Abstract
Saturated total dissolved gas (TDG) is recently considered as a serious issue in the environmental engineering field since it stands behind the reasons for increasing the mortality rates of fish and aquatic organisms. The accurate and more reliable prediction of TDG has a very significant role in preserving the diversity of aquatic organisms and reducing the phenomenon of fish deaths. Herein, two machine learning approaches called support vector regression (SVR) and extreme learning machine (ELM) have been applied to predict the saturated TDG% at USGS 14150000 and USGS 14181500 stations which are located in the USA. For the USGS 14150000 station, the recorded samples from 13 October 2016 to 14 March 2019 (75%) were used for training set, and the rest from 15 March 2019 to 13 October 2019 (25%) were used for testing requirements. Similarly, for USGS 14181500 station, the hourly data samples which covered the period from 9 June 2017 till 11 March 2019 were used for calibrating the models and from 12 March 2019 until 9 October 2019 were used for testing the predictive models. Eight input combinations based on different parameters have been established as well as nine statistical performance measures have been used for evaluating the accuracy of adopted models, for instance, not limited, correlation of determination ( R 2 ), mean absolute relative error (MAE), and uncertainty at 95% ( U 95 ). The obtained results of the study for both stations revealed that the ELM managed efficiently to estimate the TDG in comparison to SVR technique. For USGS 14181500 station, the statistical measures for ELM (SVR) were, respectively, reported as R 2 of 0.986 (0.986), MAE of 0.316 (0.441), and U 95 of 3.592 (3.869). Lastly, for USGS 14181500 station, the statistical measures for ELM (SVR) were, respectively, reported as R 2 of 0.991 (0.991), MAE of 0.338 (0.396), and U 95 of 0.832 (0.837). In addition, ELM’s training process computational time is stated to be much shorter than that of SVM. The results also showed that the temperature parameter was the most significant variable that influenced TDG relative to the other parameters. Overall, the proposed model (ELM) proved to be an appropriate and efficient computer-assisted technology for saturated TDG modeling that will contribute to the basic knowledge of environmental considerations.
Highlights
Water encounters substantial volumes of air and bubbles during the flood discharge and is transferred down the watershed to the deep-water basin
In this part of the study, results of support vector regression (SVR) and Extreme learning machine (ELM) models for different proposed combinations are presented. e obtained results for both United States Geological Survey (USGS) 14150000 and USGS 14181500 stations are further discussed in order to select the best predictive model which can provide more accurate results related to saturated total dissolved gas (TDG)
The potential for producing a robust predictive model utilizing two artificial intelligence methodologies to estimate one hour ahead TDG based on environmental variables
Summary
Water encounters substantial volumes of air and bubbles during the flood discharge and is transferred down the watershed to the deep-water basin. E average dissolved gas content in water is often controlled by two parameters, the water temperature and the barometric pressure Many essential gases, such as oxygen, nitrogen, argon, and carbon dioxide, Advances in Civil Engineering are known to contribute significantly to TDG formation [2]. E formation of the TDG is highly complex and depends on several variables in which it may be triggered by a mechanism affected by human or natural conditions It can be divided into the following: first, physical and chemical processes where the air bubbles are produced and transferred from the dam to the spillway; and second, mixing and interaction with the involvement of mass transfer equations between water and bubbles [3]. Saturated TDG is recently considered as a serious issue in the environmental engineering field since it could cause increased mortality rates in fish and aquatic organisms [4]. e phenomena take place when fish consumes water with a high level of saturated TDG, and the dissolved gases flow into the bloodstream and balance with the external pressure of water
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
