Optimal Feedback Control in Social Networks in a McKean-Vlasov-Friedkin-Johnsen System
read the original abstract
This paper presents a comprehensive analytical formulation for deriving a closed-form optimal strategy for agents operating within a social network, modeled through a McKean-Vlasov stochastic differential equation (SDE). Each agent aims to minimize a personal dynamic cost functional that accounts for deviations from the collective opinions of others, their own past beliefs, and is influenced by randomness and inherent opinion rigidity, often described as stubbornness. To tackle this, we develop a novel methodology rooted in a Feynman-type path integral framework, incorporating a specially designed integrating factor to obtain explicit feedback control laws. This approach provides a tractable and insightful solution to the control problem in a setting shaped by both memory and noise. As part of our analysis, we adopt a modified form of the Friedkin-Johnsen opinion dynamics model to more accurately capture the influence of prior beliefs and social interactions, enabling the explicit derivation of the optimal strategy. Comparative simulations further illustrate the effectiveness and adaptability of our method across different network structures, highlighting its potential relevance to understanding opinion evolution and influence strategies in complex social systems.
This paper has not been read by Pith yet.
Forward citations
Cited by 3 Pith papers
-
Modeling Educational Performance Using School Demographics and Teacher Characteristics
Introduces Adaptive Weighted Group Fused LASSO estimator with ADMM algorithm and asymptotic guarantees, demonstrated on Alabama school math proficiency data.
-
Obesity and Sociodemographic Factors in Luminal Breast Cancer
Higher BMI and African ancestry independently associate with Luminal B breast cancer, with BMI partially mediating the ancestry link in a cohort of 3,538 patients.
-
Optimal Harvesting under Stochastic Control: HJB Equation and Feynman-Kac Representation
Applies standard HJB and Feynman-Kac methods to stochastic harvesting models and claims they are consistent for policy design.
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.