A Social Distancing Framework Based on GPS and Bluetooth Empowered by Feature-based
Machine Learning Algorithm
KhanMuhammad Adnan1
RehmanAbdur2
AbbasSagheer3
AliMuhammad Nadeem4
KimByung-Seo4
-
(Department of Software, Faculty of Artificial Intelligence & Software, Gachon University,
Seongnam, 13120, Korea adnan@gachon.ac.kr)
-
(School of Computer Science, National College of Business Administration and Economics,
Lahore, 54000, Pakistan arbhatti@ncbae.edu.pk)
-
(Department of Computer Science, Prince Mohammad Bin Fahd University, Al Khobar, Saudi
Arabia sabbas@pmu.edu.sa)
-
(Department of Software and Communications Engineering, Hongik University, Sejong Campus,
Korea nadeem@mail.hongik.ac.kr, jsnbs@hongik.ac.kr)
Copyright © The Institute of Electronics and Information Engineers(IEIE)
Keywords
Covid, DELM, Social distancing, Machine learning algorithm
1. Introduction
COVID-19 is a rapidly transmitted disease that can be transmitted through body droplets
and can survive up to two days on a touched surface. The disease outbreak announcement
also illustrated the growing concerns regarding COVID‐19's unprecedented scale of
transmission and intensity. This is distinguished by its span as a global health emergency
that has expanded all around the globe.
Legislative bodies of numerous countries are imposing restrictions, limits on travel,
and social distancing, and are attempting to grow public knowledge of sanitation.
Nevertheless, the infection tends to propagate quite rapidly. In Saudi Arabia, COVID-19
has spread through various territories of the world. The Mecca area has seen the highest
incidence of COVID-19 to date. Social distancing is assumed to be an efficient measure
of the spread of the pandemic virus in the present scenario. The risk of the transmission
of viruses can be reduced by preventing physical interaction between individuals.
The development of an automated simulation model is therefore important to implementing
a social distancing scenario to prevent people from becoming infected.
A literature review revealed several studies tracking social distancing in public
spaces. Harvey et al. [1] and Robakowska et al. [6] used drone technology and cameras to track movements in a crowd. They emphasized
that the use of drone technology may help maintain public order and also help to detect
suspicious activity in a group. Currently, the system provides a comprehensive overview
of a surveillance system for patrolling and inspection. Ngu-yen et al. [3] provide a detailed social distance context, such as core principles, measurement
systems, and prototypes, and suggest alternative socially relevant distance situations.
They also describe supporting particularly efficient wire-less systems that can be
broadly accepted in practice to maintain distance and promote and implement social
distance in particular. They presented a survey on many emerging technologies like
Bluetooth and WIFI that can work as a key aspect in a social distancing scenario.
Ahmed et al. [2] planned a prototype to offer a deep-learning framework for social distance monitoring.
To recognize individuals in video sequences, this approach implements the YOLOv3 object
detection framework. To improve the model's accuracy, the transfer learning technique
is applied. They measure breaches of the social distance among persons and use a physical
gap estimation. The emphasis on many technologies and using deep learning algorithms
to track human movement plays a key role in maintaining social distancing. Punn et
al. [4] and Pouw et al. [5] proposed a system using the YOLOv3 model to detect humans and track them using bounding
boxes. They utilized information obtained from overhead commercial pedestrian monitoring
sensors. They introduce the idea of the ?Corona Event? to track two people who get
closer than a threshold distance. However, much of their work relies on live surveillance,
and cameras to detect humans [7,8,9,10].
The recent pandemic of COVID-19 has prompted several scientists to find other responses.
Rao et al. [11] suggested a framework intended for the identification of COVID-19 victims via smartphone.
Yan et al. [12] established a forecasting framework to appraise high-risk patients at an early stage
before they pass from moderate to severely sick. Several research articles on forecasting
the coronavirus pandemic have been presented in recent times [13]. The researchers concentrated on developing a new framework focused on artificial
intelligence technologies that combine machine learning algorithms and various data
modalities [14]. The Adaptive Neuro-Fuzzy Inference System (ANFIS) is suggested by Al-Qaness and
colleagues [15]. A regression framework was built for the estimation of rapid growth in COVID-19
dependent on the overall percentage of reported patients outdoors in China [16]. Many researchers produced predictions by ten common machine learning and predictive
environmental area frameworks for the observation of large-scale weather variations
[17].
Also, many mobile applications use Bluetooth technology to notify people if they have
had contact with others confirmed to be infected with the coronavirus. In contrast,
previous approaches only used cameras for tracking humans and for detection purposes.
Nevertheless, the drawback of the existing applications is that they are not embedded
with real-time detection modules to detect social distancing between people. We decided
to investigate this area for the following reasons:
Following are the points why we researched this idea.
• The social distance control system in this proposal uses smartphone GPS and Bluetooth
technologies that overcome the problems of tracking people's movement with cameras.
• A Bluetooth or GPS technology, therefore, is used to conduct the evaluation process
in the proposed framework. With personalized data collection, the trained machine
learning model is integrated with the existing applications. The applications run
the machine learning algorithm and automatically identify whether or not social distance
is retained in public.
• To verify if social distancing is preserved by individuals in a public zone, it
also measures whether any person breaches the social distancing standard. If not,
the application will send the authority a warning signal and even give the public
an alert.
• The identification system uses the location information observed to classify samples.
We can use a physical distance estimation through GPS and Bluetooth and set a standard
to approximate social distance breaches between individuals. To determine whether
the distance value violates the smallest social distance threshold, a breach threshold
is defined. In particular, a monitoring algorithm would be used to identify the individuals
who breach the social distancing standard. To evaluate the model's output, results
are analyzed through several statistical measures. Results indicate that the proposed
paradigm accurately identifies persons who approach too closely and break/violate
social distancing rules. The learning method also improves the system's overall efficacy.
• The Deep Extreme Learning Machine (DELM) framework may utilize clean anomalies
in the data obtained from various resources, and train existing approaches to build
on the optimal framework using several training sets. In this article, a DELM-based
context is proposed to achieve maximum accuracy. In the context of COVID-19, we intended
to construct a DELM system that could establish the precise system for maintaining
social distancing.
The system is designed to detect two states: whether individuals are not too close
to each other and whether they remain with each other. The system will work based
on distance tracking and the machine-learning framework. Tracking location sharing
among people removes the need to track distances between people necessary to maintaining
social distancing. The suggested method thus supports the community by saving time
and helps mitigate the spread of the coronavirus.
It is necessary to identify COVID-19 patients early to prevent transmission of the
disease to other persons. In this study, we propose using a DELM-based approach together
with a location-based dataset obtained from GPS and Bluetooth for automatic detection
of social distancing. This model achieved an accuracy of more than 90%. This research
provides insight into how deep extreme learning machines can be implemented to manage
the spread of COVID-19 in the initial phase of an outbreak. COVID‐19 has now been
a challenge to the health infrastructure around the globe and many people have collapsed
due to this deadly pandemic. Due to an increasing number of emergency patients, healthcare
professional capacity is scarce, and a computer-controlled autonomous social distancing
system can save lives by early assessment in cities and can save lives by appropriate
approach.
In this study, using an AI approach to building a social distancing control framework
in applications is presented. To decide if an individual's conduct violates the least
social distance range, a violation threshold must be employed. Additionally, a central
detection system is used to map communities. Experimental findings found that the
system successfully detects individuals who become too close to others and infringe
on social distance practices. The technique of transfer learning further advances
the overall reliability and precision of the detection system
The suggested system identifies persons who did not sustain social distance. Therefore,
this system would function effectively and automatically to assist in simple social
distance inspection. The system can retrieve distance measures from the GPS position
details and save them in the database of the concerned authorities.
The proposed framework effectively and efficiently trains itself to detect insufficient
social distancing. We propose that the model will remarkably enhance the speed and
precision of social distance tracking. It may be beneficial in a disease outbreak
where the epidemic risk and the requirement for prevention steps do not suit the available
resources. More appropriate, refined, and richer datasets will further mature the
learning rate of the system.
2. Proposed Methodology
A proposed social distance monitoring system implemented in this work uses Bluetooth
and GPS technology. The system model is seen in Fig. 1. The mobile user's dataset generated is sent to a satellite separated into sets of
different users to track the distance between both users, and a machine learning-based
tracking approach is used to extract the highest level of prediction of current location
data. A predetermined threshold is used for calculating the centroid distance to verify
whether or not the distance between any two users is lower than the standard distance.
If two entities are near one another and the gap magnitude breaches the standard of
the least social distance then the alarm is sent to concerned authorities and also
both users. A centroid detector technique is used to observe individuals who breach
the social distance threshold and trace their travel. The device presents information
about social distance violations together with the detected individuals as the result.
Fig. 1. Proposed social distance monitoring system model.
Numerous hidden neurons, in addition to activation functions of several sorts, are
utilized to attain the best framework for social distancing detection. The suggested
architecture has three layers: the information-gathering phase, the pre-processing
phase, and the application phase. Both the information-gathering layer and the pre-processing
layer are included in the application layer in which one is for prediction and the
other is for evaluation. For exploratory studies, actual information was acquired
from GPS and Bluetooth. The data were then delivered to the data collection layer
as input. Detection techniques are implemented at the data pre-processing stage to
prevent any anomalies from being used in the information. In the application phase,
the DELM framework is implemented to detect social distancing standards. The DELM
can be organized in a variety of ways to estimate health challenges, predictions of
energy consumption, transport, and traffic management, etc. [18,19,20,21].
The concept of an ELM is defined by Huang et al. [22]. Since we use the standard Feed-Forward Neural Network (FFNN) method, data is flowing
in only one direction across the network (predictions, as in ``from the inputs to
the outputs'') through each stage in the training phase. However, we have often used
the Recurrent Neural Network (RNN) approach throughout this predictive system through
the training procedure, where input streams move from a specific node back through
the network, and any time this flow reaches the node, the weights are changed to achieve
higher precision and quality without the error rate ballooning. The constant of all
the weights in the validation stage is imported in addition the actual data are predictable.
The DELM context comprises of input, several hidden, in addition to one output layer.
The principal goals of this approach are:
• The DELM algorithm will be implemented to construct the most effective strategy
for social distancing.
• To use an adaptive method to detect and track social distance among individuals
and to identify those who are not maintaining social ties in consideration of their
particular conditions.
• To incorporate and enhance Bluetooth and GPS technologies in pre-existing applications
to maintain social separation criteria. In addition, a feature learning strategy is
employed to improve the model's effectiveness. The newly trained layer is then deployed
to the pre-trained architecture to improve the system's performance.
• To use a detecting mechanism to keep track of individuals who violate the social
distance threshold.
• To evaluate the usefulness of a pre-trained system using a location dataset. The
detection system's deployment is assessed with and without learning algorithms. The
performance of the system is also assessed using other AI models.
• To slow the spread of the coronavirus epidemic and prevent the spread of infection.
• To evaluate the suggested approach using GPS and Bluetooth datasets for the purpose
of performance estimation.
• To validate the suggested method by testing the datasets with various machine
learning techniques.
Fig. 2. DELM architecture [18].
The primary objective of this study is to develop a smart algorithm to identify and
track social distancing among people and identify those individuals who are not maintaining
social distancing by improving and implementing AI in existing applications. The suggested
framework relies primarily on the use of Bluetooth and GPS technology to track the
distance between humans in real-time.
Let's imagine there are multiple different hidden layer feedforward neural networks,
each with $n$ neurons in the hidden layer, in addition to a training data set consisting
of $N$ records $(è_i , f_i)$ in which $e_i \in S_d$ and $f_i \in S_c$. The output
of such a Feedforward Neural Network with Multiple Hidden Layers may look like;
Here ${{\eth }}_j$ and ${ ç}_j $ are factors that affect learning, $ß _{j}$ Output
Weighted Nodes $j $and $ Î :$ $S \to S$ is the activation function.
It has been demonstrated by a perfect settlement of several hidden layers in a feedforward
neural network with zero errors that with discrete intervals ${{\eth }}_j$ and ${{
ç}}_j $ there occur ${ß}_{\mathrm{j}}$ like that;
which can be denoted as
where
and
Results assessment weights can be calculated using the method below when the amount
of feedback received is greater than the number of neurons in the hidden layer.
Matrix $Ú$ is inverse of ${Ú}^{{\nmid }}$. DELM is consequently a computationally
economical scheme of study.
There are a few different parts to the backpropagation system, including weight setup,
forward propagation, error propagation, and update to the ability to tell things apart.
An activation function like ${g} ({x}) =$ sigmoid is existing in each neuron's hidden
layer. This benefit projecting the sigmoid input function in addition to the DELM
hidden layer;
Backpropagation error is defined in Eq. (7) as the difference between the actual and desired result squared, divided by 2. To
correct for this frequent miscalculation, a rebalancing of the weights is required.
Indicated by Eq. (8) are the ranges of allowed weight changes in the output layer.
Where $i= 1$, $2$, $3$, $\dots$, $10$ and $j =$ output layer.
Eq. (9) demonstrates the weights update also how the biases happen among the hidden layer
and inputs.
3. Simulation & Results
3.1 Simulation Environment
In our research environment, we employed the latest Anaconda distribution running
JupyterLab on a MacBook Pro featuring an i5 2020 M1 chip. To maximize performance
and efficiency, we took advantage of the advancements offered by macOS Sonoma, which
likely incorporates optimizations tailored to the M1 chip architecture. This setup
provided us with a robust platform for conducting simulations, ensuring smooth and
reliable performance throughout our~experiments.
3.2 Results
In this study, the DELM method was implemented on the dataset. The results were randomly
allotted to the training collection (12676 samples) or (30% of the tests) (5432 records).
The data has been investigated in expectation of its intentional use to guarantee
that there is no social distancing breaching. DELM sought to determine whether the
devices were close to one another. Then, a variety of neurons were explored, counting
the activation of hidden layers and distinct active procedures. Validation assesses
the output of DELM to understand if this method is effective. The overall performance
of this system was evaluated by many numerical statistical measurements.
In Eqs. (10) and (11), $F$ signifies the projected outcome and $S$ symbolizes the factual output. $F_0$
and $S_0$ represent that there is a Safe Distance uncovered in the projected outcome
and factual output correspondingly. $F_{{1}}$ and $S_{{1}}$ signifies the unsafe distance
is presented in predictive output and actual output respectively. ${F_b}/{S_b}$ indicative
of the similarity between predicted and actual results. Likewise, ${F_b}/{S_{z{\neq
}b}}$ represents deviation between predicted and actual results.
Table 1 displays the proposed DELM-based social distancing framework for predicting the safe
distance between individuals at the training level. Training was applied to a total
of 12676 records, which were originally divided into 7067 and 5609 safe and unsafe
records, respectively. 6727 safe records of normal groups with no social distance
breaching were accurately predicted by the forecasting algorithm, whereas 340 unsafe
recordings were imprecisely predicted by this method. Comparatively, the condition
of unsafe found yielded a total of 5609 records, of which 5356 records are accurately
projected as unsafe found and 253 records are imprecisely forecasted as safe distance
established when unsafe distance persists.
Table 2 displays the proposed DELM-based social distancing framework for predicting the safe
distance between individuals during the validation phase. The training utilized a
total of 5432 records, which were subsequently divided into 3028 and 2404 safe and
hazardous records, respectively. 2777 safe recordings of typical groups with no social
distance breaching are successfully predicted by the forecasting algorithm, while
251 hazardous records are incorrectly predicted by this method. Comparatively, in
the case of unsafe create, a total of 2404 recordings are gathered, of which 2178
records were accurately predicted as an unsafe establish and 226 records are imprecisely
predicted as a safe distance create when unsafe distance occurs.
Table 3 displays the recommended DELM-based social distancing framework's mean accuracy and
miss rate as a function of training and validation level. It was determined that the
suggested DELM-based social distancing framework method for training delivers an accuracy
of 95.32 % and a miss rate of 4.68 %. During validation, the proposed DELM-based social
distancing framework system achieves an accuracy of 91.23 % and a miss rate of 8.77
%. The suggested social distancing paradigm based on DELM delivers noticeably greater
value than previous approaches and provides a viable answer to detecting breaches
of social distancing.
Table 1. Training of the DELM-based social distancing architecture for the estimation
of safe distance.
|
Suggested DELM-based Social Distancing system model
|
|
(70% of data in training)
|
|
Total records (N = 12676)
|
Outcome (Output) (F0, F1)
|
|
Input
|
Predictable result
(S0, S1)
|
F0 (Safe Distance)
|
F1 (Unsafe)
|
|
S0 = 7067
Safe Distance
|
6727
|
340
|
|
S1 = 5609
Unsafe
|
253
|
5356
|
Table 2. Validation of the DELM-based social distancing architecture for the estimation
of safe distance.
|
Suggested DELM-based Social Distancing system model
|
|
(30% of data in validation)
|
|
Total records (N = 5432)
|
Outcome (Output) (F0, F1)
|
|
Input
|
Predictable outcome
(S0, S1)
|
F0
(Safe Distance)
|
F1
(Unsafe)
|
|
S0 = 3028
Safe Distance
|
2777
|
251
|
|
S1 = 2404
Unsafe
|
226
|
2178
|
Table 3. Performance evaluation of proposed DELM based social distancing architecture
for the estimation of safe distance during validation and training.
|
|
Accuracy
|
Miss Rate
|
|
Training
|
95.32%
|
4.68%
|
|
Validation
|
91.23%
|
8.77%
|
3.3 Comparison with the existing schemes
In this section a comparison is provided in Table 4 to show the performance of the proposed methodology with the existing schemes. It
is very obvious that the proposed methodology is achieving high accuracy as compared
to the existing schemes.
Table 4. Comparison with the existing schemes.
|
Ref. No
|
ML Model
|
Dataset
|
Accuracy
|
|
[23]
|
RCNN
|
MS-COCO and
PASCAL-VOC Datasets
|
75%
|
|
[24]
|
SSD300
|
VOC2007
|
88.4%
|
|
[25]
|
Spatial-Temporal Analysis
|
Market1501,MOT16, SCU-VSD
|
61.4%
|
|
[26]
|
YoLov3
|
Private Video Data
|
88%
|
|
Proposed
|
DELM
|
Megapixels, 2019
|
91.23 %
|
4. Conclusions
A framework for social distancing has been established to increase the accuracy of
safe and unsafe distance calculation predictions. Various methodological approaches
were applied to evaluate the viability of this specific proposition. The suggested
DELM approach is notable for its effectiveness. During validation, the suggested application
had an accuracy between 95.32 and 91.2%. An additional advantage of the DELM approach
is that fundamental algorithms are inexpensive and quick. We are confident that these
initial results and intend to expand this work by analyzing other datasets in the
future. Future research will seek to accurately characterize and measure the parameters.
Future research will seek to accurately characterize and measure the parameters of
the DELM approach to monitoring social distancing. Notably, the algorithm will be
re-trained more often to improve its performance in a range of conditions.
ACKNOWLEDGMENTS
This work was supported by the National Research Foundation of Korea(NRF) grant
funded by the Korea government(MSIT) (No. 2022R1A2C1003549).
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Muhammad Adnan Khan (SM23) received his B.S. and M.Phil. degrees from International
Islamic University, Islamabad, Pakistan, and a Ph.D. degree from ISRA University,
Islamabad, Pakistan in 2016. He is currently working as an Assistant Professor at
the Department of Software, Faulty of Artificial Intelligence and Software, Gachon
University, Seongnam-si, Korea. Before joining Gachon University, he worked in various
academic and industrial roles in Pakistan. He has been teaching graduate and undergraduate
students in computer science and engineering for the past 15.5 years. He is also guiding
five Ph.D. and seven M.Phil. students. He has published more than 240 research articles
with Cumulative JCR-IF 700+ in reputed International Journals as well as International
Conferences. His research interests include machine learning, MUD, image processing
and medical diagnosis, and channel estimation in multi-carrier communication systems
using soft computing. He received scholarship awards from the Punjab Information Technology
Board, Government of Punjab, Pakistan, for his B.S. and M.Phil. degrees, and the Higher
Education Commission, Islamabad, for his Ph.D. degree, in 2016.
Abdur Rehman is currently working as an Assistant Professor at the School of Computer
Science, NCBA&E, Lahore, Pakistan, and as a game developer at the Game Object Lahore,
Pakistan. He completed his Ph.D. from the School of Computer Science, NCBA&E, Lahore,
Pakistan in 2023. He completed his M.Phil. in computer sciences from the NCBA&E, Lahore,
Pakistan. He completed his B.S. in computer sciences from the Institute of Management
Sciences, Lahore, Pakistan. He has published and submitted several research articles
in international journals as well as well-respected international conferences. His
research interests primarily include cloud computing, IoT, medical diagnosis, intelligent
agents, cognitive machines, smart homes, blockchain, network security, and smart city,
with various publications in international journals and conferences of international
repute.
Sagheer Abbas (SM23) received his M.Phil. degree in computer science from the School
of Computer Science, NCBA&E, Lahore, Pakistan, and a Ph.D. degree from the School
of Computer Science, NCBA&E, in 2016. He is currently working as a Professor with
the Department of Computer Science, Prince Mohammad Bin Fahd University, Al Khobar,
Saudi Arabia. He has been teaching graduate and undergraduate students in computer
science and engineering for the past 14 years. He has published about 190 research
articles in international journals and reputed international conferences. His research
interests include cloud computing, the IoT, intelligent agents, image processing,
and cognitive machines, with various publications in international journals and conferences.
Muhammad Nadeem Ali is currently pursuing a Ph.D. at Hongik University, Korea.
He completed his BS and MS in Electronics Engineering from the International Islamic
University Islamabad in 2012 and 2016, respectively. His BS in Electronics Engineering
was fully funded by the Ministry of Information and Technology, Government of Pakistan,
for four years. The scholarship name was ICT & RD Fund. Currently, he is a member
of the Broadband Convergence Network Laboratory at Hongik University. His major interests
are 5G wireless communication systems, intelligent transport systems and their applications,
latency issues in networks, edge computing, and name data networks. From 2015 to 2021,
he worked as a senior lecturer at the Department of Computer Science at Lahore Garrison
University.
Byung-Seo Kim (M02-SM17) received his B.S. degree in electrical engineering from
In-Ha University, In Chon, Korea, in 1998, and his M.S. and Ph.D. degrees in electrical
and computer engineering from the University of Florida, in 2001 and 2004, respectively.
His Ph.D. study was supervised by Dr. Y. Fang. From 1997 to 1999, he was with Motorola
Korea Ltd., Paju, Korea, as a Computer Integrated Manufacturing (CIM) Engineer in
Advanced Technology Research and Development (ATRD). From 2005 to 2007, he was with
Motorola Inc., Schaumburg, IL, USA, as a Senior Software Engineer in networks and
enterprises. His research focuses in Motorola Inc., designing protocol and network
architecture of wireless broadband mission-critical communications. From 2012 to 2014,
he was the Chairman with the Department of Software and Communications Engineering,
at Hongik University, Korea, where he is currently a professor. His work has appeared
in around 242 publications and 24 patents. His research interests include the design
and development of efficient wireless/wired networks including link adaptable/cross-layer-based
protocols, multi-protocol structures, wireless CCNs/NDNs, mobile edge computing, physical
layer design for broadband PLC, and resource allocation algorithms for wireless networks.
He served as the Member of the Sejong-city Construction Review Committee and Ansan-city
Design Advisory Board. He served as the General Chair for 3rd IWWCN 2017, and the
TPC member for the IEEE VTC 2014-Spring and the EAI FUTURE2016, and ICGHIC 2016 2019
conferences. He served as the Guest Editor for special issues of the International
IEEE Internet of Things Journal, Journal of Distributed Sensor Networks (SAGE), the
IEEE ACCESS, and the Journal of the Institute of Electrics and Information Engineers.
He is an Editor of Telecommunications Systems and an Associate Editor of the IEEE
ACCESS.