Forecasting Energy Consumption Time Series Using Recurrent Neural Network in Tensorflow

Yazdan, Munshi Md. Shafwat; Khosravi, Marzieh; Saki, Shah; Mehedi, Md Abdullah Al

doi:10.20944/preprints202209.0404.v1

“…In terms of the selected performance indices, DNN models outperformed the SRC method in simulating the daily SSC. These findings corroborate researchers' claims, such as Cigizoglu and Kisi, 2005, about using the feed-forward back propagation (FFBP) algorithm, sediment concentration, and streamflow data as inputs for daily or monthly SSC estimation and forecasting [40][41][42]. However, it has been reported that not enough studies have been conducted to evaluate the best performance of training algorithms within DNN modeling techniques [15].…”

Section: Introductionsupporting

confidence: 83%

“…Because of the decaying error backflow, recurrent backpropagation requires a significant amount of computational time and effort to learn to store long-term information. Hence, the concept of the vanishing gradient problem in recognizing long-term dependency of Recurrent Neural Network (RNN) was introduced [42,46]. The main element of processing and retaining long-term information is LSTM feedback connections, and this characteristic distinguishes it from the conventional feedforward neural network.…”

Section: Long Short-term Memory (Lstm) Recurrent Neuralmentioning

confidence: 99%

Demystifying the Relationship Between River Discharge and Suspended Sediment Using Exploratory Analysis and Deep Neural Network Algorithms

Akatu¹,

Khosravi²,

Mehedi³

et al. 2022

Preprint

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The dynamics of suspended sediment involves inherent non-linearity and complexity as a result of the presence of both spatial variability of the basin characteristics and temporal climatic patterns. As a result of this complexity, the conventional sediment rating curve (SRC) and other empirical methods produce inaccurate predictions. Deep neural networks (DNNs) have emerged as one of the advanced modeling techniques capable of addressing inherent non-linearity in hydrological processes over the last few decades. DNN algorithms are used to perform predictive analysis and investigate the interdependencies among the most pivotal water quantity and quality parameters i.e., discharge, suspended sediment concentration (SSC), and turbidity. In this study, the Long short-term memory (LSTM) algorithm of DNNs is used to model the discharge-suspended sediment relationship for the Stony Clove Creek. The simulations were run using primary data on discharge, SSC and turbidity. For the development of the DNN models and examining the effects of input vectors, combinations of different input vectors (namely discharge, and SSC) for the current and previous days are considered. Furthermore, a suitable modelling approach with an appropriate model input structure is suggested based on model performance indices for the training and testing phases. The performance of developed models is assessed using statistical indices such as root mean square error (RMSE), mean absolute error (MAE), and coefficient of determination (R2). Statistically, the performance of DNN-based models in simulating the daily SSC performed well with observed sediment concentration series data. The study demonstrates the suitability of the DNN approach for simulation and estimation of daily SSC, opening up new research avenues for applying hybrid soft computing models in hydrology.

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“…The initial model that was trained on historical data was a multiple linear regression and the second was a long short-term memory network. Both multiple linear regression and long short-term memory have been used by previous researchers as data driven models to predict streamflow, water table depth, and urban flooding; however, there is a need for further investigation on how these techniques can be used to optimize RTC systems for an individual SCM using rainfall data, which is commonly available [36][37][38][39][40][41][42][43]. An exploratory 3 of 18 data analysis approach was used to analyze the four years of historical data at the research site to develop a program to optimize basin performance.…”

Section: Of 18mentioning

confidence: 99%

Using Machine Learning to Improve Performance of a Low-Cost Real-Time Stormwater Control Measure

Khosravi¹,

Mehedi²,

Baghalian³

et al. 2022

Preprint

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The alteration of natural land cover to impervious surfaces during development increases stormwater runoff. Stormwater Control Measures (SCMs) are used to manage water quantity and enhance water quality by restoring the hydrologic cycle altered by development. Often, SCMs have an outflow pipe to handle overflows or to manage the release of water detained when infiltration is not possible. Traditionally, these are static controls (e.g. a small orifice is used to restrict the volume of outflow), however, these systems can be improved by instituting real-time controls (RTC). RTC improve the functionality of SCMs by dynamically controlling outflows to adjust to environmental conditions. A major impediment to the widespread implementation of RTC is the high cost of installation and operation. This study utilized machine learning methods to develop a forecasting approach for the implementation of low-cost RTC that were implemented on a programmable gate of the outlet structure of a multi-stage basin in southeastern Pennsylvania. The goals were to decrease the peak flow exiting the basin during rain events, increase the volume of water detained, decrease the number of overtopping events, maintain healthy vegetation in the basin, and protect the downstream vegetation from erosion. Multiple popular data science algorithms were evaluated including multiple linear regression and long short-term memory. These algorithms were used with a dataset, which consisted of four years of historical sensor data, collected in 5-minute intervals, to train models to predict water levels to optimize operations. The accuracy of 30 models with three different methods of handling missing values were compared. A long short-term memory model configured with a 30-minute lead time produced the best results. Having an approximate same lag time of 30 minutes for the contributing drainage area of the SCM provided a sufficient RTC functioning period to improve the performance of the outlet structure.

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“…Because of the decaying error backflow, recurrent backpropagation requires a significant amount of computational time and effort to learn to store long-term information. Hence, the concept of the vanishing gradient problem in recognizing long-term dependency of Recurrent Neural Network (RNN) was introduced [49,53]. The main element of processing and retaining long-term information is LSTM feedback connections, and this characteristic distinguishes it from the conventional feedforward neural network.…”

Section: Long Short-term Memory (Lstm) Recurrent Neuralmentioning

confidence: 99%

Demystifying the Relationship Between River Discharge and Suspended Sediment Using Exploratory Analysis and Deep Neural Network Algorithms

Akatu¹,

Khosravi²,

Mehedi³

et al. 2022

Preprint

View full text Add to dashboard Cite

The dynamics of suspended sediment involves inherent non-linearity and complexity as a result of the presence of both spatial variability of the basin characteristics and temporal climatic patterns. As a result of this complexity, the conventional sediment rating curve (SRC) and other empirical methods produce inaccurate predictions. Deep neural networks (DNNs) have emerged as one of the advanced modeling techniques capable of addressing inherent non-linearity in hydrological processes over the last few decades. DNN algorithms are used to perform predictive analysis and investigate the interdependencies among the most pivotal water quantity and quality parameters i.e., discharge, suspended sediment concentration (SSC), and turbidity. In this study, the Long short-term memory (LSTM) algorithm of DNNs is used to model the discharge-suspended sediment relationship for the Stony Clove Creek. The simulations were run using primary data on discharge, SSC and turbidity. For the development of the DNN models and examining the effects of input vectors, combinations of different input vectors (namely discharge, and SSC) for the current and previous days are considered. Furthermore, a suitable modelling approach with an appropriate model input structure is suggested based on model performance indices for the training and testing phases. The performance of developed models is assessed using statistical indices such as root mean square error (RMSE), mean absolute error (MAE), and coefficient of determination (R2). Statistically, the performance of DNN-based models in simulating the daily SSC performed well with observed sediment concentration series data. The study demonstrates the suitability of the DNN approach for simulation and estimation of daily SSC, opening up new research avenues for applying hybrid soft computing models in hydrology.

show abstract

Forecasting Energy Consumption Time Series Using Recurrent Neural Network in Tensorflow

Cited by 17 publications

References 44 publications

Demystifying the Relationship Between River Discharge and Suspended Sediment Using Exploratory Analysis and Deep Neural Network Algorithms

Demystifying the Relationship Between River Discharge and Suspended Sediment Using Exploratory Analysis and Deep Neural Network Algorithms

Using Machine Learning to Improve Performance of a Low-Cost Real-Time Stormwater Control Measure

Demystifying the Relationship Between River Discharge and Suspended Sediment Using Exploratory Analysis and Deep Neural Network Algorithms

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