On the Unambiguous Distance of Multi-Carrier Phase Ranging with Random Hopped Frequencie
Peng Liu, Wangdong Qi, Yue Zhang, and Li Wei

TL;DR
This paper investigates the unambiguous distance in multi-carrier phase ranging systems with random frequency hopping, proposing a reliable upper bound metric that accurately reflects the measurable distance despite phase noise.
Contribution
It introduces a method to determine a deterministic upper bound for the unambiguous distance in random frequency hopping MPR systems, improving measurement reliability.
Findings
The probability of the UD reaching its upper bound approaches 1 with more than a dozen carriers.
The upper bound metric remains reliable even with phase noise.
Traditional linearly spaced frequency systems have a smaller practical range due to phase error sensitivity.
Abstract
In a multi-carrier phase ranging (MPR) system, the distance that radio signal travels is estimated through phase shift of multiple carrier frequencies. Due to phase ambiguity, a unique estimation can only be obtained within the unambiguous distance (UD), which depends on the carrier frequencies used for ranging. Without external information, the maximum measurable distance of an MPR system is defined by its UD. The MPR system employing random frequency hopping (FH) waveform has a strong anti-jamming capability and sees promising potentials in many fields. However, it is challenging to depict its measurable distance. Different from current MPR system employing deterministic frequencies, the carrier frequency under the FH waveform hops randomly within the occupied bandwidth. Consequently, the UD is a random variable. In this paper, we try to find a deterministic value to depict the UD of…
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Taxonomy
TopicsRadar Systems and Signal Processing · Cognitive Radio Networks and Spectrum Sensing · Indoor and Outdoor Localization Technologies
