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Engineering, Technology & Applied Science Research Vol. 11, No. 4, 2021, 7405-7410 7405  
  

www.etasr.com Shamsan & Almuhanna: Intersystem Interference Study between Medical Capsule Camera Endoscopy … 

 

Intersystem Interference Study between Medical 

Capsule Camera Endoscopy and Other Systems in 

Co-Channel and Adjacent Bands 
 

Zaid Ahmed Shamsan 

Electrical Engineering Department 
College of Engineering 

Imam Mohammad Ibn Saud Islamic 

University (IMSIU) 
Riyadh, Saudi Arabia  

shamsan@ieee.org  

Khalid Almuhanna 

Electrical Engineering Department 
College of Engineering 

Imam Mohammad Ibn Saud Islamic 

University (IMSIU) 
Riyadh, Saudi Arabia  

kalmuhanna@imamu.edu.sa 
 

 

 

Abstract—The Ultra-High Frequency (UHF) band occupies a 
very vital region in the spectrum and is becoming very congested 

because many applications use it. The capsule camera (CapCam), 

an ultra-low power wireless device, is a Short Range Device 

(SRD) application that utilizes the UHF spectrum for medical 

endoscopy and it is designed to operate at the 430-440MHz 

frequency band range. This study will focus on the interference 

between the CapCam and other systems operating in the 
frequency of 435MHz and adjacent bands. Other systems that 

can operate in this band include non-specific SRD and 

radiolocation services such as airborne radar and ground radar 

stations. The Minimum Coupling Loss (MCL) method is 

implemented in this study. The findings showed that restricted 

distances between the CapCam and other services must be 

considered when the CapCam is in use. This should be done to 
avoid harmful interference from the CapCam especially in the 
case of radiolocation services. 

Keywords-CapCam; airborne radar; ground radar; 

interference; MCL method 

I. INTRODUCTION  

Wireless Medical Capsule Endoscopy (WMCE) is a new 
generation of medical Short Range Device (SRD) applications, 
which are characterized by operating in ultra-low power and 
short distance applications. The capsule camera (CapCam) is a 
main component of the ultra-low power WMCE application. 
The CapCam endoscopy is a practice recommended by doctors 
that uses a miniature wireless camera to take images of a 
patient’s digestive tract as it passes through it. The endoscopy 
camera is placed within a small capsule (approximately the 
same size as a vitamin pill) that the patient swallows. The 
camera takes pictures as the capsule passes through the 
patient's digestive system and transfers them wirelessly to a 
recorder carried by the patient [1]. The CapCam is a medical 
diagnostic tool designed to operate in the UHF range including 
the frequency band of 430-440MHz [2]. This frequency band is 
occupied by several services such as radiolocation services, 
amateur radio services, non-specific SRDs (NSRDs), land 
mobile services, and earth exploration-satellite services. 

Therefore, the possibility of interference occurring between 
these systems and the CapCam service is something that needs 
to be investigated. As a result of the interference, system 
performance deterioration may occur. 

Depending on the properties of various WMCE systems 
and the method of treatment, many contraindications are set by 
manufacturers. Such a contraindication is the electromagnetic 
radiation represented by the interference of the CapCam with 
other wireless devices (or intersystem interference). Based on 
previous studies and the manufacturers’ recommendations, 
these contraindications include the effect on the cardiac 
pacemakers or other implanted electro-medical devices, 
creating strong electromagnetic fields on devices such as 
Magnetic Resonance Imaging (MRI), etc. [3, 4]. More broadly, 
in this paper, the intersystem interference between the CapCam 
service and other systems is controlled in a primary-secondary 
operating basis, where the CapCam service is a secondary 
service and the other systems are considered the primary 
services [5]. Comprehensively, when the SRDs (as a secondary 
service) operate in shared bands, they are not permitted to 
cause harmful interference to radio services (primary). So, in 
general, SRD cannot claim protection from interference caused 
by radio communication services as defined by the 
International Telecommunication Union Radio Regulations 
(ITU-RR) [6]. Further, this means that the CapCam must not 
cause interference to the other primary services. Therefore, this 
paper will study the effect of the CapCam service on other 
services. Both co-channel interference and adjacent channel 
interference will be examined in Line of Sight (LOS) and non-
LOS (NLOS) environments. 

II. INTERSYSTEM INTERFERENCE SCENARIOS 

This section provides a summary of the proposed 
interference scenario between the CapCam and other systems 
that share the same frequency band of 430-440MHz. The 
services/systems involved in this study are described in detail. 

Corresponding author: Zaid Ahmed Shamsan 



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A. Interference Scenario 

The interference scenario is shown in Figure 1. The 
CapCam service is assumed to be operating in the 430-
440MHz frequency band and shares it with other services 
(radiolocation and NSRD) according to the ITU-RR's Article 5 
[5] and the European Common Allocations (ECA) [7]. The 
frequency allocation for the 430-440MHz band regarding 
radiolocations services (airborne and ground radars) and SRD 
are shown in Table I. It can be realized that the proposed use of 
the CapCam application operating in the frequency band of 
430-440MHz would lead to affecting both radiolocation and 
NSRD systems. This study will investigate this impact in order 
to coordinate the use of the CapCam with radiolocation and 
NSRD systems. 

TABLE I.  THE ITU-R SPECTRUM ALLOCATION FOR THE CAPCAM, 
RADIOLOCATION, AND NSRD SERVICES IN THE 430-440MHz BAND 

ITU RR allocation Frequency band (MHz) 

RADIOLOCATION 430-433.05 

RADIOLOCATION, NSRD 433.05-434.79 

RADIOLOCATION 434.79-440 
 

 
Fig. 1.  The interference scenario of CapCam with other services.  

 
Fig. 2.  The scenario of CapCam and DR as a WMCE application.  

It is assumed that the CapCam service (the interferer) is 
utilized inside a medical building such as a hospital and causes 
interference to three discrete outdoor wireless systems 
(airborne radar, ground radar, and NSRD), which can be 
termed as interfered services (Figure 1). In the following 
subsections, a brief description of these systems, as well as the 
CapCam service are presented. 

B. The CapCam Service 

It is a relatively new application of medical SRDs that can 
perform medical tests of patients with specific digestive 

conditions without causing bleeding or sedation hazard 
involved by traditional endoscopy [2]. The crucial part of the 
new application is a disposable tiny optical imaging camera 
imbedded in a capsule. The CapCam is given to the patient to 
swallow and while it moves through the patient’s digestive 
tract it sends images to a receiver (Data Recorder-DR) outside 
the patient’s body as shown in Figure 2.  

C. Non-specific SRDs 

NSRDs are devices for wireless telegraphy including 
telemetry, tele-command, alarms, and data transmission. 
Telemetry services use radio communication for automatically 
indicating or recording measurements at a distance from the 
measuring instrument. Tele-command services use radio 
communication for the transmission of signals to create, 
modify or dismiss functions of equipment at a distance; and the 
alarms are devices used for alarm systems, including social, 
security, and safety alarms [8]. 

D. Radiolocation  

Radiolocation services are defined as radio-determination 
services for the purpose of position determination. Radio-
determination is defined as the determination of the position, 
velocity, and/or other characteristics of an object by the 
propagation properties of radio waves [9, 10]. The airborne 
radar [11], is a radar on a plane used to detect objects moving 
at very low speeds whereas ground radar is used for fixed, 
mobile, or transportable operations. 

III. INTERFERENCE CALCULATION METHODOOLGY  

The method proposed to calculate the intersystem 
interference from the CapCam and other systems is the 
standard Minimum Coupling Loss (MCL) which consists of 
attaining the critical minimum propagation losses required to 
avoid interference. Once the total losses are obtained, it is 
straightforward to determine a matching minimum separation 
distance depending on a given propagation model. The 
propagation model used for the assessment of the separation 
distance is the free space model as well as indoor penetration 
losses due to the natural work of the CapCam from the indoor 
environment and emitting power into the outdoor environment. 
The free space wave propagation model is given by [12]: 

� �
������

��	

	�	�
�	    (1) 

where �  denotes the received interference power at the 
interfered system (radiolocation or NSRD systems), �� denotes 
the transmit power from the interferer system (the CapCam 
service), �� and �� are the gain of the transmitter and receiver 
antenna respectively, �
�  denotes the correction factor of 

bandwidth between the CapCam and the interfered system, 
and ���� is the channel propagation loss due to the free space 

(outdoor) environment and the indoor penetration loss. The 
expression in (1) can be represented using the decibel scale as 
follows [13]: 

� � �� � ����� � �
� � ����	    (2) 

where ���� is the free space loss due to the free space 

environment (��) and the indoor penetration loss ��. The �� 



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loss mainly depends on the wavelength of the traveling signal, 
�, either in LOS or NLOS environments, and the distance 
between the transmitter and receiver � . ��  is based on the 

material type used to construct the hospital building. Therefore, 
the ����  factor can be defined for the LOS and NLOS as 

follows: 

���� � �� �	��    (3) 

When the signal travels in a LOS outdoor environment, the 

loss ���� is given by (4) for true urban propagation prediction 
[14, 15]:

 

����(���) � 32.45 � 20log(&�) � ��    (4)
 

If the signal travels in an NLOS outdoor environment, the 
loss ���� is given by:

 

����('���) � 32.45 � 20log(&) � 35log(�) � ��	    (5) 

where the frequency & is in MHz and the distance � is in km.  

In this study, both interference situations (co-channel and 
adjacent channel interferences) will be considered in both 
propagation environments. 

IV. SYSTEM PARAMETERS 

The main parameters for the considered systems for the 
CapCam, NSRD, airborne radar, and ground radar are shown in 
Tables II and III. It is worth mentioning that the radiations from 
the CapCam may not be highly uniform throughout the whole 
channel bandwidth except within the co-channel frequency (at 
around 10MHz). Also, 10dB is assumed as the body loss which 
is applied to distinguish the power levels inside/outside the 
body. 

TABLE II.  MAIN PARAMETERS OF THE INTERFERER SYSTEM (THE 
CAPCAM) 

Value Parameters 

430-440MHz Frequency of operation 

10MHz Single channel RF bandwidth 

-30dBm Maximum ERP of the transmitter 

2.15dB Antenna gain 

-40dBm ERP outside patient's body 

-50dBm/100kHz Maximum ERP density outside patient's body 

8-12h Single use of activity cycle 

10dB Building penetration loss 

TABLE III.  MAIN PARAMETERS OF INTERFERED SYSTEMS 

Ground 

radar 

Airborne 

radar 
NSRD Parameters 

1 1 0.250 Channel bandwidth, MHz 

38 22 -2.85 Rx antenna gain, dB 

-115.9 -114.9 -110 Rx interference threshold, dBm 

�/) � −6 �/) � −6 C/I�8 Rx protection criteria, dB 
8 >9000 3 Height above ground level, m 

 

V. RESULTS AND DISCUSSION 

This section of the paper analyzes and discusses the results 
of the coordination between the CapCam and the considered 
systems that share the frequency band of 430-440MHz.  

A. The CapCam and NSRD Systems 

Since the NSRD is set to run in the frequency band 433.05-
434.79MHz, the operating carrier frequency is assumed as 
433.91MHz. The channel propagation will be affected by the 
penetration loss of 10dB as well as the loss in the LOS and 
NLOS environments. The values of interference levels from the 
CapCam service into the NSRD service versus the separation 
distances using co-channel frequency are shown in Figure 3. 
This Figure illustrates that the minimum distance in the LOS 
environment is about 322m whereas it is 27.6m in the NLOS 
dense urban areas. At these distances, minimum power will be 
detected according to the NSRD receiver sensitivity which is -
110dBm/25kHz. Figure 3 shows that as the distance increases 
the interference level from the CapCam into the NSRD receiver 
decreases due to the propagation effect for both LOS and 
NLOS. However, the interference level drastically decreases in 
NLOS compared to the LOS environment. To allow for proper 
coordination between the CapCam system and the NSRD 
system the required margin in the co-channel frequency band is 
depicted in Figure 4. It can be seen from Figure 4 that as the 
distance increases, the required margin decreases linearly in the 
log scale. In Figure 4, we can notice that the required margin is 
0dB at the separation distances of 322m and 27.6m for LOS 
and NLOS respectively. The reason is that at these distances 
the received power is equal to the NSRD receiver sensitivity of 
-110dBm. Before reaching the aforementioned distances, the 
interference power is high and can cause deterioration in 
NSRD receiver performance. Therefore, it is required to keep 
that distance in consideration regarding the operation of the 
CapCam and NSRDs services. 

 

 
Fig. 3.  The interference from the CapCam into the NSRD in the co-

channel frequency band. 

On the other hand, by shifting the CapCam carrier 
frequency by 10MHz the two systems will operate under the 
adjacent channel band scenario. This is illustrated in Figures 5 
and 6. In Figure 5, the interference level from the CapCam 
service is 102m in LOS areas, while the distance in NLOS 
dense urban areas is only 15m and lower than that of LOS 
environment. These findings are confirmed in Figure 6, which 
shows the power margin in both areas. This shows that the 
power margin is 0dB at the above mentioned distances due to 
the received power being equivalent to the NSRD receiver 
sensitivity. From the findings of the operation of the CapCam 
and NSRD services, it can be concluded that the interference 

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power in NLOS is less than in the LOS environment. This 
variation in interference power is due to the environment in the 
NLOS blocking the interference power from the CapCam from 
reaching the interfered system receiver in its entire strength. 
The LOS environment allows the interference signal power to 
travel with no obstacles in its path. Moreover, the minimum 
distance required to operate the CapCam and NSRD services 
simultaneously in the same area with no harmful interference 
using the co-channel frequency band is higher compared to the 
distance using the adjacent channel. This occurs due to the fact 
that the emitted power from the CapCam service in the case of 
the adjacent channel frequency band is less than the power 
emitted in the case of the co-channel band by 10dB. Thus, the 
decrease in the interference emission power is transferred into 
decreasing the distance that enough harmful interference signal 
can reach the affected receiver of the NSRD. This finding is 
consistent with the findings of [16]. 

 

 
Fig. 4.  The required margin for coordination of the CapCam and the 

NSRD in the co-channel frequency band. 

 
Fig. 5.  The interference from the CapCam to the NSRD in the adjacent 

channel frequency band. 

B. The CapCam and Airborne Radar Systems 

Here, the affected service is the airborne radar while the 
interferer is the CapCam service. The airborne radar receiver 
has an interference threshold of –114.9dBm. Figures 7 and 8 
illustrate the interference power level with the distance 
increasing between the two systems in co-channel and adjacent 
channel frequency bands respectively. Both Figures show that 
the distance required in LOS is higher than that required in 

NLOS areas. In addition, the minimum distance in the co-
channel band is higher than that in the adjacent channel band. 
In the co-channel scenario the distance is 1563m and 67.5m, 
while in the adjacent channel scenario it is 494.5m and 36m for 
LOS and NLOS respectively. Also, in Figures 9 and 10, the 
power margin is depicted for the same scenarios, in which 0dB 
is the margin at the abovementioned distance. At greater 
distances, the power margin is negative which means it allows 
the airborne radar to run with no interference acting on it from 
the CapCam.  

 

 
Fig. 6.  The required margin for the coordination of the CapCam and the 

NSRD in the adjacent channel frequency band. 

 
Fig. 7.  The interference from the CapCam to the airborne radar in the co-

channel frequency band. 

 
Fig. 8.  The interference from the CapCam to the airborne radar in the 

adjacent channel frequency band. 

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C. The CapCam and Ground Radar Systems 

For this scenario, the receiver has an interference threshold 
that is lower than that of the airborne radar, which is  
–115.9dBm. The findings shown in Figures 11 and 12 present 
the interference levels with the distance between the CapCam 
and ground radar services. It is found that the minimum 
distance at which the two systems can operate together with no 
harmful interference is 1754m and 72m for the co-channel 
frequency band in the LOS and NLOS environments 
respectively. The minimum distance decreases using the 
adjacent channel band are 555m and 39m in the LOS and 
NLOS environments respectively. Moreover, Figures 13 and 14 
show the required power margin between the received 
interference from the CapCam service and the maximum 
interference threshold. Therefore, at the abovementioned 
distances, this margin is 0dB, and before the ground radar 
cannot work. For instance, in distances less than 1754m and 
555m the ground radar may not operate properly if the 
CapCam service operates at the same time. 

 

 
Fig. 9.  The required margin for the coordination of the CapCam and the 

airborne radar in the co-channel frequency band. 

 
Fig. 10.  The required margin for the coordination of the CapCam and the 

airborne radar in the adjacent channel frequency band. 

Table IV summarizes the results from the presented 
scenarios. It shows that the ground radar service is the most 
affected among other services due to the maximum interference 
threshold and its higher antenna gain. Although, the 
exceptionally low deployment density of the CapCam services 
and the short time period of single-use of the CapCam devices, 

compared with many other SRD applications, distance should 
be taken into account. Another important point in this study is 
that it assumes that the patient treated by the CapCam is 
separated by only one wall from the considered 
devices/services. In practical situations there may be many 
walls or partitions, which can contribute to more propagation 
loss that may allow the operation of the CapCam with other 
services without interferences. 

 

 
Fig. 11.  The interference from the CapCam to the ground radar in the co-

channel frequency band. 

 
Fig. 12.  The interference from the CapCam to the ground radar in the 

adjacent channel frequency band. 

 
Fig. 13.  The required margin for the coordination of the CapCam and the 

ground radar in the co-channel frequency band. 

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Fig. 14.  The required margin for the coordination of the CapCam and the 

ground radar in the adjacent channel frequency band 

This paper illustrates new findings on the coordination of 
operating a CapCam system with radiolocation and NSRD 
services, which are investigated in order to eliminate possible 
interferences to those services. This study considered the effect 
of building penetration loss, adjacent channel interference, and 
long coverage distance which makes this study more 
technically sound compared to the work in [2]. Ultimately, the 
findings of this paper aim to decrease the required restrictions 
that should be taken into account for the CapCam service to run 
harmlessly besides other wireless services. 

TABLE IV.  MINIMUM PHYSICAL SEPARATION BETWEEN THE 
CAPCAM AND OTHER SYSTEMS IIN LOS AND NLOS ENVIRONMENTS 

Physical separation (m) 

Environment Channel type 
With 

ground 

radar 

With 

airborne 

radar 

With 

NSRD 

1754 1563 322 LOS 
Co-channel 

72 67.5 27.6 NLOS 

555 494.5 102 LOS Adjacent 

channel 39 36 15 NLOS 

 

VI. CONCLUSION 

This paper presents a study of the medical capsule camera 
endoscopy (CapCam) and other systems in the 430-440MHz 
band using the MCL approach. The study covered LOS and 
NLOS areas using co-channel and adjacent channel frequency 
bands. It has been found that 1754m is the maximum distance 
for the three systems as a conservative protection distance in 
the case of the co-channel frequency band. The minimum 
distance for the three services is 555m in the adjacent channel 
scenario within a LOS environment. In the case of NLOS, the 
physical separation distances decrease dramatically. More 
studies may be recommended to investigate and analyze the 
effect of different practical situations with different building 
construction materials, stories, and designs.  

ACKNOWLEDGMENT 

The authors would like to thank the Deanship of Scientific 
Research at Imam Mohammad Ibn Saud Islamic University 
(IMSIU) for the financial support of the project under the grant 
No. 18-11-14-001.  

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