Index

Abstract

The trend analysis and GARCH model for COVID-19 pandemic spread between FCT/Lagos and the National Weekly confirmed pandemic cases were carried out using the statistical software Minitab17 and Gretl. Four models trend behavior were considered, which are linear, quadratic, cubic and quartic trends with respect to R-square value, Adjusted R-square value, Analysis of Variance (ANOVA) p-value and the estimated coefficients p-values. In addition, GARCH(0,1),GARCH(1,0) and GARCH(1,1) models were built separately for both  FCT/Lagos on the Nigeria National Weekly confirmed pandemic cases; to determine which model has best fit for predicting weekly confirmed cases of COVID-19 pandemic in those areas. The four common information criteria was used to selected the best model, which are the Akaike Information Criteria (AIC), Schwarz-Bayesian Information Criteria (BIC), Hannan-Quinn Information Criteria (HQC) and Likelihood Criteria (LKH).This study established the quadratic trend and GARCH(1,0) as the best model that describes the data sets for FCT. Hence, both models can be used to forecasts the weekly pandemic confirmed cases in these areas.

Keywords: Weekly COVID-19 confirmed pandemic cases, Information criteria, Trend analysis models, GARCH models.

JEL Classification: C10; C50; C51; C01.

Received: 3 January 2022 / Revised: 7 February 2022 / Accepted: 18 February 2022/ Published: 24 February 2022

Contribution/ Originality

This work is one of the few that has tried to model COVID-19 weekly confirmed cases in Nigeria. The work has been able to establish that the quadratic trend with GARCH (1,0) model was the best fit model for FCT and can be used to forecast weekly cases of COVID-19 in FCT Nigeria.

1. INTRODUCTION

The emergence of the COVID-19 disease has weakened the economy  of  many  nations, caused  confusion  in  communities  and  among  the  people,  kept  even  the  healthy  people away  from their  usual  or normal  way  of life. On  the  27th  day  of February,  2020,  Nigeria   recorded   its  first  case  of  covid-19 according  to  Nigeria  Center  for Diseases  Control on the 25th of February. Generalized Autoregressive Conditional Heteroskedasticity (GARCH) is a statistical model used in analyzing time-series data where the variance error is believed to be serially autocorrelated. GARCH models assume that the variance of the error term follows an autoregressive moving average process.

The variance of the error term in GARCH models is assumed to vary systematically, conditional on the average size of the error terms in previous periods. In other words, it has conditional heteroskedasticity, and the reason for the heteroskedasticity is that the error term is following an autoregressive moving average pattern. This means that it is a function of an average of its own past values, like in trend analysis. Trend analysis attempts to predict future stock price movements based on recently observed trend data.

This work tries to determine the best fit model for predicting confirmed COVID-19 cases in Abuja and Lagos based on the National Weekly Confirmed cases (NWC) using GARCH Model. Furthermore, this research work seeks to establish the trend component in both Lagos and Abuja COVID-19 confirmed cases using trend analysis method. That is to show the effect of Lagos and Abuja COVID-19 confirmed cases on National Weekly Confirmed cases. The research will determine statistically, the area that contributes more to the national weekly confirmed cases.

2. REVIEW OF LITERATURE

Abdulmajeed, Adeleke, and Popoola (2020) in their article titled “Online Forecasting of covid-19 cases in Nigeria using limited data”, investigated the extent of the spread and effectiveness of containment strategies to stem the transmission of the disease. The combination of Autoregressive Integrated Moving Average (ARIMA) and a Hot-Winters Exponential Smoothing models combined with Generalized Autoregressive Conditional Heteroskedasticity (GARCH) was employed. They concluded that it would be difficult to model covid-19 in the real-life scenario as inherent modeling difficulties, such as the number of tests, randomness and other factors contributed to the forecast model. Onafeso et al. (2021), conducted a research on Geographical Trend Analysis of covid-19 Pandemic onset in Africa. The method of Analysis of Variance (ANOVA) was used to show that significant variations exist among African countries in the number of covid-19 confirmed cases. Awan and Aslam (2020) predicted daily covid-19 cases in European countries using Automatic Autoregressive Integrated Moving Average (ARIMA) model. Malki et al. (2021) carried out a research on ARIMA models for predicting the end of COVID-19 pandemic and the risk of second rebound. The research work was necessary so that the questions of whether or not the virus will return can be answered. In this work, a predictive model that can estimate the expected period that the virus can be stopped and the risk of the second rebound of COVID-19 pandemic. Rauf and Oladipo (2020) did a work on Forecasting the spread of COVID-19 in Nigeria using Box-Jenkins Modeling Procedure.  This study focused on the analysis of the spread of Covid-19 in Nigeria, applying statistical models and available data from the NCDC. They presented an insight into the spread of Covid-19 in Nigeria in order to establish a suitable prediction model, which can be applied as a decision-supportive tool for assigning health interventions and mitigating the spread of the Covid-19 infection. Aronu, Ekwueme, Sol-Akubude, and Okafor (2021) carried out an investigation on Coronavirus (Covid-19) in Nigeria: They examined the survival rate of Covid-19 patients in Nigeria using the Autoregressive Integrated Moving Average (ARIMA) forecasting approach. Odukoya et al. (2020), conducted a research on Epidemiological Trends of Coronavirus Disease 2019 in Nigeria: From 1 to 10,000. A secondary data collected from Nigeria Centre for Disease Control (NCDC) was used and the method of line graphs was adopted to describe the data of the daily recorded cases of covid-19 in Nigeria. They discovered that the epidemic curve in Nigeria has been on an upward trajectory as the number of cases crossed the 10,000 mark.

3. METHODOLOGY

This study design is focused on Trend Analysis and GARCH Model of Covid-19 cases between the National Weekly Confirmed cases (NWC) in Lagos and Federal Capital Territory (Abuja). The data for this study is a secondary data extracted from the website of the National Centre for Disease Control (NCDC) on the daily confirmed cases of covid-19 in Nigeria. The daily and weekly reported and confirmed cases from March 16th,2020 to May 9th,2021. The Gretl statistical software and Minitab were used for the analyses.

3.1. Model Specification

GARCH (1,1) is represented as;

3.1.1. Trend Analysis

Trend analysis done for the linear trend model:

Equations 8a…10b represents the quadratic trend model, cubic trend model and quartic trend model, with Ci as the coefficients of the model, W represents FCT and X represents Lagos state.

3.1.2. Models Selection Criteria

The three selection models criteria applied were the Akaike Information Criteria (AIC), Schwarz-Bayesian Information Criteria (BIC), and Hannan-Quinn Information Criteria.

4. RESULTS

The descriptive statistics of the Covid-19 Pandemic in the Nigeria National Weekly Confirmed cases (NNWC); Lagos and Federal Capital Territory (Abuja) COVID-19 Cases in Table 1.

Table 1. Statistics of Covid-19 pandemic in the Nigeria.

Variable
Mean
SE Mean
St.
Dev
Minimum
Q1
Median
Q3
Maximum
Skewness
Kurtosis
LAGOS(x)
980
142
1099
57
297
623
1281
4780
2.27
5.01
FCT (w)
335
51.4
398.5
7
71.3
148.5
449
1727
1.76
2.42
NNWC (y)
2792
353
2738
81
976
1703
3956
11179
1.55
1.89

Table 1 shows the mean of the Covid-19 Pandemic in Nigeria, where the expected value is 980 cases for Lagos area, 335 for FCT and 2792 for National Weekly Confirmed cases.

4.1. Trend Analysis

The trends of the Covid-19 Pandemic of the two densely populated areas in Nigeria against the National weekly confirmed cases were identified below in Table 2 and in the plots; Figures 1 to 8. The fitted trends are linear, quadratic, cubic and quartic (or polynomial of order four) with their R-squares.

The results in Table 2 and Figures 1-4 identified that the quadratic trend is the best trend among the trend curves to describe Covid-19 Pandemic in FCT against the National weekly confirmed cases. The R-square value indicates that the predictors explain 87.41% of the variance of the Covid-19 Pandemic. This suggests that a quadratic trend or order two polynomial is more appropriate. The quadratic trend does not appear to be overfit and has adequate predictive ability. The identified trend is:

Table 2. Trend analysis of NNWC (y) against FCT (w).

Note: ** significant at 5% level of significance.

Figure 1. Quadratic trend between FCT and NWC.

Figure 2. Linear trend between FCT and NWC.

Figure 3. Cubic trend between FCT and NWC.

Figure 4. Quartic trend between FCT and NWC.

Table 3. Trend analysis of NNWC (y) against LAGOS (w).

Note:  ** significant at 5% level of significance.

The results in Table 3 and Figures 5 – 8 identified that the quadratic trend is the best trend among the trend curves to describe Covid-19 Pandemic in LAGOS against the National weekly confirmed cases. The R-square value indicates that the predictors explain 92.5% of the variance of the Covid-19 Pandemic. This suggests that a quadratic trend is more appropriate. The quadratic trend does not appear to be over fit and has adequate predictive ability.

Figure 5. Linear trend between Lagos and NWC.

Figure 6. Quadratic trend between Lagos and NWC.

Figure 7. Cubic trend between Lagos and NWC.

Figure 8. Quartic trend between Lagos and NWC.

4.2. GARCH Model

Three GARCH models were built to the COVID 19 pandemic FCT and Lagos against the Nigeria National weekly confirmed case, which are ARCH(1) or GARCH(0,1); GARCH(1,0) and GARCH(1,1). The summarized result is in Table 4.

Table 4. GARCH (p,q) models parameter estimate and selection criteria values for FCT against the national weekly confirmed case.

Note: **-Sig. at 5%; *-Sig. at 10%.

From the Table 4, the identified GARCH model is GARCH (0,1), since all its parameters are significant at 5% and 10% also two of its model selection criteria are smaller than the other two GARCH models. 

Table 5. GARCH (p,q) Models parameter estimate and selection criteria values for LAGOS against the national weekly confirmed case.

Note: **-Sig. at 5%; *-Sig. at 10%;

From the Table 5, the identified GARCH model is GARCH (1,0), since all its parameters are significant at 5% and 10% and all its model selection criteria are smaller better than the other GARCH model.

4.2.1. Comparison of the Identified GARCH Model of the Two AREA

We compare the two identified GARCH model in the two areas to determine the model that has more effect on National weekly confirmed cases in Table 6.

Table 6. GARCH (p,q) models parameter estimate and selection criteria values between FCT/LAGOS against the national weekly confirmed cases.

Note:  **-Sig. at 5%; *-Sig. at 10%.

Table 6 show that GARCH model with the highest effect on Nigeria National weekly confirmed cases is GARCH (1,0) for LAGOS, since all its parameters are significant at 5% and 10% and all its model selection criteria are smaller better than of FCT GARCH model (GARCH (0,1).

5. SUMMARY AND CONCLUSION 

The trend analysis and GARCH model on covid-19 pandemic spread between FCT/Lagos and the National Weekly confirmed pandemic cases were carried out using the Minitab17 software and Gretl. The Figures 1 to 8 show the linear, quadratic, cubic and quartic trends for both FCT and Lagos, Tables 2 to 4 show the analysis of the GARCH models. However, this study has established the quadratic trend and the Lagos GARCH (1,0) as the best model that describes the data. GARCH (0,1), GARCH (1,0) and GARCH (1,1) were built separately for both FCT and Lagos to determine which one was best for the weekly reported cases of covid-19 pandemic in those areas. GARCH (0,1) was identified as the best of the three (3) models built for FCT weekly confirmed cases. While GARCH (1,0) was identified for Lagos weekly pandemic confirmed cases. Comparing the two models; GARCH(0,1) of FCT and GARCH(1,0) of Lagos, considering the model selection criteria (AIB,BIC,HQC and LKH)and parameter estimates (p-values), GARCH (1,0) was found to be better. This implies that the effects of the number of pandemic cases confirmed will be more on Lagos.

Funding: This study received no specific financial support.  

Competing Interests: The authors declare that they have no competing interests.

Authors’ Contributions: All authors contributed equally to the conception and design of the study.

REFERENCES

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