Abstract:
Communication technologies evolve drastically in recent years. These recent developments
in communication technologies inevitably lead to increasing demand for communication
technologies. They also lead to allocating progressively communication
channels between transmitting and receiving elements. However, the scarcity of spectrum
began to appear with the accelerating rise in the usage of various communication
technologies and the preservation of traditional channel access methods. That is what
is called the spectrum under-utilization and frequencies crisis.
Cognitive Radio (CR) is an innovative solution developed to avoid these obstacles
mentioned above. It deals with the surrounding environment and determines the appropriate
communication parameters. The CR life cycle goes through many tasks.
Spectrum sensing is a key task in this cycle that gains significance where the spectrum
holes can be detected during this task. Spectrum sensing task is needed in
both non-cooperative spectrum sensing (Non-CSS) or cooperative spectrum sensing
(CSS) modes, whereby the secondary users (SUs) cooperate to determine channel
state. The deployment of machine learning-based spectrum sensing techniques in CR
networks has been attracting researchers in recent years. The idea is to provide the
network with some intelligence to enhance the spectrum sensing process and thus
the possibility of accurately detecting PU activity. Examples of these techniques are
the energy detection-based, the covariance matrix-based, and Machine learningbased
techniques.
In this thesis, firstly we study and compare the performance of the Non-CSS, the
And-based, the Or-based techniques, as well as the KMeans-based ML technique
in stationary CRNs. In contrast to the majority of published research, we examine
the performance of that mentioned spectrum sensing techniques in mobile CRNs.
Also, we try to grasp the effect of the fading channels on the sensing performance.
Moreover, we try to find the optimal parameters that can improve the performance
of various spectrum sensing techniques. Finally, we investigate the circumstances in
iii
which KMeans-based spectrum sensing techniques introduce superior to traditional
techniques.
Stationary and mobile CRNs were simulating using the third version of the network
simulator (ns3 simulation). The result showed the effect of the communication
channel on the spectrum sensing performance. Difficult conditions such as noise and
fading effects on the transmitted signals lead to a notable decrease in sensing performance.
Also, the results generally revealed that spectrum sensing techniques provide
better performance in stationary networks. However, the results showed we need
above three SUs and about 1500 samples to reach an acceptable performance level
in mobile CRN. In addition, the results showed that the KMeans-based technique
slightly outperforms the Or-based technique, especially in highly-noisy environments
and under severe fading channels.
Description:
CD, no of pages 82 , 31103 , informatics 4/2021 , in the store