Non-Intrusive Distributed Tracing of Wireless IoT Devices with the FlockLab 2 Testbed

Trüb, Roman; Forno, Reto Da; Daschinger, Lukas; Biri, Andreas; Beutel, Jan; Thiele, Lothar

doi:10.1145/3480248

Cited by 5 publications

(7 citation statements)

References 34 publications

(32 reference statements)

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“…From these results, we can conclude that Grace achieves a building-wide time-synchronization in the range of a few microseconds. This does not fully reach the degree of timesynchronization offered by custom solutions with specific hardware requirements or using FPGA's for the GPIO tracing [9], [10]. However, our system is easily and cost efficiently retrofittable to existing testbeds and offers a sufficient time synchronization for tracing of many application fields.…”

Section: E Receiver Stabilitymentioning

confidence: 91%

“…A more recent work is Flocklab 2 [10], which uses the programmable real-time unit (PRU) of a Beaglebone Green for GPIO tracing. For time synchronization, the system uses GNSS with an accuracy of approx.…”

Section: Related Workmentioning

confidence: 99%

“…There are distributed, time-synchronized GPIO logging systems implemented in existing testbeds [8]- [10]. However, they use custom hardware with FPGAs and require a specific testbed observer platform throughout the testbed.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Grace: Low-cost time-synchronized GPIO tracing for IoT testbeds

Harms

Richter

2023

Computer Networks

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Section: E Receiver Stabilitymentioning

confidence: 91%

Section: Related Workmentioning

confidence: 99%

See 1 more Smart Citation

Grace: Low-cost time-synchronized GPIO tracing for IoT testbeds

Harms

Richter

2023

Computer Networks

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“…We first evaluate the proposed protocol using the FlockLab [6] testbed, creating a network of 11 nodes and one host. We use an indoor solar harvesting data set [5] to estimate energy budgets at different office locations.…”

Section: Methodsmentioning

confidence: 99%

Poster Abstract: Selective Flooding-Based Communication for Energy Harvesting Networks

Stricker

Forno

Brandl

et al. 2022

2022 21st ACM/IEEE International Conference on Information Processing in Sensor Networks (IPSN)

Self Cite

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With the Internet of Things (IoT) large amounts of data can be gathered at the edge, centrally collected and subsequently utilized for various application domains. Efficient and reliable synchronous communication protocols are essential for automated data gathering, yet they typically require a stable energy supply. Energy harvesting enables long-term deployments, but it imposes widely varying energy budgets on each node in the network. To remain efficient, synchronous protocols need to consider this energy variability. We propose a selective flooding protocol that employs low-energy communication rounds for all nodes and additional high-energy rounds only for nodes with high input power thus increasing their throughput. Low-energy rounds gather data with high reliability and maintain global network synchronization, while high-energy rounds use increased transmit power to overcome potentially-broken links that depend on low-power nodes. We evaluate our proposed method on the FlockLab testbed and build a small network composed of standalone energy harvesting nodes. The average power consumption of almost 84 𝜇W and 177 𝜇W for low-and high-power nodes, respectively, are fully sustainable by indoor photovoltaic harvesting.

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“…Wireless Experimentation: With regards to wireless experimentation, some notable examples are the FIT IoT-Lab [7], FlockLab 2 Testbed [8], D-Cube [9], w-ILab [12], Cosmos Lab [16], etc. These testbeds are publicly accessible and can enable experimentation around the LPWAN area.…”

Section: Related Work and Testbedsmentioning

confidence: 99%

UMBRELLA: A One-Stop Shop Bridging the Gap From Lab to Real-World IoT Experimentation

Mavromatis,

Jin,

Stanoev

et al. 2024

IEEE Access

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UMBRELLA a is an open, large-scale IoT ecosystem deployed across South Gloucestershire, UK. It is intended to accelerate innovation across multiple technology domains. UMBRELLA is built to bridge the gap between existing specialised testbeds and address holistically real-world technological challenges in a System-of-Systems (SoS) fashion. UMBRELLA provides open access to real-world devices and infrastructure, enabling researchers and the industry to evaluate solutions for Smart Cities, Robotics, Wireless Communications, Edge Intelligence, and more. Key features include over 200 multi-sensor nodes installed on public infrastructure, a robotics arena with 20 mobile robots, a 5G network-in-a-box solution, and a unified backend platform for management, control and secure user access. The heterogeneity of hardware components, including diverse sensors, communication interfaces, and GPU-enabled edge devices, coupled with tools like digital twins, allows for comprehensive experimentation and benchmarking of innovative solutions not viable in lab environments. This paper provides a comprehensive overview of UMBRELLA's multi-domain architecture and capabilities, making it an ideal playground for Internet of Things (IoT) and Industrial IoT (IIoT) innovation. It discusses the challenges in designing, developing and operating UMBRELLA as an open, sustainable testbed and shares lessons learned to guide similar future initiatives. With its unique openness, heterogeneity, realism and tools, UMBRELLA aims to continue accelerating cutting-edge technology research, development and translation into real-world progress.

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Non-Intrusive Distributed Tracing of Wireless IoT Devices with the FlockLab 2 Testbed

Cited by 5 publications

References 34 publications

Grace: Low-cost time-synchronized GPIO tracing for IoT testbeds

Grace: Low-cost time-synchronized GPIO tracing for IoT testbeds

Poster Abstract: Selective Flooding-Based Communication for Energy Harvesting Networks

UMBRELLA: A One-Stop Shop Bridging the Gap From Lab to Real-World IoT Experimentation

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