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1. Feedback-Based Control Loop Congestion Control Algorithm for Wireless Networks

Author

Ramyashree Venkatesh Bhat, Jetmir Haxhibeqiri, Ingrid Moerman, and Jeroen Hoebeke

Subjects
Congestion control, airtime fairness, wireless networks, INT, APP-NET, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Wi-Fi plays a crucial role in connecting private professional networks by providing varying data rates based on channel quality. Despite advancements in Wi-Fi protocols, there is still a problem of throughput degradation for higher data rate devices when lower data rate devices are around, due to airtime unfairness. The diverse requirements of emerging applications emphasize the necessity for network protocols that cater specifically to these needs. To tackle the problem of throughput degradation in devices that use higher physical data rates, we have designed a control-loop congestion control algorithm that decides the application data transfer rate based on the real-time network context and aggregated airtime feedback from the access point. The design is based on in-band network telemetry and stack programmability of eBPF. Using the designed algorithm, the throughput of the device that uses a higher physical data rate is improved by 58% without compromising the overall network efficiency. The average airtime difference between the end devices of the network is as low as 18%. Other than airtime fairness, the features implemented in the algorithm and monitoring and feedback system in the access point can also be utilized for priority-based airtime fairness and several such potential use cases in wireless networks in the future.

Published
2024
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2. Unlocking Mobility for Wi-Fi-Based Wireless Time-Sensitive Networks

Author

Pablo Avila-Campos, Jetmir Haxhibeqiri, Xianjun Jiao, Ben Van Herbruggen, Ingrid Moerman, and Jeroen Hoebeke

Subjects
Handover, IEEE 802.11, openwifi, UWB, wireless time-sensitive networking, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Undoubtedly, mobility remains a fundamental asset in wireless communications. Conversely, time-sensitive networking (TSN) represents a vital technology that enables determinism and low latency, fundamental for time-sensitive applications. In our study, we marry these two concepts by introducing a pioneering procedure that facilitates seamless roaming within a Wi-Fi-based Wireless Time-Sensitive Network (W-TSN). Through extensive real-world development and testing, we assess various techniques for optimizing handover moment selection and reducing handover delay. Our findings demonstrate that an integrated approach combining Received Signal Strength Indication (RSSI) and location-based online reduces the need for traditional channel scanning. This approach surpasses the offline and midpoint selection methods, excelling in identifying the optimal handover point and reducing handover delay to less than 20 milliseconds.

Published
2024
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3. Multimodal Network Architecture for Shared Situational Awareness amongst Vessels

Author

Amina Seferagić, Jetmir Haxhibeqiri, Paolo Pilozzi, and Jeroen Hoebeke

Subjects
Wi-Fi, IEEE 802.11, maritime communications, application-network integration, shared situational awareness, multimodal communications, Chemical technology, TP1-1185
Abstract

To shift the paradigm towards Industry 4.0, maritime domain aims to utilize shared situational awareness (SSA) amongst vessels. SSA entails sharing various heterogeneous information, depending on the context and use case at hand, and no single wireless technology is equally suitable for all uses. Moreover, different vessels are equipped with different hardware and have different communication capabilities, as well as communication needs. To enable SSA regardless of the vessel’s communication capabilities and context, we propose a multimodal network architecture that utilizes all of the network interfaces on a vessel, including multiple IEEE 802.11 interfaces, and automatically bootstraps the communication transparently to the applications, making the entire communication system environment-aware, service-driven, and technology-agnostic. This paper presents the design, implementation, and evaluation of the proposed network architecture which introduces virtually no additional delays as compared to the Linux communication stack, automates communication bootstrapping, and uses a novel application-network integration concept that enables application-aware networks, as well as network-aware applications. The evaluation was conducted for several IEEE 802.11 flavors. Although inspired by SSA for vessels, the proposed architecture incorporates several concepts applicable in other domains. It is modular enough to support existing, as well as emerging communication technologies.

Published
2021
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4. An End-To-End LwM2M-Based Communication Architecture for Multimodal NB-IoT/BLE Devices

Author

Subho Shankar Basu, Jetmir Haxhibeqiri, Mathias Baert, Bart Moons, Abdulkadir Karaagac, Pieter Crombez, Pieterjan Camerlynck, and Jeroen Hoebeke

Subjects
multi-modal architecture, handover, narrowband internet of things (NB-IoT), bluetooth low energy (BLE), light-weight machine to machine (LwM2M), Chemical technology, TP1-1185
Abstract

The wireless Internet of Things (IoT) landscape is quite diverse. For instance, Low-Power Wide-Area Network (LPWAN) technologies offer low data rate communication over long distance, whereas Wireless Personal Area Network (WPAN) technologies can reach higher data rates, but with a reduced range. For simple IoT applications, communication requirements can be fulfilled by a single technology. However, the requirements of more demanding IoT use cases can vary over time and with the type of data being exchanged. This is pushing the design towards multimodal approaches, where different wireless IoT technologies are combined and the most appropriate one is used as per the need. This paper considers the combination of Narrow Band IoT (NB-IoT) and Bluetooth Low Energy (BLE) as communication options for an IoT device that is running a Lightweight Machine to Machine/Constrained Application Protocol (LwM2M/CoAP) protocol stack. It analyses the challenges incurred by different protocol stack options, such as different transfer modes (IP versus non-IP), the use of Static Context Header Compression (SCHC) techniques, and Datagram Transport Layer Security (DTLS) security modes, and discusses the impact of handover between both communication technologies. A suitable end-to-end architecture for the targeted multimodal communication is presented. Using a prototype implementation of this architecture, an in-depth assessment of handover and its resulting latency is performed.

Published
2020
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8. A Survey of LoRaWAN for IoT: From Technology to Application

Author

Jetmir Haxhibeqiri, Eli De Poorter, Ingrid Moerman, and Jeroen Hoebeke

Subjects
LoRaWAN, LoRa, IoT, LPWANs, IoT applications, Chemical technology, TP1-1185
Abstract

LoRaWAN is one of the low power wide area network (LPWAN) technologies that have received significant attention by the research community in the recent years. It offers low-power, low-data rate communication over a wide range of covered area. In the past years, the number of publications regarding LoRa and LoRaWAN has grown tremendously. This paper provides an overview of research work that has been published from 2015 to September 2018 and that is accessible via Google Scholar and IEEE Explore databases. First, a detailed description of the technology is given, including existing security and reliability mechanisms. This literature overview is structured by categorizing papers according to the following topics: (i) physical layer aspects; (ii) network layer aspects; (iii) possible improvements; and (iv) extensions to the standard. Finally, a strengths, weaknesses, opportunities and threats (SWOT) analysis is presented along with the challenges that LoRa and LoRaWAN still face.

Published
2018
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9. LoRa Scalability: A Simulation Model Based on Interference Measurements

Author

Jetmir Haxhibeqiri, Floris Van den Abeele, Ingrid Moerman, and Jeroen Hoebeke

Subjects
low-power wide area networks (LPWAN), LoRa, LoRaWAN, Internet of Things (IoT), scalability, interference modeling, Chemical technology, TP1-1185
Abstract

LoRa is a long-range, low power, low bit rate and single-hop wireless communication technology. It is intended to be used in Internet of Things (IoT) applications involving battery-powered devices with low throughput requirements. A LoRaWAN network consists of multiple end nodes that communicate with one or more gateways. These gateways act like a transparent bridge towards a common network server. The amount of end devices and their throughput requirements will have an impact on the performance of the LoRaWAN network. This study investigates the scalability in terms of the number of end devices per gateway of single-gateway LoRaWAN deployments. First, we determine the intra-technology interference behavior with two physical end nodes, by checking the impact of an interfering node on a transmitting node. Measurements show that even under concurrent transmission, one of the packets can be received under certain conditions. Based on these measurements, we create a simulation model for assessing the scalability of a single gateway LoRaWAN network. We show that when the number of nodes increases up to 1000 per gateway, the losses will be up to 32%. In such a case, pure Aloha will have around 90% losses. However, when the duty cycle of the application layer becomes lower than the allowed radio duty cycle of 1%, losses will be even lower. We also show network scalability simulation results for some IoT use cases based on real data.

Published
2017
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44. Enabling time-sensitive network management over multi-domain wired/Wi-Fi networks

Author

Gilson Miranda, Esteban Municio, Jetmir Haxhibeqiri, Jeroen Hoebeke, Ingrid Moerman, and Johann M. Marquez-Barja

Subjects
Computer Networks and Communications, Electrical and Electronic Engineering, Engineering sciences. Technology
Abstract

Deterministic performance and reliable operation are vital for many applications with industrial-grade requirements. Such applications rely on Time-Sensitive Networking (TSN) to enable time-critical deterministic communication. While standardization efforts were focused mainly on TSN features for wired domains, recent advances in wireless technologies (e.g., Wi-Fi 6/7) are extending time-sensitive communication towards wireless networks as well. However, achieving multi-domain LAN/wlan end-to-end TSN communication requires addressing challenges on end-to-end time synchronization, multi-domain control plane interoperability, run-time end-to-end scheduling, and fine-grained monitoring. Because state-of-the-art TSN controllers’ scope lays far below these new required capabilities, in this work we present a novel, fully-programmable controller for end-to-end TSN-enabled networks. Our controller is based on a modular architecture to be adaptable to challenges arising when shifting the standard TSN scope towards WLAN domain. We deploy a proof-of-concept in a cloud-wired environment to evaluate its key performance indicators when handling increasing numbers of nodes and simultaneous requests. Further, we run experiments on real TSN-enabled networks comprising Ethernet and Wi-Fi technologies, demonstrating the effectiveness of the controller in performing seamless fine-grained traffic control in both domains.

Published
2023

45. LoRaWAN Scheduling: From Concept to Implementation

Author

Teresa Olivares, Jeroen Hoebeke, Antonio Fernández-Caballero, F. Javier Ramirez, Celia Garrido-Hidalgo, Jetmir Haxhibeqiri, and Bart Moons

Subjects
Standards, Technology and Engineering, Computer Networks and Communications, Computer science, Distributed computing, Internet of Things, Clock drift, Access control, Synchronization, Receivers, LoRa, Scheduling (computing), Hardware, Synchronization (computer science), scheduling, clock skew, Clocks, Network packet, business.industry, Logic gates, Clock skew, LoRaWAN, Computer Science Applications, Hardware and Architecture, Aloha, Signal Processing, Scalability, business, Information Systems
Abstract

While the Internet of Things continues to grow, the LoRaWAN standard is generating special interest due to its open-source nature, ultralow-power consumption and long-range connectivity. Recent works have explored the challenges of implementing LoRaWAN, with scalability being considered one of the major bottlenecks imposed by its Aloha-based medium access control (MAC) layer. Despite much on-going research on LoRaWAN scheduling aimed at alleviating this concern, experimental approaches are rarely found in the literature. In this work, we describe the steps taken and the technical issues overcome to move from a low-overhead synchronization and scheduling concept to its real-world implementation on top of LoRaWAN Class A. Accordingly, an end-to-end architecture was designed and deployed on top of STM32L0 MCUs, which communicate with a central entity responsible for providing synchronization metrics and allocating transmission slots on demand. The clock drift of devices was measured in a temperature-controlled chamber, which served as a basis to define slot lengths in the network. As a result, an operational end-to-end system was implemented and evaluated for different setup scenarios, with 10-ms accuracy being achieved. Our experimental results show significant improvements in packet delivery ratios with respect to Aloha-based setups, especially under high network loads (up to 29% for SF12), thereby demonstrating the feasibility of the presented approach.

Published
2021

46. Removing the wires in time-sensitive networks

Author

Pablo Avila-Campos, Jetmir Haxhibeqiri, Xianjun Jiao, Ingrid Moerman, and Jeroen Hoebeke

Subjects
Technology and Engineering
Abstract

From machine control applications to multimedia, and distributed real-time monitoring, all require a high level of determinism and low end-to-end latency. Time-Sensitive Networking, running on top of Ethernet, has been proposed as the solution over the past years. This paper analyses the crucial challenges that need to be overcome to go beyond Ethernet and seamlessly extend such time-sensitive operation into the wireless domain. A TSN-compatible design, based on our open-source WiFi implementation, is presented, with a specific focus on scheduling. Two experiments, in our IEEE802.11-based W-TSN testbed, comparing contention arising from a shared and dedicated time slot were performed. The results show a lower difference in the number of received packets between shared and dedicated time slots at smaller time slots.

Published
2022

47. Hardware efficient clock synchronization across Wi-Fi and ethernet-based network using PTP

Author

Gilson Miranda, Muhammad Aslam, Jeroen Hoebeke, Ingrid Moerman, Jetmir Haxhibeqiri, Johann M. Marquez-Barja, Xianjun Jiao, and Wei Liu

Subjects
Ethernet, Technology and Engineering, precision time protocol (PTP), Computer science, 11 Standard, openwifi, synchronization (CS), Synchronization, Spread spectrum communication, Clock synchronization, IEEE 802, Hardware, Clock, Synchronization (computer science), Wireless, Wireless fidelity, Electrical and Electronic Engineering, Wi-Fi, Clocks, Computer. Automation, IEEE 802.11, business.industry, Wireless network, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, Timestamping, (TSF), timing synchronization function, Software-defined radio, Computer Science Applications, Control and Systems Engineering, Performance evaluation, Timing Synchronization Function, business, Engineering sciences. Technology, Computer hardware, Information Systems, hardware (HW) timestamping (TS)
Abstract

Precision time protocol (PTP), a state-of-the-art clock synchronization protocol primarily designed for wired networks, has recently gained attention in the wireless community, due to the increased use of the IEEE 802.11 wireless local area networks (WLAN) in real-time distributed systems. However, all the existing WLAN-based PTP designs either incorporate software timestamping (TS) delivering poor clock synchronization accuracy, or hardware (HW) TS providing better synchronization accuracy at the cost of a significant amount of HW overhead. Moreover, the performance of the existing PTP solutions is mostly evaluated in single-hop wireless networks, while the performance across wired and wireless networks is taken for granted. In this article, a new software-defined-radio-based approach to implement PTP is introduced and validated for the IEEE 802.11 WLAN. Instead of using a dedicated HW clock, the solution utilizes the timing synchronization function clock, an existing clock in the IEEE802.11 standard for synchronization between access point and WLAN stations. The performance of the proposed solution is first investigated within a single-hop WLAN and then across wired-wireless networks. Experimental results unveil that 90% of the absolute clock synchronization error falls within 1.4 mu s.

Published
2022

50. Adaptive Transport Layer Protocols using In-band Network Telemetry and eBPF

Author

Ingrid Moerman, Jetmir Haxhibeqiri, Ramyashree Venkatesh Bhat, and Jeroen Hoebeke

Subjects
wireless networks, Technology and Engineering, INT, business.industry, Computer science, Telemetry, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, Transport layer, eBPF, business, Computer network
Abstract

Many applications use Transmission Control Protocol (TCP) to achieve end-to-end reliable, ordered, and error-free data transfer in the network. The decisions are entirely based on the partial end-to-end information obtained from the acknowledgment packets. With several applications moving towards the wireless domain or wired-wireless domain, there has been advancements in the field of application-network interaction and innovations to obtain real-time network monitoring information on a per-hop basis. This paves a way for extensibility and customization of transport protocols. In this paper, we use detailed real-time in-band network telemetry information to adjust the data transfer at the sender side by modifying the congestion control algorithms in real time. This new technique is tested for different network scenarios and the obtained results indicate that a more network-aware TCP design can greatly increase performance under lossy conditions. The implemented technique illustrates how tighter interactions between higherlayer protocols and the network, in combination with real-time telemetry, can facilitate the way for novel, more adaptive protocol designs.

Published
2021

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