397 research outputs found
Spectrum Sensing Techniques for Cognitive Radio Sensor Networks (CRSN)
Cognitive radio sensor network (CRSN) is a recently emerging paradigm that aims to utilize the unique features provided by CR concept to incorporate additional capabilities to Wireless Sensor Network (WSN). A CRSN is a distributed network of wireless cognitive radio sensor nodes, which perform sensing operation on event signals and collaboratively communicate their readings over dynamically available spectrum bands in a multi-hop manner ultimately to satisfy the application-specific requirements. The realization of CRSN depends on addressing many difficult challenges, posed by the unique characteristics of both cognitive radio and sensor networks, and further amplified by their union. Spectrum sensing technique plays an important role in the design of a CRSN. The first phase of this thesis work is concentrated in identifying the suitable spectrum sensing strategy for a CRSN by analysing different spectrum sensing strategies and comparing together. The second phase involves a search for an optimum spectrum sensing scheme suitable for the resource constrained nature of CRSN by combining two or more sensing schemes together i.e. Hybrid Spectrum Sensing. The thesis concludes with a remark that hybrid spectrum sensing schemes are the most appropriate sensing schemes for CRSN under its unique constraints
A Real Time Radio Spectrum Scanning Technique Based On The Bayesian Model And Its Comparison With The Frequentist Technique
The proliferation of mobile devices led to an exponential demand for wireless radio spectrum resources. The current fixed spectrum assignment has caused some portions of the radio spectrum to be heavily used whereas others to be scarcely used. This has resulted in underutilization of spectrum resources, and, hence has demanded the need for solutions to address the spectrum scarcity problem. Cognitive radio was proposed as one of the solutions. One of the techniques involved in cognitive radio is the dynamic spectrum access technique. This technique requires the identification of free channels in order to allow secondary users to exploit the spectrum resources. The process of identification of free channels is known as radio spectrum scanning, which is performed by sensing a particular channel in the radio spectrum to determine the presence or absence of a signal. In most of existing studies, the frequentist technique using energy detection with fixed threshold was used to scan the radio spectrum. However, this method comes with a major drawbacks. First, energy detection is unable to distinguish between signals and noise and suffer for high false detection rates. Second, energy detection has high false alarm probability. Finally, frequentist techniques are subject to uncertainty and do not provide real time monitoring/sensing. Therefore, the goal of this thesis is to develop a more efficient scanning technique that deals with uncertainty and scans the radio spectrum in real time and determines its occupancy levels.
An enhanced spectrum scanning approach is developed using an efficient spectrum sensing technique: an uncertainty handling Bayesian model along with a Bayesian inferential approach. Two Bayesian models are developed: 1) a simplified model, and 2)
an improved model to incorporate the Bayesian inferential approach to estimate the
spectrum occupancy level.
The performance evaluation of the proposed technique has been done using simulations as well as real experiments. For this purpose, two metrics were used:
probability of detection and probability of false alarm. Furthermore, the efficiency of the
proposed technique was compared to the efficiency of the frequentist technique, which uses only a spectrum sensing technique to identify the occupancy of the spectrum channels. As expected significant improvements in the spectrum occupancy measurements have been observed with the proposed Bayesian inference method
Spectrum Awareness in Cognitive Radio Systems
The paper addresses the issue of the Electromagnetic Environment Situational Awareness techniques. The main focus is put on sensing and the Radio Environment Map. These two dynamic techniques are described in detail. The Radio Environment Map is considered the essential part of the spectrum management system. It is described how the density and deployment of sensors affect the quality of maps and it is analysed which methods are the most suitable for map construction. Additionally, the paper characterizes several sensing methods
Enhanced Spectrum Sensing for Cognitive Cellular Systems
This dissertation aims at improving spectrum sensing algorithms in order to effectively apply
them to cellular systems. In wireless communications, cellular systems occupy a significant
part of the spectrum. The spectrum usage for cellular systems are rapidly expanding due to the
increasing demand for wireless services in our society. This results in radio frequency spectrum
scarcity. Cellular systems can effectively handle this issue through cognitive mechanisms for
spectrum utilization. Spectrum sensing plays the first stage of cognitive cycles for the adaptation
to radio environments.
This dissertation focuses on maximizing the reliability of spectrum sensing to satisfy
regulation requirements with respect to high spectrum sensing performance and an acceptable
error rate. To overcome these challenges, characteristics of noise and manmade signals are
exploited for spectrum sensing. Moreover, this dissertation considers system constraints, the
compatibility with the current and the trends of future generations. Newly proposed and existing
algorithms were evaluated in simulations in the context of cellular systems. Based on a prototype
of cognitive cellular systems (CCSs), the proposed algorithms were assessed in realistic scenarios.
These algorithms can be applied to CCSs for the awareness of desired signals in licensed and
unlicensed bands.
For orthogonal frequency-division multiplexing (OFDM) signals, this dissertation exploits
the characteristics of pilot patterns and preambles for new algorithms. The new algorithms
outperform the existing ones, which also utilize pilot patterns. Additionally, the new algorithms
can work with short observation durations, which is not possible with the existing algorithms. The
Digital Video Broadcasting - Terrestrial (DVB-T) standard is taken as an example application for
the algorithms. The algorithms can also be developed for filter bank multicarrier (FBMC) signals,
which are a potential candidate for multiplexing techniques in the next cellular generations. The
experimental results give insights for the reliability of the algorithms, taking system constraints
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into account. Another new sensing algorithm, based on a preamble, is proposed for the DVBT2
standard, which is the second generation of of DVB system. DVB-T2 systems have been
deployed in worldwide regions. This algorithm can detect DVB-T2 signals in a very short
observation interval, which is helpful for the in-band sensing mode, to protect primary users (in
nearly real-time) from the secondary transmission.
An enhanced spectrum sensing algorithm based on cyclostationary signatures is proposed
to detect desired signals in very low signal-to-noise ratios (SNRs). This algorithm can be
developed to detect the single-carrier frequency division multiple access (SC-FDMA) signal,
which is adopted for the uplink of long-term evolution (LTE) systems. This detector substantially
outperforms the existing detection algorithms with the marginal complexity of some scalar
multiplications. The test statistics are explicitly formulated in mathematical formulas, which
were not presented in the previous work. The formulas and simulation results provide a useful
strategy for cyclostationarity-based detection with different modulation types.
For multiband spectrum sensing, an effective scheme is proposed not only to detect but
also to classify LTE signals in multiple channels in a wide frequency range. To the best of our
knowledge, no scheme had previously been described to perform the sensing tasks. The scheme is
reliable and flexible for implementation, and there is almost no performance degradation caused
by the scheme compared to single-channel spectrum sensing. The multiband sensing scheme was experimentally assessed in scenarios where the existing infrastructures are interrupted to
provide mobile communications.
The proposed algorithms and scheme facilitate cognitive capabilities to be applied to real
cellular communications. This enables the significantly improved spectrum utilization of CCSs
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Cognitive MAC protocols for mobile Ad-Hoc networks
This thesis was submitted for the degree of Doctor of Philosophy and awarded by Brunel University.The term of Cognitive Radio (CR) used to indicate that spectrum radio could be accessed dynamically and opportunistically by unlicensed users. In CR Networks, Interference between nodes, hidden terminal problem, and spectrum sensing errors are big issues to be widely discussed in the research field nowadays. To improve the performance of such kind of networks, this thesis proposes Cognitive Medium Access Control (MAC) protocols for Mobile Ad-Hoc Networks (MANETs). From the concept of CR, this thesis has been able to develop a cognitive MAC framework in which a cognitive process consisting of cognitive elements is considered, which can make efficient decisions to optimise the CR network. In this context, three different scenarios to maximize the secondary user's throughput have been proposed. We found that the throughput improvement depends on the transition probabilities. However, considering the past information state of the spectrum can dramatically increases the secondary user's throughput by up to 40%. Moreover, by increasing the number of channels, the throughput of the network can be improved about 25%. Furthermore, to study the impact of Physical (PHY) Layer errors on cognitive MAC layer in MANETs, in this thesis, a Sensing Error-Aware MAC protocols for MANETs has been proposed. The developed model has been able to improve the MAC layer performance under the challenge of sensing errors. In this context, the proposed model examined two sensing error probabilities: the false alarm probability and the missed detection probability. The simulation results have shown that both probabilities could be adapted to maintain the false alarm probability at certain values to achieve good results. Finally, in this thesis, a cooperative sensing scheme with interference mitigation for Cognitive Wireless Mesh Networks (CogMesh) has been proposed. Moreover, a prioritybased traffic scenario to analyze the problem of packet delay and a novel technique for dynamic channel allocation in CogMesh is presented. Considering each channel in the system as a sub-server, the average delay of the users' packets is reduced and the cooperative sensing scenario dramatically increases the network throughput 50% more as the number of arrival rate is increased
Spectrum Sensing in Cognitive Radio
In modern wireless communications the spectrum is allocated to fixed licensed users and on the other side the number of wireless devices are increasing rapidly, that has lead to spectrum crunch. As the spectrum is precious it has to be utilized efficiently. The solution to mitigate this problem is “Spectrum Sharing”. One of the innovative approach to recognize and access the spectrum holes present in the licensed spectrum is ‘Cognitive Radio (CR)’. Spectrum sensing is a base for the performance of all functions performed by the Cognitive Radio (CR). Cognitive radio recognizes the unused spectrum and shares it to secondary users (SU’s) without creating harmful interference to primary users (E.g. Cellular Networks, TV). Literature discusses various SS techniques like ED, CSD, CMME with their advantages and disadvantages. ED is most preferred in CR because of simple implementation and semi-blind nature. But its performance is very poor at low SNR bound. So other combined techniques are preferred over the ED to enhance sensitivity of CR. So, thesis proposes Two Stage Spectrum Sensing as preferred in IEEE 802.22 standard. Combination of both ED and CMME method to enhance accuracy and timing of sensing in coarse and fine sensing stage respectively, is proposed and compared with individual sensing techniques. As the type of sensing takes place in two-level, the weak primary signals present in the spectrum are easily detected. If the signal is not identified in the first stage, it will be sensed in the second stage even if it is not detected, it can be declared as the absence of PU in the spectrum. In this thesis, the performance of Single user and Global decision using Modified Deflection Coefficient (MDC) method is observed. Extensive study of cooperative SS and optimal cooperative sensing is done and results are presente
Fast and reliable detection of incumbent users in cognitive radios
Fast and reliable Spectrum Sensing (SS) plays a crucial role in the cognitive radio (CR) technology in order to prevent unwanted interference to the primary users (PU) and to reliably and quickly detect the white spaces in the spectrum for opportunistic access by the secondary users (SU). Spectrum Sensing must often be performed in the absence of information such as PU signaling scheme, noise level and channel fading coefficients. While these parameters can be estimated in the SU, estimation errors significantly deteriorates the performance of SS techniques. In this thesis, we introduce and evaluate the performance of two novel blind spectrum sensing algorithms which do not rely on knowledge of these parameters. The first is a SS technique for signaling schemes which introduce controlled intersymbol interference in the transmitter. The second is for cases when the receiver of the SU is equipped with a multiantenna system. This approach exploits the path correlation among the signals received at different antennas. Next we analyze the performance of Spectrum Monitoring (SM), an new technique which allows the SU to detect the presence of the PU using its own receiver statistics. In contrast to SS, with SM, the SU does not need to interrupt its own transmission in order to detect the presence of the PU. We carefully construct the decision statistics for SM and evaluate its performance. The performance of a hybrid SM/SS system shows a significant improvement over SS alone
Machine learning algorithms for cognitive radio wireless networks
In this thesis new methods are presented for achieving spectrum sensing in cognitive radio wireless networks. In particular, supervised, semi-supervised and unsupervised machine learning based spectrum sensing algorithms are developed and various techniques to improve their performance are described.
Spectrum sensing problem in multi-antenna cognitive radio networks is considered and a novel eigenvalue based feature is proposed which has the capability to enhance the performance of support vector machines algorithms for signal classification. Furthermore, spectrum sensing under multiple primary users condition is studied and a new re-formulation of the sensing task as a multiple class signal detection problem where each class embeds one or more states is presented. Moreover, the error correcting output codes based multi-class support vector machines algorithms is proposed and investigated for solving the multiple class signal detection problem using two different coding strategies.
In addition, the performance of parametric classifiers for spectrum sensing under slow fading channel is studied. To address the attendant performance degradation problem, a Kalman filter based channel estimation technique is proposed for tracking the temporally correlated slow fading channel and updating the decision boundary of the classifiers in real time. Simulation studies are included to assess the performance of the proposed schemes.
Finally, techniques for improving the quality of the learning features and improving the detection accuracy of sensing algorithms are studied and a novel beamforming based pre-processing technique is presented for feature realization in multi-antenna cognitive radio systems. Furthermore, using the beamformer derived features, new algorithms are developed for multiple hypothesis testing facilitating joint spatio-temporal spectrum sensing. The key performance metrics of the classifiers are evaluated to demonstrate the superiority of the proposed methods in comparison with previously proposed alternatives
Wideband Spectrum Sensing for Dynamic Spectrum Sharing
The proliferation of wireless devices grows exponentially, demanding more and more data
communication capacity over wireless links. Radio spectrum is a scarce resource, and traditional
wireless networks deployed by Mobile Network Operators (MNO) are based on an exclusive
spectrum band allocation. However, underutilization of some licensed bands in time and geographic
domains has been reported, especially in rural areas or areas away from high population density
zones. This coexistence of increasingly high data communication needs and spectrum
underutilization is an incomprehensible scenario. A more rational and efficient use of the spectrum
is the possibility of Licensed Users (known as Primary Users – PU) to lease the spectrum, when
not in use, to Unlicensed Users (known as Secondary Users – SU), or allowing the SU to
opportunistically use the spectrum after sensing and verifying that the PU is idle. In this latter
case, the SU must stop transmitting when the PU becomes active.
This thesis addresses the spectrum sensing task, which is essential to provide dynamic spectrum
sharing between PUs and SUs. We show that the Spectral Correlation Function (SCF) and the
Spectral Coherence Function (SCoF) can provide a robust signal detection algorithm by exploiting
the cyclostationary characteristics of the data communication signal. We enhance the most used
algorithm to compute de SCF - the FAM (FFT Accumulation Method) algorithm – to efficiently
compute the SCF in a local/zoomed region of the support ( ; ) plane (frequency/cycle frequency
plane). This will provide the quick identification of spectral bands in use by PUs or free, in a
wideband sampling scenario.
Further, the characterization of the probability density of the estimates of the SCF and SCoF
when only noise is present, using the FAM algorithm, will allow the definition of an adaptive
threshold to develop a blind (with respect to the noise statistics) Constant False Alarm Rate
(CFAR) detector (using the SCoF) and also a CFAR and a Constant Detection Rate (CDR)
detector when that characterization is used to obtain an estimate of the background noise variance
(using the SCF).A proliferação de dispositivos sem fios cresce de forma exponencial, exigindo cada vez mais
capacidade de comunicação de dados através de ligações sem fios. O espectro radioelétrico é um
recurso escasso, e as redes sem fios tradicionais implantadas pelos Operadores de Redes Móveis
baseiam-se numa atribuição exclusiva de bandas do espectro. No entanto, tem sido relatada a
subutilização de algumas bandas licenciadas quer ao longo do tempo, quer na sua localização
geográfica, especialmente em áreas rurais, e em áreas longe de zonas de elevada densidade
populacional. A coexistência da necessidade cada vez maior de comunicação de dados, e a
subutilização do espectro é um cenário incompreensível. Uma utilização mais racional e eficiente
do espectro pressupõe a possibilidade dos Utilizadores Licenciados (conhecidos como Utilizadores
Primários – Primary Users - PU) alugarem o espectro, quando este não está a ser utilizado, a
Utilizadores Não Licenciados (conhecidos como Utilizadores Secundários – Secondary Users - SU),
ou permitir ao SU utilizar oportunisticamente o espectro após a deteção e verificação de que o PU
está inativo. Neste último caso, o SU deverá parar de transmitir quando o PU ficar ativo.
Nesta tese é abordada a tarefa de deteção espectral, que é essencial para proporcionar a partilha
dinâmica do espectro entre PUs e SUs. Mostra-se que a Função de Correlação Espectral (Spectral
Correlation Function - SCF) e a Função de Coerência Espectral (Spectral Coherence Function -
SCoF) permitem o desenvolvimento de um algoritmo robusto de deteção de sinal, explorando as
características ciclo-estacionárias dos sinais de comunicação de dados. Propõe-se uma melhoria ao
algoritmo mais utilizado para cálculo da SCF – o método FAM (FFT Accumulation Method) -
para permitir o cálculo mais eficiente da SCF numa região local/ampliada do plano de suporte
/ (plano de frequência/frequência de ciclo). Esta melhoria permite a identificação rápida de
bandas espectrais em uso por PUs ou livres, num cenário de amostragem de banda larga.
Adicionalmente, é feita a caracterização da densidade de probabilidade das estimativas da SCF e
SCoF quando apenas o ruído está presente, o que permite a definição de um limiar adaptativo,
para desenvolver um detetor de Taxa de Falso Alarme Constante (Constant False Alarm Rate –
CFAR) sem conhecimento do ruído de fundo (usando a SCoF) e também um detetor CFAR e Taxa
de Deteção Constante (Constant Detection Rate – CDR), quando se utiliza aquela caracterização
para obter uma estimativa da variância do ruído de fundo (usando a SCF)
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