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QoE Estimation for the Wi-Fi Edge with Gradient Boosting-based Machine Learning

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dc.contributor.authorArgın, Berke
dc.contributor.authorDemir, Mehmet Özgün
dc.contributor.authorOnalan, Aysun Gurur
dc.contributor.authorSalik, Elif DIlek
dc.contributor.authorGelal, Ece
dc.contributor.institutionArgın, Berke, Lifemote Networks, Istanbul, Turkey
dc.contributor.institutionDemir, Mehmet Özgün, Lifemote Networks, Istanbul, Turkey
dc.contributor.institutionOnalan, Aysun Gurur, Lifemote Networks, Istanbul, Turkey
dc.contributor.institutionSalik, Elif DIlek, Lifemote Networks, Istanbul, Turkey
dc.contributor.institutionGelal, Ece, Bahçeşehir Üniversitesi, Istanbul, Turkey
dc.date.accessioned2025-10-05T15:08:24Z
dc.date.issued2023
dc.description.abstractAn integral part of the Intent-Based Networking paradigm is estimating and improving the end-user quality of experience (QoE). Estimating user experience from the (wide-area) network data alone does not accurately represent the performance at customer premises since Wi-Fi at the edge also significantly affects the perceived QoE. We propose machine learning-based estimation of the end-users' perceived QoE for web browsing and video streaming applications, based on Wi-Fi statistics. We implement support vector machine (SVM), decision tree (DT), multilayer perceptron (MLP), XGBoost, and CatBoost algorithms and compare their performance. To the best of our knowledge, our CatBoost-based model yields the highest accuracy to date, 0.92 R2, in estimating the QoE for web browsing based on Wi-Fi statistics. Our experiments also show that the XGBoost-based QoE estimator outperformed the neural network-based model in estimating the QoE for video streaming. Our work demonstrates that network operators can infer the user-perceived QoE in a Wi-Fi network through telemetry data obtained by passive measurements. © 2023 Elsevier B.V., All rights reserved.
dc.identifier.conferenceName2023 International Balkan Conference on Communications and Networking, BalkanCom 2023
dc.identifier.conferencePlaceIstanbul
dc.identifier.doi10.1109/BalkanCom58402.2023.10167908
dc.identifier.isbn9798350339109
dc.identifier.scopus2-s2.0-85165666070
dc.identifier.urihttps://doi.org/10.1109/BalkanCom58402.2023.10167908
dc.identifier.urihttps://hdl.handle.net/20.500.14719/8278
dc.language.isoen
dc.publisherInstitute of Electrical and Electronics Engineers Inc.
dc.subject.authorkeywordsMachine Learning
dc.subject.authorkeywordsMean Opinion Score
dc.subject.authorkeywordsQuality Of Experience
dc.subject.authorkeywordsVideo Streaming
dc.subject.authorkeywordsWeb Browsing
dc.subject.authorkeywordsWi-fi
dc.subject.authorkeywordsAdaptive Boosting
dc.subject.authorkeywordsHttp
dc.subject.authorkeywordsLearning Systems
dc.subject.authorkeywordsQuality Of Service
dc.subject.authorkeywordsSupport Vector Machines
dc.subject.authorkeywordsVideo Streaming
dc.subject.authorkeywordsWide Area Networks
dc.subject.authorkeywordsWireless Local Area Networks (wlan)
dc.subject.authorkeywordsEnd-users
dc.subject.authorkeywordsGradient Boosting
dc.subject.authorkeywordsIntegral Part
dc.subject.authorkeywordsMachine-learning
dc.subject.authorkeywordsMean Opinion Scores
dc.subject.authorkeywordsPerceived Quality
dc.subject.authorkeywordsPerformance
dc.subject.authorkeywordsQuality Of Experience
dc.subject.authorkeywordsVideo-streaming
dc.subject.authorkeywordsWeb Browsing
dc.subject.authorkeywordsDecision Trees
dc.subject.indexkeywordsAdaptive boosting
dc.subject.indexkeywordsHTTP
dc.subject.indexkeywordsLearning systems
dc.subject.indexkeywordsQuality of service
dc.subject.indexkeywordsSupport vector machines
dc.subject.indexkeywordsVideo streaming
dc.subject.indexkeywordsWide area networks
dc.subject.indexkeywordsWireless local area networks (WLAN)
dc.subject.indexkeywordsEnd-users
dc.subject.indexkeywordsGradient boosting
dc.subject.indexkeywordsIntegral part
dc.subject.indexkeywordsMachine-learning
dc.subject.indexkeywordsMean opinion scores
dc.subject.indexkeywordsPerceived quality
dc.subject.indexkeywordsPerformance
dc.subject.indexkeywordsQuality of experience
dc.subject.indexkeywordsVideo-streaming
dc.subject.indexkeywordsWeb browsing
dc.subject.indexkeywordsDecision trees
dc.titleQoE Estimation for the Wi-Fi Edge with Gradient Boosting-based Machine Learning
dc.typeConference Paper
dcterms.referencesIEEE Communications Surveys Tutorials, (2022), Intent Based Networking Concepts and Definitions, (2020), Vocabulary for Performance and Quality of Service, (2008), Estimating End to End Performance in Ip Networks for Data Applications, (2025), Wamser, Florian, Modeling the YouTube stack: From packets to quality of experience, Computer Networks, 109, pp. 211-224, (2016), Lundberg, Scott M., From local explanations to global understanding with explainable AI for trees, Nature Machine Intelligence, 2, 1, pp. 56-67, (2020), da Hora, Diego Neves, Predicting the effect of home Wi-Fi quality on QoE, Proceedings - IEEE INFOCOM, 2018-April, pp. 944-952, (2018), Morshedi, Maghsoud, Estimating PQoS of video streaming on wi-fi networks using machine learning, Sensors, 21, 2, pp. 1-17, (2021), Mok, Ricky K.P., Measuring the quality of experience of HTTP video streaming, pp. 485-492, (2011), Egger, Sebastian L., Waiting times in quality of experience for web based services, pp. 86-96, (2012)
dspace.entity.typePublication
local.indexed.atScopus
person.identifier.scopus-author-id58503795000
person.identifier.scopus-author-id59432197400
person.identifier.scopus-author-id57192232293
person.identifier.scopus-author-id57212084418
person.identifier.scopus-author-id16244814400

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