Your search keyword '"Alrowais, Fadwa"' showing total 3 results

1. Deep Learning with Dipper Throated Optimization Algorithm for Energy Consumption Forecasting in Smart Households.

Author

Abdelhamid, Abdelaziz A., El-Kenawy, El-Sayed M., Alrowais, Fadwa, Ibrahim, Abdelhameed, Khodadadi, Nima, Lim, Wei Hong, Alruwais, Nuha, and Khafaga, Doaa Sami

Subjects

ENERGY consumption forecasting, DEEP learning, MATHEMATICAL optimization, STANDARD deviations, ENERGY consumption, HOUSEHOLDS

Abstract

One of the relevant factors in smart energy management is the ability to predict the consumption of energy in smart households and use the resulting data for planning and operating energy generation. For the utility to save money on energy generation, it must be able to forecast electrical demands and schedule generation resources to meet the demand. In this paper, we propose an optimized deep network model for predicting future consumption of energy in smart households based on the Dipper Throated Optimization (DTO) algorithm and Long Short-Term Memory (LSTM). The proposed deep network consists of three parts, the first part contains a single layer of bidirectional LSTM, the second part contains a set of stacked unidirectional LSTM, and the third part contains a single layer of fully connected neurons. The design of the proposed deep network targets represents the temporal dependencies of energy consumption for boosting prediction accuracy. The parameters of the proposed deep network are optimized using the DTO algorithm. The proposed model is validated using the publicly available UCI household energy dataset. In comparison to the other competing machine learning models, such as Random Forest (RF), Support Vector Machine (SVM), K-Nearest Neighbor (KNN), Multi-Layer Perceptron (MLP), Sequence-to-Sequence (Seq2Seq), and standard LSTM, the performance of the proposed model shows promising effectiveness and superiority when evaluated using eight evaluation criteria including Root Mean Square Error (RMSE) and R 2 . Experimental results show that the proposed optimized deep model achieved an RMSE of (0.0047) and R 2 of (0.998), which outperform those values achieved by the other models. In addition, a sensitivity analysis is performed to study the stability and significance of the proposed approach. The recorded results confirm the effectiveness, superiority, and stability of the proposed approach in predicting the future consumption of energy in smart households. [ABSTRACT FROM AUTHOR]

Published

2022

2. IoT Based Electric Vehicle Application Using Boosting Algorithm for Smart Cities.

Author

Urooj, Shabana, Alrowais, Fadwa, Teekaraman, Yuvaraja, Manoharan, Hariprasath, Kuppusamy, Ramya, Ferreira, Joao, and Bayram, Islam Safak

Subjects

*BOOSTING algorithms, *SMART cities, *ELECTRIC vehicles, *ELECTRIC vehicle batteries, *INTERNET of things, *PLUG-in hybrid electric vehicles

Abstract

The application of Internet of Things (IoT) has been emerging as a new platform in wireless technologies primarily in the field of designing electric vehicles. To overcome all issues in existing vehicles and for protecting the environment, electric vehicles should be introduced by integrating an intellectual device called sensor all over the body of electric vehicle with less cost. Therefore, this article confers the need and importance of introducing electric vehicles with IoT based technology which monitors the battery life of electric vehicles. Since the electric vehicles are implemented with internet, an online monitoring system which is called Things Speak has been used for monitoring all the vehicles in a continuous manner (day-by-day). These online results will then be visualized in MATLAB after an effective boosting algorithm is integrated with objective function. The efficiency of proposed method is tested by visual analysis and performance results prove that the projected method on electric vehicle is improved when using IoT based technology. It is also observed that cost of implementation is lesser and capacity of electric vehicle is increased to about 74.3% after continuous monitoring with sensors. [ABSTRACT FROM AUTHOR]

Published

2021

3. New Gen Controlling Variable Using Dragonfly Algorithm in PV Panel.

Author

Urooj, Shabana, Alrowais, Fadwa, Kuppusamy, Ramya, Teekaraman, Yuvaraja, and Manoharan, Hariprasath

Subjects

*MAXIMUM power point trackers, *RENEWABLE energy sources, *ENERGY shortages, *TRACKING algorithms, *SOLAR energy, *ODONATA, *MATHEMATICAL optimization

Abstract

In the present scenario the depletion of conventional sources causes an energy crisis. The energy crisis causes load demand with respect to electricity. The use of renewable energy sources plays a vital role in reducing the energy crisis and in reduction of CO2 emission. The use of solar energy is the major source of power in generation as this is the root cause for the development of wind, tides, etc. However, due to climatic condition the availability of PV sources varies from time to time. Hence it is essential to track the maximum source of energy by implementing different types of MPPT algorithms. However, use of MPPT algorithms has the limitation of using the same during partial shadow conditions. The issue of tracking power under partial shadow conditions can be resolved by implementing an intelligent optimization tracking algorithm which involves a computation process. Though many of nature's inspired algorithms were present to address real world problems, Mirjalili developed the dragonfly algorithm to provide a better optimization solution to the issues faced in real-time applications. The proposed concept focuses on the implementation of the dragonfly optimization algorithm to track the maximum power from solar and involves the concept of machine learning, image processing, and data computation. [ABSTRACT FROM AUTHOR]

Published

2021