dc.description.abstract |
Wireless Body Area Networks (WBANs) open many challenges by placing biosensors
on/inside human bodies for collecting various health-related information. Communication
in WBANs suffers from high channel attenuation due to human body fat and the low
transmission power used by the biosensors present on the body. The low power signals
transmitted by the biosensors towards the coordinator node (placed outside the human
body), experience high attenuation during the non-line-of-sight (NLOS) communications.
The NLOS communications are possible in WBANs when the patient’s body impedes the
signals transmitted by a biosensor towards the coordinator node. The reception of poor
signals at the coordinator node could further deteriorate the quality-of-service (QoS) provided
by a WBAN. Therefore, relay-based communications with data forwarding techniques
are used to handle link failures and poor network connectivity. Relay-based communication
in a WBAN helps in enhancing the lifetime of the network and improves the
quality of the signal delivered at the coordinator. However, the existing works related to
relay-based communications did not consider the different human postures. This thesis
considers three human postures— sitting, sleeping, and walking/ running. Every posture
has different mobility patterns and pace of motion due to which, the duration of NLOS
communication could vary for different human postures.
In the first work, a remote patient monitoring (RPM) application of WBANs is considered
where a patient is sitting on the chair in his residential room. This work analyzes
the signal received from RPM sensors when a patient rotates by different angles while
sitting on a chair as well as heed the use of a relay node placed on his/her body. Literature
suggests many relay-based communication protocols to deliver physio-signals efficiently in an RPM application. However, limited studies have focused on the position of a relay
node on the human body. This work empirically analyzes the off-body communication
path of sensor nodes by collecting data from different body orientations in a residential
room. The collected data is used for estimating the path loss parameters for underweight,
normal and overweight body mass index (BMI) categories. The estimated parameters are
then used to simulate the physical layer of a home-based indoor RPM application. Further,
this work inspects different relay node positions on the human body and allude an
optimal position of the relay node that cover the transmission range of all sensors and
provides an improved channel quality. Finally, an adaptive cross-layer communication
protocol is designed for WBANs using the proposed relay node position and improve the
Quality of Service (QoS) during non-line-of-sight (NLOS) situation.
Sometimes, the special relay node (node installed in a WBAN for supporting relaying
only) kept for a sitting position may fail to support the communication during the human
sleeping positions. This is possible when the person sleeps on the same side where the
relay node is placed on the body. The NLOS situation lasts for a longer duration during
human sleeping postures. In such circumstances, an intermediate biosensor forwards the
signal of the occluded biosensor node. The forwarding of messages results in quick depletion
of energy resources at the intermediate biosensor which affects the overall WBAN
services. To resolve this, first, an adaptive Relay-Node Centric (RNC) relay-based communication
protocol for WBANs is proposed, which reduces energy used in relaying and
improves the stability period of the network. Second, a novel simulation model is designed
using an existing real-life experimental dataset to simulate a WBAN placed on
the sleeping patient’s body. This work derive a Discrete Time Markov Chain (DTMC)
model from real-life data and use human biomechanisms to simulate biosensors’ connectivity
status in four human sleeping positions namely, supine, prone, lying on the left side,
and lying on the right side. Lastly, performance of RNC is evaluated against the existing
cost-function-based and Analytical Hierarchical Process (AHP) based relay selection protocols.
Results show that RNC outperforms the existing methods, primarily when nodes
are distributed across all body parts. The mobility of nodes in a WBAN is periodic and highly dynamic during the human
walking/running scenarios. Existing related work on WBAN used the characteristics,
such as periodical movement of WBAN nodes and improves the Quality of Service (QoS)
at the coordinator. For example, a biosensor present on the human wrist moves in a back
and forth motion while walking. The sensor communicating with the coordinator, present
on the chest of the person experiences best communication channel condition when the
arm is in the front side of the body. The WBANs exploit opportunistic communication
and perform delivery of the signal at best channel conditions. However, the nodes present
on the human torso (i.e., front or back side of the person) are static with respect to the coordinator
node and hence, cannot use the advantages of the opportunistic communication.
Therefore, in this work, an existing real-life health datasets on human heart rate, diabetes,
and body temperature are analyzed to find the reduced sampling frequencies for the static
nodes present in a mobile WBAN. Next, a direct communication algorithm is proposed
that combines the use of the reduced sampling frequencies and the opportunistic communication
for a human walking scenario in WBANs. The results show that the algorithm
improves the lifetime and the quality of signal delivered in a WBAN.
Additionally, this thesis proposes an adaptive sampling for enhancing the lifetime of
the smart wearable devices used for monitoring health in day-to-day life. Smartwatches
are used widely by people for recording the running performance. All watches sense heart
rate continuously during running for maintaining the record of varying heart rate with the
change in running speed. The continuous monitoring of heart rate consumes energy of
the device. Therefore, existing literature related to this area proposed different methods
for reducing the sampling rate of the heart rate sensor during less active events like sitting
or sleeping. However, no efforts have been made for adjusting the sampling rate of the
heart rate sensor for high acceleration events like running. In such cases, the energy consumption
rate of the wearable device increases for long running events. Therefore, in this
work, existing real-life human heart rate datasets are used for finding the trends in varying
heart rate with the change in the running speed of the person. The observations made are
then used for designing an adaptive sampling algorithm for the heart rate sensor present in heart rate monitoring devices. The results show nearly 50% reduction in the sensed data
and hence, improves the lifetime of the device. On the other hand, the adaptive sampling
of the heart rate may induce information gaps in the sensed data. Therefore, this work
also designs a data regeneration system for regenerating the missing information. The
results show that the proposed data regeneration system provides atleast 90% accuracy in the regenerated information. |
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