Abstract
Millimeter-wave channel sounders are much more sensitive to phase drift than their microwave counterparts by virtue of shorter wavelength. This matters when coherently combining untethered channel measurements - scanned over multiple antennas either electronically or mechanically in seconds, minutes, or even hours - to obtain directional information. To eliminate phase drift, a synchronization cable between the transmitter and receiver is required, limiting deployment range and flexibility indoors, and precluding most outdoor and mobile scenarios. Instead, we propose a blind technique to calibrate for phase drift by post-processing the channel measurements; the technique is referred to as blind because it requires no reference signal and, as such, works even in non-line-of-sight conditions when the (reference) direct path goes undetected. To substantiate the technique, it was tested on real measurements collected with our 60 GHz virtual phased-array channel sounder, as well as through simulation. The technique was demonstrated robust enough to deal with the most severe case of phase drift (uniformly distributed phase) and in non-line-of-sight conditions.
Highlights
The design and deployment of fifth-generation (5G) communication networks, based on millimeter-wave technology, are currently underway
The verification is conducted through two means: The first is based on real measurements collected in both LoS and non LoS (NLoS) conditions; the second is based on simulations in even harsher channel conditions: in lower signal-to-noise ratio (SNR) and with uniformly distributed phase drift, the worst possible case
Phase drift is inherent to radio-frequency channel sounders that operate in untethered mode, due to separate transmitter and receiver clocks
Summary
The design and deployment of fifth-generation (5G) communication networks, based on millimeter-wave (mmWave) technology, are currently underway. J. Chuang et al.: Blind Calibration of Phase Drift in Millimeter-Wave Channel Sounders spherical (in azimuth and elevation), and whether the scan is double-directional [22] (both at the transmitter (T) and receiver (R)). In our paper we propose a blind calibration technique for phase drift in mmWave channel sounders that mitigates against hardware tolerances, phase noise, and temperature variation. The proposed technique was verified against severe phase drift, through real measurements with our 60 GHz virtual phased-array channel sounder in NLoS conditions and over a scan duration of an hour, as well as through simulations with the worst case of phase drift (uniformly distributed) and in low signal-to-noise ratio (SNR) conditions.
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