Continuous Integration in Wireless Technology Development

Vucnik, Matevz; Solc, Tomaz; Gregorc, Urban; Hrovat, Andrej; Bregar, Klemen; Smolnikar, Miha; Mohorčič, Mihael; Fortuna, Carolina

doi:10.1109/mcom.2018.1800107

Cited by 17 publications

(13 citation statements)

References 13 publications

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“…Wireless network development, testing, and deployment calls for testbeds supporting continuous deployment principles, which have to be adjusted to the software and hardware architecture of the particular testbed. In order to better understand the implementation of the experiment control and monitoring system (EC and MS), we briefly review the LOG-a-TEC testbed first and afterwards, the reference continuous deployment architecture is given [ 5 ], followed by highlighted deficiencies of the current solution, which motivated this work.…”

Section: Continuous Deployment Framework For the Log-a-tec Testbedmentioning

confidence: 99%

“…The WiFi module supports dual-band communications on 2.4 GHz and 5 GHz bands. For experimentation purposes, the 2.4 GHz portion of the frequency band is used, while the 5 GHz band is applied for the infrastructure management links [ 5 ]. The experimentation node is a custom VESNA (Versatile Platform for Sensor Network Applications) device, based on the ARM Cortex-M3 microcontroller, which can run a dedicated OS (e.g., Contiki-NG and TinyOS) or custom firmware [ 22 ].…”

Section: Continuous Deployment Framework For the Log-a-tec Testbedmentioning

confidence: 99%

“…In addition, the testbed has to be remotely accessible and controlled, in order to provide access to a wide international research community. When a testbed is applied for the evaluation and testing of new devices, protocols, or applications, the testbed’s support of continuous deployment principles is of vital importance [ 5 ].…”

Section: Introductionmentioning

confidence: 99%

“…LOG-a-TEC [ 6 ], included in a Fed4FIRE+ facilities, combines outdoor and indoor heterogeneous wireless testbeds for experimentation with sensor networks and machine-type communications. It supports continuous deployment principles [ 5 ], enabling fully automated experiment execution and results collection, but the interactivity with the nodes has not been fully supported until now. The real-time control and monitoring is very important in the process of designing a software or testing process, which simplifies experiment application debugging and allows for faster comprehension of the results [ 7 ].…”

Section: Introductionmentioning

confidence: 99%

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Experiment Control and Monitoring System for LOG-a-TEC Testbed

Morano

Hrovat

Vucnik

et al. 2021

Sensors

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The LOG-a-TEC testbed is a combined outdoor and indoor heterogeneous wireless testbed for experimentation with sensor networks and machine-type communications, which is included within the Fed4FIRE+ federation. It supports continuous deployment principles; however, it is missing an option to monitor and control the experiment in real-time, which is required for experiment execution under comparable conditions. The paper describes the implementation of the experiment control and monitoring system (EC and MS) as the upgrade of the LOG-a-TEC testbed. EC and MS is implemented within existing infrastructure management and built systems as a new service. The EC and MS is accessible as a new tab in sensor management system portal. It supports several commands, including start, stop and restart application, exit the experiment, flash or reset the target device, and displays the real-time status of the experiment application. When nodes apply Contiki-NG as their operating system, the Contiki-NG shell tool is accessible with the help of the newly developed tool, giving further experiment execution control capabilities to the user. By using the ZeroMQ concurrency framework as a message exchange system, information can be asynchronously sent to one or many devices at the same time, providing a real-time data exchange mechanism. The proposed upgrade does not disrupt any continuous deployment functionality and enables remote control and monitoring of the experiment. To evaluate the EC and MS functionality, two experiments were conducted: the first demonstrated the Bluetooth Low Energy (BLE) localization, while the second analysed interference avoidance in the 6TiSCH (IPv6 over the TSCH mode of IEEE 802.15.4e) wireless technology for the industrial Internet of Things (IIoT).

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Section: Continuous Deployment Framework For the Log-a-tec Testbedmentioning

confidence: 99%

Section: Continuous Deployment Framework For the Log-a-tec Testbedmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Experiment Control and Monitoring System for LOG-a-TEC Testbed

Morano

Hrovat

Vucnik

et al. 2021

Sensors

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“…RFDMA networks, an increase of frame repetitions may be required to compensate packet losses, which can indeed lead to a large amount of energy dissipation. Overlapping with the Sigfox channels in the unlicensed 868 MHz, other technologies such as LoRa, IEEE 802.15.4 and proprietary also operate [23] and thus can interfere with the Sigfox network as exemplified in time slot TS-4 of Fig. 2.…”

Section: B Intra-and Inter-technology Interference In Rfdmamentioning

confidence: 99%

Whitelisting in RFDMA Networks

et al. 2019

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Uplink transmissions, within coexisting distinct sub-GHz technologies operating in the same unlicensed band, can be exposed to detrimental impact of the interference. In such scenarios, transmission scheduling becomes important for mitigating interference or minimizing the impact of the interference. For this purpose, we aim to whitelist relatively better channels in terms of their yielded packet reception ratio using our proposed channel quality metric that is based on the received signal-to-interference-plusnoise ratio. In this paper, we investigate the trade-offs of the channel whitelisting in random frequency division multiple access (RFDMA) networks in the presence of the cumulative intra-and inter-technology interferences. Our main findings indicate that, although channel whitelisting reduces the degree of freedom, and thus the overall capacity, it empowers a certain amount of devices to be served at a much lower received signal power, whereas this is infeasible for non-whitelisting scenarios at larger received signal power, which signifies the energy conservation ability of our proposed whitelisting method. It is experimentally demonstrated, on Sigfox, a particular type of RFDMA network, that non-whitelisting scenarios are not capable of supporting any devices at a received signal power below −118 dBm. Even for lower received signal power, we are able to reduce the required number of retransmissions at the same reception probability, which indeed indicates that the overall reliability of the network is improved. INDEX TERMS Aloha, inter-technology interference, Internet of things, RFDMA, whitelisting.

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