Abstract
Millimeter wave (mmWave) has been claimed to be the only viable solution for high-bandwidth vehicular communications. However, frequent channel estimation and beamforming required to provide a satisfactory quality of service limits mmWave for vehicular communications. In this paper, we propose a novel channel estimation and beam tracking framework for mmWave communications in a vehicular network setting. For channel estimation, we propose an algorithm termed robust adaptive multi-feedback (RAF) that achieves comparable estimation performance as existing channel estimation algorithms, with a significantly smaller number of feedback bits. We derive upper and lower bounds on the probability of estimation error (PEE) of the RAF algorithm, given a number of channel estimations, whose accuracy is verified through Monte Carlo simulations. For beam tracking, we propose a new practical model for mmWave vehicular communications. In contrast to the prior works, the model is based on position, velocity, and channel coefficient, which allows a significant improvement of the tracking performance. Focused on the new beam tracking model, we re-derive the equations for Jacobian matrices, reducing the complexity for vehicular communications. An extensive number of simulations is conducted to show the superiority of our proposed channel estimation method and beam tracking algorithm in comparison with the existing algorithms and models. Our simulations suggest that the RAF algorithm can achieve the desired PEE, while on average, reducing the feedback overhead by 75.5% and the total channel estimation time by 14%. The beam tracking algorithm is also shown to significantly improve beam tracking performance, allowing more room for data transmission.
Highlights
Millimeter wave1 wireless communications is one of the primary candidates proposed to cater for the high data traffic demand of 5G mobile network [2], [3]
SIMULATION CONFIGURATIONS In simulations, the number of antennas at both the TX and RX is set to be 64, with λ/2 spacing, the channel coefficient is assumed to follow a Gaussian distribution with zero mean and unit covariance, i.e., CN (0, 1), and the initial angle of departure (AoD) and angle of arrival (AoA) are set to −135 and 45 degrees
Note that the probability of estimation error (PEE) performance of both robust adaptive multi-feedback (RAF) and RACE algorithms are over the PEE threshold in low signal-to-noise ratio (SNR)
Summary
Millimeter wave wireless communications is one of the primary candidates proposed to cater for the high data traffic demand of 5G mobile network [2], [3]. The mmWave spectrum is considered to be from 30 to 300 GHz, which enables high-rate data transmission. To regulate the use of mmWave, such as ECMA-387 [5], IEEE 802.15.3.c [6], and more importantly, IEEE 802.11ad [7], which is the first standard in the IEEE 802.11 family to support a mmWave band, i.e., 60 GHz band. Exploiting the high data rate of mmWave paves the way for a number of exciting applications, such as mmWave cellular systems, vehicle to vehicle (V2V) communications, and vehicle to infrastructure (V2I) communications.
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