, c ι j represent the connection weights, y ι (τ k ) = y ι (τ − k ) and y ι (τ + k ) in the impulsive condition are, respectively, the neuronal states of the ι-th node before and after an impulsive perturbation at τ k and the impulsive functions P ιk ∈ C[R, R] represent the effects of the impulse controls on the node y ι at τ k , ι = 1, 2, . . . , n, k = 1, 2, . . . .
According to the theory of impulsive conformable systems [46][47][48], the solution φ(t) of the initial value problem (1), (2) is an α-generalized conformable differentiable function, which is piecewise continuous with points of discontinuity of the first kind τ k , k = 1, 2, . . . , at which it is left continuous. At the impulsive moments, the functions φ(t) is such that The set of all such functions will be denoted by PC α [R + , R n ]. For example, for the solution of an impulsive scalar generalized conformable neural network of the type where u ∈ R, a, b ∈ C[R + , R + ], p k ∈ R, k = 1, 2, . . . , we obtain We will study some stability properties of the introduced model (1) under the following hypotheses: H1. The continuous functions a ι ∈ R + , ι = 1, 2, . . . , n are such that there exist positive constants a ι and a ι for which 1 < a ι ≤ a ι (χ) ≤ a ι for χ ∈ R, and a = min 1≤ι≤n a ι , a = max 1≤ι≤n a ι .
H3. There exist Lipschitz constants L f j > 0 such that Remark 7. The developed Cohen-Grossberg type model (1) with generalized conformable derivatives is an extension of the existing integer-order neural network models studied in [3,5]. It also extends some impulsive models investigated in [15-17, 20, 21] to the conformable setting. Since the concept of the conformable derivative overcomes some limitations related to the classical fractional-order derivatives, the introduced model is more suitable for applications than the models considered in [26,27,29,30]. In addition, considering impulsive perturbations will allow for the application of efficient impulsive control strategies [18-21, 58, 59].
, t ≥ τ 0 for some τ 0 ∈ R + , then the manifold M H t is said to be practically stable for the model (1). Definition 9. If for given (λ, A) with 0 < λ < A, y 0 ∈ M H τ 0 (λ) implies where 0 < α < 1, µ, δ > 0, and E α (ν, o) is the conformable exponential function given as [47] then the manifold M H t is said to be practically exponentially stable for the model (1). Remark 10. Definitions 8 and 9 generalize and extend the classical stability notions to the combined practical stability with respect to manifolds case. The combined setting increases the benefits of both approaches. In some particular cases, the defined concept can be reduced to simple practical stability notions that are used widely in the applied problems [60][61][62][63]. For example, if the function that defines the manifold H(t, y) = 0 only for y = 0, then definitions 8 and 9 are the classical definitions of practical stability and exponential practical stability of the zero solution of the model (1), respectively. Similarly, if the manifold M H t includes only an equilibrium state y * , i.e., H(t, y * ) = 0, then the above definitions are reduced to the practical stability and exponential practical stability definitions of y * , respectively. Other particular cases, such as practical stability and exponential practical stability of periodic and almost periodic solutions can be considered analogously. Thus, the proposed practical stability with respect to manifolds technique offers a high-powered mechanism which can be applied not only for single solutions, but also in the cases when manifolds of solutions are attractors for the models. This technique is also appropriate to investigate such manifolds that are not stable in the classical Lyapunov sense, but their dynamic is acceptable from the practical point of view [55,58].
We will also need the following additional hypothesis related to the specifics of the stability with respect to manifolds concepts.

Conformable Lyapunov functions method
Consider the sets In the further study, we apply a modified conformable Lyapunov function approach. A class of Lyapunov-like functions L α τ k is defined as [47] a set of functions L(t, y) : G → R + that are continuous on G, α-generalized conformable differentiable in t, locally Lipschitz continuous with respect to y on each of the sets G k , L(t, 0) = 0 for t ≥ τ 0 , and for each k = 1, 2, . . . and y ∈ R n , there exist the finite limits . For a function L ∈ L α τ k , the upper right conformable derivative is defined by [47] Denote by F(t, y) = (F 1 (t, y), F 2 (t, y), . . . , F n (t, y)) T , where y = (y 1 , y 2 , . . . , y n ) T and Then, the generalized conformable derivative of the function L(t, y) with respect to system (1), (2) is [47] If L(t, y(t)) = L(y(t)), 0 < α ≤ 1, the function L is differentiable on y, and the function y(t) is α-generalized conformable differentiable on [τ 0 , ∞), then Lemma 4 can applied componentwise.
The next Lemma from [47] will be also necessary.
Lemma 11. If for the function L ∈ L α τ k and for t ∈ [τ 0 , ∞), y ∈ R n , we have:

Main practical stability with respect to manifolds criteria
In this Section, we will apply the modified conformable Lyapunov-function approach to establish our main practical stability with respect to the manifold M H t criteria for the conformable impulsive Cohen-Grossberg neural network model (1).
Then, the manifold M H t is practically stable for the model (1).
Proof. For the given 0 < λ < A and y 0 ∈ R n let suppose that y 0 ∈ M H τ 0 (λ) and consider the solution y(t; τ 0 , y 0 ) of the impulsive conformable Cohen-Grossberg model (1) corresponding to the initial condition (2).
Using H1-H3 and conditions (16) of Theorem 13, for t τ k , k = 0, 1, 2, . . . , we have where ϱ 1 (t) = n ι=1 a ι U ι (t). Now, from (13) and (18), using again Lemma 11, we have Hence, from condition (i) of Theorem 13 and (17), and from the choice of the function L 1 ∈ L α k , we have ||H(t, y(t; τ 0 , y 0 ))|| ≤ L 1 (t, y(t; τ 0 , y 0 )) which implies that the manifold M H t is practically exponentially stable for the model (1). □ In the next result, we will use a different Lyapunov function in order to establish more relaxed sufficient conditions for the parameters in the continuous part of model (1). The price is, more restrictive conditions for the jump functions.
Remark 16. The results in this section generalize and extend many existing stability results for integerorder Cohen-Grossberg neural network models [3][4][5][6][7][8], impulsive Cohen-Grossberg neural network models [15][16][17], as well as, Cohen-Grossberg neural network models with classical fractional-order derivatives [26,27,29,30] to the generalized impulsive conformable setting. Also, since the concept of practical stability with respect to manifolds is more general, results on practical stability, stability with respect to manifolds, stability and practical stability of a single solution can be obtained as corollaries. Thus, the proposed results are very general and include many particular stability notions. For example, if in Definition 9, A = 0 and the manifold M H t consists only of a single solution y * , Theorems 13 and 14 offered criteria for exponential stability of the solution y * of the impulsive conformable Cohen-Grossberg neural network model (1).
Remark 17. The proposed stability of manifold results are also consistent with the results in the pioneering work of Cohen and Grossberg [3], where models capable of approaching infinitely many equilibrium points in response to arbitrary initial data, have been considered.
Remark 18. The impulsive functions P ιk , ι = 1, 2, . . . , n, k = 1, 2, . . . are the impulsive control functions in the introduced model (1). The suitable choice of these functions is crucial for the elaboration of effective impulsive control strategies that can be applied to the trajectories of the model to control their stability properties. Hence, our results contribute to the development of this direction of research. Indeed, the impulsive conformable Cohen-Grossberg neural network model (1) can be considered as a closed-loop control system represented as is the control input, δ(t) is the Dirac impulsive function. The controller u(t) = (u 1 (t), ..., u n (t)) T has an effect on sudden change of the states of (1) at the time instants τ k where each state y ι (t) changes from the position y ι (τ k ) into the position y ι (τ + k ), P ιk are the functions that characterize the magnitudes of the impulse effects on the units y ι at the moments τ k , i.e., u(t) is an impulsive control of the conformable model without impulses Therefore, our stability results also presents a general design method of impulsive control law u(t) for the impulse free conformable Cohen-Grossberg neural network model. The constants γ ιk in condition (ii) of Theorem 12 characterize the control gains of synchronizing impulses. Hence, our results can be used to design impulsive control law under which the controlled neural networks of type (1) are practically (practically exponentially) synchronized onto systems without impulses.

Impulsive conformable BAM Cohen-Grossberg neural networks
BAM neural networks have attracted an increased interest of numerous researchers since their introduction by Kosko [61,62], due mainly to their important applications in many areas. Some typical applications are related to associative phenomena in two-layer hetero-associative circuits existing in biology, medicine, engineering and computer sciences.
Significant progress has been made in the theory and applications of different classes of integer-order BAM Cohen-Grossberg neural networks [63,64], including impulsive models [21,65,66]. A practical stability analysis has also been proposed for some integer-order BAM Cohen-Grossberg neural network models [67].
Correspondingly, there are not reported results in the existing literature on BAM Cohen-Grossberg neural networks with conformable derivatives. In this Section, we will propose results on practical stability of such models with respect to manifolds as corollaries of the results offered in Section 3.
Following the definitions of solutions of the one layer Cohen-Grossber model (1) will denote by u(t), u(t) = (y(t), z(t)), where y(t) = y(t; τ 0 , y 0 ), z(t) = z(t; τ 0 , z 0 ) the solution of the BAM neural network model (28) that satisfies the initial conditions: where y 0 ∈ R n , z 0 ∈ R N and u 0 = (y 0 , z 0 ) ∈ R n+N . We will apply the practical stability notion with respect to a H * -manifold defined by a function H * = H * (t, u), H * : [τ 0 , ∞) × R n+N → R m , using the following definition.
Remark 21. As a Corollary of Theorem 14, Theorem 20 proposes criteria for practical exponential stability of a manifold for the BAM impulsive conformable Cohen-Grossberg model (28). Similarly, criteria for practical stability of the manifold M H * t can be established as a Corollary of Theorem 12.

Illustrative examples
In this section, examples are constructed to illustrate the usefulness of the proposed results.
If we consider a manifold containing the zero solution y * = (0, 0) T of the model (34), defined by a function H : R 2 → R 2 , H = (H 1 , H 2 ) T , then according to Theorem 14 the manifold (35) is practically exponentially stable for the model (34). The graphs of the trajectories of the model (34) with corresponding fixed τ k are shown in Figure 1.
Hence, the criteria provided by Theorem 13 for the parameters in the continuous part are more restrictive.
(B) If in the model (34), we have a 1 (y 1 ) = a 2 (y 2 ) = 1.4, then, hypotheses H1-H3 are satisfied for a 1 = a 1 = a 2 = a 2 = a = a = 1.4, In this case, conditions of Theorem 13 and Theorem 14 are satisfied for δ = δ 1 = 0.56 > 0. Therefore, the practical exponential stability of the manifold (35)   Remark 23. The demonstrated Example 22 illustrates the validity of theorems 13 and 14 for practical exponential stability of a manifold with respect to an impulsive conformable Cohen-Grossberg neural network model of the type (1). Similar demonstration for the practical stability behavior can be provided for a particular choice of the model's parameters. We show that the conditions for the parameters in the continuous part in Theorem 14 are more relaxed than these in Theorem 13. Also, we demonstrate that the choice of the impulsive functions is very important to control the practical stability behavior of manifolds related to models of type (1).

Concluding comments
In this paper, using the impulsive generalization of the conformable calculus approach, an impulsive conformable Cohen-Grossberg neural network model is proposed. The introduced model extends and complements numerous existing integer-order Cohen-Grossberg neural network models [3][4][5][6][7][8], impulsive Cohen-Grossberg neural network models [15][16][17] as well as Cohen-Grossberg neural network models with classical fractional-order derivatives [26,27,29,30] to the generalized impulsive conformable setting. The proposed model possesses the flexibility of the fractional-order models. Moreover, since the conformable derivatives simplify the computational procedures, it overcomes some limitations existing in the applications of the classical fractional-order problems. We adopt the combined concept of practical stability with respect to manifolds to the introduced model. Using a Lyapunov-based analysis, sufficient conditions are derived to ensure the practical stability and practical exponential stability with respect to manifolds. The case of BAM impulsive conformable Cohen-Grossberg neural network models is also studied to contribute to the development of the stability and control theories. Two illustrative examples are given to demonstrate the effectiveness of the contributed results. The application of the proposed conformable calculus approach to more neural network models is an interesting and challenging topic for future research. Also, it is possible to extend the proposed results to the delayed case and study the delay effects on the qualitative behavior of the neuronal states. In fact, delay effects are unavoidable in most of the neuronal network models. In addition, time delays, also known as transmission delays, may affect the dynamical properties of neural networks.

Use of AI tools declaration
The authors declare they have not used Artificial Intelligence (AI) tools in the creation of this article.