8 research outputs found
A New Protocol for Cooperative Spectrum Sharing in Mobile Cognitive Radio Networks
To optimize the usage of limited spectrum resources, cognitive radio (CR) can be used as a viable solution. The main contribution of this article is to propose a new protocol to increase throughput of mobile cooperative CR networks (CRNs). The key challenge in a CRN is how the nodes cooperate to access the channel in order to maximize the CRN's throughput. To minimize unnecessary blocking of CR transmission, we propose a so-called new frequency-range MAC protocol (NFRMAC). The proposed method is in fact a novel channel assignment mechanism that exploits the dependence between signal's attenuation model, signal's frequency, communication range, and interference level. Compared .to the conventional methods, the proposed algorithm considers a more realistic model for the mobility pattern of CR nodes and also adaptively selects the maximal transmission range of each node over which reliable transmission is possible. Simulation results indicate that using NFRMAC leads to an increase of the total CRN's throughput by 6% and reduces the blocking rate by 10% compared to those of conventional methods
CR-MAC: A multichannel MAC protocol for cognitive radio ad hoc networks
This paper proposes a cross-layer based cognitive radio multichannel medium
access control (MAC) protocol with TDMA, which integrate the spectrum sensing
at physical (PHY) layer and the packet scheduling at MAC layer, for the ad hoc
wireless networks. The IEEE 802.11 standard allows for the use of multiple
channels available at the PHY layer, but its MAC protocol is designed only for
a single channel. A single channel MAC protocol does not work well in a
multichannel environment, because of the multichannel hidden terminal problem.
Our proposed protocol enables secondary users (SUs) to utilize multiple
channels by switching channels dynamically, thus increasing network throughput.
In our proposed protocol, each SU is equipped with only one spectrum agile
transceiver, but solves the multichannel hidden terminal problem using temporal
synchronization. The proposed cognitive radio MAC (CR-MAC) protocol allows SUs
to identify and use the unused frequency spectrum in a way that constrains the
level of interference to the primary users (PUs). Our scheme improves network
throughput significantly, especially when the network is highly congested. The
simulation results show that our proposed CR-MAC protocol successfully exploits
multiple channels and significantly improves network performance by using the
licensed spectrum band opportunistically and protects PUs from interference,
even in hidden terminal situations.Comment: 14 Pages, International Journa
An Energy Efficient Multichannel MAC Protocol for Cognitive Radio Ad Hoc Networks
This paper presents a TDMA based energy efficient cognitive radio
multichannel medium access control (MAC) protocol called ECR-MAC for wireless
Ad Hoc Networks. ECR-MAC requires only a single half-duplex radio transceiver
on each node that integrates the spectrum sensing at physical (PHY) layer and
the packet scheduling at MAC layer. In addition to explicit frequency
negotiation which is adopted by conventional multichannel MAC protocols,
ECR-MAC introduces lightweight explicit time negotiation. This two-dimensional
negotiation enables ECR-MAC to exploit the advantage of both multiple channels
and TDMA, and achieve aggressive power savings by allowing nodes that are not
involved in communication to go into doze mode. The IEEE 802.11 standard allows
for the use of multiple channels available at the PHY layer, but its MAC
protocol is designed only for a single channel. A single channel MAC protocol
does not work well in a multichannel environment, because of the multichannel
hidden terminal problem. The proposed energy efficient ECR-MAC protocol allows
SUs to identify and use the unused frequency spectrum in a way that constrains
the level of interference to the primary users (PUs). Extensive simulation
results show that our proposed ECR-MAC protocol successfully exploits multiple
channels and significantly improves network performance by using the licensed
spectrum band opportunistically and protects QoS provisioning over cognitive
radio ad hoc networks.Comment: 8 Pages, International Journa
An Energy Efficient MAC Protocol for QoS Provisioning in Cognitive Radio Ad Hoc Networks
The explosive growth in the use of real-time applications on mobile devices has resulted in new challenges to the design of medium access control (MAC) protocols for ad hoc networks. In this paper, we propose an energy efficient cognitive radio (CR) MAC protocol for QoS provisioning called ECRQ-MAC, which integrate the spectrum sensing at physical (PHY) layer and the channel-timeslots allocation at MAC layer. We consider the problem of providing QoS guarantee to CR users as well as to maintain the most efficient use of scarce bandwidth resources. The ECRQ-MAC protocol exploits the advantage of both multiple channels and TDMA, and achieves aggressive power savings by allowing CR users that are not involved in communication to go into sleep mode. The proposed ECRQ-MAC protocol allows CR users to identify and use the unused frequency spectrum of licensed band in a way that constrains the level of interference to the primary users (PUs). Our scheme improves network throughput significantly, especially when the network is highly congested. The simulation results show that our proposed protocol successfully exploits multiple channels and significantly improves network performance by using the licensed spectrum opportunistically and protects QoS provisioning over cognitive radio ad hoc networks
Cognitive Radio Systems
Cognitive radio is a hot research area for future wireless communications in the recent years. In order to increase the spectrum utilization, cognitive radio makes it possible for unlicensed users to access the spectrum unoccupied by licensed users. Cognitive radio let the equipments more intelligent to communicate with each other in a spectrum-aware manner and provide a new approach for the co-existence of multiple wireless systems. The goal of this book is to provide highlights of the current research topics in the field of cognitive radio systems. The book consists of 17 chapters, addressing various problems in cognitive radio systems
Modeling and Analysis of Cognitive Radio Ad Hoc Networks
Eine Welt ohne drahtlose Ad-Hoc Netzwerke ist heute kaum noch
vorstellbar.Auf Grund der geringen Kosten und des minimalen
Installationsaufwands werden gegenwärtig immer mehr Geräte in immer mehr
Anwendungsfeldern eingesetzt. Da die meisten dieser Netzwerke im
lizenzfreien ISM-Band operieren, ist dieses heute stark ausgelastet und
weist kaum noch freie Kapazitäten auf. Aktuelle Studien der Federal
Communication Commission (FCC) belegen allerdings, dass groĂźe Teile (bis zu
70%) der lizenzbehafteten Frequenzen ungenutzt sind. Dieser Umstand zeigt,
dass das Problem weniger die generelle Knappheit an freien Frequenzen ist,
sondern vielmehr in der ineffizienten Verteilung bzw.Nutzung der
verfĂĽgbaren Resourcen zu suchen ist. Das Hauptaugenmerk der vorliegenden
Dissertation liegt in der Verbesserung der Spektrumsauslastung, um dadurch
die weitere Entwicklung von drahtlosen Ad-Hoc Netzwerken zu ermöglichen.In
dieser Arbeit wird ein neues Spektrum-Management-Konzept mit dem
Namen Opportunistic Spectrum Access with Backup channel (OSAB) entwickelt und
vorgestellt. Das hierbei zugrunde liegende Konzept gestattet Secondary
Users (SUs)dynamisch und flexibel auf Frequenzen unlizenzierter als auch
lizensierterFrequenzbänder zu zugreifen, wenn diese vom Primary User (PU)
gerade nicht genutzt werden - es also keine Interferenzen geben kann.Da der
Zugriff auf das Frequenzspektrum heute existierender Systeme noch sehr
unflexibel ist, soll dieser in Zukunft durch Cognitive Radios (CR)weit
flexibler und dynamischer gestaltet werden können. Bei der Entstehung von
OSAB wurden speziell die unterschiedlichen Eigenschaften verschiedener
Frequenzbänder berücksichtigt.Der Hauptvorteil von lizenzbehafteten Bändern
ist, dass diese in hoher Anzahl verfĂĽgbar sind. Der Hauptvorteil von
lizenzfreien Frequenzen ergibt sich hingegen aus der Gleichstellung aller
Nutzer. Sobald ein SU einmal einen Kanal belegt hat, kann er nicht mehr aus
selbigem verdrängt werden.Kommuniziert OSAB in lizenzierten Bändern, so
wird stets ein Backup Channel (BC)vorgehalten um auf das plötzliche
Auftreten des PUs reagieren zu können.Das vorgeschlagene Konzept wurde in
dieser Arbeit auĂźerdem einer intensiven Analyse mittel Markov-Ketten
unterzogen. Die dabei erzielten Ergebnisse zeigen,dass OSAB den
Paketverlust und die erwartete Anzahl an Spektrum-Hand-Offs um 60% bzw. 17%
reduzieren kann.Um den Nutzen und die Vorteile von OSAB praktisch unter
Beweis zu stellen, wurde in der vorliegenden Arbeit weiterhin das
MAC-Protokoll SWITCH (opportunisticSpectrum access WITh backup CHannel)
entwickelt.SWITCH ist ein dezentrales, asynchrones, verbindungsbasiertes
MAC-Protokoll, welchesdurch das Backup-Channel-Konzept in der Lage ist,
effektiv auf das plötzliche Eintreffen von PUs zu reagieren.Jeder SU ist
dabei mit zwei Transceivern ausgestattet, wobei einer davon stets fĂĽr
die Kommunikation auf dem gemeinsam genutzten Kontroll-Kanal (Common Control
Channel) verantwortlich ist. Der zweite Transceiver ist so ausgelegt, dass
dieser periodisch alle ungenutzten Kanäle absucht und dynamisch auf diese
zugreifen kann. Um den Zustand eines Kanals (belegt/nicht belegt) korrekt
erkennen zu können wird in dieser Arbeit eine einfache aber effektive Form
des kooperativen Sensings genutzt. Die Performanz des Protokolls wurde mit
Hilfe von Simulationen evaluiert. Die Ergebnisse zeigen, dass SWITCH im
Vergleich zu anderen CR-MAC-Protokollen eine Verbesserung des Durchsatzes
von bemerkenswerten 91,7% erzielen konnte. Zusammenfassend kann gesagt
werden, dass die vorgeschlagenen Beiträge einen Schritt hin zu einer
effektiveren Nutzung der verfügbaren Funkressourcen und zur Erhöhung der
Kapazität von drahtlosen Ad-Hoc Netzwerken darstellen.Wireless ad hoc networks are becoming more ubiquitous in terms of devices,
application areas, etc. due to their low cost and minimal deployment
effort. Since all these networks operate in the unlicensed band, the
problems of congestion and spectrum scarcity have arisen. On the other
hand, a recent study by Federal Communications Commission (FCC) has
revealed that swathes of licensed bands, measured by 70%, are unutilized.
This highlights that the actual problem is not the scarcity of spectrum but
inefficient allocation policies and usage. Therefore, this dissertation is
focused on improving spectrum utilization and efficiency to tackle the
spectrum scarcity problem and support further wireless ad hoc networks.This
thesis proposes a new spectrum management concept called opportunistic
spectrum access with backup channel (OSAB). The proposed concept provides
secondary users (SUs) (e.g. ad hoc users) with the ability to adaptively
and dynamically exploit channels from both licensed and unlicensed bands
without interfering the legacy users of licensed bands, i.e. the so called
primary users (PUs). Since existing radio systems offer very limited
flexibility, cognitive radios (CR), which can sense and adapt to radio
environments, are exploited to support such a dynamic concept. For the
development of OSAB, the channels' characteristics from each band are taken
into consideration. The main advantage of licensed channels is their
availability in significant numbers, whereas, the main advantage of
unlicensed channels is that all users have the same rights to channel
access and thus no preemption occurs once a user obtains a channel. In
addition, OSAB uses a backup channel (BC) to handle the appearance of PUs
and thus facilitates SU communication. The proposed concept is extensively
evaluated using a Markov chain model and compared to existing spectrum
management approaches such as opportunistic spectrum access (OSA). The
results indicate that OSAB decreases the dropping probability and the
expected number of spectrum handoffs for SUs compared to OSA by 60% and 17%
respectively.In order to apply OSAB practically, we develop a MAC protocol
that reacts efficiently to sudden appearance of PUs. The new protocol is
named opportunistic Spectrum access WITh backup CHannel (SWITCH) protocol.
SWITCH is a decentralized, asynchronous, and contention-based MAC protocol.
The BC's concept makes SWITCH extremely robust to the appearance of PUs.
Each SU is equipped with two transceivers, one is tuned to a common control
channel for the negotiation purpose with other SUs while the other is
designed specifically to periodically sense and dynamically use the
identified unused channels. To obtain the channel state accurately, we
propose an efficient spectrum sensing strategy. This strategy is based on
cooperative spectrum sensing among SUs. The performance of proposed
protocol is evaluated through simulations. The results show that SWITCH
accomplishes a remarkable 91.7% throughput gain over other CR-MAC
protocolsTo conclude, the proposed contributions are a step forward towards
efficient use of available radio resources and improve the spectrum
capacity for wireless ad hoc networks