Models for Computational Emotions from Psychological Theories Using Type I Fuzzy Logic

Ayesh, Aladdin; Blewitt, William

doi:10.1007/s12559-014-9287-7

Cited by 10 publications

(7 citation statements)

References 72 publications

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“…Based on the cognitive appraisal theory, Kim and Kwon and Jiang et al 17,20,21 proposed a computational model of event evaluation which was developed for each appraisal criteria and the robot's emotions during the task can lead to a better human–robot interaction experience. Ayesh and Blewitt 22,23 proposed models for affective computing from psychological theories using type I and II fuzzy logic. Cai et al and Wang et al 24‐26 also proposed methods about affective computing.…”

Section: Related Workmentioning

confidence: 99%

A computational model of emotion based on audio‐visual stimuli understanding and personalized regulation with concurrency

Jiang

Jin

Zhuang

et al. 2021

Concurrency and Computation

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The target of Emotion modeling is to establish an system that can perceive, recognize, and express emotions with concurrency which humanity have by proper mathematical models. A big challenge in Emotion modeling is to establish the complex personal system of an intelligent agent or machine in a quasi‐physical and quasi‐sociological way, so that it rationally responds to emotions and behaviors by different internal and external stimuli with concurrency. For this purpose, an emotion classification model is presented for the audio‐visual external stimuli based on an improved long short‐term memory network. Then, based on Gross's emotional regulation theory, a hidden Markov model is constructed to imitate the process framework of human emotional cognition and personalized emotional regulation and expression, so as to realize the machine's intuitive and reasonable response to stimuli with concurrency. In this article, a framework of machine personalized artificial emotion simulation is preliminarily constructed, which provides a new model for human–computer interaction, in order to provide a reference solution for machine emotion understanding and expression.

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Section: Related Workmentioning

confidence: 99%

A computational model of emotion based on audio‐visual stimuli understanding and personalized regulation with concurrency

Jiang

Jin

Zhuang

et al. 2021

Concurrency and Computation

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“…DEAP consists of EEG and peripheral physiological signals collected from 32 participants. These signals were recorded as each participant watched 40 one-minute long excerpts of music videos, which were selected in order to elicit emotions in each of the 4 quadrants of the Russells Circumplex Model [7], [13], [16], [30], [34].…”

Section: Eeg Data a Motivationmentioning

confidence: 99%

“…This may assume a set of distinct emotional categories, such is the case in Ekman's Basic Emotions Model [15]. Another approach is to describe the emotion as a point in a continuous multidimensional space where each dimension represents one aspect of the emotion such is the case in Millenson's Model [12]; other examples of this approach can be found in [7], [8], [16], [34]. The resulting model is used to predict the most likely emotional state by using the same description approach as for labelling the training samples.…”

Section: Eeg Data a Motivationmentioning

confidence: 99%

Class discovery from semi-structured EEG data for affective computing and personalisation

Ayesh

Arevalillo‐Herráez

Arnau-González

2017

2017 IEEE 16th International Conference on Cognitive Informatics &Amp; Cognitive Computing (ICCI*CC)

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Many approaches to recognising emotions from metrical data such as EEG signals rely on identifying a very small number of classes and to train a classifier. The interpretation of these classes varies from a single emotion such as stress [24] to features of emotional model such as valence-arousal [4]. There are two major issues here. First classification approach limits the analysis of the data within the selected classes and is also highly dependent on training data/cycles, all of which limits generalisation. Second issue is that it does not explore the interrelationships between the data collected missing out on any correlations that could tell us interesting facts beyond emotional recognition. This second issue would be of particular interest to psychologists and medical professions. In this paper, we investigate the use of Self-Organizing Maps (SOM) in identifying clusters from EEG signals that could then be translated into classes. We start by training varying sizes of SOM with the EEG data provided in a public dataset (DEAP). The produced graphs showing Neighbour Distance, Sample Hits, Weight Position are analysed holistically to identify patterns in the structure. Following that, we have considered the groundtruth label provided in DEAP, in order to identify correlations between the label and the clustering produced by the SOM. The results show the potential of SOM for class discovery in this particular context. We conclude with a discussion on the implications of this work and the difficulties in evaluating the outcome.

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“…This is mainly due to their good capability of coping with vague, imprecise, and uncertain concepts. It is worth underlining that fuzzy logic has been recognized also as an important tool to keep the fidelity of psychological interpretation of emotion [12], opening up new ways to analyze the sentiment contents of huge amounts of data available from web sources. From a more technical point of view, the use of overlapped fuzzy labels ensures a good coverage of the problem space.…”

Section: Introductionmentioning

confidence: 99%

Optimizing Partition Granularity, Membership Function Parameters, and Rule Bases of Fuzzy Classifiers for Big Data by a Multi-objective Evolutionary Approach

et al. 2019

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Background/Introduction -Classical data mining algorithms are considered inadequate to manage the volume, variety, velocity, and veracity aspects of Big Data. The advent of a number of open source cluster computing frameworks has opened new interesting perspectives for handling the volume and velocity features. In this context, thanks to their capability of coping with vague and imprecise information, distributed fuzzy models appear to be particularly suitable for handling the variety and veracity features of big data. Moreover, the interpretability of fuzzy models may assume a particular relevance in the context of big data mining.Methods -In this work, we propose a novel approach for generating, out of big data, a set of fuzzy rule-based classifiers characterized by different optimal trade-offs between accuracy and interpretability. We extend a state-of-theart distributed multi-objective evolutionary learning scheme, implemented under the Apache Spark environment. In particular, we exploit a recently proposed distributed fuzzy decision tree learning approach for generating an initial rule base that serves as input to the evolutionary process. Furthermore, we integrate the evolutionary learning scheme with an ad-hoc strategy for the granularity learning of the fuzzy partitions, along with the optimization of both the rule base and the fuzzy set parameters.Results and Conclusions -Experimental investigations show that the proposed approach is able to generate fuzzy rule-based classifiers that are significantly less complex than the ones generated by the original multi-objective evolutionary learning scheme, while keeping the same accuracy levels.

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Models for Computational Emotions from Psychological Theories Using Type I Fuzzy Logic

Cited by 10 publications

References 72 publications

A computational model of emotion based on audio‐visual stimuli understanding and personalized regulation with concurrency

A computational model of emotion based on audio‐visual stimuli understanding and personalized regulation with concurrency

Class discovery from semi-structured EEG data for affective computing and personalisation

Optimizing Partition Granularity, Membership Function Parameters, and Rule Bases of Fuzzy Classifiers for Big Data by a Multi-objective Evolutionary Approach

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