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Main Authors: Huang, Yuanzhe, Faruque, Saurab, Wu, Minjie, Mizuno, Akiko, Diniz, Eduardo, Yang, Shaolin, Stetten, George Dewitt, Schweitzer, Noah, Jin, Hecheng, Wang, Linghai, Aizenstein, Howard J.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2403.03414
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author Huang, Yuanzhe
Faruque, Saurab
Wu, Minjie
Mizuno, Akiko
Diniz, Eduardo
Yang, Shaolin
Stetten, George Dewitt
Schweitzer, Noah
Jin, Hecheng
Wang, Linghai
Aizenstein, Howard J.
author_facet Huang, Yuanzhe
Faruque, Saurab
Wu, Minjie
Mizuno, Akiko
Diniz, Eduardo
Yang, Shaolin
Stetten, George Dewitt
Schweitzer, Noah
Jin, Hecheng
Wang, Linghai
Aizenstein, Howard J.
contents Traditional approaches in mental health research apply General Linear Models (GLM) to describe the longitudinal dynamics of observed psycho-behavioral measurements (questionnaire summary scores). Similarly, GLMs are also applied to characterize relationships between neurobiological measurements (regional fMRI signals) and perceptual stimuli or other regional signals. While these methods are useful for exploring linear correlations among the isolated signals of those constructs (i.e., summary scores or fMRI signals), these classical frameworks fall short in providing insights into the comprehensive system-level dynamics underlying observable changes. Hidden Markov Models (HMM) are a statistical model that enable us to describe the sequential relations among multiple observable constructs, and when applied through the lens of Finite State Automata (FSA), can provide a more integrated and intuitive framework for modeling and understanding the underlying controller (the prescription for how to respond to inputs) that fundamentally defines any system, as opposed to linearly correlating output signals produced by the controller. We present a simple and intuitive HMM processing pipeline vcHMM (See Preliminary Data) that highlights FSA theory and is applicable for both behavioral analysis of questionnaire data and fMRI data. HMMs offer theoretic promise as they are computationally equivalent to the FSA, the control processor of a Turing Machine (TM) The dynamic programming Viterbi algorithm is used to leverage the HMM model. It efficiently identifies the most likely sequence of hidden states. The vcHMM pipeline leverages this grammar to understand how behavior and neural activity relate to depression.
format Preprint
id arxiv_https___arxiv_org_abs_2403_03414
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Leveraging The Finite States of Emotion Processing to Study Late-Life Mental Health
Huang, Yuanzhe
Faruque, Saurab
Wu, Minjie
Mizuno, Akiko
Diniz, Eduardo
Yang, Shaolin
Stetten, George Dewitt
Schweitzer, Noah
Jin, Hecheng
Wang, Linghai
Aizenstein, Howard J.
Machine Learning
Neurons and Cognition
Traditional approaches in mental health research apply General Linear Models (GLM) to describe the longitudinal dynamics of observed psycho-behavioral measurements (questionnaire summary scores). Similarly, GLMs are also applied to characterize relationships between neurobiological measurements (regional fMRI signals) and perceptual stimuli or other regional signals. While these methods are useful for exploring linear correlations among the isolated signals of those constructs (i.e., summary scores or fMRI signals), these classical frameworks fall short in providing insights into the comprehensive system-level dynamics underlying observable changes. Hidden Markov Models (HMM) are a statistical model that enable us to describe the sequential relations among multiple observable constructs, and when applied through the lens of Finite State Automata (FSA), can provide a more integrated and intuitive framework for modeling and understanding the underlying controller (the prescription for how to respond to inputs) that fundamentally defines any system, as opposed to linearly correlating output signals produced by the controller. We present a simple and intuitive HMM processing pipeline vcHMM (See Preliminary Data) that highlights FSA theory and is applicable for both behavioral analysis of questionnaire data and fMRI data. HMMs offer theoretic promise as they are computationally equivalent to the FSA, the control processor of a Turing Machine (TM) The dynamic programming Viterbi algorithm is used to leverage the HMM model. It efficiently identifies the most likely sequence of hidden states. The vcHMM pipeline leverages this grammar to understand how behavior and neural activity relate to depression.
title Leveraging The Finite States of Emotion Processing to Study Late-Life Mental Health
topic Machine Learning
Neurons and Cognition
url https://arxiv.org/abs/2403.03414