A Study of Cellular Neural Networks with Vertex-Edge Topological Descriptors

: The Cellular Neural Network (CNN) has various parallel processing applications, image processing, non-linear processing, geometric maps, high-speed computations. It is an analog paradigm, consists of an array of cells that are interconnected locally. Cells can be arranged in different configu-rations. Each cell has an input, a state, and an output. The cellular neural network allows cells to communicate with the neighbor cells only. It can be represented graphically; cells will represent by vertices and their inter-connections will represent by edges. In chemical graph theory, topological descriptors are used to study graph structure and their biological activities. It is a single value that characterizes the whole graph. In this article, the vertex-edge topological descriptors have been calculated for cellular neural network. Results can be used for cellular neural network of any size. This will enhance the applications of cellular neural network in image processing, solving partial differential equations, analyzing 3D surfaces, sensory-motor organs, and modeling biological vision. maps representations, high-speed computations, partial differential equations, analyzing 3D surfaces, sensory-motor organs, and modeling biological vision.

Let G be a simple connected graph with vertex sets V (G) and edge sets E(G). The degree of a vertex , denoted by d( ), is the number of edges that are incident to the . The open neighbourhood of is defined as N( ) = {ε ∈ V (G) : ε ∈ E(G)} and closed neighbourhood N[ ] = N( ) ∪ { } [19]. The ve-degree, denoted by d ve ( ), of any vertex ∈ V is the number of different edges that are incident to any vertex from the N[ ]. In [20] defined the ev-degree of the edge e = ε ∈ E, denoted by d ev (e), the number of vertices of the union of the closed neighborhoods of and ε. For details see [21][22][23][24][25][26][27].
The ve-degree and ev-degree topological indices are defined as: αve ) index, the first ve-degree Zagreb β (M 1 βve ) index, the second ve-degree Zagreb (M 2 ve ) index, ve-degree Randic (R ve ) index, the ev-degree Randic (R ev ) index, the ve-degree atombond connectivity (ABC ve ) index, the ve-degree geometric-arithmetic (GA ve ) index, the ve-degree harmonic (H ve ) index and the ve-degree sum-connectivity (χ ve ) index, respectively.

Applications and Importance
The Cellular Neural Network (CNN) is an array of cells that are interconnected locally. It is an analog paradigm with various applications including image processing, parallel processing, and high-speed computations. Each cell has an input, an output, and its state. A cell can interact with neighbor cells only. A neighbor cell of a cell is in its radius. A neighborhood includes the cell itself and its eight neighboring cells [28,29]. Fig. 1, consists of two diagrams (a) and (b). Diagram (a), is a graph of two-dimensional CNN, in which a neighborhood is representing red and blue colors. Diagram (b), is the internal structure of the red cell of diagram (a), this cell can interact with all blue cells in this neighborhood. In this article, vertex-edge topological descriptors have been calculated for CNN. The results are generalized and can be used for CNN of any structure and size. This will enhance the applications of CNN in image processing, parallel processing, image processing, non-linear processing, geometric maps, high-speed computations, solving partial differential equations, analyzing 3D surfaces, sensory-motor organs, and modeling biological vision [30].
In 2018, new degree-based topological indices are considered and the analytical sharp bounds has been derived for neural networks in [31]. In 2019, Imran et al. [32] has been calculated the degree based topological indices of cellular neural network. Topology optimization and Zagreb connection indices for cellular neural network are studied in [30,33]. Recently in 2021, the comparison and analysis between the dominating topological indices are determined for the cellular neural network [34]. Some topological indices have been calculated for cellular neural network, and are prominence their importance, but still many topological indices have not been calculated. Their calculation will provide an analytical study of cellular neural network in different applications. The cellular neural network is also known as the strong product of two paths, which has applications in different area of research, see [35,36].
We partitioned the edges of CNN, based on ev-degree in Tab. 4.
In Tab. 5, we partitioned the vertices of CNN, based on ev-degree.

The ev-Degree Zagreb Index
The values of ev-degree of each edge is calculated by the sum of degree of its end vertices. The edge partition according to ev-degree for cellular neural network (CNN) is shown in Tab. 4. By using ev-degree of CNN from Tab. 4, we compute the ev-degree based Zagreb index:

The First ve-Degree Zagreb α Index
The ve-degree of each vertex is obtained by the sum of all degrees of its neighboring vertices. We partitioned the vertices of cellular neural network (CNN) according to its ve-degree that is shown in Tab. 5. Using Tab. 5 we compute the first ve-degree Zagreb α index:

The First ve-Degree Zagreb β Index
The edge partition of cellular neural network (CNN) with respect to ve-degree is shown in Tab. 6. Using Tab. 6 we compute the first ve-degree Zagreb β index:

The Second ve-Degree Zagreb Index
Using Tab. 6 we compute the second ve-degree Zagreb index:

The ve-Degree Randic Index
Using Tab. 6 we compute the ve-degree Randic index:

The ve-Degree Atom-Bond Connectivity Index
Using Tab. 6 we compute the ve-degree atom-bond connectivity index:

The ve-Degree Geometric-Arithmetic Index
Using Tab. 6 we compute the ve-degree geometric-arithmetic index:

The ve-Degree Harmonic Index
Using Tab. 6 we compute the ve-degree harmonic index:

The ve-Degree Sum-Connectivity Index
Using Tab. 6 we compute the ve-degree sum-connectivity index:

Advantages
As a machine learning algorithm, CNN can take image as an input, highlight image key features, and differentiate one image from the other [37]. CNN has powerful function-fitting capabilities and has great potential to study partial differential equations [38,39]. CNN has been widely used in analyzing 3D surfaces and facial images applications [40]. The design components underlying the implementation of the physiologically faithful retina and other topographic sensory organ models on CNN universal chips. The results obtained through the proposed technique can better understand the features and characteristics of CNN. It can enhance image processing applications, solve partial differential equations, analyze 3D surfaces, sensory-motor organs, and model biological vision. Combinations of CNN and artificial intelligence provide enhanced human-level performance to computer architectures [41]. This article is vital in the implementation of Human-level visual recognition.

Limitations
The calculation of vertex-edge topological descriptors carried out in this research are specifically derived for cellular neural networks. However, with some modifications they can be applied in other fields like image processing, biological modelling, 3D surface analyzing, and complex imaging. The applicability of this research still needs to be validated for these fields to identify the full potential of this research. These open problems can be further studied to get full benefit of this research.

Conclusion
A cell in Cellular Neural Network (CNN), can communicate with neighbor cells only. Due to its architecture, it is used to manage hierarchical levels, and it has variety of applications. In applied sciences, graph theory provides different tools and methods to remedy real-world problems.
To solve these problems, it represents them in the form of graphs. Topological descriptors in graph theory are used to study and characterize biological activities in the form of graphs. In this article, the vertex-edge topological descriptors have been calculated for the graphic representation of CNN. Results can be used for the CNN of any size. The proposed technique can enhance the CNN's applications in image processing, parallel processing, non-linear processing, geometric maps representations, high-speed computations, solving partial differential equations, analyzing 3D surfaces, sensory-motor organs, and modeling biological vision.