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Engineering, Technology & Applied Science Research Vol. 11, No. 2, 2021, 7006-7010 7006 
 

www.etasr.com Al-Shammari et al.: Development of an Automatic Contactless Thermometer Alert System Based on … 

 

Development of an Automatic Contactless 

Thermometer Alert System Based on GPS and 

Population Density 
 

Naif K. Al-Shammari 

Department of Mechanical Engineering 
College of Engineering 
University of Ha’il 

Hail, Saudi Arabia 
naif.alshammarif@uoh.edu.sa 

Husam B. Almansour 

Department of Health Management 
College of Public Health and Health Informatics 

University of Ha’il 

Hail, Saudi Arabia 
h.almansour@uoh.edu.sa 

Muzamil Basha Syed  

School of Computing and Information Technology 
REVA University 

Bangaluru, Karnataka, India 

muzamilbasha.s@reva.edu.in 
 

 

Abstract-In today's out-breaking Covid-19 circumstance, 

treatments are preferred to be contactless. Social distancing has 

become a mandate in order to prevent disease spreading. In such 

a scenario, checking the body temperature is preferable to be 

made contactless because it helps the doctors and social workers 
to stay away from the symptomatic patients. Infrared (IR) 

contactless thermometers are employed in measuring the 

temperature while preventing direct contact with the body. 

Improved functionalities in the contactless thermometer can 

provide accurate precision in measurements and calculations. 

Technological advancement in pharmacy has cohesively 

improved over time. Coupling Machine Learning (CML) will 
revolutionize the process of testing. The demand for automated 

temperature test equipment is likely to grow at a significant pace, 

with the continuous advancements in technology and the 

adoption of ATE (Automated Test Equipment). The Global 

Positioning System (GPS) easy tracking and navigation can be 

used for easy tracking. Population density can be used to 
calculate the amount of population in a particular area. The 

proposed automatic contact-less thermometer system has the 

potential to replace the traditional temperature measuring 

techniques and safeguard from human-to-human transmission 
diseases. 

Keywords-Covid-19; IR technology; ATE; GPS; population 
density 

I. INTRODUCTION  

The Global Positioning System (GPS) is used to determine 
locations using a satellite navigation process. It is well suited 
for different kinds of tracking applications [1] and is used for 
safety and security purposes. The main components of the GPS 
system are the space segment, control segment, and user 
segment. These segments collaborate with each other and 

process the signals received from the satellites and use them for 
further information processing like tracking, security in 
banking applications, automatic toll services, location 
identification, and navigation [2]. In our example, the idea is to 
develop an automatic contactless thermometer system based on 
GPS location (latitude-longitude) and population density. 
Population density is used to calculate the amount of 
population in a particular area. It is calculated as [3]: 

Pn
Pd

Ln
=     (1) 

where Pd is the population density, Pn is the total population, 
and Ln the total land area covered by the population. The 
calculation of population density varies depending on 
environmental (climate, resources) and human (economic and 
societal) factors [4]. Globally, millions of Covid-19 and 
temperature tests are conducted every day. Testing temperature 
for every person is very crucial: most enterprises, governments, 
and organizations are following very strict protocols in order to 
minimize the impact. Educational organizations are struggling 
to reopen schools, colleges, and research centers, mainly due to 
the lack of testing centers. Testing is time-consuming, and is 
conducted with low accuracy. The automatic contactless 
thermometer provides a solution. The contactless process is 
efficient and provides easy scalability among large groups. 
Automatic temperature test-centers will be the future regarding 
this matter. Public places, and the transportation sector need 
such technology during these hours. 

In Figure 1, the details of the product development stages 
are presented. The first and second stages of the project are 
already completed, with stage three being our future plan. The 
increased adoption of smartphones brings a great opportunity to 

Corresponding author: Naif Khalaf Al-Shammari



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www.etasr.com Al-Shammari et al.: Development of an Automatic Contactless Thermometer Alert System Based on … 

 

locate people affected with covid-19. Smartphones enable the 
governments to track and locate affected people and virtually 
fencing people is now possible. Technological advancement in 
pharmacy has improved with times. Coupling Machine 
Learning (CML) will revolutionize the way we test. The 
demand for automated temperature test equipment is likely to 
grow at a significant pace along with the continuous 
advancement in technology and the adoption of ATE 
(Automated Test Equipment). The increased adoption of 
smartphones brings great opportunity to locate Covid-19 
affected people. Focusing on minimizing error in detection is a 
very important task. Using an automated contact-less 
thermometer and geolocation feature from a smartphone will 
help monitoring on a large scale. However, technology 
nowadays has become more sophisticated. For example, the 
number of available infrared (IR) detectors has highly 
increased, and thanks to their selective filtering capabilities, 
these detectors can promise more efficiency and speed. 

 

 
Fig. 1.  Design and development steps of the complete product. 

Minimizing error in detecting is a very important task. 
Public transportation is highly dynamic, testing the public in a 
fast phase and with high accuracy is essential. Non-contact 
temperature measurement is the preferred technique for 
monitoring [5]. During the Covid-19 pandemic, the bolometer 
IR sensor is commonly used, since it provides an IR based 
solution to measure the temperature and it is efficient with ~4% 
error rate. GPS provides satellite tracking that is very useful in 
many ways. The main objective of this research work is to 
develop and deploy an automatic alert system based on the IR 
thermometer. The two main parameters that are taken into 
consideration to fully automate the body temperature 
measurements are the population density and its accurate 
location identification. The hardware circuit diagram of the 
traditional non-contact IR thermometer is presented in Figure 
2. In the proposed work, focus is given on developing the 
contact-less thermometer to work in a situation where there is a 
necessity to calculate the body temperature in mass gathering 
places.  

The GPS tracking system in collaboration with the 
population density helps in identifying and locating densely 
populated areas. The aim is to develop an automatic contactless 

thermometer system to work in such an environment where the 
system can be deployed in identifying critically ill people. The 
proposed work is automated to initiate the functioning of the 
thermometer system by gathering the location identification of 
the densely populated area with the help of the GPS tracking 
system, and the IR signals of the contactless thermometer that 
provide an accurate measurement of the body temperature. As 
an outcome, the proposed system will help in identifying red 
alert areas, in which the population is affected with fever in 
order to isolate and prevent the general public from entering. 

 

 
Fig. 2.  The hardware circuit diagram of the non-contact IR thermometer. 

 

 
Fig. 3.  The timing diagram of the IR temperature measurement module. 

II. LITERATURE REVIEW 

Globally, health centers have uploaded Covid-19 strains 
long ago and researchers and scientists are reverse-engineering 
the strains to find the solution [6]. Research institutions collect 
data regarding temperature, location, test results, and personal 
details to predict the future consequences using Machine 
Learning algorithms. 

A. Smart IR Thermometers 

Companies are focused on developing smart IoT 
thermometers. Real-time trackability is very crucial. To 
provide compliance with non-contact temperature 
measurements, it is necessary to calculate the effective 
efficiency of the black body and the difference in temperature 
between the workplace and the point or object in which the 
contact temperature is set [7]. Effective recreation can be 
calculated by applying the theory of evolution or by adjusting 
the temperature. The latter method seems to be difficult to use, 
as long as the black hole is cleaned. 



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B. Health-Internet of Things (H-IoT) 

Considering the impact of the 2019 pandemic, it is natural 
that many contact tracing and self-assessment mobile 
applications have already been developed, such as the Aarogya 

Setu App1 of the Indian Government. Health organizations like 
Apollo have developed chatbots for analyzing the symptoms. 
Health IoT devices typically belong to two broad types, 
personal H-IoT devices and clinical H-IoT devices [8, 9]. 

 

 
Fig. 4.  Flow chart of the automatic test equipment. 

 
Fig. 5.  The voice broadcast circuit. 

III. METHODOLOGY 

In Figure 4, the data flow between the modules of the 
proposed technique is presented. In the first step, the non-
contact mode of operation is selected. In step two, we get the 
information from the source using sensors. If the reading 
received from the sensor is within the acceptable range, then 
the reading temperature is processed for future decision 
making. Else, the system is switched to contact mode to get the 
temperature, thus always making sure that acceptable accurate 

temperature is displayed on the display unit. Switching 
between the possible modes is only made based on the format 
of the data received from the sensor and the acceptable range of 
the received data. The circuit diagram is presented in Figure 5 
with complete details.  

IV. EXPERIMENTAL SETUP AND RESULTS 

The circuit unit is simulated on the Proteus platform, where 
the PCB board is designed and built after simulation. The MCU 
download system and other components are mounted on the 
PCB board [9]. The temperature of the object is usually 
simultaneously measured by a mercury thermometer and with a 
non-contact IR thermometer, time is measured by the length of 
the clock, temperature is set at 25

0
C to 48

0
C. The results of the 

measurements are: Temperature error is less than 0.1
0
C, 

measurement time is about 5s with an IR contact thermometer. 
The measurements are accompanied with a voice message 
transmission, and LCD display of temperature and time. In 
general, the measured data are very accurate. A screenshot of 
the experimental work is presented in Figure 6. The display 
unit IR with the VBC is presented in Figure 7. When a 
temperature of an object below 25

0
C is detected with the IR 

contact thermometer, a buzzer alarm and a voice transmission 
take place. Object temperature at 25

0
C ~ 48

0
C is accompanied 

with voice transmission and LCD display of the temperature 
and time. Temperature above 48

0
C is accompanied with a 

buzzer alarm, and a voice transmission. The data from the 
sensors are fed into the circuit and the outcome is obtained 
from the display component shown in Figure 7. To estimate the 
performance of the experimental setup, the collected data 
(temperature, GPS attributes) from the sensors are stored in an 



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Excel sheet. The corresponding output label (message to be 
displayed) for each input is included to establish the train data 
with the help of human radiologists for diagnosis. In order to 
test the experimental setup, new data instances are used (test 
data) and the output is stored in the same sheet. The Decision 
Tree model is constructed using the trained dataset [10]. The 
evaluation parameters used to estimate the performance of the 
model constructed are shown in Table I. 

 

 

Fig. 6.  Matlab experimental setup. 

 
Fig. 7.  Display unit interface.  

TABLE I.  EVALUATION PARAMETERS 

Parameters Formula 

Accuracy (A) 
TP+TN

A=
Total

 

Misclassification Rate 

(MCR) 

FP+FN
MCR=

Total
 

Recall (R) 
TP

R=
ActualTrue

 

Precision (P) 
TP

P=
PredictedTrue

 

Prevalence (PV) 
ActualTrue

PV=
Total

 

F Score (FS) 
R×P

FS=2×
R+P

 

TP: true positive, TN: true negative, FP: false positive, FN: false negative

 

In Figure 8, the x-axis represents the evaluation metric used 
in estimating the performance of the experiment carried and in 
the y-axis the performance of the experiment is shown on a 
scale of 0 to 1. The experiment carried out in the present 
research work is reliable and proved to be robust with 
classification accuracy A=0.96. The present experimental setup 
and its performance are compared with the results of the similar 
research carried out in [12], in which, the recorded temperature 
is ±0.2°C accurate. The reason for achieving such accuracy is 
because of the metal cap attached to the thermopile sensor. The 
present circuit is designed to have ±0.5 trueness (P), which is 
better than the design of [11]. The provision of switching 
between contactless and contact modes allows much better 
precision in the current design. The GPS and population 
density values are used in identifying the crowded areas. The 
aim of the proposed work is to keep the average temperature 
36.5-37.5°C in the tested locations. The latitude and longitude 
of the locations help to give alert messages to people in 
problematic areas in order to maintain their social distance. 

 
Fig. 8.  Accuracy plot of the experimental work. 

V. CONLCUSIONS AND FUTURE WORK 

Advancement in technology and infrastructure will give us 
the cure to Covid-19 and its fellow strains. Automated testing 
and GPS-based geofencing will provide trackability on large 
scale. The GPS tracking system in collaboration with the 
population density help in identifying and locating the densely 
populated areas. The proposed system is aimed to develop an 
automatic contact-less thermometer system to work in such an 
environment where the system can be deployed in identifying 
critically ill people. The advantage of the proposed model is 
that it uses GPS coordinates and population density values 
towards identifying the most crowded areas. The aim of the 
proposed work is to keep the average temperature between 36.5 
and 37.5°C in the tested locations. The latitude and longitude 
details of the locations allow sending alert messages in order to 
maintain social distance. The limitation of the product designed 
in the present research work is that its contactless mode has not 
been implemented yet. Regarding future work, we would like 
to extend our work in adding a metal cap to the thermopile 
sensor towards achieving better accuracy.  



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TABLE II.  CHARACTERISTICS OF THE DATASET 

Name of the 

area (India) 
Latitude Longitude 

Density 

level 
Population Area (m

2
) Density value 

Average temperature 

of the area (°C) 
Alert message (text) 

Coimbatore 11.0168 76.9558 Low 190 7516 0.0252 36.6 Temperature is normal 

Coimbatore 11.0168 76.9558 Low 239 13,200 0.10176 36.6 Temperature is normal 

Bangalore 12.9716 77.5946 Low 670 32,666 0.0205 36.7 Temperature is normal 

Bangalore 12.9716 77.5946 Low 189 90,100 0.0012 37.4 Temperature is normal 

Coimbatore 11.0168 76.9558 High 165 5501 0.03 37.4 Temperature is unusually high 

Coimbatore 11.0168 76.9558 High 208 6890 0.0303 37.9 Temperature is unusually high 

Coimbatore 11.0168 76.9558 High 260 9634 0.0304 38.2 Temperature is unusually high 

Bangalore 12.9716 77.5946 High 259 6890 0.0303 38.3 Temperature is unusually high 
 

ACKNOWLEDGMENT 

This research has been funded by the Scientific Research 
Deanship of the University of Ha’il, project number COVID-
1908. 

REFERENCES 

[1] R. Maddison and C. Ni Mhurchu, “Global positioning system: a new 

opportunity in physical activity measurement,” International Journal of 
Behavioral Nutrition and Physical Activity, vol. 6, no. 1, Nov. 2009, Art. 

no. 73, https://doi.org/10.1186/1479-5868-6-73. 

[2] F. Abulude, A. Akinnusotu, and A. Adeyemi, “Global Positioning 
System and It’s Wide Applications,” Continental Journal of Information 

Technology, vol. 9, no. 1, pp. 22–32, Oct. 2015, https://doi.org/10.5707/ 
cjit.2015.9.1.22.32. 

[3] “Population Density: Definition, Formula & Examples - Video & Lesson 

Transcript,” Study.com. https://study.com/academy/lesson/population-
density-definition-formula-examples.html (accessed Mar. 21, 2021). 

[4] J. F. McDonald, “Econometric studies of urban population density: A 
survey,” Journal of Urban Economics, vol. 26, no. 3, pp. 361–385, Nov. 

1989, https://doi.org/10.1016/0094-1190(89)90009-0. 

[5] J.-H. Min, N. Gelo, and H. Jo, “Non-contact and Real-time Dynamic 
Displacement Monitoring using Smartphone Technologies,” Life Cycle 

Reliability and Safety Engineering, vol. 4, no. 2, pp. 40–51, May 2015. 

[6] T. M. Fernández-Caramés and P. Fraga-Lamas, “Towards The Internet 
of Smart Clothing: A Review on IoT Wearables and Garments for 

Creating Intelligent Connected E-Textiles,” Electronics, vol. 7, no. 12, p. 
405, Dec. 2018, https://doi.org/10.3390/electronics7120405. 

[7] P. F. Paradis and W. Rhim, “Non-Contact Measurements of 

Thermophysical Properties of Titanium at High Temperature,” Journal 
of Chemical Thermodynamics, vol. 32, no. 1, pp. 123–133, Mar. 1999. 

[8] V. Siva Brahmaiah, B. Rajkiran, and S. Pradeep, “An Intellectual Dual 

Axis Efficient Solar Tracking System by Using IoT Integrated 
Controller,” SSRN, https://dx.doi.org/10.2139/ssrn.3554005. 

[9] S. K. Kumaravel et al., “Investigation on the impacts of COVID-19 

quarantine on society and environment: Preventive measures and 
supportive technologies,” 3 Biotech, vol. 10, no. 9, Sep. 2020, Art. no. 

393, https://doi.org/10.1007/s13205-020-02382-3. 

[10] S. M. Basha and D. S. Rajput, “Chapter 9 - Survey on Evaluating the 
Performance of Machine Learning Algorithms: Past Contributions and 

Future Roadmap,” in Deep Learning and Parallel Computing 
Environment for Bioengineering Systems, A. K. Sangaiah, Ed. Academic 

Press, 2019, pp. 153–164, https://doi.org/10.1016/B978-0-12-816718-
2.00016-6. 

[11] E. Moisello, M. Vaiana, M. E. Castagna, G. Bruno, P. Malcovati, and E. 
Bonizzoni, “An Integrated Micromachined Thermopile Sensor With a 

Chopper Interface Circuit for Contact-Less Temperature 
Measurements,” IEEE Transactions on Circuits and Systems I: Regular 

Papers, vol. 66, no. 9, pp. 3402–3413, Sep. 2019, https://doi.org/ 
10.1109/TCSI.2019.2928717. 

[12] B. Trstenjak, D. Donko, and Z. Avdagic, “Adaptable Web Prediction 

Framework for Disease Prediction Based on the Hybrid Case Based 
Reasoning Model,” Engineering, Technology & Applied Science 

Research, vol. 6, no. 6, pp. 1212–1216, Dec. 2016, https://doi.org/ 
10.48084/etasr.753. 

 
AUTHORS PROFILE 

 

Naif Khalaf Al-Shammari Academic Qualifications: 1993 B.S., MEng, 

KSU, rating (4.25/5), 1999 M.S., MEng, KSU, rating (4.56), 2011 PhD, BEng, 
Birmingham University, UK. Professional Experience: 1994-2000 Saudi 

Electric Company, 2001-2010 Sultan B.A Al Saud Foundation. 2010-to date: 
University of Hail Research Interests Rehabilitation Engineering Robotics & 

Control. Scientific areas: Mechanisms design, biomechanical systems and 
bio/nano-robotics, dual-arm & flexible manipulator dynamics, smart 

materials, and structure mechatronics. 

 

Husam Almansour is a distinguished doctor in Nursing Education and 
Leadership and Management programs at the University of Hail. He worked 

as the Head of the Health Management Department and as a vice-dean for 
Quality and Development of the Faculty of Public Health & Health 

Informatics. He has been inclined with research focusing on practice and 
education.  

 

Syed Muzamil Basha completed his PhD at Vit University, Vellore, India in 

2020. His current research interests include BigData Analytics, BlockChain 
Management, and Internet of Things. He has more than 30 publications, which 

include 21 research papers, and 7 conference papers, and 6 book chapters. He 
is an editor of 4 textbooks. He conducted guest lectures in various Engineering 

Colleges in India. He received an award for his scientific contribution from 
VIT in 2018.