Abstract
The cellular-based infrastructure is regarded as one of the potential solutions for massive Internet of Things (mIoT), where the random access (RA) procedure is used for requesting channel resources in the uplink data transmission. Due to the nature of the mIoT network with the sporadic uplink transmissions of a large amount of IoT devices, massive concurrent channel resource requests lead to a high probability of RA failure. To relieve the congestion during the RA in mIoT networks, we model RA procedure and analyze as well as evaluate the performance improvement due to different RA schemes, including power ramping (PR), back-off (BO), access class barring (ACB), hybrid ACB and back-off schemes, and hybrid power ramping and back-off (PR&BO). To do so, we develop a traffic-aware spatio-temporal model for the contention-based RA analysis in the mIoT network, where the signal-to-noise-plus-interference ratio (SINR) outage and collision events jointly determine the traffic evolution and the RA success probability. Compared to existing literature that only models collision from the single-cell perspective, we model both SINR outage and the collision from the network perspective. Based on this analytical model, we derive the analytical expression for the RA success probabilities to show the effectiveness of different RA schemes. We also derive the average queue lengths and the average waiting delays of each RA scheme to evaluate the packets accumulation status and packets serving efficiency. Our results show that our proposed PR&BO scheme outperforms other schemes in heavy traffic scenarios in terms of the RA success probability, the average queue length, and the average waiting delay.
Highlights
W ITH the rapid proliferation of innovative applications in the paradigm of massive Internet of Things, such as smart city, smart home, smart industrial, and vehicular communication, the demand of data traffic for wireless networks is explosively grown [2], [3]
IoT devices randomly move to a new position, and the active ones randomly choose a preamble for the current Random Access (RA) attempt
We developed a spatio-temporal mathematical model to analyze the contention-based RA in the massive Internet of Things (mIoT) network by taking into account the signal-to-noiseplus-interference ratio (SINR) outage problem as well as the collision problem
Summary
W ITH the rapid proliferation of innovative applications in the paradigm of massive Internet of Things (mIoT), such as smart city, smart home, smart industrial, and vehicular communication, the demand of data traffic for wireless networks is explosively grown [2], [3]. To improve the success RA performance under limited channel resources, efficient RA schemes need to be proposed and analyzed, which is utilized to alleviate uplink congestion by reducing the high interference and high collision probability when massive IoT devices contend for the uplink channel resources at the same time [5], [6], [8]. In our previous work [21], we provided a novel spatiotemporal mathematical framework to analyze the preamble transmission success probability of mIoT network, where the queue evolution of IoT devices is modeled via probability theory (i.e., a new approach is developed to track the queue evolution, which is different from [19] and [20]), and the SINR outage of preamble transmission is studied using stochastic geometry.
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