Abstract
Real-time monitoring of river water quality is at the forefront of a proactive urban water management strategy to meet the global challenge of vital freshwater resource sustainability. The concentration of dissolved oxygen (DO) is a primary indicator of the health state of the aquatic habitats, and its modeling is crucial for river water quality management. This paper investigates the importance of the choices of different techniques for preprocessing and stochastic modeling for developing a simple and reliable linear stochastic model for forecasting DO in urban rivers. We describe several methods of evaluation, preprocessing, and modeling for the DO parameter time series in the Credit River, Ontario, Canada, to achieve the optimum data preprocessing and input selection techniques and consequently obtain the optimum performance of the stochastic models as an effective river management tool. The Manly normalization and standardization (Std) methods were chosen for preprocessing the time series. Modeling the preprocessed time series using the stochastic autoregressive integrated moving average (ARIMA) model resulted in very accurate forecasts with a negligible difference from sole normalization and spectral analysis (Sf) methods.
Highlights
River water quality monitoring programs have been established around the globe to help watershed managers better protect the quality of water in their watersheds [1]
For dissolved oxygen (DO) I, the period of record is from 20 February 2010 to 11 December 2016 for 2337 days
Methods to investigate the effect of increasing the order of parameters for all 10 parameters were considered
Summary
River water quality monitoring programs have been established around the globe to help watershed managers better protect the quality of water in their watersheds [1]. The dissolved oxygen (DO) concentration plays a critical role in regulating various biogeochemical processes and biological communities in river ecosystems. Maintaining sufficient levels of DO in water is critical for water quality because oxygen is needed for the survival and preservation of various aquatic species, including fish, amphibians, benthos, bacteria, and aquatic plants. The occurrence of low DO concentrations, in a normally well-oxygenated river system, can cause mortality in fish and other aquatic life. When DO concentrations are reduced, aquatic species are forced to lower their activity and alter respiration rates, which will delay their development, and can cause reproductive problems and/or deformities [6]
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