Applying artificial intelligence modeling to optimize green roof irrigation

Resource type
Journal Article
Authors/contributors
Title
Applying artificial intelligence modeling to optimize green roof irrigation
Abstract
Recent increase in green-roof installation has increased irrigation water consumption which could be wasteful using conventional watering management protocol. The knowledge gap in irrigation optimization to achieve water conservation could be filled. The complicated conventional approach uses weather and soil sensors to calculate watering needs, which is impractical and not cost-effective. This study employs artificial intelligence algorithms composed of artificial neural network and fuzzy logic, using weather data to simulate soil moisture changes to develop an optimal irrigation strategy. The artificial neural network is trained to predict soil moisture based on four daily weather variables: real-time air temperature, relative humidity, solar radiation, and wind speed. Fuzzy-neural network is applied to determine the irrigation time and watering volume. The simulation model successfully mimics the human brain in making irrigation decision. The artificial intelligence irrigation could maintain adequate soil moisture ranging from 0.13 to 0.22m3/m3 and reduce 20% of water use with improved plant coverage. Since the evapotranspiration from living vegetation plays a key role in the passive cooling mechanism, better plant coverage could increase the thermal-energy performance of green roofs. The low-cost and effective technique can motivate the adoption of green roofs by alleviating the water consumption obstacle.
Publication
Energy and Buildings
Volume
127
Pages
360-369
Date
2016-09-01
Journal Abbr
Energy and Buildings
ISSN
0378-7788
Accessed
12/02/2024, 21:30
Library Catalogue
ScienceDirect
Call Number
openalex:W2417027211
Extra
openalex: W2417027211
Citation
Tsang, S. W., & Jim, C. Y. (2016). Applying artificial intelligence modeling to optimize green roof irrigation. Energy and Buildings, 127, 360–369. https://doi.org/10.1016/j.enbuild.2016.06.005