efficient physical-layer unknown tag identification in large-scale rfid systems

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Radio frequency identification (RFID) is an automatic identification technology that brings a revolutionary change to quickly identify tagged objects from the cunknown tags is of paramount importance, especially in large-scale RFID systems. Existing solutions can either identify all unknown tags with low time-efficiency, or identify most unknown . We exploit the physical signals in collision slots to separate unknown tags from known tags, a new technique to speed up the ID collection.This paper exploits the physical signals in collision slots to separate unknown tags from known tags, a new technique to speed up the ID collection, and proposes a protocol that utilizes .

o detect unknown tags brought by new tagged items, misplacement, or counterfeit tags. While unknown tag identification is able to pinpoint all the unknown tags, probabilistic unknown tag . While unknown tag identification is able to pinpoint all the unknown tags, probabilistic unknown tag detection is preferred in large-scale RFID systems that need to be . One of the most important applications of Radio Frequency Identification (RFID) technology is to detect unknown tags brought by new tagged items moved in, misplacement, . In this paper, for high dynamic RFID systems, we propose an efficiently and accurately protocol HDMI to identify missing tags. By combining the reply slot location of the .

To fill in this gap, two filtering-based protocols (at the bit level) are proposed in this paper to address the problem of unknown tag identification efficiently. Theoretical analysis of . This paper exploits the physical signals in collision slots to separate unknown tags from known tags, a new technique to speed up the ID collection, and proposes a protocol that .Radio frequency identification (RFID) is an automatic identification technology that brings a revolutionary change to quickly identify tagged objects from the cunknown tags is of paramount importance, especially in large-scale RFID systems. Existing solutions can either identify all unknown tags with low time-efficiency, or identify most unknown tags quickly by sacrificing the identification accuracy. Unlike existing work, this paper proposes a protocol that utilizes physical la.

We exploit the physical signals in collision slots to separate unknown tags from known tags, a new technique to speed up the ID collection.This paper exploits the physical signals in collision slots to separate unknown tags from known tags, a new technique to speed up the ID collection, and proposes a protocol that utilizes physical layer (PHY) information to identify the intact unknown tag set with high efficiency.

o detect unknown tags brought by new tagged items, misplacement, or counterfeit tags. While unknown tag identification is able to pinpoint all the unknown tags, probabilistic unknown tag detection is preferred in large-scale RFI systems that need to be frequently checked up, e.g., real-time inventory monito While unknown tag identification is able to pinpoint all the unknown tags, probabilistic unknown tag detection is preferred in large-scale RFID systems that need to be frequently checked up, e.g., real-time inventory monitoring. One of the most important applications of Radio Frequency Identification (RFID) technology is to detect unknown tags brought by new tagged items moved in, misplacement, or counterfeit tags. In this paper, for high dynamic RFID systems, we propose an efficiently and accurately protocol HDMI to identify missing tags. By combining the reply slot location of the tags and the reply bits, HDMI identifies missing tags and filters the unknown tags simultaneously, which maximizes the slot utilization.

To fill in this gap, two filtering-based protocols (at the bit level) are proposed in this paper to address the problem of unknown tag identification efficiently. Theoretical analysis of the protocol parameters is performed to minimize the execution time of the proposed protocols. This paper exploits the physical signals in collision slots to separate unknown tags from known tags, a new technique to speed up the ID collection, and proposes a protocol that utilizes physical layer (PHY) information to identify the intact unknown tag set with high efficiency.Radio frequency identification (RFID) is an automatic identification technology that brings a revolutionary change to quickly identify tagged objects from the c

unknown tags is of paramount importance, especially in large-scale RFID systems. Existing solutions can either identify all unknown tags with low time-efficiency, or identify most unknown tags quickly by sacrificing the identification accuracy. Unlike existing work, this paper proposes a protocol that utilizes physical la. We exploit the physical signals in collision slots to separate unknown tags from known tags, a new technique to speed up the ID collection.This paper exploits the physical signals in collision slots to separate unknown tags from known tags, a new technique to speed up the ID collection, and proposes a protocol that utilizes physical layer (PHY) information to identify the intact unknown tag set with high efficiency.

o detect unknown tags brought by new tagged items, misplacement, or counterfeit tags. While unknown tag identification is able to pinpoint all the unknown tags, probabilistic unknown tag detection is preferred in large-scale RFI systems that need to be frequently checked up, e.g., real-time inventory monito While unknown tag identification is able to pinpoint all the unknown tags, probabilistic unknown tag detection is preferred in large-scale RFID systems that need to be frequently checked up, e.g., real-time inventory monitoring. One of the most important applications of Radio Frequency Identification (RFID) technology is to detect unknown tags brought by new tagged items moved in, misplacement, or counterfeit tags. In this paper, for high dynamic RFID systems, we propose an efficiently and accurately protocol HDMI to identify missing tags. By combining the reply slot location of the tags and the reply bits, HDMI identifies missing tags and filters the unknown tags simultaneously, which maximizes the slot utilization.

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To fill in this gap, two filtering-based protocols (at the bit level) are proposed in this paper to address the problem of unknown tag identification efficiently. Theoretical analysis of the protocol parameters is performed to minimize the execution time of the proposed protocols.

Efficient Unknown Tag Detection in Large

Efficient and accurate identification of missing tags for large

Efficient Unknown Tag Identification Protocols in Large

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efficient physical-layer unknown tag identification in large-scale rfid systems|Efficient and accurate identification of missing tags for large

efficient physical-layer unknown tag identification in large-scale rfid systems|Efficient and accurate identification of missing tags for large.

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