A Novel Intelligent Computational Approach to Model Epidemiological Trends and Assess the Impact of Non-Pharmacological Interventions for COVID-19

The novel coronavirus disease 2019 (COVID-19) pandemic has led to a worldwide crisis in public health. It is crucial we understand the epidemiological trends and impact of non-pharmacological interventions (NPIs), such as lockdowns for effective management of the disease and control of its spread. We develop and validate a novel intelligent computational model to predict epidemiological trends of COVID-19, with the model parameters enabling an evaluation of the impact of NPIs. By representing the number of daily confirmed cases (NDCC) as a time-series, we assume that, with or without NPIs, the pattern of the pandemic satisfies a series of Gaussian distributions according to the central limit theorem. The underlying pandemic trend is first extracted using a singular spectral analysis (SSA) technique, which decomposes the NDCC time series into the sum of a small number of independent and interpretable components such as a slow varying trend, oscillatory components and structureless noise. We then use a mixture of Gaussian fitting (GF) to derive a novel predictive model for the SSA extracted NDCC incidence trend, with the overall model termed SSA-GF. Our proposed model is shown to accurately predict the NDCC trend, peak daily cases, the length of the pandemic period, the total confirmed cases and the associated dates of the turning points on the cumulated NDCC curve. Further, the three key model parameters, specifically, the amplitude (alpha), mean (mu), and standard deviation (sigma) are linked to the underlying pandemic patterns, and enable a directly interpretable evaluation of the impact of NPIs, such as strict lockdowns and travel restrictions. The predictive model is validated using available data from China and South Korea, and new predictions are made, partially requiring future validation, for the cases of Italy, Spain, the UK and the USA. Comparative results demonstrate that the introduction of consistent control measures across countries can lead to development of similar parametric models, reflected in particular by relative variations in their underlying sigma, alpha and mu values. The paper concludes with a number of open questions and outlines future research directions.

[1]  Kaizhu Huang,et al.  Discriminant Zero-Shot Learning with Center Loss , 2019, Cognitive Computation.

[2]  Carl A. B. Pearson,et al.  The effect of control strategies to reduce social mixing on outcomes of the COVID-19 epidemic in Wuhan, China: a modelling study , 2020, The Lancet Public Health.

[3]  Ruifu Yang,et al.  An investigation of transmission control measures during the first 50 days of the COVID-19 epidemic in China , 2020, Science.

[4]  Wei Feng,et al.  Trend and forecasting of the COVID-19 outbreak in China , 2020, Journal of Infection.

[5]  Yaqing Fang,et al.  Transmission dynamics of the COVID‐19 outbreak and effectiveness of government interventions: A data‐driven analysis , 2020, Journal of medical virology.

[6]  P. Klepac,et al.  Early dynamics of transmission and control of COVID-19: a mathematical modelling study , 2020, The Lancet Infectious Diseases.

[7]  Justin A. Drake,et al.  SVD Identifies Transcript Length Distribution Functions from DNA Microarray Data and Reveals Evolutionary Forces Globally Affecting GBM Metabolism , 2013, PloS one.

[8]  Jessica T Davis,et al.  The effect of travel restrictions on the spread of the 2019 novel coronavirus (COVID-19) outbreak , 2020, Science.

[9]  Kaizhu Huang,et al.  Style-Neutralized Pattern Classification Based on Adversarially Trained Upgraded U-Net , 2019, Cognitive Computation.

[10]  I. Barany,et al.  Central limit theorems for Gaussian polytopes , 2006 .

[11]  Cheng-Shang Chang,et al.  A Time-Dependent SIR Model for COVID-19 With Undetectable Infected Persons , 2020, IEEE Transactions on Network Science and Engineering.

[12]  M. Xiong,et al.  Artificial Intelligence Forecasting of Covid-19 in China , 2020, International Journal of Educational Excellence.

[13]  Erfu Yang,et al.  A New Algorithm for SAR Image Target Recognition Based on an Improved Deep Convolutional Neural Network , 2018, Cognitive Computation.

[14]  D. Adam Special report: The simulations driving the world’s response to COVID-19 , 2020, Nature.

[15]  J. Ji,et al.  Real-time estimation and prediction of mortality caused by COVID-19 with patient information based algorithm , 2020, Science of The Total Environment.

[16]  M. Ward,et al.  COVID-19 transmission in Mainland China is associated with temperature and humidity: A time-series analysis , 2020, Science of The Total Environment.

[17]  Rui Zhang,et al.  A Novel Deep Density Model for Unsupervised Learning , 2018, Cognitive Computation.

[18]  Cui Meng,et al.  Propagation analysis and prediction of the COVID-19 , 2020, Infectious Disease Modelling.

[19]  Peide Liu,et al.  A Novel Decision-Making Method Based on Probabilistic Linguistic Information , 2019, Cognitive Computation.

[20]  Rajan Gupta,et al.  Trend Analysis and Forecasting of COVID-19 outbreak in India , 2020, medRxiv.

[21]  G. Leung,et al.  Nowcasting and forecasting the potential domestic and international spread of the 2019-nCoV outbreak originating in Wuhan, China: a modelling study , 2020, The Lancet.

[22]  Charles F. F. Karney Sampling Exactly from the Normal Distribution , 2013, ACM Trans. Math. Softw..

[23]  Anatoly A. Zhigljavsky,et al.  Singular Spectrum Analysis for Time Series , 2013, International Encyclopedia of Statistical Science.

[24]  Cui Meng,et al.  Propagation analysis and prediction of the COVID-19 , 2020, Infectious Disease Modelling.

[25]  Haoyang Sun,et al.  Interventions to mitigate early spread of SARS-CoV-2 in Singapore: a modelling study , 2020, The Lancet Infectious Diseases.

[26]  Giancarlo Fortino,et al.  CNN-Based Health Model for Regular Health Factors Analysis in Internet-of-Medical Things Environment , 2020, IEEE Access.