Predicting the spread of COVID-19 in Delhi, India using Deep Residual Recurrent Neural Networks

• URL: http://arxiv.org/abs/2110.05477v1
• Date: Sat, 9 Oct 2021 19:16:36 GMT
• Title: Predicting the spread of COVID-19 in Delhi, India using Deep Residual Recurrent Neural Networks
• Authors: Shashank Reddy Vadyala, Sai Nethra Betgeri
• Abstract summary: The dynamics of COVID 19 were extracted using Convolutional Neural Networks and Deep Residual Recurrent Neural Networks. The DRRNNs COVID-19 prediction model has been shown to have accurate COVID-19 predictions.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Detecting the spread of coronavirus will go a long way toward reducing human and economic loss. Unfortunately, existing Epidemiological models used for COVID 19 prediction models are too slow and fail to capture the COVID-19 development in detail. This research uses Partial Differential Equations to improve the processing speed and accuracy of forecasting of COVID 19 governed by SEIRD model equations. The dynamics of COVID 19 were extracted using Convolutional Neural Networks and Deep Residual Recurrent Neural Networks from data simulated using PDEs. The DRRNNs accuracy is measured using Mean Squared Error. The DRRNNs COVID-19 prediction model has been shown to have accurate COVID-19 predictions. In addition, we concluded that DR-RNNs can significantly advance the ability to support decision-making in real time COVID-19 prediction.

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