Michelle Feng scite author profile

Michelle Feng

5Publications

39Citation Statements Received

147Citation Statements Given

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A Bounded-Confidence Model of Opinion Dynamics on Hypergraphs

Hickok¹,

Kureh²,

Brooks³

et al. 2021

Preprint

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People's opinions evolve over time as they interact with their friends, family, colleagues, and others. In the study of opinion dynamics on networks, one often encodes interactions between people in the form of dyadic relationships, but many social interactions in real life are polyadic (i.e., they involve three or more people). In this paper, we extend an asynchronous boundedconfidence model (BCM) on graphs, in which nodes are connected pairwise by edges, to hypergraphs. We show that our hypergraph BCM converges to consensus under a wide range of initial conditions for the opinions of the nodes. We show that, under suitable conditions, echo chambers can form on hypergraphs with community structure. We also observe that the opinions of individuals can sometimes jump from one opinion cluster to another in a single time step, a phenomenon (which we call "opinion jumping") that is not possible in standard dyadic BCMs. We also show that there is a phase transition in the convergence time on the complete hypergraph when the variance σ 2 of the initial opinion distribution equals the confidence bound c. Therefore, to determine the convergence properties of our hypergraph BCM when the variance and the number of hyperedges are both large, it is necessary to use analytical methods instead of relying only on Monte Carlo simulations.

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Persistent Homology of Geospatial Data: A Case Study with Voting

Feng¹,

Porter²

2019

Preprint

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An Adaptive Bounded-Confidence Model of Opinion Dynamics on Networks

Kan¹,

Feng²,

Porter³

2021

Preprint

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Individuals who interact with each other in social networks often exchange ideas and influence each other's opinions. A popular approach to studying the dynamics of opinion spread on networks is by examining bounded-confidence (BC) models, in which the nodes of a network have continuous-valued states that encode their opinions and are receptive to other opinions if they lie within some confidence bound of their own opinion. We extend the Deffuant-Weisbuch (DW) model, which is a well-known BC model, by studying opinion dynamics that coevolve with network structure. We propose an adaptive variant of the DW model in which the nodes of a network can (1) alter their opinion when they interact with a neighboring node and (2) break a connection with a neighbor based on an opinion tolerance threshold and then form a new connection to a node following the principle of homophily. This opinion tolerance threshold acts as a threshold to determine if the opinions of adjacent nodes are sufficiently different to be viewed as discordant. We find that our adaptive BC model requires a larger confidence bound than the standard DW model for the nodes of a network to achieve a consensus. Interestingly, our model includes regions with 'pseudo-consensus' steady states, in which there exist two subclusters within an opinion-consensus group that deviate from each other by a small amount. We conduct extensive numerical simulations of our adaptive BC model and examine the importance of early-time dynamics and nodes with initial moderate opinions for achieving consensus. We also examine the effects of coevolution on the convergence time of the dynamics.

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Topological Data Analysis of Spatial Systems

Feng¹,

Hickok²,

Porter³

2021

Preprint

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Repulsive Bounded-Confidence Model of Opinion Dynamics in Polarized Communities

Kann¹,

Feng²

2023

Preprint

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Collective opinions affect civic participation, governance, and societal norms. Due to the influence of opinion dynamics, many models of their formation and evolution have been developed. A commonly used approach for the study of opinion dynamics is bounded-confidence models. In these models, individuals are influenced by the opinions of others in their network. They generally assume that individuals will formulate their opinions to resemble those of their peers. In this paper, inspired by the dynamics of partisan politics, we introduce a bounded-confidence model in which individuals may be repelled by the opinions of their peers rather than only attracted to them. We prove convergence properties of our model and perform simulations to study the behavior of our model on various types of random networks. In particular, we observe that including opinion repulsion leads to a higher degree of opinion fragmentation than in standard bounded-confidence models.

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Michelle Feng

A Bounded-Confidence Model of Opinion Dynamics on Hypergraphs

Persistent Homology of Geospatial Data: A Case Study with Voting

An Adaptive Bounded-Confidence Model of Opinion Dynamics on Networks

Topological Data Analysis of Spatial Systems

Repulsive Bounded-Confidence Model of Opinion Dynamics in Polarized Communities

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