International Journal of Interactive Mobile Technologies – ISSN: 1865-7923 – Vol. 13, No. 01, 2019


Paper—Sensor Enhanced Health Information Systems: Issues and Challenges 

Sensor Enhanced Health Information Systems: 
Issues and Challenges 
https://doi.org/10.3991/ijim.v13i01.7037 

Abubakar Adam, Adamu Abubakar(*), Murni Mahmud 
International Islamic University Malaysia, Kuala Lumpur, Malaysia 

adamu@iium.edu.my 

Abstract—Owing to the fact that the world population is aging and 
considering the high cost of healthcare services, researchers are exploiting the 
use of sensors to support mobile monitoring of healthcare systems remotely. 
However, this area is faced with numerous challenges. In this research, the 
challenges facing the integration of sensors in Health Information Systems 
(HIS) were reviewed. One of the major challenges faced by such systems is 
interoperability. In this article, a survey of existing mobile monitoring system is 
presented and the challenges facing this area are categorized. A significant 
contribution by some research has indicated the need for further study to 
thoroughly investigate Interoperability as a Property (IaaP) paradigm for HIS. 
Recommendation by some researchers requires that a prototype be developed in 
order to evaluate the performance of IaaP paradigm. 

Keywords—Patient Monitoring Systems, Wireless Body Area Network, Smart-
Shirt, M-Health, E-Health 

1 Introduction 

The world population is aging, as indicated in [1], and this lead to a situation 
whereby older people, critically ill, or disabled people will depend on younger ones 
for their daily needs. Unfortunately this dependency problem will get worse because 
the world population is aging [1]; population aging shows the changes in the 
proportion of different age groups usually based on a three-age-group population 
model: young age group (<20), working age group (20–64), and elderly people 
(>64)[1]. Based on population projection, the number of elderly people (>65 years 
old) is expected to grow rapidly due to factors such as lack of fertility, mortality and 
migration. The trend in European Union (EU) population shows that while there is a 
decline in EU population, the population of people over the age of 65 will increase 
considerably. This trend is the same for any society because it is usually young adults 
that migrate to more developed countries for better life. This implies that elder people 
and kids that are below working class will be left behind. Similarly, when there is 
high mortality rate, due to catastrophic events such as war, it is usually young adults 
that are mostly affected, which also affects the population as a whole but that of the 

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Paper—Sensor Enhanced Health Information Systems: Issues and Challenges 

elderly is minimally affected and therefore while the population decreases that of the 
elder increases. 

There is an indication that whereas in 2004 there was one elderly person (>65 years 
old) for every four persons of ‘working age’ (20 to 64 years old), in 2050 there would 
be about one elderly person for every two of working age. A similar research was 
conducted by the UN and results show that; the proportion of older persons (>60) in 
the world has been rising steadily, passing from 8 per cent in 1950 to 11 per cent in 
2009, and is expected to reach 22 per cent in 2050. To add to the dependency 
problem, the elderly people are prone to diseases; the Berlin Aging Study (BASE) has 
shown that 88% of the persons aged above 70 years suffer from five or more somatic 
diseases. Hence, it is of utmost importance to exploit the opportunities provided by 
new information and communication technologies in order to support efficient health 
and social care, especially looking at the fact that health and social care systems 
services have high costs [1]. 

Due to population ageing, as described above, and the fact that healthcare is very 
expensive, technological advancements demands that different kinds of sensors be 
used to capture physiological signals from a patient’s body who does not have to be 
physically in the hospital. The signals from the sensors will be sent to the health 
professionals, which can be used to monitor the patient remotely. In case of 
emergencies, health experts will prepare for the patients before reaching the hospital. 
Such monitoring systems will notify the health professionals about even the slightest 
change in the vital signals of the patient and therefore the patient can easily be 
monitored wherever he/she might be. Hence, older people, critically ill, and disabled 
people can achieve independent living with minimal human supervision. As a result, 
various technological aid are required, for example, a service-oriented architecture for 
wireless health systems has been presented [2]. Similarly, mHealth platform for 
Parkinson’s disease patient management has been proposed, where sensors have been 
utilized to capture data and send to the cloud infrastructure to allow easy access for 
clinicians [3]. Sensors has been utilized to proposed a noncontact sleep monitoring 
system, in order to provide a sleeping status and breathing [4]. A concept based on 
correlating situation information and patient mood captured by sensors has been 
utilized for understanding mental health situation of individuals [5]. Temperature and 
pulse rate sensor and GSM technology has been used to proposed a medical sensing 
system that transfer information between a patient, doctor and the nearby paramedical 
unit [6]. Considering the above-mentioned studies, it is imperative to outline the 
challenges faced by the outpouring of such system. That is why this study, reviewed 
the existing challenges facing the available systems. 

2 Mobile Monitoring System of Healthcare  

The attempts to make health electronics started in the early 1950’s. However, the 
use of mobile handheld devises to wirelessly access hospital data and the 
implementation of web-based e-health was not seen until mid-1990s. The use of 
hardware to support health-started way back in 1950’s where only mainframes were 

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Paper—Sensor Enhanced Health Information Systems: Issues and Challenges 

used. Today handheld mobile devices are used for such purposes. ARPANET E-mail 
were used in 1970’s for health related services while in the contemporary world 4G 
network are used [7]. 

2.1 Architectural Description of the Existing Wireless-PDA based Systems 

A wireless-PDA based physiological monitoring system was presented in [8]. The 
system consists mainly of two parts: (i) the mobile unit, which is set up around the 
patient to acquire the patient’s physiological data, and (ii) the management unit, 
which enables the medical staffs to telemonitor the patient’s condition in real-time. 
Through the WLAN, the patient’s biosignals can be transmitted in real-time to a 
remote central management unit, and authorized medical staff can access the data and 
the case history of the patient via the central management unit or the wireless devices. 
The management unit is usually a fixed computer within an existing hospital network 
or a mobile laptop via WLAN. However, Personal Digital Assistant (PDA) was used 
as a monitoring devise. PDA (such as Palm TX) is an old technology and consumed a 
lot of power. Furthermore, the mobile unit (patient environment), consultant terminal 
(doctors), and management unit (at the hospital) are expected to be within WLAN. If, 
for any reason, the car transporting the patient goes out of the network, the system 
will not work. 

The Advanced Health and Disaster Aid Network (AID-N) system, which is 
sponsored by the National Library of Medicine was proposed in [9]. Three 
hierarchical layers are involved. The bottom layer consists of an ad hoc network of 
embedded medical systems that collect the vital signs of the patients. The second 
layer consists of servers that connect up to the backbone of the Internet to relay 
information to a central server on the third layer. The main benefits of the AID-N 
electronic triage include: (i) continuous monitoring of triage levels, physiological 
status, and location of the patients (ii) automated distribution of patient data in real-
time to response team members both on and off the disaster site [9]. However, the 
framework is based PDA as the monitoring device, which is an old technology as 
stated earlier on. Moreover, for optimal performance, tags should not be more than 
one meter from the base station; which is clearly a limitation because dealing with 
patients of disaster might affect huge area. 

2.2 Architectural Description of the Existing Smartphone based Systems 

A typical example of a smartphone based WBAN healthcare structure for 
monitoring real time physiological parameters was presented in [10]. The WBAN 
consists of three types of modules: The first module-vital physiological parameters 
monitoring device–discusses the sensor technologies that can be used to read and 
monitor physiological parameters such as ECG, EEG, B. The second module - 
Wireless Communication Standards for WBAN-deals with the wireless standards for 
transmitting the physiological data from the biosensors to the mobile phone. The third 
module-Software Development Phase for WBAN-has to do with software 
development for WBAN [10]. 

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A low cost Windows Mobile BSN was proposed in [11]; one of the research 
objectives is to come up with some sort of correlation between core-body temperature 
and women fertility & ovulation periods. Even though the work was centered on 
continuously measuring the body temperature, by inserting a sensor into a woman’s 
vagina, it could also be extended to include other types of sensors. The proposed 
system consists of a SHIMMER-based body sensor network, which is used to 
measure and collect bio signals and send them to the processing unit using Bluetooth, 
which eventually send the signals to a mobile device also using Bluetooth. The 
system is consists of three modules (i) sensor (ii) processing unit and (iii) windows 
mobile device. However, only one sensor was used to measure cervix women's 
temperature and thus raise the issue of interoperability with other devices. 

A personalized health monitoring system, using smart phones, is presented in [12]. 
The proposed system was designed for heart related diseases. The heart specialist can 
select one or more sensors to be used for a particular patient and configure the 
corresponding threshold levels for that patient. The application can generate alarms or 
warnings when thresholds have been reached. However, they identified in their 
research that power consumption still remains a challenge. A ubiquitous mobile 
health system for continuous monitoring of elderly patients from indoor and outdoor 
environments has been presented in [13]. The system consists of three components: (i) 
Wireless Wearable Body Area Network (WWBAN) (ii) Intelligent Central Node 
(ICN) (iii) Intelligent Central Server (ICS). The Intelligent Central Node (which is 
basically a smartphone) servers as an accelerometer, in the architecture, where it is 
responsible for collecting, and processing the data generated by the WWBAN 
(Wireless Wearable Body Area Network) sensors. After collecting all the sensor data, 
the ICN ensures that there is no change in the collected data before sending it to the 
Intelligent Central Server (ICS). Once the data is received by ICS, it is stored in the 
database for analysis. Ubiquitous mobile health monitoring system for elderly 
(UMHMSE), which is the prototype system, monitors location and health status 
through the use of Bluetooth and smartphone [13]. 

2.3 Architectural Description of the Existing Location-based Systems 

A framework that extends the European Telecommunications Standards Institute 
(ETSI)/Parlay architecture, which is used for the deployment of standardized services 
over the next generation IP networks was proposed in [14]. Although, it is typically 
not a full-fledged location-based, but ETSI/Parlay architecture was expanded with 
new service capability features as well as sensor, profiling, and security mechanisms. 
In this architecture, NGeH domain is considered as an operational domain of well-
defined state and transactions, where the patient interacts with various entities whose 
behavior is posed by constructed profiles. There are three types of peer entities that 
interact with each other: (i) subjects (e.g., doctors, nurses, pharmacists, family 
member) (ii) objects (ICT components that are deployed around the patient/subjects 
such as the biosensors, GPS, mobile terminals etc.) and (iii) operational domains 
(these are the places where the NGeH servers are provided such as hospitals, 
healthcare units, vehicles, homes etc.). In the new proposed framework architecture, 

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Paper—Sensor Enhanced Health Information Systems: Issues and Challenges 

the new set of SCFs (Service Capability Features) Interfaces is considered as 
extended set of SCFs Interfaces and the new Framework is considered as Extended 
Framework [14].  

EmerLoc (Location-based services for emergency medical incidents) [15] and 
CAALYX (Complete Ambient Assisted Living Experiment) [16] are location-based 
systems for emergency purposes. Based on a middleware and network infrastructure, 
emergency incidents are handled in random locations either in a controlled 
environment (e.g. hospitals) or on sites where immediate health support is not 
possible (e.g., urban areas). Both EmerLoc and CAALYX incorporates wearable 
devices comprising of wireless sensors that continuously monitor the user’s bio-
signals, a micro computing unit, which is responsible for processing sensor readings 
and a central monitoring unit (CMU), which transmits the information to the medical 
personnel. Patient’s device (PD) sends the patient’s bio signals and data about the 
current location of the patient to the Central Monitoring Unit (CMU). Therefore, if 
there is any critical situation the PD (first level of incident handling) will first detect it 
and then it will be communicated to the CMU (second level of incident handling). 
The CMU is capable of alerting the attending doctor (or any doctor in proximity to the 
patient) on the situation and advise him to handle the incident. However, one of the 
major problems of this architecture is that it involves the use of heterogeneous 
network infrastructures (e.g., WLAN, PAN, GSM/UMTS) and the exploitation of the 
position fixing technologies that such networks offer. CAALYX has three main areas 
of development (i) Roaming Monitoring System (RMS), which monitors the older 
person independent of where he is at home or outdoors (ii) The Home Monitoring 
System (HMS), which is intended to integrate other home devices in order to improve 
health services that can be provide to the patient and (iii) The Central Care Service 
and Monitoring System (CCS/MS) is intended to serve as the control center where 
alerts will be received and determine the necessary cause of action. 

2.4 Architectural Description of the Existing Wearable-based Systems 

The use of wearable smart shirt for healthcare was proposed in [17], which 
measures electrocardiogram (ECG) and acceleration signals for continuous and real 
time health monitoring. The architecture consists of multi-hop sensors in smart shirt 
having Universal Serial Bus (USB) programming board as a separate module. The 
size of integrated wearable sensor nodes is reduced by mounting the device on two 
process control blocks. The smart shirt, hence, consists of a wireless sensor node, an 
ECG and accelerometer sensor board and conductive fabric electrodes for ECG 
measurement in normal shirt design. Similarly, an approach to monitor Blood 
Pressure (BP) cufflessly and continuously using health-Shirt (h-Shirt) was proposed 
in [18]. The h-Shirt is designed to record ECG and photoplethysmogram (PPG) at the 
same time and to use them to estimate BP with the PTT-based approach. ECG is 
captured from the two wrists, with reference to an electrode placed on the forearm to 
avoid noise induced by respiration. Recent development of Wearable Intelligent 
Systems for e-Health (WISEs) is reviewed in [19], including breakthrough 
technologies and technical challenges that remain to be solved.  

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2.5 Issues with the Architectural Framework of the Existing Systems 

One of the major issue of wearable sensor devices, like the ones on smart shirt, is 
that the shirt should be non-invasive in such a way that the patient can carry out 
his/her daily activities with ease. In addition, interference from the fabric of the shirt 
could also cause a challenge. 

All the architectures/frameworks presented so far are designed by integrating 
specific sensors, which can send data to a processing unit using some communication 
protocols such as Bluetooth, WLAN etc. For the most part, in their design, they are 
standalone and hence cannot fully support the interoperability functions, which are 
highly required in such systems. Some commercial solutions to integrate devices 
compliant with the HDP, such as the Bluegiga AP3201 e-Health Gateway are 
available in the market. However, the interoperability is limited to only HDP devices 
and therefore does not satisfy the requirement of integrating devices heterogeneously 
[20].  

The Internet could provide the pillars upon which solutions to such problems could 
be achieved where it is used as a medium to integrate clinical devices in a term called 
the Future Internet of Things (IoT). Internet of Things is considered as one of the 
major communication advances in recent years because it offers the basis for the 
development of independent cooperative services and applications. Assisted Living 
Environments for patients with respiratory illnesses under the AIRE project was 
presented in [20]. Monere and Movital are hardware resources, which make 
heterogeneous devices to communicate smoothly. The solution is designed to serve as 
a bridge between the sensors connected to the patient and the information systems so 
that a Ubiquitous Integration of Clinical Environments can be achieved. With respect 
to hardware, the framework offers a gateway and a personal clinical device used for 
the wireless transmission of continuous vital signs through 6LoWPAN, and patient 
identification through RFID. While in terms of software, the framework presented 
YOAPY, which is a protocol that attempts to provide an efficient, secure, and scalable 
integration of the sensors deployed in the patient’s personal environment [20]. 
However, owing to the fact that IoT consist of increasingly heterogeneous set of 
devices that exchange relevant information, interoperability remains an issue. The 
proposed architecture may face problems later when new communication protocols 
and standards are introduced to the fast growing world of information technology.  

To address the problem of interoperability, a concept of interoperability as a 
property of a single system/devise rather than in connection to other pre-committed 
systems was presented in [21]. The research subsequently attempted to assess and 
exemplify the impact that Interoperability as a Property (IaaP) paradigm on the 
healthcare information systems’ landscape. Sensors are attached or implanted into 
patient’s body, which will be used to measure physiological data from the patient’s 
body and this form what is known as Body Area Network (BAN). In the patient’s 
environment, there might be some sensors that measure environmental signals, which 
might be useful for data analysis. The body sensors and the environmental plus the 
processing unit make up what is known as Personal Area Network (PAN). All sensory 
ata are first transmitted to a local processing unit using some network/communication 

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Paper—Sensor Enhanced Health Information Systems: Issues and Challenges 

medium. The processing unit can be a PDA, smart phone or other complex sensors, 
which can be used for pre-processing before sending the data to a Health Information 
System. 

3 Challenges of Using Sensor(S) Networks for Healthcare 

The major challenges observed for using sensor(s) networks for healthcare are 
categorized into four, namely: (i) Challenges based on OSI layers/level (ii) 
Challenges based on network types (iii) Challenges based on data processing and 
interpretation (iv) Challenges Based on the Category of the Challenges. It is worth 
mentioning here that these challenges affect, mobile monitoring systems, irrespective 
of the target group (elderly, critically ill etc.) 

3.1 Challenges Based on OSI Layer/Level  

The application of sensors in healthcare has a lot of benefits. However, there are 
numerous challenges of wireless sensors when used in the healthcare. Such challenges 
can be viewed from different perspectives. Table 1 and Table 2 and are based on the 
survey presented in [23 and 24] and they present the challenges of using sensor 
networks for health care with respect to OSI layers and network types respectively. 

Table 1.  Challenges based on OSI Layers 
Level/Layer Challenge Discussion 

Hardware Level 

Unobtrusiveness Integrating many sensors to be used by one patient makes 
it even more difficult for the system/architectures to be as 
unobtrusive as possible. 

Sensitivity and 
calibration 

Sensitivity of the sensors in accurate measuring data from 
the patient body especially in different operational 
conditions; such as raining condition, exercising 
condition etc. 

Energy Energy consumption, by the sensors, is one of the major 
challenges. 

Data Acquisition 
Efficiency 

The rate at which the sensors collect data is also a 
challenge at the hardware level. 

Physical Layer 

Error resilience and 
reliability 

Quite a number of sensors are affected by Signal-to-Noise 
Ratio (SNR) hence causing higher bit error rates and 
thereby reducing the reliable coverage area. 

Interoperability The fact that many sensors might be connected together 
and each might be operating at different frequencies raise 
the problem of interoperability. 

Bandwidth The bandwidth available for data communication for 
wireless body area networks is relatively low thereby 
affecting the performance of the whole system. 

MAC Layer Some challenges are addressed at the MAC level such as the Quality of Service requirements of emergency traffic. 

Network Layer Due to the huge amount of traffic that are common in wireless sensor networks may cause data movement difficulty at the nodes closer to the base station. 

Transport Layer It is of utmost importance to have a congestion and flow control mechanisms at the transport layer. 

Application Layer Challenges at the application layer has to do with how the data is organized, analyzed in such a way that meaningful information can derived to help in 

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Paper—Sensor Enhanced Health Information Systems: Issues and Challenges 

Level/Layer Challenge Discussion 
decision making. 

Layer Independent 

Security 
As far as the OSI Layer is concerned, the challenges 
identified here are not directly related to any layer; but 
are of utmost importance to be considered when dealing 
with sensors in healthcare related systems.  

Privacy 
User-friendliness 
Ease of deployment 
and scalability 
Mobility 

3.2 Challenges Based on Network Types  

Pervasive healthcare monitoring systems dwells on five subsystems [23-34] as 
discussed in Table 2, which enumerates the  types of subsystem or network alongside 
challenges that are commonly faced by such system or networks. The table further 
discusses each type of network with respect to the design consideration. 

Table 2.  Challenges based on subsystems/network types 
Subsystem/Network Design Consideration Discussion 

Medical Body Area 
Network (MBAN) 

Power consumption 
Transmission  
Power Unobtrusiveness 
Portability  
Real-time availability 
Reliable communications 
Multi-hop routing 
Security/Localization of 
micro-robot inside the body 

As the name implies, A Medical Body 
Area Network (MBAN) is a network 
that is built around the human body. 
Usually it consists of wireless devices 
that are either (i) implanted within the 
human body or (ii) attached to the 
human body in a form of wrist-band, e-
shirt etc. All the challenges identified 
here, directly or indirectly affect the 
performance of the Wireless Body Area 
Network. 

Wireless Personal Area 
Network (WPAN) 

Energy efficiency 
Scalability 
Self-organization between 
the nodes 

A WPAN is a low range wireless 
network that consists of personal 
devices of an individual such as 
computers, cellphones, and personal 
digital assistant. It uses technology that 
can be used to exchange data over short 
distance such as Bluetooth, NFC, 
ZigBee, IrDA (Infrared Data 
Association). Scalability, self-
organization between nodes and other 
similar challenges need to be properly 
addressed in this subsystem. 

Gateway to the Wide Area 
Networks 

Security Congestion 
prevention 

Typically, a WAN gateway is a network 
device such as network switch, a 
wireless router, a wireless access point 
etc.; that allows the connection of the 
WAN with other networks. Due to the 
high level of data traffic passing 
through this point security and data 
congestion are issues that needs to be 
properly looked into at this point. 

Wide Area Networks 

Data rate, Reliable 
communication protocols, 
Secure data transmission, 
Coverage 

All the challenges mentioned here 
should be carefully addressed at this 
level. 

End-user healthcare 
monitoring application 

Privacy, Security Reliability 
User-friendliness, 

All the challenges mentioned here 
should be carefully addressed at this 

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Subsystem/Network Design Consideration Discussion 
Middleware design 
Scalability, Interoperability 
Context-awareness 

level. 

3.3 Challenges Based on Data Processing and Interpretation  

With the huge amount of data collected from wearable sensors used for 
physiological monitoring, it is difficult to expeditiously processed and interpret such 
data. Therefore, we are faced with numerous challenges, when analyzing and 
interpreting data from wearable wireless sensor networks. Data mining related 
challenges are discussed in [35-38]: 

• Need for Large scale monitoring in non-clinical context 
• Dealing with annotated data sets 
• Multiple measurements 
• Contextual information 
• Reliability, level of trust to the system 
• Discovering of unseen features 
• Post-processing and Representation 

3.4 Challenges Based on the Category of the Challenges  

Another angle from which the challenges can be viewed are discussed in the Table 
3. 

Table 3.  Challenges based on their natures  
Subsystem/Network Design Consideration Discussion 

Security related Security Privacy 

Looking at the tendency of processing 
huge amount of data, privacy and security 
is always an issue. 

Communication related 
Bandwidth 
Data acquisition 
Interoperability 

The challenges here have to do with 
communication related issues. 

User Acceptance related 
Unobtrusiveness 
Mobility 
User friendliness 

The challenges here have to do more with 
the willingness, comfort and the ease with 
which the user interact with the systems. 

Functional related 

Energy consummation, 
Interoperability 
Error Resilience, 
Reliability, Ease of 
deployment, 
Sensitivity/calibration 

The challenges here have to do with the 
actual function of the devise itself. 
Therefore, they are more related to the 
sensors themselves. 

4 Interoperability as a Property (IaaP) 

Sensor is very important, that is why is used for healthcare, Vibration sensor is 
used in fault detection of solenoid valves by the signal gathered in Labview 
SignalExpress system [39]. A sensor based framework for real-time sensing of the 

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state of equipment of post-prognostics decision has been proposed. This can help in 
understanding malfunction or failure in the system [40]. Wireless body area network 
has been utilized to proposed a model for patient that requires continues monitoring, 
through the use of the remote monitoring application [41]. Remote and continuous 
monitoring of individual’s health technique using wearable motion sensor has been 
proposed through integrating body activity and sensor location [42-44]. With the 
exponentially increasing number of devices that are connected to what is termed as 
the Internet of Things, it is extremely difficult for devices to interoperate. Currently, 
devices interoperate based on pre-agreements of the various devices to exchange 
information and to act upon this information. The major problem with these 
arrangements is that they lead to application silos with fragmented architectures, 
which will lead to potentially biased observations. For example diastolic blood 
pressure is affected by environmental temperature [21].Therefore, diastolic blood 
pressure could be wrongly observed if environmental temperature is not considered 
and this can lead to wrong decision. Hence, if many sensors are to work together 
accordingly then the following scenario should be in place. Consider a setup with 
three sensors P, Q and R. Observations by P, Q and R can be represented using OP, 
OQ and OR respectively; and messages sent by P, Q and R can be represented using 
MP, MQ and MR respectively as shown in the following diagram.  

 
Fig. 1. IaaP Concepts 

In the environment shown in Figure1, P sends a message (MP) to Q, where Q 
observes the message from P and can be represented as OQP. Similarly, R sends a 
message (MR) to Q, where Q observes the message from R and can be represented as 
OQR. At the same time, Q is making its own observation as OQ. When all these 
observations are put together as percepts then a meaningful decision can be taken else 
any decision taken without considering all the observations in may lead to wrong 
conclusions. Since, there could be many sensors in the environment, it is important 
the Q makes intelligent decision. 

4.1 Challenges Based on Data Processing and Interpretation  

In the current Wireless Sensor Network (WSN) setting, for two or more 
devices/components to communicate they must agree on the standard and format to 

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Paper—Sensor Enhanced Health Information Systems: Issues and Challenges 

interoperate. With the increasing number of devise that are connected to the network 
in what is termed as IoT, devices should be able to identify and communicate with 
devices on the network without any prior agreements. This can be achieved if each 
“thing” on the network exhibits certain attributes/factors.  

The enabling factors for IaaP are [21]: (i) Awareness: has two aspects: self-
awareness and environmental awareness. As the name implies, self-awareness is the 
ability of the system to be aware of events within itself such as available energy 
levels. On the other hand, environmental awareness is related to the capability of the 
system to sense events from its environment. (ii) Perceptivity: is the capability of the 
system to assign a meaning to an observation. (iii) Intelligence: encompasses 
assertion, storing and acquisition of the behavior patterns in order to take intelligent 
decisions for actions to be taken. (iv) Extroversion: is related to the willingness and 
capability of the system to articulate its actions. 

4.2 Challenges Based on Data Processing and Interpretation  

Due to technical reasons, power related issues, and mobility, systems/subsystems 
could be disconnected and reconnected to a network. Hence, in addition to the above 
four enabling factors identified in [21], two more factors should be considered. These 
factors are: (i) Track and (ii) Trace. 

Track: Locate where objects are; it is important to locate where objects are in 
order to make intelligent decisions. 

Trace: Ability, of the “thing”, to log its sensor measurements so that when it is 
outside a network all readings can be log. The moment it gets reconnected to a 
network all the readings (in the history that was logged) can be downloaded or and 
communicated to other “things” if needed. 

Refined Setup: Sensors in IaaP enabled environment can be classified into two: (i) 
Master sensor (ii) Auxiliary (supporting or primary) sensor. The function of each type 
of sensor is shown in Figure 2. 

 
Fig. 2. Sensor classification based on IaaP Concepts 

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While the auxiliary sensor is designed to be used in measuring basic sensory data 
(such as temperature, pressure etc.) the master sensor is designed to have some 
processing capability. In addition to sensing and transmitting data, the Master sensor 
should have the capability of collecting and managing percepts in order to make sense 
out of the numerous observations received from auxiliary sensors; and subsequently 
making intelligent decision. Therefore, an IaaP enabled environment can be 
represented using the diagram shown in Figure 3. 

 
Fig. 3. Representation of IaaP enabled environment 

As indicated in the diagram above, the auxiliary sensors measure individual senor 
data and transmit it to the master sensor, which has the capability of managing 
percepts in order to make sense out of all the collected observations. Based on all the 
operations, MS makes an intelligent decision on what to do (for example call the 
medical doctor) and sends it directly to the health professional (such as the medical 
doctor), control center or to a broadcasting device which will in turn broadcast it to 
multiple recipients which include loved ones, health professionals, ambulance 
department etc. 

5 Conclusion 

A survey of the different approaches for proposing patient monitoring system was 
presented. There are three major components required in building Sensor Enhanced 
HIS. Previous studies have identified them to be: (i) Network technologies (ii) Sensor 
& actuators and (iii) Processing Unit. Numerous challenges are faced when 
developing such systems. Such challenges affect the performance, integrity and 
acceptability of Sensor-Enhanced HIS. The challenges affecting the integration of 
sensors in Health Information System (HIS) are categorized. Interoperability as a 
Property (IaaP) paradigm has been found to be a promising approach that could 
unravel the problems of interoperability among interacting systems, subsystems or 
devises. IaaP is a promising approach that will go a long way to solve quite a number 
of the problems faced by elderly, critically ill or young children who depend on others 
for their daily need. Thus, thorough studies are required on refining the enabling 

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Paper—Sensor Enhanced Health Information Systems: Issues and Challenges 

factors as well as intensive implementation of prototype to further revamp the new 
paradigm. 

6 Acknowledgement 

This paper was supported by a Research Initiative Grant Scheme (No. RIGS16-
364-0528) from the International Islamic University of Malaysia (IIUM). 

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8 Authors 

Abubakar Adam is a PhD student in the Department of Computer Science at the 
International Islamic University of Malaysia.  His research interests include software 
matrix, Internet of things and sensor networks. 

Murni Mahmud is an Associate Professor with the Department of Information 
System at the International Islamic University of Malaysia. Her current research 
interest is in the area of Human Computer Interaction. 

Adamu Abubakar is an Assistant Professor with the Department of Computer 
Science at the International Islamic University of Malaysia. His current research 
interests include machine learning and computer networking. 

Article submitted 24 April 2017. Resubmitted 23 September 2017 and 23 August 2018. Final 
acceptance 14 December 2018. Final version published as submitted by the authors. 

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