Deciphering Unilateral Communication Patterns in Directed Temporal Networks: Network Role Distribution Approach

In the vast expanse of online communication, identifying unilateral preference patterns can be pivotal in understanding and mitigating risks such as predatory behavior. This paper presents a comprehensive approach to dissect and visualize such patterns in social networks. Through the lens of a directed network model, we simulate a scenario where a predominant cluster 'A' disperses information unilaterally towards a much larger, but passive, cluster 'B', while being overseen by a vigilant cluster 'C', restricted by an information blocking cluster 'D', and countered by an alerting cluster 'E'. Incorporated into this study is a simulation framework that models the flow of information across a directed network comprising various clusters with distinct roles and communication behaviors. The simulation employs a dynamic system where clusters 'A' through 'E' interact over a series of time steps, with each cluster's activity shaped by both intrinsic message-generation rules and external media influences. By tracking the accumulated media influence on each cluster, we gain a nuanced understanding of the long-term effects of media on communication patterns. The results provide a window into the cyclical nature of influence and the propagation of information, with potential applications in detecting and mitigating unilateral communication patterns that could signal harmful activities such as online predation. This study, therefore, presents a comprehensive approach that combines network theory, simulation modeling, and dynamic media influence analysis to explore and understand the complexities of unilateral preference communication within social networks.This paper is partially an attempt to utilize "Generative AI" and was written with educational intent. There are currently no plans for it to become a peer-reviewed paper.