Abstract
Nowadays, smart devices as a part of daily life collect data about their users with the help of sensors placed on them. Sensor data are usually physical data but mobile applications collect more than physical data like device usage habits and personal interests. Collected data are usually classified as personal, but they contain valuable information about their users when it is analyzed and interpreted. One of the main purposes of personal data analysis is to make predictions about users. Collected data can be divided into two major categories: physical and behavioral data. Behavioral data are also named as neurophysical data. Physical and neurophysical parameters are collected as a part of this study. Physical data contains measurements of the users like heartbeats, sleep quality, energy, movement/mobility parameters. Neurophysical data contain keystroke patterns like typing speed and typing errors. Users’ emotional/mood statuses are also investigated by asking daily questions. Six questions are asked to the users daily in order to determine the mood of them. These questions are emotion-attached questions, and depending on the answers, users’ emotional states are graded. Our aim is to show that there is a connection between users’ physical/neurophysical parameters and mood/emotional conditions. To prove our hypothesis, we collect and measure physical and neurophysical parameters of 15 users for 1 year. The novelty of this work to the literature is the usage of both combinations of physical and neurophysical parameters. Another novelty is that the emotion classification task is performed by both conventional machine learning algorithms and deep learning models. For this purpose, Feedforward Neural Network (FFNN), Convolutional Neural Network (CNN), Recurrent Neural Network (RNN), and Long Short-Term Memory (LSTM) neural network are employed as deep learning methodologies. Multinomial Naïve Bayes (MNB), Support Vector Regression (SVR), Decision Tree (DT), Random Forest (RF), and Decision Integration Strategy (DIS) are evaluated as conventional machine learning algorithms. To the best of our knowledge, this is the very first attempt to analyze the neurophysical conditions of the users by evaluating deep learning models for mood analysis and enriching physical characteristics with neurophysical parameters. Experiment results demonstrate that the utilization of deep learning methodologies and the combination of both physical and neurophysical parameters enhances the classification success of the system to interpret the mood of the users. A wide range of comparative and extensive experiments shows that the proposed model exhibits noteworthy results compared to the state-of-art studies.
Highlights
Intelligent and integrated devices became one of the essential parts of both our social and business daily life
Our main contributions are summarized as follows: (i) We propose the usage of the combination of physical and neurophysical features to predict the mood of users which is the novelty of this study (ii) For the purpose of detecting the mood of user, both conventional machine learning algorithms and deep learning techniques are employed and classification performances of each model are compared (iii) To demonstrate the contribution of proposed model, a customized data gathering platform is constructed and data collected for one year e rest of this paper is organized as follows: Section 2 gives a summary of related work about parameters for the estimation of user behaviors and emotion analysis of the users
In addition to Convolutional Neural Network (CNN), Decision Tree (DT) and Recurrent Neural Network (RNN) exhibit approximately 5% improvement compared to the first approach. ere is a performance increase of 16% with Support Vector Regression (SVR) algorithm in terms of classification success while a minimum improvement of the classification performance is observed as nearly 2% with Random Forest (RF) in the second approach
Summary
Intelligent and integrated devices became one of the essential parts of both our social and business daily life. Ese devices gather many parameters about their users including mobility (walking, running, and climbing) information, sleep time, and places where the users visited. New developments in technology integrate these devices to the biological body of their users, and this creates online information about human beings accessible by all over the world [1]. E application period of NPT is usually one a year or twice which is not sufficient Measuring such risks should be a part of daily operation which can be realized with intelligent and integrated devices. Base keystroke patterns and some of derived parameters from keystroke patterns are used as a feature in our study
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