Abstract
In semiarid areas, precipitations usually appear in the form of big and brief floods, which affect the aquifer through water infiltration, causing groundwater temperature changes. These changes may have an impact on the physical, chemical and biological processes of the aquifer and, thus, modeling the groundwater temperature variations associated with stormy precipitation episodes is essential, especially since this kind of precipitation is becoming increasingly frequent in semiarid regions. In this paper, we compare the predictive performance of two popular tools in statistics and machine learning, namely Bayesian networks (BNs) and artificial neural networks (ANNs), in modeling groundwater temperature variation associated with precipitation events. More specifically, we trained a total of 2145 ANNs with different node configurations, from one to five layers. On the other hand, we trained three different BNs using different structure learning algorithms. We conclude that, while both tools are equivalent in terms of accuracy for predicting groundwater temperature drops, the computational cost associated with the estimation of Bayesian networks is significantly lower, and the resulting BN models are more versatile and allow a more detailed analysis.
Highlights
Rivers of small basins have a limited thermal capacity and are very sensitive to transient thermal disturbances [1], especially those originated from storm episodes
Precipitations are characterized by a high space-time variability with strong stormy events [2], which affect the aquifer through water infiltration [3], causing groundwater temperature changes [4,5,6]
Bayesian networks constitute an appropriate methodology to reach a better understanding of the system and the relation between storm episodes and the groundwater
Summary
Rivers of small basins have a limited thermal capacity and are very sensitive to transient thermal disturbances [1], especially those originated from storm episodes. Since groundwater is a common source of drinking water and irrigation supply, especially in semiarid areas, the identification of the type of precipitation is essential for the proper management of these water bodies, and becomes crucial regarding the fact that the extension of semiarid areas is likely to increase in the future [10]. From the renewable energy viewpoint, there is an increasing interest in groundwater temperature due to its potential use as heat pump systems [11,12]. Since the temperature of groundwater is relatively constant, it can be used as a source of geothermal energy for heating in winter and cooling in summer.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
