Optimization of ultra-narrowband wireless communication: An experimental case study

“…When the devices are arbitrarily scheduled to transmit, they select a random transmission microchannel from the whitelist, where potentially the impact of interference is mitigated up to a certain level. More technical details about the experimental set-up are provided in [6], and the code 3 as well as the datasets 4 that we were able to release under an open source license are available on GitHub.…”

“…To test the stationarity and discover the length of temporal channel coherence, we employ a technique discussed in [32]. Initially, the spectrum data are partitioned into channels, where each channel is then split into a sequence of m non-overlapping intervals of length l. Independent hypothesis tests 6 for distribution fitting of data in addition to mean and variance stationarity tests are performed on each consecutive pair of intervals, totaling m − 1 pairwise comparisons per channel. Supposing that two consecutive intervals form a window of length 2l which is considered stationary if the null hypothesis on the corresponding intervals is satisfied.…”

“…The offset between clocks and frequency references in the test device and the spectrum sensor was determined by matching transmission times and frequencies with the corresponding peaks in the power spectral density. The experimental set-up and the implementation details are similar to those used in [6], which utilizes elements of the Fed4FIRE+ LOG-a-TEC 5 testbed [31].…”

“…Therefore, considering the assumptions of the tests and 28 days of data recordings, it is safe to say that updating channels of whitelist after every 37 minutes highly likely guarantees to exploit relatively better channels for uplink transmissions. 6 Kolmogorov-Smirnov, ANOVA and Levene's test. Additionally, one way to ensure the up-to-date whitelist and to minimize the overheads incurred by the transmission of whitelists is to update channels of the whitelist just before the uplink transmissions are initiated, so that about 37 minutes time frame guarantees a highly likely unchanged whitelist for these uplink transmissions.…”

“…focus on the coexistence of different technologies in the 2.4 GHz and 5 GHz bands [5] and very little is known about the coexistence of different technologies in sub-GHz bands, particularly in terms of the detrimental impact of the interference arriving both from intra-and inter-technology devices, i.e. devices belonging to the same and different technology, respectively [6].…”

Whitelisting in RFDMA Networks

“…When the devices are arbitrarily scheduled to transmit, they select a random transmission microchannel from the whitelist, where potentially the impact of interference is mitigated up to a certain level. More technical details about the experimental set-up are provided in [6], and the code 3 as well as the datasets 4 that we were able to release under an open source license are available on GitHub.…”

“…To test the stationarity and discover the length of temporal channel coherence, we employ a technique discussed in [32]. Initially, the spectrum data are partitioned into channels, where each channel is then split into a sequence of m non-overlapping intervals of length l. Independent hypothesis tests 6 for distribution fitting of data in addition to mean and variance stationarity tests are performed on each consecutive pair of intervals, totaling m − 1 pairwise comparisons per channel. Supposing that two consecutive intervals form a window of length 2l which is considered stationary if the null hypothesis on the corresponding intervals is satisfied.…”

“…The offset between clocks and frequency references in the test device and the spectrum sensor was determined by matching transmission times and frequencies with the corresponding peaks in the power spectral density. The experimental set-up and the implementation details are similar to those used in [6], which utilizes elements of the Fed4FIRE+ LOG-a-TEC 5 testbed [31].…”

“…Therefore, considering the assumptions of the tests and 28 days of data recordings, it is safe to say that updating channels of whitelist after every 37 minutes highly likely guarantees to exploit relatively better channels for uplink transmissions. 6 Kolmogorov-Smirnov, ANOVA and Levene's test. Additionally, one way to ensure the up-to-date whitelist and to minimize the overheads incurred by the transmission of whitelists is to update channels of the whitelist just before the uplink transmissions are initiated, so that about 37 minutes time frame guarantees a highly likely unchanged whitelist for these uplink transmissions.…”

“…focus on the coexistence of different technologies in the 2.4 GHz and 5 GHz bands [5] and very little is known about the coexistence of different technologies in sub-GHz bands, particularly in terms of the detrimental impact of the interference arriving both from intra-and inter-technology devices, i.e. devices belonging to the same and different technology, respectively [6].…”

Whitelisting in RFDMA Networks

Performance assessment of long‐range and Sigfox protocols with mobility support

An Adaptive Channel Quality Metric for Ultra-Narrowband Systems