LTE/LTE-A Random Access for Massive Machine-Type Communications in Smart Cities

TL;DR

This paper reviews current methods for managing massive random access in LTE/LTE-A networks for smart city MTC applications, introduces a novel collision resolution model, and demonstrates significant improvements in access success rate through simulations.

Contribution

It proposes a new collision resolution random access model for massive MTC that improves success rates and coexists with existing LTE protocols.

Findings

Significant increase in access success rate with the proposed model.

The model effectively manages bursty and massive access attempts.

Compatibility with existing LTE MAC protocols is maintained.

Abstract

Massive Machine-Type Communications (MTC) over cellular networks is expected to be an integral part of wireless "Smart City" applications. The Long Term Evolution (LTE)/LTE-Advanced (LTE-A) technology is a major candidate for provisioning of MTC applications. However, due to the diverse characteristics of payload size, transmission periodicity, power efficiency, and quality of service (QoS) requirement, MTC poses huge challenges to LTE/LTE-A technologies. In particular, efficient management of massive random access is one of the most critical challenges. In case of massive random access attempts, the probability of preamble collision drastically increases, thus the performance of LTE/LTE-A random access degrades sharply. In this context, this article reviews the current state-of-the-art proposals to control massive random access of MTC devices in LTE/LTE-A networks. The proposals are compared in terms of five major metrics, namely, access delay, access success rate, power efficiency, QoS guarantee, and the effect on Human-Type Communications (HTC). To this end, we propose a novel collision resolution random access model for massive MTC over LTE/LTE-A. Our proposed model basically resolves the preamble collisions instead of avoidance, and targets to manage massive and bursty access attempts. Simulations of our proposed model show huge improvements in random access success rate compared to the standard slotted-Aloha-based models. The new model can also coexist with existing LTE/LTE-A Medium Access Control (MAC) protocol, and ensure high reliability and time-efficient network access.