Determining the location of patients in remote rehabilitation by means of a wireless network


ACTA IMEKO 
ISSN: 2221-870X 
September 2023, Volume 12, Number 3, 1 - 5 

 

ACTA IMEKO | www.imeko.org September 2023 | Volume 12 | Number 3 | 1 

Determining the location of patients in remote rehabilitation 
by means of a wireless network  

Oleksii Tohoiev1 

1 Petro Mohyla Black Sea National University, 68 Desantnykiv Str., 10, 54003 Mykolaiv, Ukraine 

 

 

Section: RESEARCH PAPER  

Keywords: Wi-Fi; MAC; wireless network; throughput; spatial flow; transport protocol 

Citation: Oleksii Tohoiev, Determining the location of patients in remote rehabilitation by means of a wireless network, Acta IMEKO, vol. 12, no. 3, article 8, 
September 2023, identifier: IMEKO-ACTA-12 (2023)-03-08 

Section Editor: Susanna Spinsante, Grazia Iadarola, Polytechnic University of Marche, Ancona, Italy   

Received March 10, 2023; In final form June 13, 2023; Published September 2023 

Copyright: This is an open-access article distributed under the terms of the Creative Commons Attribution 3.0 License, which permits unrestricted use, 
distribution, and reproduction in any medium, provided the original author and source are credited. 

Funding: This work was supported by Petro Mohyla Black Sea National University (PM BSNU) in Mykolaiv (Ukraine), and also financed in part of the PM 
BSNU Science-Research Work by the Ministry of Education and Science of Ukraine “Development of the modules for automatization of wireless devices for 
recovery of postinfarction, post-stroke patients in individual conditions of remote individual rehabilitation” (State Reg. No. 0121U109898). 

Corresponding author: Oleksii Tohoiev, e-mail: oleksii.tohoiev@chmnu.edu.ua  

 

1. INTRODUCTION 

This article addresses an explanation of indoor location 
identification method usage developed to be of practical use in 
medical facilities. It is worth noting the numerous indoor 
localization methods having limitations, such as complexity of 
use (the necessity of special equipment being one of the 
complexities). The method described in this paper does not 
require additional maintenance or special equipment other than 
Wi-Fi access points. The reason why the method is unique lies in 
the fact that the one not requires the mobile device to be in 
hotspot mode. But more importantly, Wi-Fi access points 
location the only required data. The current paper shows that the 
acceptable accuracy of the location can be achieved in the real 
environment exclusively by means of the method described, 
which relies on simple hardware and software requirements. This 
paper presents a non-standard innovative way of using Wi-Fi 
access points (routers) as measuring equipment to determine the 
coordinates of a patient's location within a medical institution. 
To be able to use the described method, the patient must have 
some device with a built-in Wi-Fi module (smartphone, smart 

watch, etc.) or, for example, based on a microcontroller with Wi-
Fi capabilities (CC3200) for ECG monitoring [1]. The work does 
not set the task of improving the accuracy of the indicated 
coordinates, a satisfactory result for the staff is the determination 
of the room in which the patient is currently located. This is 
especially important when it is necessary to provide assistance to 
patients after serious illnesses (who are in rehabilitation), when, 
for example, they were given an alarm signal or its biomedical 
signals are unstable.  

Modern scientists are also actively considering the possibility 
of transferring data from body sensors of patients to remote 
cloud servers through access points [2]. Determining the 
patient's location near certain telecommunications equipment 
will facilitate remote monitoring of the patient in the interests of 
telemedicine. 

2. THE CURRENT STATE AND PROBLEMS OF DETERMINING 
THE LOCATION OF MOBILE NETWORK OBJECTS 

Systems for determining the position of moving objects in 
space using a stationary network (for example, by means of 
parameters of telecommunications equipment) are effective for 

ABSTRACT 
This article discusses the indoor object's location identification method that had been developed to use in medical facilities. Differently 
from other similar methods, the one reported in this paper requires access to Wi-Fi access points only and, most importantly, it does 
not require the mobile device to be in hotspot mode. It is proposed to use Wi-Fi access points (routers) with non-standard firmware as 
measuring equipment to determine the coordinates of the patient's location within the medical institution. Thus, it can be claimed that 
using of the proposed method will help to achieve acceptable accuracy in real environments at real-time identification mobile devices 
using simple hardware and software requirements. 

mailto:oleksii.tohoiev@chmnu.edu.ua


 

ACTA IMEKO | www.imeko.org September 2023 | Volume 12 | Number 3 | 2 

controlling patient movement over short distances. Such 
"moving objects" can include patients undergoing remote 
rehabilitation. In any case, such a mobile delivery network should 
be regarded as a corporate network with a single MAC address 
plan and the ability to listen in (sniffing) on nodes connected via 
wireless communication means. In the classic sense, a sniffing 
attack refers to intercepting data by capturing network traffic 
using a packet sniffer (a program designed to capture network 
packets). Sniffing is typically used by attackers to gain 
unauthorized access to confidential information, eventually 
leading to a network outage or damage, or to read messages 
circulating in the network. Therefore, information security 
measures are aimed at countering sniffing attacks in computer 
networks [3]. 

The aforementioned traffic sniffing technology can be applied 
to determine the location of people moving around within an 
area where a wireless local network is deployed, if they have a 
gadget with them (such as a smartphone, tablet, smartwatch, etc.) 
that has a Wi-Fi module enabled. Such an approach can also be 
useful for providing individualized conditions for the remote 
rehabilitation of post-stroke and post-heart attack patients. By 
using traffic sniffing technology, it is possible to determine the 
location of both the patient and the doctor, if necessary, to 
provide timely assistance to patients who are in remote 
rehabilitation and can move independently. 

Currently, scientists and practitioners have conducted a 
significant amount of research on the problem of deploying a 
positioning system for moving objects that have a built-in 
wireless communication module. Analysis of such research 
indicates that the error of existing methods ranges from 1.78 to 
10 meters. Scientists have considered various aspects of 
positioning and navigation methods [4], [5]. The most common 
technologies for positioning are satellite systems (such as GPS 
and Galileo) and terrestrial cellular networks. 

The tasks of determining the ultimate limits of positioning 
system accuracy, which are defined by the presence of noise and 
obstacles, remain completely unsolved and relevant; describing 
the operation of a number of new methods (such as direct 
positioning) aimed at enabling GPS operation with very weak 
received radio signals (for example, in mountainous terrain); and 
methods of optimal combining of measurements based on radio 
signals and signals from various sensors, such as inertial 
platforms (including those with gyroscopes). 

Research in new areas of cooperative positioning, where 
multiple nodes exchange signals and information to improve 
their positions, is also promising. In the last decade, one of the 
most popular solutions has been object localization based on 
Wi-Fi, which is considered the most promising for investigating 
open questions in both scientific and industrial communities. 

The main concept of a wireless Wi-Fi network is the presence 
of an access point (AP) that connects to the Internet service 
provider and transmits a radio signal. Usually, an AP consists of 
a receiver, a transmitter, a wired network interface, and software 
for quick setup. A network is formed around the AP within a 
radius of 50–100 meters (called a hotspot or Wi-Fi zone) where 
the wireless network can be used. The transmission distance 
depends on the transmitter's power (programmable in some 
equipment models), the presence and characteristics of obstacles 
such as antennas. Today, the 802.11n standard is widely used, 
which provides a data transfer speed of up to 320 Mbps [6]. 

Methods of Wi-Fi positioning can be divided into two main 
groups. One is based on mapping and a map catalog compiled 
from data from satellite systems (SS) [4], and the other is based 

on modeling the propagation of radio waves (RF) [7]. The RF 
model determines the relationship between signal strength and 
distance. To determine the distance between known points and 
the patient, trilateration algorithms can be used [8]. 

However, currently, it takes several dozen measurements to 
determine the relationship between distance and signal strength. 
Therefore, this model is not entirely dynamic and requires further 
research and improvement, such as 

1) Analyze the trends in the development of radio wave-
based methods towards the implementation of projects 
for determining the position of moving objects.  

2) Substantiate the feasibility and implement the 
development of a MAC-directed approach for 
monitoring numerous objects in a wireless corporate 
network.  

3) Develop an algorithm for detecting the location of 
moving objects based on a comprehensive approach to 
determining their positioning and identification. 

Define the limits of using different methods for determining 
the location of moving objects in systems with a high level of 
information security. 

Let us consider positioning based on radio wave propagation 
modeling (RF) [9]. The authors use RSSI with Bluetooth; 
however, this is not a suitable method for use at medical 
institution, because for this you need a separate device or turn on 
Bluetooth separately on the smartphone. The purpose of such 
modeling is to express the mathematical relationship between the 
distance from the transmitter to the receiver and the signal 
strength. The mathematical expression is obtained from a third-
order polynomial regression. The main advantage of this 
technology is the speed of positioning. In addition, an important 
point is that access points (AP) have fixed coordinates (Figure 1).  

The development of methods for determining a patient's 
location based on a combination of signal characteristics from 
APs is currently a relevant issue. However, regression requires a 
large amount of accurate information on signal strength over a 
fairly long period. This method provides positioning accuracy 
within 1–3 m. An integral quadratic quality criterion is used to 
evaluate the effectiveness of positioning technologies [10]. 

For tracking patient movement, the RADAR radio frequency 
system [11] is also used. RADAR works by recording and 
processing signal strength information at several base stations 
located in the area of interest to provide overlapping coverage. It 
is possible to eliminate unwanted noise in SONAR and RADAR 
systems by implementing the beamforming method proposed in 

 

Figure 1. Patient in a system with fixed access points APi. 



 

ACTA IMEKO | www.imeko.org September 2023 | Volume 12 | Number 3 | 3 

[12] and well proven in the building of separate infrastructure for 
medical telemetry applications.  

Using RADAR technology [13], a mobile device uses a CC-
map of the required location. The original CC-map is generated 
from the coordinates, CC measurements, and patient location. 
The signal strength from each AP is compared to the 
corresponding values in the database, and the appropriate 
location is predicted. The average error of this method is 1.78 m, 
but the maximum error can be up to 40 m [14]. 

Thus, if it is necessary to determine the location of a moving 
object with greater accuracy, then it is necessary to turn to other 
methods of positioning such an object. 

3. THE METHOD OF ANALYZING THE POSITIONING OF 
MOVING OBJECTS BASED ON DETERMINING THE 
RELATIVE SIGNAL STRENGTH 

Existing mobile positioning methods designed for stationary 
objects do not allow to track moving objects, and they will not 
be picked up by a Wi-Fi sniffer [15]. 

The proposed search method can be divided into three stages: 
data collection, propagation modeling, and location 
determination, which are presented in Figure 2. During the data 
collection stage, the server periodically requests (position 1 in 
Figure 2) each AP to scan for signals. During the search stage, 
the terminal investigates the Wi-Fi spectrum for available access 
points and determines the received signal strength indication 
(RSSI) that reaches the antenna of each AP (position 2 in 
Figure 2). Then this information is sent (position 3 in Figure 2) 
to the search server, which determines the point on the modeled 
signal propagation map from the device with a Wi-Fi module on 
the moving object (patient). 

At the data collection stage, the search server queries each 
access point for RSSI survey results (Figure 3). The results, 
including the list of access points and their corresponding RSSI, 
are stored in a database (DB) on the server. 

Each time the RSSI data is obtained from the access points 
for the current time, new location parameters are calculated. 
When calculating location parameters for a specific access point, 
a request is sent to the database to measure the signal received 
from this access point and detected by another access point. To 
calculate the distance from the transmitter to the receiver based 
on the IEEE 802.11 standard, RSSI is used to measure the 
relative signal strength, which is typically measured in decibel-
milliwatts (dBm). However, there are no specific formulas for 
calculating accurate distances due to the influence of the real 
indoor environment and the implementation by manufacturers. 

According to [9] and using a simple power loss propagation 
model, the RSSI distance measurement is given as: 

𝑃𝐿 = 𝑃𝐿0 + 10 𝛾 log10(𝑑 𝑑0⁄ ) + Δ, (1) 

where PL represents the path loss at distance d (in m); PL0 (in 

dBm) is the total path loss at distance d0(m); 𝛾 is the exponent of 
path loss depending on the surrounding environment; d is the 
distance between the patient and the control access point; Δ is 
the variable that takes into account the change in the mean value, 
it is also often referred to as shadow fading [16]. 

Let us denote each record in the database using the notation 

𝑅𝑆𝑆𝐼𝑗,𝑖 , where the subscript j denotes 𝐴𝑃𝑗 , on which the signal 

was measured, and the index i means 𝐴𝑃𝑖 , from which the 
measured signal came. When identifying a parameter 𝛾𝑖  for the 
propagation of the signal coming from 𝐴𝑃𝑖 , it is necessary to 
query the database for the measurements 𝑅𝑆𝑆𝐼𝑚 , and 𝑅𝑆𝑆𝐼𝑛,𝑖 , 
collected in the interval δ, where subscripts m, n represent a pair 

of APs that are not 𝐴𝑃𝑖 .  
The experimental assessment, as detailed in Figure 3, 

demonstrated that better accuracy could be achieved by 
excluding measurements from the access point (AP) situated on 
the same wall as APi. Specifically, the performance of the 
parameters for AP2 in Figure 1, computed based on 
measurements acquired at AP3 and AP4, outperformed those 
generated using measurements from AP1. The observed 
disparity in parameter estimation was attributed to the reflection 
of the wall on which the transmitting AP was mounted. 

Knowing the spatial positions of access points, it is possible 

to obtain distances 𝑑𝑖,𝑚  і 𝑑𝑖,𝑛, which are the distances between 

𝐴𝑃𝑖  and 𝐴𝑃𝑚 or 𝐴𝑃𝑛 . Rewriting Equation (1) with the introduced 
subscripts, we obtain an equation that can be used to determine 

𝛾𝑖 .  
At the same time, 𝑑0 is taken equal to 1. Thus, Equation (1) 

turns into (2): 

𝑅𝑆𝑆𝐼𝑚,𝑖 − 𝑅𝑆𝑆𝐼𝑛,𝑖 = 10 𝛾𝑖  log10
𝑑𝑖,𝑚
𝑑𝑖,𝑛

. (2) 

Indicator 𝛾𝑖  loss of signal strength on the path for the access 
point 𝐴𝑃𝑖  can be calculated using the least-squares regression of 
Equation (2). To explain this phenomenon, it is advisable to 

extend the signal loss model with a parameter 𝛽𝑖 , which takes 
into account the effect of the angle difference between the 
direction of the direct path of the signal and the normal vector 
to the wall on which the AP is installed. The extended log distance 
path model can be written as: 

 

 

Figure 2. Main stages of patient search. 

 

Figure 3. Example of signals emitted from AP1, detected at AP2, AP3, and AP4 
and Patient. 



 

ACTA IMEKO | www.imeko.org September 2023 | Volume 12 | Number 3 | 4 

𝑅𝑆𝑆𝐼𝑚,𝑖 − 𝑅𝑆𝑆𝐼𝑛,𝑖

= 10 𝛾𝑖 log 10
𝑑𝑖,𝑚
𝑑𝑖,𝑛

+ 10 𝛽𝑖 log 10
𝑑𝑖,𝑚
𝑑𝑖,𝑛

× (𝑎𝑖,𝑚 − 𝑎𝑖,𝑛 ) 

(3) 

where the introduced additional symbol αi,j is defined as:  

𝑎𝑖,𝑗 =
∢(𝑛𝑖 , 𝑠𝑖,𝑗 )

𝜋 2⁄
 . (4) 

Using (3), it is possible to use data from all surveyed access 

points as input data to determine the values 𝛾𝑖  and 𝛽𝑖 . It means 
that there is N×(N−1)/2×h measurement data points to infer 
signal strength parameters, where N is the number of access 

points within range 𝐴𝑃𝑖 . 
The indoor signal propagation model is developed and 

regularly updated by the International Telecommunication 
Union (ITU), which is a UN agency in the field of information 
and communication technologies. According to the ITU R.1238 
standard, for the walls of hospital buildings, γi will always be 
equal to 20 [17]. 

The power of the signal strength depends on the AP 
manufacturer. In the example from part 4, for MikroTik hAP2 
Lite was used, it has a Tx dBm of 27. 

There is also no standard dBm power for mobile devices, in 
the example, a mobile phone with a Tx dBm of 22 antenna was 
used. Hence, from a good signal level of –35 dBm to a weaker 
signal level of –55 dBm, as shown in the Figure 3. As we see that 
signal strength of AP3 is good (–39 dBm), Patient signal is good 
enough (–43 dBm). AP2 and AP4 signal is weak. 

4. SIGNAL PROPAGATION SIMULATION STAGE 

Knowing the calculated signal propagation parameters, a 
model was chosen that was built to estimate the path loss inside 
the closed area to simulate the signal propagation. Therefore, it 
was decided to use the ITU model [17]. This ITU model attempts 
to account for reflection and diffraction caused by objects, 
energy collisions, movements within the room, multipath effects, 
etc. Their model provides guidance on indoor signal propagation 
in the 300 MHz to 100 GHz frequency range. The basic model 
can be expressed as [9]: 

𝑃𝐿𝑖,𝑗 = 20 log10(𝑓) + 𝑁 log10(𝑑𝑖,𝑗 ) + 𝐿𝑓 (𝑛) − 28, (5) 

where 𝑃𝐿𝑖,𝑗 is the total loss on the path of the signal arriving at 

the access point 𝐴𝑃𝑖  at point j, dB; f is the frequency, MHz; N is 
an indicator of power loss over distance; 𝑑𝑖,𝑗  is the distance 

between 𝐴𝑃𝑖  and point j,m; 𝐿𝑓 (𝑛) is a factor that takes into 
account the loss of signal power between floors (its influence is 
not taken into account in these studies).  

In the propagation simulation step, the location server 
calculates the expected power loss in the room for each access 
point in the mesh pattern and creates a propagation map. 

To eliminate the need for patient identification, the proposed 
method only requires the ability of access points to probe Wi-Fi 
channels and report the RSSI of neighboring access points. Most 
APs on the market today have this feature built in, as it is an 
integral part of automatically determining the most suitable 
channel for Wi-Fi communication. Usually, information about 
these readings is not available to the end user. This is one of the 
reasons, apart from its popularity, that one of the most common 

wireless routers, the MikroTik hAP2 Lite, was chosen for the 
study. 

Scanning is a periodic event. If its frequency is too high, it 
leads to an additional load on the Wi-Fi network, which is 
undesirable because it affects the performance of data 
transmission in the wireless network. A scan rate that is too low 
means that changes to the Wi-Fi network that is decided to be 
used to locate moving objects (patients in remote rehabilitation) 
will take too long to become meaningful and effective. Choosing 
too many iterations will have the same consequences as choosing 
too long a listening period. Too few iterations will result in more 
influence on the RSSI variance than desired. After testing, one 
minute was chosen as the refresh rate, which ensures that 
changes due to long-term Wi-Fi instability and changes in indoor 
space will have a significant effect in less than 10 minutes, as they 
will be present in more than 50% of the data points used for 
calculation. 

After all the calculations and drawing the map, the developed 
application will show the doctor in which ward/room of the 
building the selected patient is located. An example of such a 
map is shown in Figure 4. 

In the given example, you can see that the patient is in 
Room 1. 

5. CONCLUSIONS 

The proposed method, based on listening to Wi-Fi signals, is 
a further development of the ITU-R Recommendations [17]. 
This method can be applied to a variety of wireless 
telecommunication equipment and requires only AP 
information. A map of the patient's location is built on the basis 
of the RSSI indicators. To track the location of patients, they 
(patients) only need to have a smartphone with the Wi-Fi 
transmitter turned on.  

The disadvantages of the proposed method are that the RSSI 
indicator is poorly correlated with the signal quality, but it can be 
used to approximate the signal quality. A more accurate 
assessment can be obtained using the Link Quality Indicator 
(LQI). The expediency of using the specified parameter is 
justified by the fact that if there are numerous devices in the local 
network with enabled Wi-Fi modules in an open environment, 
such devices are also sources of interference. In this case, the 
power of the received signal may be high, but the ratio between 
the received signal and the noise level is lower than necessary to 
determine the location of the moving object. To use the LQI 
parameter, the Bluetooth module, which is also built into most 
popular gadgets, or other types of technologies according to the 
802.15 standard, are more suitable. 

 

Figure 4. An example of a patient location map. 



 

ACTA IMEKO | www.imeko.org September 2023 | Volume 12 | Number 3 | 5 

The implementation of the proposed algorithm does not 
require specialized antennas, which were used in previous studies 
[18]. Different from previous approaches that relied on specific 
antenna configurations to achieve optimal results, our algorithm 
uses built-in signal processing techniques to achieve reliable 
results using standard antennas commonly found in most 
devices. This eliminates the need for expensive and specialized 
antenna systems, making the algorithm affordable and practical 
for a wide range of applications. 

ACKNOWLEDGEMENT 

This study was funded and supported by Petro Mohyla Black 
Sea National University (PM BSNU) in Mykolaiv (Ukraine), and 
also financed in part of the PM BSNU Science-Research Work 
by the Ministry of Education and Science of Ukraine 
“Development of the modules for automatization of wireless 
devices for recovery of postinfarction, post-stroke patients in 
individual conditions of remote individual rehabilitation” (State 
Reg. No. 0121U109898). The author declares that there are no 
conflicts of interest regarding the publication of this article. 
Written & Oral informed consent was obtained from all 
individual participants included in the study but nothing 
identifying information is included in this paper. 

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