Modeling Provincial Covid-19 Epidemic Data Using an Adjusted Time-Dependent SIRD Model

Ferrari, Luisa; Gerardi, G; Manzi, Giancarlo; Micheletti, Alessandra; Nicolussi, Federica; Biganzoli, Elia; Salini, Silvia

doi:10.3390/ijerph18126563

Cited by 25 publications

(17 citation statements)

References 46 publications

(47 reference statements)

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“…1 . The situation is quite different from the german case, in which mild measures were implemented very early to curb the spread [8] , the italian case, where strongth spatiotemporal differences between regions occurred [6] , [17] , and from studies of initial stages [11] , [19] . Nevertheless, our methods apply to data for diagnosed, dead and recovered individuals from any other country.…”

Section: Introductionmentioning

confidence: 85%

“…An increasing number of mathematical studies assess the efficacy of different policies [4] , [5] , [6] , [7] , [8] , [9] . Moreover, mathematical models and data analysis are employed to estimate relevant epidemiological parameters [4] , [10] , [11] , [12] , [13] , [14] and to try to forecast the evolution [15] , [16] , [17] , [18] , [19] , [20] , [21] . While some of this research is based on direct data analysis [4] , [13] , machine learning techniques [15] , [21] or empirical laws for different populations [9] , the use of balance equations to predict population dynamics is a common approach.…”

Section: Introductionmentioning

confidence: 99%

“…The specific structure of the selected models depends on the available information and on assumptions about the epidemic spread [24] . Basic SIR models involve populations of susceptible

, infected

, and recovered

individuals, expecting immunity of the latter [8] , [14] , [17] , [25] . SEIR variants distinguish also the individuals exposed to the virus

, which may become infective [11] , [19] .…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Uncertainty quantification in Covid-19 spread: Lockdown effects

Carpio

Pierret²

2022

Results in Physics

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Section: Introductionmentioning

confidence: 85%

Section: Introductionmentioning

confidence: 99%

“…The specific structure of the selected models depends on the available information and on assumptions about the epidemic spread [24] . Basic SIR models involve populations of susceptible

, infected

, and recovered

individuals, expecting immunity of the latter [8] , [14] , [17] , [25] . SEIR variants distinguish also the individuals exposed to the virus

, which may become infective [11] , [19] .…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Uncertainty quantification in Covid-19 spread: Lockdown effects

Carpio

Pierret²

2022

Results in Physics

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“…Pinter et al [106] Multi-layered perceptron Predictions of mortality rate and infected cases Aminu et al [107] Deep neural networks Detection of people with COVID-19 Magar et al [108] Ensemble techniques Virus-antibody sequence analysis and patients' Identification Zeng et al [109] Extreme Gradient Boosting (XGBoost) Forecasting of patient survival probability Ashraf et al [110] Machine & deep learning models Predict the severity of disease or chances of death Shah et al [111] Convolutional neural network (CNN) COVID-19 detection from X-ray images Prakash et al [112] Autoregressive Integrated Moving Average Impact analysis of various policies Rathod et al [113] AI Prediction models Effective crisis preparedness and management Ullah et al [114] Logistic Regression and Support Vector Machine Classification of patients with/without COVID-19 Rathod et al [115] SVM, RProp, and Decision tree Detection of abnormal data for effective analysis Hu et al [116] Spectral Clustering (SC) algorithm Feasible analysis model for the treatment & diagnosis Rashed et al [117] Long short-term memory (LSTM) network Provides public awareness about the risks of COVID-19 Singh et al [118] ResNet152V2 and VGG16 CNN Reduce the high false-negative results of the RT-PCR Saverino et al [119] Digital and artificial intelligence platform (DAIP) Changes implementation in rehabilitation services Peddinti et al [120] Convolutional Neural Network (CNN) Detection of COVID-19 cases in public places Malla et al [121] Ensemble deep learning model Real-time sentiment analysis of COVID-19 data Lella et al [122] Convolutional Neural Network (CNN) model Respiratory sound classification for patient identification Haleem et al [123] Artificial neuronal networks (ANN) Predictions of survival of COVID-19 patients Hashimi et al [124] Deep learning models Tracking and identifying potential virus spreaders Amaral et al [125] Artificial neuronal networks (ANN) forecasting and monitoring the progress of Covid-19 Zgheib et al [126] Collection of ensemble learning methods Detecting COVID-19 virus based on patient's demographics Ferrari et al [127] Bayesian framework Predictions about the behavior of the COVID-19 epidemic Almalki et al [128] COVID Inception-ResNet model (CoVIRNet) Automatic diagnosis of the COVID-19 patients Umair et al …”

Section: Ai Technique Used Purpose In the Context Of Covid-19 Pandemicmentioning

confidence: 99%

Data-Driven Analytics Leveraging Artificial Intelligence in the Era of COVID-19: An Insightful Review of Recent Developments

Majeed

Hwang

2021

Symmetry

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This paper presents the role of artificial intelligence (AI) and other latest technologies that were employed to fight the recent pandemic (i.e., novel coronavirus disease-2019 (COVID-19)). These technologies assisted the early detection/diagnosis, trends analysis, intervention planning, healthcare burden forecasting, comorbidity analysis, and mitigation and control, to name a few. The key-enablers of these technologies was data that was obtained from heterogeneous sources (i.e., social networks (SN), internet of (medical) things (IoT/IoMT), cellular networks, transport usage, epidemiological investigations, and other digital/sensing platforms). To this end, we provide an insightful overview of the role of data-driven analytics leveraging AI in the era of COVID-19. Specifically, we discuss major services that AI can provide in the context of COVID-19 pandemic based on six grounds, (i) AI role in seven different epidemic containment strategies (a.k.a non-pharmaceutical interventions (NPIs)), (ii) AI role in data life cycle phases employed to control pandemic via digital solutions, (iii) AI role in performing analytics on heterogeneous types of data stemming from the COVID-19 pandemic, (iv) AI role in the healthcare sector in the context of COVID-19 pandemic, (v) general-purpose applications of AI in COVID-19 era, and (vi) AI role in drug design and repurposing (e.g., iteratively aligning protein spikes and applying three/four-fold symmetry to yield a low-resolution candidate template) against COVID-19. Further, we discuss the challenges involved in applying AI to the available data and privacy issues that can arise from personal data transitioning into cyberspace. We also provide a concise overview of other latest technologies that were increasingly applied to limit the spread of the ongoing pandemic. Finally, we discuss the avenues of future research in the respective area. This insightful review aims to highlight existing AI-based technological developments and future research dynamics in this area.

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“…In [ 12 , 13 ], accurate prediction of NACPs and NADPs of COVID-19 in different countries were made. Alos [ 14 ], Lounis [ 15 ], Ferrari [ 16 ], and Sedaghat [ 17 ] used SIRD model to predict the spread trend of COVID-19 in some countries. Long-term forecast of COVID-19 was made in some regions at home and abroad in [ 18 , 19 ].…”

Section: Introductionmentioning

confidence: 99%

Long-term prediction of the sporadic COVID-19 epidemics induced by $$\delta$$-virus in China based on a novel non-autonomous delayed SIR model

Pei

2022

Eur. Phys. J. Spec. Top.

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With the outbreaks of the COVID-19 epidemics in several provinces of China, government takes prevention and control measures to contain the epidemics. It is more difficult to make the long-term prediction of the sporadic COVID-19 epidemics than widespread ones in that the former cannot obey the laws of the infectious disease well like the latter. In this paper, we make long-term predictions including end time and final size, peak and peak time of current confirmed cases and the number of accumulative removed cases of the sporadic COVID-19 epidemics in different regions of China by a novel non-autonomous delayed SIR compartment model (S—susceptible, I—infected, R—removed). The key contribution of this paper is that under the rigorous containments, we find transmission rate is approximately an exponential decreasing function with respect to time t, rather than a fixed constant. In addition, the removed rate is approximately a piecewise linear increasing function instead of a linear increasing function which is (at + b)heaviside (t-14). First, according to the few data in the early stage, i.e., roughly the first 7 days, issued by the National Health Commission of China and local Health Commissions, we can accurately estimate these parameters, i.e., transmission and removed rates of the model. Then, by them, we accurately predict the evolution of the COVID-19 there. On the basis of them to predict Category A of the sporadic COVID-19 epidemics since July 20th, 2021 in this summer. The results agree very well to the actual ones. It is also adopted to predict Category B the tour group epidemics since October 17th, 2021 and Category C other sporadic epidemics since October 27th, 2021. The results show that although our method is simple and the needed data are very few, the long-term prediction of the sporadic COVID-19 epidemics in China is quite effective. We can use this novel non-autonomous delayed SIR model to accurately predict its end time and final size, peak and peak time of current confirmed cases and the number of accumulative removed cases in China. This work can help governments and policy-makers make optimal prevention and control policies for all cities and provinces to contain the COVID-19 epidemics, and prepare well for the resumption of work, production and classes in advance to reduce the economic and social losses.

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Modeling Provincial Covid-19 Epidemic Data Using an Adjusted Time-Dependent SIRD Model

Cited by 25 publications

References 46 publications

Uncertainty quantification in Covid-19 spread: Lockdown effects

Uncertainty quantification in Covid-19 spread: Lockdown effects

Data-Driven Analytics Leveraging Artificial Intelligence in the Era of COVID-19: An Insightful Review of Recent Developments

Long-term prediction of the sporadic COVID-19 epidemics induced by $$\delta$$-virus in China based on a novel non-autonomous delayed SIR model

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