27,797 research outputs found
A Technical Review of Real-time QoS Protocols in Wireless Sensor Networks
Real-time wireless sensor networks become more and more important in emerging new applications as message delivery timeliness is highly concerned. However, supporting real-time QoS in sensor networks has faced many challenges due to their wireless nature, limited resource, dynamic network topology, and the demand of distributed architecture. There are tradeoffs between different application requirements including energy efficiency and delay performance. This paper studies the state of the art of current real-time solutions including MAC protocols, routing protocols, data aggregation strategies, and cross-layer designs. Some research challenges and design favors are also identified. The discussion may offer a reference for future investigations
XLP: A Cross-Layer Protocol for Efficient Communication in Wireless Sensor Networks
Severe energy constraints of battery-powered sensor nodes necessitate energy-efficient communication in Wireless Sensor Networks (WSNs). However, the vast majority of the existing solutions is based on classical layered protocols approach, which leads to significant overhead. It is much more efficient to have a unified scheme which blends common protocol layer functionalities into a cross-layer module. In this paper, a cross layer protocol (XLP) is introduced, which achieves congestion control, routing, and medium access control in a cross-layer fashion. The design principle of XLP is based on the cross-layer concept of initiative determination, which enables receiver-based contention, initiative-based forwarding, local congestion control, and distributed duty cycle operation to realize efficient and reliable communication in WSNs. The initiative determination requires simple comparisons against thresholds, and thus is very simple to implement, even on computationally impaired devices. To the best of our knowledge, XLP is the first protocol that integrates functionalities of all layers from PHY to transport into a cross-layer protocol. A cross-layer analytical framework is developed to investigate the performance of the XLP. Moreover, in a cross-layer simulation platform, the state-of-the- art layered and cross-layer protocols have been implemented along with XLP for performance evaluations. XLP significantly improves the communication performance and outperforms the traditional layered protocol architectures in terms of both network performance and implementation complexity
XLP: A Cross-Layer Protocol for Efficient Communication in Wireless Sensor Networks
Severe energy constraints of battery-powered sensor nodes necessitate energy-efficient communication in Wireless Sensor Networks (WSNs). However, the vast majority of the existing solutions is based on classical layered protocols approach, which leads to significant overhead. It is much more efficient to have a unified scheme which blends common protocol layer functionalities into a cross-layer module. In this paper, a cross layer protocol (XLP) is introduced, which achieves congestion control, routing, and medium access control in a cross-layer fashion. The design principle of XLP is based on the cross-layer concept of initiative determination, which enables receiver-based contention, initiative-based forwarding, local congestion control, and distributed duty cycle operation to realize efficient and reliable communication in WSNs. The initiative determination requires simple comparisons against thresholds, and thus is very simple to implement, even on computationally impaired devices. To the best of our knowledge, XLP is the first protocol that integrates functionalities of all layers from PHY to transport into a cross-layer protocol. A cross-layer analytical framework is developed to investigate the performance of the XLP. Moreover, in a cross-layer simulation platform, the state-of-the- art layered and cross-layer protocols have been implemented along with XLP for performance evaluations. XLP significantly improves the communication performance and outperforms the traditional layered protocol architectures in terms of both network performance and implementation complexity
Cooperative Medium Access Mechanisms and Service-oriented Routing in Multi-hop Wireless Networks
Doktorgradsavhandling i informasjons- og kommunikasjonsteknologi, Universitetet i Agder, Grimstad, 2011Multi-hop wireless networks have been regarded as a promising path towards future
wireless communication landscape. In the past decade, most related work has been
performed in the context of mobile ad hoc networks. In very recent years, however,
much effort has been shifted to more static networks such as wireless mesh networks
and wireless sensor networks. While significant progress has been achieved through
these years, both theoretically and experimentally, challenges still exist in various
aspects of these networks. For instance, how to use multi-hop networks as a means
for providing broadband Internet services with reliability and balanced load remains
as a challenging task. As the number of end-users is increasing rapidly and more
and more users are enjoying multimedia services, how to provide Quality of Service
(QoS) with user satisfaction in such networks remains also as a hot topic.
Meanwhile, another direction which has recently attracted lots of efforts in the
international research community is the introduction of cooperative communications.
Cooperative communications based on relaying nodes are capable of improving
network performance in terms of increased spectral and power efficiency, extended
network coverage, balanced QoS, infrastructure-less deployment, etc. Cooperation
may happen at different communication layers, at the physical layer where
the received signal is retransmitted and at the MAC and routing layers where a
packet is forwarded to the next hop in a coordinated manner towards the destination,
respectively. However, without joint consideration and design of physical
layer, MAC layer and network layer, the benefit of cooperative communication cannot
be exploited to the maximum extent. In addition, how to extend one-hop cooperative
communication into multi-hop wireless network scenarios remains as an
almost un-chartered research frontier.
In this dissertation, we enhance the state of the art technologies in the field of
multi-hop wireless networks from a layered perspective. While efficient scheduling
mechanisms are proposed at the MAC layer, elaborate routing protocols are devised
at the network layer. More specifically, by taking into account of cross layer design
we cope with network congestion problems in wireless mesh networks mainly at the
network layer. In order to further improve the performance of cooperative wireless
networks, we propose a contention-based cooperative MAC protocol in the presence
of multiple relay nodes. Since a large majority of existing cooperative MAC
protocols are designed based on widely-used IEEE 802.11 MAC protocol which
exhibits inherent design constraint when applied in multi-hop wireless networks, it
is imperative to develop a novel cooperative MAC protocol which is appropriate
for multi-hop network scenarios. Next, we propose a TDMA-based MAC protocol supporting cooperative communications in static multi-hop wireless networks. Furthermore,
a cooperative lifetime maximization MAC protocol is proposed to cope
with the energy hole problem in wireless sensor networks
Maximize resource utilization based channel access model with presence of reactive jammer for underwater wireless sensor network
Underwater sensor networks (UWSNs) are vulnerable to jamming attacks. Especially, reactive jamming which emerged as a greatest security threat to UWSNs. Reactive jammer are difficult to be removed, defended and identified. Since reactive jammer can control and regulate (i.e., the duration of the jam signal) the probability of jamming for maintaining high vulnerability with low detection probability. The existing model are generally designed considering terrestrial wireless sensor networks (TWSNs). Further, these models are limited in their ability to detect jamming correctly, distinguish between the corrupted and uncorrupted parts of a packet, and be adaptive with the dynamic environment. Cooperative jamming model has presented in recent times to utilize resource efficiently. However, very limited work is carried out using cooperative jamming detection. For overcoming research challenges, this work present Maximize Resource Utilization based Channel Access (MRUCA). The MRUCA uses cross layer design for mitigating reactive jammer (i.e., MRUCA jointly optimizes the cooperative hopping probabilities and channel accessibility probabilities of authenticated sensor device). Along with channel, load capacity of authenticated sensor device is estimated to utilize (maximize) resource efficiently. Experiment outcome shows the proposed MRUCA model attain superior performance than state-of-art model in terms of packet transmission, BER and Detection rate
Portability, compatibility and reuse of MAC protocols across different IoT radio platforms
To cope with the diversity of Internet of Things (loT) requirements, a large number of Medium Access Control (MAC) protocols have been proposed in scientific literature, many of which are designed for specific application domains. However, for most of these MAC protocols, no multi-platform software implementation is available. In fact, the path from conceptual MAC protocol proposed in theoretical papers, towards an actual working implementation is rife with pitfalls. (i) A first problem is the timing bugs, frequently encountered in MAC implementations. (ii) Furthermore, once implemented, many MAC protocols are strongly optimized for specific hardware, thereby limiting the potential of software reuse or modifications. (iii) Finally, in real-life conditions, the performance of the MAC protocol varies strongly depending on the actual underlying radio chip. As a result, the same MAC protocol implementation acts differently per platform, resulting in unpredictable/asymmetrical behavior when multiple platforms are combined in the same network. This paper describes in detail the challenges related to multi-platform MAC development, and experimentally quantifies how the above issues impact the MAC protocol performance when running MAC protocols on multiple radio chips. Finally, an overall methodology is proposed to avoid the previously mentioned cross-platform compatibility issues. (C) 2018 Elsevier B.V. All rights reserved
Middleware for Wireless Sensor Networks: An Outlook
In modern distributed computing, applications are rarely built directly atop operating system facilities, e.g., sockets. Higher-level middleware abstractions and systems are often employed to simplify the programmer’s chore or to achieve interoperability. In contrast, real-world wireless sensor network (WSN) applications are almost always developed by relying directly on the operating system.
Why is this the case? Does it make sense to include a middleware layer in the design of WSNs? And, if so, is it the same kind of software system as in traditional distributed computing? What are the fundamental concepts, reasonable assumptions, and key criteria guiding its design? What are the main open research challenges, and the potential pitfalls? Most importantly, is it worth pursuing research in this field?
This paper provides a (biased) answer to these and other research questions, preceded by a brief account on the state of the art in the field
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