PRODUCTION OF ISO-INTENSITY MAP FOR THE ELAZIG EARTHQUAKE (JAN 24, 

2020) USING CITIZEN COLLECTED GEODATA 
 

 

I. Yalcin 1, 2, S. Kocaman 2, C. Gokceoglu 3, * 

 
1 Bursa Uludag University, Gemlik Asim Kocabiyik Vocational College, 16600 Gemlik, Turkey - ilyasyalcin@uludag.edu.tr 
2 Dept. of Geomatics Engineering, Hacettepe University, 06800 Beytepe Ankara, Turkey - sultankocaman@hacettepe.edu.tr 

3* Dept. of Geological Engineering, Hacettepe University, 06800 Beytepe Ankara, Turkey - cgokce@hacettepe.edu.tr 

 

Commission V, WG V/3 

 

 

KEY WORDS: Citizen Science, Earthquake, Disaster Management, Iso-Intensity Maps, Spatial Analysis 

 

 

ABSTRACT: 

 

Earthquake, depending on its intensity and location of epicentre, is one of the destructive hazards. Disaster mitigation after a 

severe earthquake are important to minimize its detrimental effects. Nowadays, several scientific disciplines, such as biodiversity, 

ecology, geosciences, natural hazards etc., utilize the Citizen Science (CitSci) approaches for various purposes, since the relevant 

attributes can easily be provided by non-experts with mobile devices. With the CitSci method, disaster related information can be 

identified and provided rapidly by locals during or after a disaster. Timely, in-situ data after an earthquake can also be collected 

with CitSci approaches via mobile devices, which can be even more important for all countries. In addition, scientific studies on 

earthquakes can be enriched and accelerated by using the information provided by volunteers. By collecting reliable data with the 

CitSci method, the disaster mitigation efforts can be improved, and losses may be decreased. This study aims at developing a 

CitSci pilot project by using the data collected by volunteers (citizens) to reduce the need for field work in creating earthquake iso-

intensity maps and produce them promptly. The present study was based on the 6.8 Mw Elazig earthquake occurred at 20:55 UTC 

on January 24th, 2020. Through the mobile application “I felt the quake”, the observations of citizens regarding the earthquake 

were collected. The intensities were revised from the Modified Mercalli Intensity Scale. With the help of data, an iso-intensity map 

was created and compared to the map produced by The Disaster and Emergency Management Presidency (AFAD), Turkey.  

 

 

                                                             
*  Corresponding author 

 

1. INTRODUCTION 

The world is in a state of change, like a living organism, with 

all beings on it. Natural hazards going on throughout history 

have been seen as the results of these changes. Among natural 

hazards, earthquakes are the ones with the most destructive 

effects. Earthquakes cause both losses of life and substantial 

financial losses upon living beings (Swiss RE Group, 2019; 

Munich RE 2017). Mobile sensor technologies can be used to 

reduce the harmful effects of earthquakes and to improve the 

quality of risk management efforts after disasters. 

 

As of January 2020, it has been reported that there are 4.5 

billion Internet users and 3.8 billion social media users in the 

world (We Are Social, 2020). In addition, satellites that 

provide the Internet to the Earth orbit are sent with the Starlink 

(2020) Project to make the Internet usage even more 

widespread. In the light of these technological developments, it 

can be said that mobile device technology and the Internet 

usage rates will increase day by day. Scientific research can be 

contributed by using the Internet, mobile devices and social 

media data. 

 

Citizen Science (CitSci) can be defined as the type of science 

that focuses on contributing to scientific studies by people who 

are not experts in research (Cohn, 2008). Within the scope of 

CitSci approach, many studies have been conducted on the 

management of natural disasters. A mobile application called 

LaMA has been developed by Kocaman and Gokceoglu (2019) 

to help record landslides while Can et al. (2019) have ensured 

the control of data from users by revising LaMA application 

with its convolutional neural network (CNN) architecture. 

Kong et al. (2016) have developed a mobile application that 

has previously identified the earthquake and alerted its users. 

Liang et al. (2017) have worked towards increasing the 

awareness of the people about earthquakes and reducing the 

impact of the earthquake in Taiwan. Yalcin et al. (2020) have 

produced iso-intensity map employing the intensity values they 

have collected from users for the (Mw=5.8) earthquake 

occurred in Istanbul, Turkey. Gokceoglu et al. (2020a and b) 

have published technical reports on detailed review of Elazig 

(Sivrice) earthquake occurred on January, 24th, 2020. Eravci et 

al. (2013) produced iso-intensity map for Mugla (Ula) province 

from the data collected from users with eAFAD application. 

Hicks et al. (2019) analyzed over a hundred CitSci projects and 

collected these studies on a website. There are also studies in 

which data collected from the user through different platforms 

such as mobile application, web, are presented with a web-

based GIS approach (e.g. Yalcin, 2018; Yalcin and Kocaman, 

2018). 

 

In Turkey, the use of such approaches are also extremely 

needed. Anatolian Plate is surrounded by North Anatolian 

Fault Zone, Eastern Anatolian Fault Zone, and Aegean horst-

graben system and all these are seismically active. During the 

last two decades, several large earthquakes such as 1999 

The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLIII-B5-2020, 2020 
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51

mailto:cgokce@hacettepe.edu.tr


 

Gölcük (Mw=7.5), 1999 Düzce (Mw=7.2), 2003 Bingöl 

(Mw=6.4), 2011 Van (Mw=7.1), 2020 Manisa (Akhisar) 

(Mw=5.4), 2020 Elazig (Sivrice) (Mw=6.8), occurred. 

Following the main shocks, many aftershocks occurred. The 

earthquake intensity maps generated after an earthquake is 

crucial to analyze the disaster affected areas and very important 

for disaster mitigation efforts. Accurate production of such 

maps take a long time and requires fieldwork. In addition, the 

earthquake intensity felt by people is affected by ground 

conditions and the construction quality. Therefore, CitSci 

provide new opportunities for rapid production of earthquake 

intensity maps. 

 

The aim of this study is to perform a CitSci pilot project by 

using the data obtained from volunteers (citizens) to reduce the 

need for field studies in creating earthquake iso-intensity maps 

and produce them quickly. The study performed here was 

based on the Elazig Earthquake (Mw=6.8) occurred on January 

24th, 2020, at 20:55 UTC. Through the mobile app “I felt the 

quake” developed by Yalcin et al. (2020), the observations of 

citizens regarding the earthquake were collected. The 

intensities used in “I felt the quake” were revised from the 

Modified Mercalli Intensity Scale (MM). With the help of 

data, an iso-intensity map was created and compared to the 

map produced by The Disaster and Emergency Management 

Presidency (AFAD), Turkey.     

 

2. STUDY AREA 

Located in eastern Anatolian region in Turkey, Elazig province 

is surrounded by Tunceli in the north, Malatya in the west, 

Diyarbakir in the south and Bingol in the east. Elazig which is 

on the eastern Anatolian Fault Zone, has high earthquake 

activity. Over the past hundred years, 299 earthquakes with 

magnitudes (Mw) of more than 4.0 have occurred in the region 

(AFAD, 2020). The last earthquake with a magnitude of Mw 

6.8 has been stated in the report of AFAD, which occurred on 

the Sivrice-Pötürge segment of the Eastern Anatolian Fault 

Zone and  the length of the segment is about 50-55 km (AFAD, 

2020). 

 

The iso-intensity map of the Elazig (Sivrice) earthquake was 

produced in this study with location-based user intensity 

values. In order to increase the number of user data and the 

accuracy of the map, user data from the surrounding provinces 

were utilized. For this reason, the study area was defined 

between 35,430° E - 43,721° E longitudes, 36,157° N - 

40,933° N latitudes, including Elazig Province.  

  

3. METHODOLOGY 

3.1 System Design and Implementation 

Compatible with Android 4.0.3 (Ice Cream Sandwich) and 

advanced versions, “I felt the quake” mobile application 

collects name, surname, sensible intensity scale value, date, 

time and location (coordinate values) data from users. The 

application is currently available on Google Play Store website 

and runs actively (Sarsıntıyı Hissettim, 2019). PostgreSQL 

with PostGIS extension was chosen as database management 

system (DBMS) because it serves as an open source medium 

for storing the collected data and enabling fast spatial queries 

(PostgreSQL, 2020). The data fields of the app and their types 

in the spatial DBMS are provided in Table 1 (Yalcin et al., 

2020). 

Column Data type 

Id Integer 

Name Character 

Surname Character 

Intensity Character 

Latitude Double precision 

Longitude Double precision 

Date Character 

Time Character 

Transaction date and time  Timestamp 

 

Table 1. The data fields of the developed mobile app and their 

storage types in the spatial DBMS (Yalcin et al., 2020). 

 

Name and surname information are optionally provided by the 

user. There are date and time fields in the database to provide 

data entry from the user after the earthquake. The interface of 

the application and the map on which the user can choose the 

geographical location where he/she felt the earthquake are 

shown in Figure 1 (Yalcin et al., 2020). The selection of 

location data on the map in the application was provided by the 

PlacePicker API (Application Programming Interface) 

developed by Google (PlacePicker, 2020). 

 

           
(a)                                    (b) 

 

Figure 1. (a) Interface of the ‘I felt the quake’ application; (b) 

A screenshot from the ‘Select location’ interface (Yalcin et al., 

2020). 

 

The Modified Mercalli (MM) scale consisting of 12 different 

values developed in 1931 is a standardized scale used in the 

production of Earthquake iso-intensity maps (Wood and 

Neumann, 1931). The MM scale is actively used in web 

applications prepared by the United States Geological Survey 

(USGS) in accordance with the CitSci approach (USGS, 2020). 

The intensity values shown in the application interface in 

Figure 1(a) are rearranged based on the MM values commonly 

used today and these values are given in Table 2 (Yalcin et al., 

2020). In total, 8 intensity values were obtained by subtracting 

1,2,11 and 12 values from the scale in the MM values; since it 

is almost impossible for the user to feel the weakest values 

(i.e. 1-2) and to send data from the strongest values (i.e. 11-

12). The purpose of reducing the MM values is to enable the 

user to easily mark the value that he/she felt. In this way, the 

provided scales are easily understandable by the users. 

 

 

 

 

 

 

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52



 

Scale Value 

in the 

Mobile App 

Description of the 

Intensity Scale in the 

Developed App 

Corresponding 

Modified 

Mercalli 

Intensity Scale 

1 Not felt Nobody felt it 

 

3 

2 Weak Some people felt it 

 

4 

3 Light Tall or suspended 

objects shook 

5 

4 Moderate Heavy furniture moved 

 

6 

5 Strong Minor damages that can 

be fixed occurred in the 

buildings 

7 

6 Very 

Strong 

There were cracks in the 

buildings 

8 

7 Severe Partial collapses 

occurred in the buildings 

9 

8 Extreme Some buildings 

completely collapsed 

10 

 

Table 2. The relationship between MM Intensity Scale and 

values used in the app developed by Yalcin et al., (2020). 

 

In the system architecture of the application running on the 

Android-based platform, as shown in Figure 2, name-surname 

(optional), date, time, location, and felt earthquake intensity 

value are entered and the save button is clicked by the user. 

These data provided by Amazon.com Inc., Seattle, U.S.A. are 

sent to Amazon Web Services (AWS) Ubuntu 16.04.6 LTS 

virtual machine. The web server transmits the data received 

from the user to the PostgreSQL positional database with the 

PostGIS extension. The data saved in the database returns to 

the user as a toast message. 

 

 
 

Figure 2. System architecture design of the application (Yalcin 

et al., 2020). 

 

 

3.2 Geostatical Analysis for Iso-intensity Map Production 

Defined also as a sub-discipline of statistics that is used 

effectively in determining spatial changes based on 

mathematical and statistical bases, Geostatistical analysis is 

used in many fields such as the determination of groundwater 

quality (Singh and Verma, 2019), resource and reserve 

estimation (Gandhi and Sarkar, 2016), production of 

earthquake iso-intensity maps (Yalcin et al., 2020). Kriging 

interpolation method, known as positional interpolation 

method in geostatistical approaches, includes many types such 

as ordinary kriging, simple kriging, universal kriging and 

cokriging. The kriging interpolation method applied by 

considering the semi-variance values of the distance between 

the point pairs, allows to calculate the values of the unknown 

points in the area statistically by using sample data in a field.  

The semi-variance consisting of nugget, range and sill 

components is used as an expression of dissimilarity between 

point pairs (Oyana and Margai, 2015). The semi-variance 

value focuses on the distance between these points instead of 

the spatial coordinates of the sample points. The kriging 

methods estimate the value from known points to unknown 

points and calculate weight in relation to semi variance 

(O'sullivan and Unwin, 2014). 

 

In this study, location-based earthquake intensity values 

collected from the users were calculated by ordinary kriging 

method to produce possible location-based earthquake intensity 

values within the whole study area. In Ordinary kriging 

method, local mean is calculated in the interpolation area while 

in simple kriging method, local mean is taken as a constant 

value. This creates the need to have prior knowledge about the 

field of study (Goovaerts, 1997). 

 

 

4. RESULTS AND DISCUSSION 

In this study, 161 data entries were retrospectively obtained in 

one and half month after January 24th, 2020 for (Mw = 6.8) 

Elazig (Sivrice) earthquake. Whether the data collected by non-

expert users in CitSci studies is correct or not is of high 

significance. In order to prevent incorrect data provided by 

non-expert, users in the earthquake region were given training 

on the use and purpose of the mobile application. To make it 

sure that the collected data came from the real person, the 

name-surname information in the data was employed. As a 

result of filtering in this context, 121 records from the trained 

users were accepted as sample data.  

 

In the study, the iso-intensity map in the January 2020 report 

prepared about the Elazig (Sivrice) earthquake by AFAD 

shown in Figure 3 (AFAD, 2020) was compared with the iso-

intensity map created by ordinary kriging technique based on 

121 sample data collected from the trained users. Elazig 

(Sivrice) earthquake maximum intensity value is presented as 

9 in MM scale on AFAD map consisting of a legend with 12 

MM intensity values. This value represents “7-Severe” among 

the revised values shown in Table 2 in the study. In Figure 4, 

the AFAD map, which is georeferenced according to The 

European Petroleum Survey Group (EPSG) 4326 projection 

system, and the sample data in EPSG 4326 projection system 

collected from users are shown together. It is seen that the 

intensity data provided by the user is higher than the iso-

intensity map limits produced by AFAD. These data are also 

included in the study. 

 

In the study, “4-Moderate” value provides the compatibility 

between the Iso-intensity map by AFAD and map formed 

according to the user data while there are not any values 

corresponding to the “1-Not Felt” value and the “8-Extreme” 

value in the field. There are also differences among other 

values. Because earthquake intensity value may vary in relation 

to variables such as age, height, and strength of the building. 

The compatibility between user intensity value and AFAD map 

is shown in Table 3. 

 

 

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53



 

 
 

Figure 3. AFAD Earthquake Iso-intensity Map produced after 

the Elazig (Sivrice) Earthquake (Mw=6.8) (AFAD, 2020) 

 

 

 
 

Figure 4. Data points collected in the study and AFAD Iso-

intensity map; additionally zoomed views for two sub-parts. 

 

 

App Scale 

Number 

Overall 

Frequency 

Frequency 

within 

AFAD map 

boundaries 

Number of 

data 

matching 

AFAD map 

1 (Not felt) 13 3 No data 

2 (Weak) 11 9 3 

3 (Light) 24 24 2 

4 (Moderate) 38 38 21 

5 (Strong) 20 20 0 

6 (Very strong) 13 12 1 

7 (Severe) 1 1 0 

8 (Extreme) 1 1 No data 

 

Table 3. The number of intensity values obtained on the AFAD 

map and the data collected in the study. 

 

The results of ordinary kriging interpolation with 121 sample 

data provided by the user are shown in Figure 5, and the semi-

variogram of the interpolation is shown in Figure 6. According 

to the result of the interpolation, the lowest and the highest 

intensity values were calculated as 0,99 and 6,5 respectively. 

The interpolation map was produced based on the semi 

variogram shown in Figure 6. If a comparison between the iso-

intensity map produced in the present study (Figure 6) and the 

field observations provided by Gokceoglu et al. (2020b), there 

is a good accordance between the iso-intensity values and the 

earthquake damages.  

 

The horizontal axis of the semi-variogram shows the distance 

between the point pairs while the vertical axis shows the half 

variance value. Since the distance (in degrees) between the 

point pairs decreases in the variance values after the 2,49 range 

value, the semi-variogram takes values around the peak 

variance value. As the distance between the point pairs 

decreases, the similarity between points will increase. As 

shown in Table 3, the presence of extreme value affects the 

variance between the points in an area where intensity values 

are expected to be lower than the earthquake intensity. 

 

 
Figure 5. Interpolation map produced from the data collected in 

the study using the ordinary kriging method. 

 

 
 

Figure 6. Variogram produced from the data collected in the 

study. 

 

The comparison of two iso-intensity maps illustrates that the 

accuracy of the iso-intensity maps produced after the 

earthquake can be questioned. This indicates that there are 

some challenges in iso-intensity map production. The main 

problem is the uncertainty of the exact location of the epicentre 

that triggered the earthquake. Besides, it is not possible for the 

earthquake to affect the entire settlement area at the same 

intensity. Because some buildings in the area are new and 

durable, some buildings may be old and worn out. In addition, 

the height of the buildings will directly affect the intensity 

values and the local ground conditions will also affect the 

intensity. With this study, CitSci approach was used to reduce 

the uncertainties sourced from these problems. Unlike sensors 

providing information on a single field, CitSci can obtain 

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accurate information on many fields such as earthquake 

intensity from each local dwelling. Thus, scientific studies can 

be contributed by collecting data on different fields from a 

volunteer. 

 

The most important factor in CitSci studies is the accuracy of 

the collected data. As seen in this study, it is the data coming 

from trained users that facilitates the application of the 

interpolation method. Grounding CitSci studies on data from 

trained users may provide more accurate and more reliable 

results. Therefore, users should often be given a preliminary 

training on projects. In this study, obtaining sample data in iso-

intensity map production in large numbers and evenly 

distributed in the field can make the results more accurate. For 

this reason, more citizens should be encouraged to take part in 

CitSci studies and it should be ensured that citizens see 

themselves as part of scientific projects. 

 

 

5. CONCLUSION 

In this study, which is about the production of iso-intensity 

map of (Mw = 6.8) Elazig (Sivrice) earthquake that occurred at 

20:55 UTC on January 24th, 2020, it was made use of the 

CitSci approach. A total of 121 location-based intensity values 

were obtained from trained users in the surrounding provinces 

of the Elazig earthquake. In the light of these data, iso-intensity 

map was produced employing ordinary kriging spatial 

interpolation method. The methodology used in this study was 

also used for the September 26th, 2019 Istanbul earthquake 

(Mw = 5.8) (Yalcin et al., 2020).  

 

As seen in the results of both studies, there are some minor 

problems on iso-intensity maps produced after the earthquake. 

The difference between the map produced from the user data 

and the AFAD map is due to the intensity values used in the 

iso-intensity map production. The differences in intensity 

values vary depending on the quality, height, age of the 

building and the local ground conditions on which it is located. 

In the study, it has been shown that CitSci method can be used 

reliably to overcome these problems. 

 

In order to obtain correct results in CitSci projects, citizens' 

data must be accurate and reliable. To make this possible, 

technologies such as machine learning (ML), CNN, and 

artificial neural network (ANN) can be used or users can be 

trained on the project prior to the CitSci project or both can be 

preferred. In this study, it was preferred to give pre-project 

training to users. In addition, existence of correct and large 

number of data distributed in the region on iso-intensity map 

production will increase the accuracy of the map. The use of 

understandable and participant friendly questionnaire and 

mobile application in CitSci projects to collect data can help 

get better results. In this context, the revision on the scale of 12 

MM eliminated the uncertainty of the users in selecting the 

earthquake intensity value. In addition, the mobile 

application’s being clear, simple and understandable provided 

an easy use to the citizens. 

 

It is expected that the number and the diversity of CitSci 

projects will increase and help to improve the scientific studies 

by training the society around these projects. CitSci studies, 

which will diminish field studies in the production of 

earthquake iso-intensity maps, will reduce the cost of scientific 

studies and can help to obtain the results faster. The present 

study was one of the first and did not focus on the speed of the 

production, but in fact it is possible to obtain the results in a 

few hours. In addition, the integration of CitSci method with 

Internet and mobile device technology will enable societies that 

cannot allocate high budget for scientific research subjects to 

produce projects scientifically. 

 

 

ACKNOWLEDGEMENTS 

The authors thank sincerely to the volunteers who provided the 

data about the earthquake intensity.  

 

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https://doi.org/10.5194/isprs-archives-XLIII-B5-2020-51-2020 | © Authors 2020. CC BY 4.0 License.

 
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The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLIII-B5-2020, 2020 
XXIV ISPRS Congress (2020 edition)

This contribution has been peer-reviewed. 
https://doi.org/10.5194/isprs-archives-XLIII-B5-2020-51-2020 | © Authors 2020. CC BY 4.0 License.

 
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https://developers.google.com/android/reference/com/google/android/gms/location/places/ui/PlacePicker
https://developers.google.com/android/reference/com/google/android/gms/location/places/ui/PlacePicker
https://www.postgresql.org/
https://play.google.com/store/apps/details?id=com.ilyas.asus.postgresqlsample2&gl=TR
https://play.google.com/store/apps/details?id=com.ilyas.asus.postgresqlsample2&gl=TR
https://doi.org/10.1016/B978-0-12-815413-7.00005-5
https://www.starlink.com/
https://www.swissre.com/media/news-releases/nr-20191219-global-catastrophes-estimate.html
https://www.swissre.com/media/news-releases/nr-20191219-global-catastrophes-estimate.html
https://wearesocial.com/digital-2020
https://doi.org/10.3390/ijgi9040266