ORCHESTRA: Enabling Inter-Technology Network Management in Heterogeneous Wireless Networks

Schepper, Tom De; Bosch, Patrick; Zeljković, Ensar; Mahfoudhi, Farouk; Haxhibeqiri, Jetmir; Hoebeke, Jeroen; Famaey, Jeroen; Latré, Steven

doi:10.1109/tnsm.2018.2866774

Cited by 21 publications

(20 citation statements)

References 29 publications

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“…In addition to monitoring, network needs to be (re)configured based on monitored data and its application requirements. In this context, few frameworks capable of controlling and managing wireless networks [33]- [35] exists.…”

Section: Related Workmentioning

confidence: 99%

In-Band Network Monitoring Technique to Support SDN-Based Wireless Networks

Haxhibeqiri

Isolani

Marquez-Barja

et al. 2021

IEEE Trans. Netw. Serv. Manage.

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Most industrial applications demand determinism in terms of latency, reliability, and throughput. This goes hand in hand with the increased complexity of real-time network programability possibilities. To ensure network performance low-overhead, high-granularity, and timely network verification techniques need to be deployed. The first cornerstone of network verification ability is to enable end-to-end network monitoring, including end devices too. To achieve this, this article shows a novel and low overhead in-band network telemetry and monitoring technique for wireless networks focusing on IEEE 802.11 networks. A design of in-band network telemetry enabled node architecture is proposed and its proof of concept implementation is realized. The PoC realization is used to monitor a real-life SDN-based wireless network, enabling onthe-fly (re)configuration capabilities based on monitoring data. In addition, the proposed monitoring technique is validated in terms of monitoring accuracy, monitoring overhead, and network (re)configuration accuracy. It is shown that the proposed inband monitoring technique has 6 times lower overhead than other active monitoring techniques on a single-hop link. Besides this, it is demonstrated that (re)configuration decisions taken based on monitored data fulfill targeted application requirements, validating the suitability of the proposed monitoring technique.

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Section: Related Workmentioning

confidence: 99%

In-Band Network Monitoring Technique to Support SDN-Based Wireless Networks

Haxhibeqiri

Isolani

Marquez-Barja

et al. 2021

IEEE Trans. Netw. Serv. Manage.

Self Cite

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“…However, they focus mainly on reliability, reporting latencies between 10 and 20 ms. As such, their solution is not applicable to URLLC. De Schepper et al proposed the ORCHESTRA framework as an enabler for interface diversity [18]. It supports packet duplication, splitting, load balancing, and seamless inter-AP/BS (i.e., horizontal) and inter-RAT (i.e., vertical) handovers at the network layer through a central controller and virtual medium access control (MAC) abstractions.…”

Section: State Of the Artmentioning

confidence: 99%

Immersive Interconnected Virtual and Augmented Reality: A 5G and IoT Perspective

et al. 2020

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In this article, we articulate the technical challenges to enable a future AR/VR end-to-end architecture, that combines 5G URLLC and Tactile IoT technology to support this next generation of interconnected AR/VR applications. Through the use of IoT sensors and actuators, AR/VR applications will be aware of the environmental and user context, supporting human-centric adaptations of the application logic, and lifelike interactions with the virtual environment. We present potential use cases and the required technological building blocks. For each of them, we delve into the current state of the art and challenges that need to be addressed before the dream of remote AR/VR interaction can become reality.

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“…In contrast with most SDN systems however, no specific rules about routing, firewalls or load balancing are placed in a centralized server. This provides the opportunity of combining the proposed framework with a wireless SDN framework like ORCHESTRA [20], with our framework being responsible for flow control optimization, for informing nodes in the network about each other's states (using the virtual Medium Access Control (MAC) layer), and for applying flow-specific routing rules. In contrast with previously mentioned approaches, the framework developed by the SCATTER team [21] uses the proposed collaborative flow control in this article to manage and optimize the inter-network QoS and spectrum footprint, using information gathered within our network and received from external ones.…”

Section: Related Workmentioning

confidence: 99%

Collaborative Flow Control in the DARPA Spectrum Collaboration Challenge

Mennes

Struye

Donato

et al. 2020

IEEE Trans. Netw. Serv. Manage.

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Wireless network technologies are becoming more and more popular. Because of this, important parts of the wireless spectrum become overloaded. Static spectrum allocation, which has been the norm for decades, is not suitable anymore. To maintain the high demand for spectrum and the continuous development of new wireless technologies, there is a need for an intelligent, dynamic spectrum allocation mechanism, where different network technologies collaboratively optimize the spectrum usage. New wireless network paradigms, such as Neutral Host Networks (NHNs) and private 5G, require a smart, spectrumfootprint-aware flow control algorithm to overcome the spectrum scarcity in collaborative way. This article presents a strategy, vision and flow control mechanism to implement collaboration in a Quality of Service (QoS)-driven way. The solution in this article is based on policies which may activate depending on its current and neighbor's network states. Through a flow ordering and selection strategy, these policies optimize the spectrum footprint, based on the performance and QoS-requirements of the own and surrounding networks. The proposed algorithm is tested extensively and validated on a large scale during the DARPA Spectrum Collaboration Challenge (SC2) competition. The results of the SC2 final event and intermediate scrimmages showed that the proposed approach increased the score, indicating increased inter-network collaboration was achieved. Index Terms-Quality of service, wireless flow control, wireless networks and cellular networks, wireless spectrum collaboration. I. INTRODUCTION C OLLABORATION in the wireless spectrum is key to further exploration of the capacity of today's wireless communication. Driven by the increasing need for wireless capacity [1], spectrum scarcity is a familiar phenomenon,

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ORCHESTRA: Enabling Inter-Technology Network Management in Heterogeneous Wireless Networks

Cited by 21 publications

References 29 publications

In-Band Network Monitoring Technique to Support SDN-Based Wireless Networks

In-Band Network Monitoring Technique to Support SDN-Based Wireless Networks

Immersive Interconnected Virtual and Augmented Reality: A 5G and IoT Perspective

Collaborative Flow Control in the DARPA Spectrum Collaboration Challenge

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