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RESEARCH ARTICLE 

 

Quantifying The Significance of Distance to Temporal Dynamics of 

Covid-19 Cases in Nigeria Using a Geographic Information System 

Ifeyinwa Sarah Obuekwe1, 2* , Umar Saleh Anka1,3 , Sodiq Opeyemi Ibrahim1,3 , 

Usman Ahmad Adam4 
1Nigerian Environmental Society, Nigeria 

2Department of Microbiology, Faculty of Life Sciences, University of Benin, Benin City, Edo 

State, PMB. 1154, Nigeria 
3 Department of Geography, Faculty of Earth and Environmental Sciences, Bayero University, 

Kano State, Nigeria 
4 Department of Geography, Sa’adatu Rimi College of Education, Kumbotso, Kano, Nigeria 

 
Received 16 December 2020 /Revised 8 April 2021 /Accepted 17 April 2021 /Published  25 April 2021 

 

Abstract 

The coronavirus disease 2019 (COVID-19) is caused by a new strain of coronavirus that spreads 

primarily by close contact. Although Nigeria adopted lockdown measures, no defined strategies 

were used in setting the distance threshold for these lockdowns. Hence, understanding the drivers 

of COVID-19 is pivotal to an informed decision for containment measures in the absence of 

vaccines. Spatial and temporal analyses are crucial drivers to apprehending the pattern of 

diseases over space and time. Thus, this study aimed to quantify the significance of distance to 

the temporal dynamics of COVID-19 cases in Nigeria using the Geographic Information System. 

Incremental spatial autocorrelation was used to analyze datasets of each month in ArcGIS. 

March, April, May, and June exhibited patterns with no significant peaks, while July and August 

exhibited patterns with two statistically significant peaks. The first and second peaks of July 

were 301,338.39 and 365,947.83 meters, respectively, while August was 301,338.39 and 

336,128.09 meters, respectively. Therefore, a significant difference in the clustering of COVID-

19 over distances between July and August was established. This indicated that progression in 

the spread of the virus increased the virus's spatial coverage while the distance of risk of 

exposure decreased. This study's findings could be utilized to establish maximum movement 

restriction areas to contain the spread of COVID-19. 

Keywords: Distance; Incremental spatial autocorrelation; Covid-19; Disease; Nigeria 

1. Introduction 

COVID-19 is a respiratory disease that emerged in late 2019 caused by a new 

coronavirus that presents pneumonia-like symptoms. Therefore, it has high transmission 

competence and spreads primarily when people are in close contact (Dhama et al., 2020). 

 

                Geosfera Indonesia                              

*Corresponding author. 

 Email address : ifeyinwa.obuekwe@uniben.edu (Ifeyinwa Sarah Obuekwe) 

 

 

 

Vol. 6 No. 1, April 2021, 40-54 

p-ISSN 2598-9723, e-ISSN 2614-8528                                                                                                                                         

https://jurnal.unej.ac.id/index.php/GEOSI          

DOI : 10.19184/geosi.v6i1.21405 

 

https://orcid.org/0000-0002-0187-7731
https://orcid.org/0000-0002-7984-0947
https://orcid.org/0000-0002-4635-8521
mailto:ifeyinwa.obuekwe@uniben.edu


 

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COVID-19 is causing an ongoing pandemic in many countries and territories, and therefore, it is 

a global health crisis (Mckee & Stuckler, 2020).  

Infected people are accommodated and isolated in designated health facilities across the 

world for treatment. In the absence of a vaccine to prevent or aid speedy recovery, a significant 

concern is that, as the number of infected people increases, the healthcare system will be 

overwhelmed (Murray et al., 2020). Nevertheless, efforts to prevent further spreading are 

ongoing in many nations as vaccines, and antiviral drugs are awaited. 

In response to the worldwide COVID-19 outbreak, many sub-Saharan Africa countries 

have implemented strict lockdown measures to emulate high-income countries to contain the 

spread of the virus (Teachout & Zipfel, 2020).  However, severe restrictions placed on people's 

travel may impact different livelihoods, especially the world’s poorest people (Woodhill, 2020). 

Gradually, the impact of the lockdown is unfolding and remains largely guesswork. 

Despite the likelihood of severe impact of lockdown on livelihoods, there is no adequate 

information to help guide the threshold with which movement restriction can be placed. Details 

about places where cases may arise concerning identified cases could help enhance movement 

restriction decisions. Wang et al. (2021) claimed that the temporal trends of COVID-19 across 

space require deliberation when considering lifting lockdown. This makes the need for a timely 

knowledge of the temporal and spatial patterns of COVID-19 transmission. However, knowledge 

of the geographical mean distances between the locations of cases and the direct estimation of 

distances between sequential cases requires both the recognition of cases and their infectors 

(Salje et al., 2016). Such contact tracing efforts are nearly impossible because of two major 

restrains, cost and time. Thus, limited data hinders the ability to characterize the space and time 

scales where cases tend to occur.  

Estimating mean transmission distances have been possible previously only in situations 

where there is available data for most cases in a transmission network or detailed 

epidemiological data on who infected whom (Memish et al., 2014; Marziano et al., 2017; Yang 

et al., 2020). In the absence of data on where COVID-19 cases were discovered in Nigeria, there 

is the need to seek alternatives that can help in decision-making before the spread of the virus is 

beyond management capacity. Hence, this study's novelty was that it demonstrated an approach 

to quantify the significance of temporal dynamics in the mean transmission distance of recorded 

COVID-19 cases in Nigeria. This was based on the use of geographic information system 



 

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software, data of the monthly COVID-19 recorded cases, and the coordinates of the capital of the 

thirty-six (36) States in Nigeria and the Federal Capital Territory. This study aimed to quantify 

the significance of distance to the temporal dynamics of COVID-19 cases in Nigeria using the 

Geographic Information System. 

2. Methods 

2.1  Description of Study Area 

Nigeria  covers an area of 923,769 square kilometers, and it’s bordered by different 

countries on the north, south, east and west. On the north is Niger and Chad, south is Gulf of 

Guinea while the east and west are Cameroon, Benin and Niger respectively (National Bureau of 

Statistics, 2011). 

2.2 Study Area Ecosystem 

The coast of Nigeria is surrounded by flowering trees in marshes which are traversed by 

estuaries and rivers as well as the great Niger basin (National Bureau of Statistics, 

2011).Eastwards however, lie successive belts of tropical rain forests and the undulating plateau, 

rising from 609.6 meters on the average to 1,828.8 meters. Grassland vegetation interspersed 

with trees and shrubs is seen midway north of the country however, this stops at the north-east 

desert which is the grassy coast region. 

River Niger receives its Benue counterpart at Lokoja, and from there flows into the 

Atlantic Ocean for about 547 kilometers. Its tributaries include include Sokoto, Kaduna and 

Anambra Rivers (National Bureau of Statistics, 2011). However, the Benue River is fed by two 

rivers namely Katsina-Ala and Gongola. Nigeria has other rivers which include Cross River, 

Benin and Ogun rivers (National Bureau of Statistics, 2011). 

2.3 Study Area Population and Geopolitical Zones 

The population of Nigeria in mid-year of 2020 is estimated at 206,139,589 people based 

on United Nation data (Worldometer, 2020). Nigeria practices democratic system of government 

and each state and the Federal Capital Territory has their elected officials. The elected officials 

are from political parties within the country. 



 

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Figure 1. Nigeria 36 states and the federal capital territory in their geopolitical zones (GIS Lab 

Geography Department, 2020) 

 

2.4 Research Design 

The study was an explorative research. Due to the newness of COVID-19, explorative 

research has been adopted in several studies (Scarpone et al., 2020) as it offers researchers the 

opportunity to study a problem that has not been thoroughly studied in the past. 

2.5 Data and Sources of Data 

The study made use of publicly available COVID-19 and spatial datasets. The COVID-19 

dataset used include monthly recorded cases from March to August, 2020. The data were 

downloaded from Nigeria Centre for Disease Control (2020) website 

(https://covid19.ncdc.gov.ng/). This data is updated once a day (at 23:59 WAT).The spatial data 

used for this study was shapefile of Nigeria including states and coordinates of state capitals. The 

spatial data were sourced from the Geographic Information System Laboratory, Department of 

Geography Bayero University, Kano. 

https://covid19.ncdc.gov.ng/


 

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2.6 Data Analysis 

The monthly COVID-19 recorded cases for the 36 states and the federal capital of 

Nigeria were subjected to incremental spatial autocorrelation analysis in ArcGIS 10.5 with the 

use of a conceptualized fixed distance. The incremental spatial autocorrelation analysis work in 

such a way that it calculates the Moran’s I index and z score of a single data set at multiple 

distances. Z-score is a standard deviation which measures the distance of a raw score from the 

mean. Also, the rule of thumb for pattern analysis like spatial autocorrelation is that the z-score 

and p-values obtained determine the confidence level which can be used to accept or reject a null 

hypothesis. Hence, the threshold for determining the confidence level of a z-score and p-value is 

shown in Table 1. 

Hence, analyzed fixed distances were derived from each of the possible distance between 

a data point (a state capital) and all other data points (other state capitals). As in the case of this 

study, Moran’s I index was run for all the possible distances that existed between the 36 states 

and the federal capital of Nigeria. Instead of using the Moran’s I index value, the distance was 

used to plot the z scores. This enabled a standardized distance-based comparison of statistical 

significance using the threshold in Table 1. Larger positive z scores indicate high significant 

clustering (Table 1). Thus, in each of the plots, distances of the first peak and maximum peak 

were identified, as the first peak indicates lower statistically significant clustering while the 

maximum peak indicates the distance that clustering or spatial autocorrelation was of most 

statistical significance in the data set. Also, different colors were used to indicate the z-scores 

each distant point belong to as well as which distance is characterized as a peak.  

Table 1. Critical p-values and z-scores for Different Confident Levels (Moran, 1948) 

z-score (Standard Deviations) p-value (Probability) Confidence Level (%) 

< -1.65 or > + 1.65 < 0.10 90 

< -1.96 or > + 1.96 < 0.05 95 

< -2.58 or > + 2.58 < 0.01 99 

 

Furthermore, the distance of each state capital to other state capital and the federal capital 

was first obtained in ArcGIS via point distance analysis. The obtained distance was then 

exported to excel where the mean was determined. In addition, bar graph was used to visualize 

the mean distance and distances where Covid 19 clustering were significant. Afterwards, 



 

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distances with significant peaks was compared with the mean distance of each state capital and 

the Federal Capital to other state capital and Federal Capital. The flowchart of the methodology 

for the study is summarized in Figure 2. 

 

Figure 2. Flowchart of the method of the study 

 

3. Results and Discussion 

After the index case of COVID 19 in February, by the end of March, Lagos has recorded 

62 cases and was the highest state in Nigeria with recorded cases (Figure 3). This was followed 

by the Federal Capital Territory, which had a recorded 9-28 victims. South Western states that 

were closer to Lagos were also observed to have recorded 4-8 victims. The cases recorded in 

Kaduna, Bauchi, Ekiti, Edo, Benue, Enugu, and Rivers were within 1-3 while the other states had 

no recorded cases. Alkhamis et al. (2020) also observed that after about a month from the first 

reported case of COVID-19 in Kuwait, the size was small despite sporadic infections. Gayawan 

et al. (2020) also stated that COVID-19 initially had a slow spread across Africa, only for the 

situation to escalate in the last week of March. 

In April, although Lagos still had the highest recorded cases, the spread of the virus in the 

north within the addition of one month is a course to worry about (Figure 5). Kano state that had 

no recorded case in March had the same range of 77-219 recorded cases with the Federal Capital 

Territory. This implies that the rate of spread in the north was high in April, despite the Federal 

Government imposing a lockdown on Lagos, Ogun, and Abuja on March 30, 2020. The high 



 

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spread indicates the lockdown was not as effective as that of China's strict lockdown (Prem et al., 

2020).  

May's spread exceeds that of March and April combined with Kano having more 

recorded cases than the Federal Capital Territory. Despite the lockdown, border porosity, which 

is an issue in most African countries (Okunade & Ogunnubi, 2019), makes it hard to restrict 

mobility effectively. The ability to contain human mobility has been an issue worldwide as 

Migrant workers and travelers have been the mostly affected and responsible for spreading the 

virus (Kuwait Government Online, 2020; Gayawan et al.,2020). 

There was an increase in the spread of COVID-19 between June and July. However, the 

range of increase in Abuja and Oyo for July exceeded Kano, Edo, Delta, and Rivers State (Figure 

9 and Figure 11). It was also observed that Cross River was the last state to record the COVID-

19 case in Nigeria (Figure 11). As of August, all the states in Nigeria had a recorded case of 

more than 52 except Kogi. Also, states like Kano, Kaduna, Plateau, Oyo, Ogun, Ondo, Edo 

Delta, River Lagos, and the Federal Capital Territory each had more than 1000 recorded cases.  

The variability in the monthly pattern of COVID-19 that can be observed from 3,5,7,9, 11 

and 13 was how clustered the COVID-19 cases are. In March, the first cluster was observed 

where states around Lagos had high recorded cases (Figure 3).  The cluster that stood out in 

April, May, and June was that of Kano state and the state around it. By July and August, more 

cases have been recorded in most states, thus resulting in a smaller number of states forming a 

cluster.  Studies of Wang et al. (2021); Kim & Castro (2020), and Xie et al. (2020) also observed 

spatial clustering about COVID-19 distribution at a national scale. 

 

 



 

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Figure 3. Covid 19 recorded cases-march    Figure 4. Spatial autocorrelation by distance-march 

 

 
Figure 5. Covid 19 recorded cases-april    Figure 6. Spatial autocorrelation by distance-april 

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Figure 7. Covid 19 recorded cases-may     Figure 8. Spatial Autocorrelation by Distance-May 

  
 

 

 

 

 

 

 

 

 
 

 

 

 

 

 

Figure 9. Covid 19 Recorded Cases-June     Figure 10. Spatial Autocorrelation by Distance-June 

Ifeyinwa Sarah Obuekwe et al. / Geosfera Indonesia 6 (1), 2021, 40-54 

 



 

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Figure 11.  COVID 19 Recorded Cases-July     Figure 12. Spatial Autocorrelation by Distance-July 

 

  

Figure 13. covid 19 Recorded Cases-August   Figure 14. Spatial Autocorrelation by Distance-August 

 

 

 

 

 

 

 

  
Figure 13. Covid 19 recorded cases-august Figure 14. Spatial autocorrelation by distance-august 

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Figure 15. Mean distance of Nigeria State Capitals and the federal capital to other states capital and federal capital with peak category

0

100000

200000

300000

400000

500000

600000

700000

800000

900000
M

e
a
n

 D
is

ta
n

c
e
 i

n
 M

e
te

r

State Capital and FCT with Peak Category

Ifeyinwa Sarah Obuekwe et al. / Geosfera Indonesia 6 (1), 2021, 40-54 

 



Despite more visible clustering, the trend in the clustering of the COVID-19 over 

distance shows no significant peak from March to June (Figures 4, 6, 8, and 10). However, 

that of July and August exhibited patterns with two statistically significant peaks (Figure 12 

and Figure 14). The first and second peak of July were 301,338.39 meter (Z score =2.098; 

p<0.036) and 365,947.83 meter (Z score = 2.299; p=0.022) respectively while that of August 

were 301,338.39 meter (Z score =1.918; p=0.055) and 336,128.09 meter (Z score =2.013; 

p=0.044) respectively (Figure 12 and Figure 14).  

The result shows that the mean distance of July and August's first peak was the same 

(301,338.39 meter). Therefore, the distance where the spatial processes responsible for 

clustering is the most pronounced was about 301,338.39 meter. Also, the second peak of 

August (336,128.09 meter) was less than that of July (365,947.83 meter). This implies that 

there was a significant drop in the mean transmission distance between July and August 

2020.  This was attributed to the fact that the spread has increased among neighboring state as 

more states recorded a similar range of COVID-19 cases. 

Blank et al. (2016) used a similar approach, observed spatial clustering of bacterial 

canker severity, and showed that disease severity had significant spatial autocorrelation with 

dominant pattern recognized as clustered. A drop in mean transmission distance throughout 

foot-and-mouth outbreaks was similarly reported by Salje et al. (2016). Kiang et al. (2020) 

also found a significant spatial correlation associated with COVID-19 infections in China. 

Each state capital and the Federal Capital had a mean distance of more than 300,000 

meters to other states and federal capital (Figure 15). Although, only Yola, Maiduguri, 

Sokoto, and Damaturu have a mean distance above 600,000 meters (Figure 15). This is 

because these states are in the far north of the country, bordering the Niger Republic. Also, 

each of the state and the Federal Capital had a mean distance that is above the first and 

second peak of July and August except for Lokoja that has a mean distance (361,924 meters) 

that was less than the second peak of July (365,947.83 meters) (Figure 15). This implies that 

the interstate lockdown placed to curb the spread of COVID-19 was justifiable as any 

movement within the minimum and maximum significant peak distance can fast-track the 

spread of COVID-19. This corresponds with Salje et al. (2016) 's assertion, who claimed that 

a fundamental property of infectious disease dispersal is the average spatial distance between 

transmission-linked cases. 

Although this study does not compare COVID-19 spread with population density nor 

socioeconomic activities. However, COVID-19 cases have been clustered around two states 

in Nigeria (Kano and Lagos). Moreover, this cannot be farfetched from the fact that Kano and 

Lagos happen to be the most populous states in Nigeria with vibrant industrial and 

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commercial activities. Rapone (2020); Rocklöv & Sjödin (2020) also pointed out that high 

population density and socioeconomic status are essential drivers of the spread of COVID-19.  

The disbelief regarding the presence of the virus also results in people taking preventive 

measures lightly. Even six months after the first case of coronavirus was reported in Nigeria, 

many Nigerians still doubt its existence (CSR-in-Action, 2020). Negligence could be 

detrimental to the spread to other states. Kiang et al. (2020) also reported that people with a 

history of travel in epidemic areas fail to isolate themselves on time, thus accelerating 

transmission risk. Thus, a study of this capacity that was able to showcase the significance of 

the temporal dynamics of COVID-19 can help guide decision-making regarding how a 

movement should be restricted to reduce the clustering phenomenon observed across Nigeria.  

 

4. Conclusion  

This study has shown that the point location of each state capital in Nigeria and 

recorded cases for each of the 36 Nigeria states and the Federal Capital Territory, Abuja 

displayed the significance of temporal dynamics in the mean transmission distance of 

recorded COVID-19 cases in Nigeria. This indicates that progression in the spread of the 

virus increased the spatial coverage of the virus while the distance of risk of exposure 

decreased. This information could be utilized to establish maximum movement restrictions to 

contain the spread of COVID-19 through lockdown as implemented by the Nigeria 

Government. This method can also be applied to well-detailed data and a small proportion of 

adequately collected data. 

Conflicts of Interest 

The authors declare no conflict of interest. 

 

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