Gradient auto-tuned Takagi-Sugeno Fuzzy Forward control of a HVAC system using predicted mean vote index
Controllers of HVAC systems are expected to be able to manipulate the inherent nonlinear characteristics of these large scale systems that also have pure lag times, big thermal inertia, uncertain disturbance factors and constraints. In addition, indoor thermal comfort is affected by both temperature...
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my.uniten.dspace-295302023-12-28T14:30:23Z Gradient auto-tuned Takagi-Sugeno Fuzzy Forward control of a HVAC system using predicted mean vote index Homod R.Z. Sahari K.S.M. Almurib H.A.F. Nagi F.H. 36994633500 57218170038 35305238400 56272534200 Building energy control HVAC system PMV signal reference TS Fuzzy identification TSFF control Cascade control systems Climate control Control nonlinearities Newton-Raphson method Building energy Cascade control Control methods Control objectives Control strategies Disturbance factors Gauss-Newton methods Gradient algorithm HVAC system Indoor thermal comfort Lag time Non-linear regression Nonlinear characteristics Offline PMV signal reference Predicted mean vote Residential loads Save energy T S models T-S fuzzy Takagi-sugeno Thermal inertia Thermal parameters Thermal sensitivity Uncertainty effects Weather conditions Humidity control Controllers of HVAC systems are expected to be able to manipulate the inherent nonlinear characteristics of these large scale systems that also have pure lag times, big thermal inertia, uncertain disturbance factors and constraints. In addition, indoor thermal comfort is affected by both temperature and humidity, which are coupled properties. To control these coupled characteristics and tackle nonlinearities effectively, this paper proposes an online tuned Takagi-Sugeno Fuzzy Forward (TSFF) control strategy. The TS model is first trained offline using Gauss-Newton Method for Nonlinear Regression (GNMNR) algorithm with data collected from both building and HVAC system equipments. The model is then tuned online using the gradient algorithm to enhance the stability of the overall system and reject disturbances and uncertainty effects. As control objective, predicted mean vote (PMV) is adopted to avoid temperature-humidity coupling, thermal sensitivity and to save energy at the same time. The proposed TSFF control method is tested in simulation taking into account practical variations such as thermal parameters of buildings, weather conditions and other indoor residential loads. For comparison purposes, normal Takagi-Sugeno fuzzy and hybrid PID Cascade control schemes were also tested. The results demonstrated superior performance, adaptation and robustness of the proposed TSFF control strategy. � 2012 Elsevier B.V. All rights reserved. Final 2023-12-28T06:30:23Z 2023-12-28T06:30:23Z 2012 Article 10.1016/j.enbuild.2012.02.013 2-s2.0-84861801850 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84861801850&doi=10.1016%2fj.enbuild.2012.02.013&partnerID=40&md5=cdea59b1f9851dbda4981aecc1617f12 https://irepository.uniten.edu.my/handle/123456789/29530 49 254 267 Scopus |
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Building energy control HVAC system PMV signal reference TS Fuzzy identification TSFF control Cascade control systems Climate control Control nonlinearities Newton-Raphson method Building energy Cascade control Control methods Control objectives Control strategies Disturbance factors Gauss-Newton methods Gradient algorithm HVAC system Indoor thermal comfort Lag time Non-linear regression Nonlinear characteristics Offline PMV signal reference Predicted mean vote Residential loads Save energy T S models T-S fuzzy Takagi-sugeno Thermal inertia Thermal parameters Thermal sensitivity Uncertainty effects Weather conditions Humidity control |
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Building energy control HVAC system PMV signal reference TS Fuzzy identification TSFF control Cascade control systems Climate control Control nonlinearities Newton-Raphson method Building energy Cascade control Control methods Control objectives Control strategies Disturbance factors Gauss-Newton methods Gradient algorithm HVAC system Indoor thermal comfort Lag time Non-linear regression Nonlinear characteristics Offline PMV signal reference Predicted mean vote Residential loads Save energy T S models T-S fuzzy Takagi-sugeno Thermal inertia Thermal parameters Thermal sensitivity Uncertainty effects Weather conditions Humidity control Homod R.Z. Sahari K.S.M. Almurib H.A.F. Nagi F.H. Gradient auto-tuned Takagi-Sugeno Fuzzy Forward control of a HVAC system using predicted mean vote index |
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Controllers of HVAC systems are expected to be able to manipulate the inherent nonlinear characteristics of these large scale systems that also have pure lag times, big thermal inertia, uncertain disturbance factors and constraints. In addition, indoor thermal comfort is affected by both temperature and humidity, which are coupled properties. To control these coupled characteristics and tackle nonlinearities effectively, this paper proposes an online tuned Takagi-Sugeno Fuzzy Forward (TSFF) control strategy. The TS model is first trained offline using Gauss-Newton Method for Nonlinear Regression (GNMNR) algorithm with data collected from both building and HVAC system equipments. The model is then tuned online using the gradient algorithm to enhance the stability of the overall system and reject disturbances and uncertainty effects. As control objective, predicted mean vote (PMV) is adopted to avoid temperature-humidity coupling, thermal sensitivity and to save energy at the same time. The proposed TSFF control method is tested in simulation taking into account practical variations such as thermal parameters of buildings, weather conditions and other indoor residential loads. For comparison purposes, normal Takagi-Sugeno fuzzy and hybrid PID Cascade control schemes were also tested. The results demonstrated superior performance, adaptation and robustness of the proposed TSFF control strategy. � 2012 Elsevier B.V. All rights reserved. |
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36994633500 |
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36994633500 Homod R.Z. Sahari K.S.M. Almurib H.A.F. Nagi F.H. |
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Homod R.Z. Sahari K.S.M. Almurib H.A.F. Nagi F.H. |
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Homod R.Z. |
title |
Gradient auto-tuned Takagi-Sugeno Fuzzy Forward control of a HVAC system using predicted mean vote index |
title_short |
Gradient auto-tuned Takagi-Sugeno Fuzzy Forward control of a HVAC system using predicted mean vote index |
title_full |
Gradient auto-tuned Takagi-Sugeno Fuzzy Forward control of a HVAC system using predicted mean vote index |
title_fullStr |
Gradient auto-tuned Takagi-Sugeno Fuzzy Forward control of a HVAC system using predicted mean vote index |
title_full_unstemmed |
Gradient auto-tuned Takagi-Sugeno Fuzzy Forward control of a HVAC system using predicted mean vote index |
title_sort |
gradient auto-tuned takagi-sugeno fuzzy forward control of a hvac system using predicted mean vote index |
publishDate |
2023 |
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1806426400254590976 |
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13.214268 |