System and method for wireless communications
First Claim
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1. An object localization system comprised of backscattering tags attached to objects moving along a known unidirectional path and interrogators, wherein each of said interrogators comprises:
- an antenna system to transmit and receive radio frequency (RF) signals to and from said backscattering tags;
a transmitter and a receiver using homodyne down-conversion;
a localization processor for providing tag position information, wherein said localization processor estimates the position of one of said backscattering tags based on phase measurement and comprises;
i) a phase detector;
ii) a power detector;
iii) a phase gradient null estimator; and
iv) a position estimator,wherein one of said interrogators receives one of said RF signals backscattered by one of said backscattering tags with a single antenna, and wherein said phase gradient null estimator estimates location of the zero phase gradient of the tag backscattered signal by performing the following algorithm;
first, local phase jumps are found from raw data and obvious outliers are detected;
then local instantaneous power relative to mean power around phase peaks is used to identify and filter the local phase jumps to smooth out phase trajectory and further improve gradient zero crossing detection and consequently locate the position of the one of said backscattering tags.
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Abstract
A method of detecting position of a moving RFID tag relative to an antenna, includes continually receiving a signal from the RFID tag at the antenna. The phase of the received signal over a time period is detected and, based on a maximum detected phase, the position of the RFID tag relative to the antenna is detected.
18 Citations
15 Claims
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1. An object localization system comprised of backscattering tags attached to objects moving along a known unidirectional path and interrogators, wherein each of said interrogators comprises:
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an antenna system to transmit and receive radio frequency (RF) signals to and from said backscattering tags; a transmitter and a receiver using homodyne down-conversion; a localization processor for providing tag position information, wherein said localization processor estimates the position of one of said backscattering tags based on phase measurement and comprises; i) a phase detector; ii) a power detector; iii) a phase gradient null estimator; and iv) a position estimator, wherein one of said interrogators receives one of said RF signals backscattered by one of said backscattering tags with a single antenna, and wherein said phase gradient null estimator estimates location of the zero phase gradient of the tag backscattered signal by performing the following algorithm;
first, local phase jumps are found from raw data and obvious outliers are detected;
then local instantaneous power relative to mean power around phase peaks is used to identify and filter the local phase jumps to smooth out phase trajectory and further improve gradient zero crossing detection and consequently locate the position of the one of said backscattering tags. - View Dependent Claims (2, 3, 4, 5, 6, 7)
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8. An object localization system comprising:
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at least one backscattering tag attached to an object moving along a known unidirectional path; and at least one interrogator comprising; an antenna system to transmit and receive radiofrequency signals to and from said at least one backscattering tag; and a localization processor for providing position information of said at least one backscattering tag, said localization processor comprising a phase gradient null estimator for estimating location of zero phase gradient, wherein said localization processor estimates the position of said at least one backscattering tag based on a phase measurement of at least one received signal from the at least one backscattering tag; and wherein said at least one interrogator receives at least one received signal backscattered by the at least one backscattering tag with a single antenna, and wherein said phase gradient null estimator is capable of estimating location of zero phase gradient of the at least one received signal by finding local phase jumps from raw data and detecting outliers and using local instantaneous power relative to mean power around phase peaks to identify and to filter the local phase jumps to smooth out phase trajectory and improve gradient zero crossing detection. - View Dependent Claims (9, 10, 11, 12, 13, 14, 15)
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Specification