A non-central beta model to forecast and evaluate pandemics time series

Firmino, Paulo Renato Alves; Sales, Jair Paulino de; Júnior, Jucier Gonçalves; Silva, Taciana Araújo da

doi:10.1016/j.chaos.2020.110211

Cited by 14 publications

(7 citation statements)

References 36 publications

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“…Furthermore, we clarify that cluster number (three) in our empirical evidence is associated with the four phases of COVID-19. For more details, see: [23] , [24] , [25] , [26] . In this way, the discussion is divided into two distinct phases.…”

Section: Resultsmentioning

confidence: 99%

Dynamics diagnosis of the COVID-19 deaths using the Pearson diagram

Gonçalves¹,

Fernandes²,

Nascimento³

2022

Chaos, Solitons & Fractals

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Section: Resultsmentioning

confidence: 99%

Dynamics diagnosis of the COVID-19 deaths using the Pearson diagram

Gonçalves¹,

Fernandes²,

Nascimento³

2022

Chaos, Solitons & Fractals

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“…Finally, some studies [16] – [22] , [131] – [146] followed a model-agnostic approach and relied solely on the historical time series data of COVID-19 cases or other relevant predictors to forecast future cases. These methods employ machine learning models (neural networks [17] – [21] , [133] , [135] , [138] , [142] and deep learning [139] ) to make predictions while using various optimization algorithms (such as Gaussian process regression [16] , Bayesian optimization [17] , and metaheuristic algorithms [18] – [22] , [144] , [147] – [149] ) to optimize the model hyperparameters.…”

Section: The Four Framework and Literature Reviewmentioning

confidence: 99%

Optimization in the Context of COVID-19 Prediction and Control: A Literature Review

et al. 2021

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This paper presents an overview of some key results from a body of optimization studies that are specifically related to COVID-19, as reported in the literature during 2020-2021. As shown in this paper, optimization studies in the context of COVID-19 have been used for many aspects of the pandemic. From these studies, it is observed that since COVID-19 is a multifaceted problem, it cannot be studied from a single perspective or framework, and neither can the related optimization models. Four new and different frameworks are proposed that capture the essence of analyzing COVID-19 (or any pandemic for that matter) and the relevant optimization models. These are: (i) microscale vs. macroscale perspective; (ii) early stages vs. later stages perspective; (iii) aspects with direct vs. indirect relationship to COVID-19; and (iv) compartmentalized perspective. To limit the scope of the review, only optimization studies related to the prediction and control of COVID-19 are considered (public health focused), and which utilize formal optimization techniques or machine learning approaches. In this context and to the best of our knowledge, this survey paper is the first in the literature with a focus on the prediction and control related optimization studies. These studies include optimization of screening testing strategies, prediction, prevention and control, resource management, vaccination prioritization, and decision support tools. Upon reviewing the literature, this paper identifies current gaps and major challenges that hinder the closure of these gaps and provides some insights into future research directions.

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“…Countries and territories suffered different impacts due to the SARS-COV-2 pandemic reflected by the cumulative deaths per 100 thousand population that varied enormously from 0.0 in Mongolia to 191.5 in San Marino [7] . Previous studies indicate different spread dynamics between diverse countries, maybe reflecting different degrees of efficiency in relation to the response to the pandemic [8] , [9] . It is essential to understand COVID-19 lethality dynamics to design more robust strategies to the pandemic.…”

Section: Introductionmentioning

confidence: 99%

Predictability of COVID-19 worldwide lethality using permutation-information theory quantifiers

Fernandes¹,

Araujo²,

Silva³

et al. 2021

Results in Physics

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This paper examines the predictability of COVID-19 worldwide lethality considering 43 countries. Based on the values inherent to Permutation entropy ( ) and Fisher information measure ( ), we apply the Shannon-Fisher causality plane (SFCP), which allows us to quantify the disorder an evaluate randomness present in the time series of daily death cases related to COVID-19 in each country. We also use Hs and Fs to rank the COVID-19 lethality in these countries based on the complexity hierarchy. Our results suggest that the most proactive countries implemented measures such as facemasks, social distancing, quarantine, massive population testing, and hygienic (sanitary) orientations to limit the impacts of COVID-19, which implied lower entropy (higher predictability) to the COVID-19 lethality. In contrast, the most reactive countries implementing these measures depicted higher entropy (lower predictability) to the COVID-19 lethality. Given this, our findings shed light that these preventive measures are efficient to combat the COVID-19 lethality.

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A non-central beta model to forecast and evaluate pandemics time series

Cited by 14 publications

References 36 publications

Dynamics diagnosis of the COVID-19 deaths using the Pearson diagram

Dynamics diagnosis of the COVID-19 deaths using the Pearson diagram

Optimization in the Context of COVID-19 Prediction and Control: A Literature Review

Predictability of COVID-19 worldwide lethality using permutation-information theory quantifiers

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