Radio frequency identification reader antenna having a dynamically adjustable Q-factor
First Claim
1. A reader circuit for a radio frequency identification (RFID) reader having a dynamically adjustable Q-factor, wherein the reader transmits an activation signal configured to activate half duplex and full duplex transponders, the reader circuit comprising:
- a signal source configured to drive a resonant antenna; and
a dynamic switching circuit configured to set the Q-factor of the resonant antenna to a first value during the transmission of the activation signal;
wherein the resonant antenna is a multi-filar antenna comprising a primary filar and a set of secondary filars and a resistor is connected in series with at least one of the filars in the multi-filar antenna;
wherein the dynamic switching circuit is configured to set the Q-factor of the resonant antenna to a second value below the first value during detection of a data signal from a full duplex transponder;
wherein the dynamic switching circuit is configured to set the Q-factor of the resonant antenna to a third value below the second value when the RFID reader is not transmitting the activation signal; and
wherein the dynamic switching circuit is configured to control the Q-factor of the multi-filar resonant antenna by controlling the filars that are incorporated into the resonant antenna circuit by;
setting the Q-factor of the resonant antenna at a first value during the transmission of an activation signal comprises incorporating at least two of the filars into the resonant antenna circuit so that the resistor is not incorporated within the resonant antenna circuit;
decreasing the Q-factor of the resonant antenna during receipt of a data signal from any full duplex transponders present and during the transmission of the activation signal comprises incorporating a primary filar into the resonant antenna circuit so that the resistor is not incorporated in the resonant antenna circuit; and
decreasing the Q-factor of the resonant antenna upon stopping the transmission of the activation signal comprises incorporating the primary filar and the resistor into the resonant antenna circuit.
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Accused Products
Abstract
Turning now to the drawings, systems and methods for reading RFID transponders utilizing readers in which the Q-factor of the resonant antenna of the reader shifts over the course of the reader'"'"'s interrogation cycle in response to the detection of data from FDX and HDX RFID transponders in accordance with embodiments of the invention are illustrated. One embodiment having a dynamically adjustable Q-factor, wherein the reader transmits an activation signal configured to activate half duplex and full duplex transponders includes a signal source configured to drive a resonant antenna and a dynamic switching circuit configured to set the Q-factor of the resonant antenna to a first value during the transmission of the activation signal. In addition, the dynamic switching circuit is configured to set the Q-factor of the resonant antenna to a second value below the first value during and/or in response to detection of a data signal from a full duplex transponder, the dynamic switching circuit is also configured to set the Q-factor of the resonant antenna to a third value below the second value when the RFID reader is not transmitting the activation signal, and the resonant antenna is multi-filar and the dynamic switching circuit is configured to control the Q-factor of the multi-filar resonant antenna by controlling the filars that are incorporated into the resonant antenna circuit.
68 Citations
19 Claims
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1. A reader circuit for a radio frequency identification (RFID) reader having a dynamically adjustable Q-factor, wherein the reader transmits an activation signal configured to activate half duplex and full duplex transponders, the reader circuit comprising:
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a signal source configured to drive a resonant antenna; and a dynamic switching circuit configured to set the Q-factor of the resonant antenna to a first value during the transmission of the activation signal; wherein the resonant antenna is a multi-filar antenna comprising a primary filar and a set of secondary filars and a resistor is connected in series with at least one of the filars in the multi-filar antenna; wherein the dynamic switching circuit is configured to set the Q-factor of the resonant antenna to a second value below the first value during detection of a data signal from a full duplex transponder; wherein the dynamic switching circuit is configured to set the Q-factor of the resonant antenna to a third value below the second value when the RFID reader is not transmitting the activation signal; and wherein the dynamic switching circuit is configured to control the Q-factor of the multi-filar resonant antenna by controlling the filars that are incorporated into the resonant antenna circuit by; setting the Q-factor of the resonant antenna at a first value during the transmission of an activation signal comprises incorporating at least two of the filars into the resonant antenna circuit so that the resistor is not incorporated within the resonant antenna circuit; decreasing the Q-factor of the resonant antenna during receipt of a data signal from any full duplex transponders present and during the transmission of the activation signal comprises incorporating a primary filar into the resonant antenna circuit so that the resistor is not incorporated in the resonant antenna circuit; and decreasing the Q-factor of the resonant antenna upon stopping the transmission of the activation signal comprises incorporating the primary filar and the resistor into the resonant antenna circuit. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
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10. A process for interrogating full duplex transponders using a radio frequency identification (RFID) reader having a resonant circuit with a dynamically adjustable Q-factor, comprising:
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setting the Q-factor of a resonant antenna at a first value during the transmission of an activation signal, wherein; the resonant circuit comprises a resonant antenna and the resonant antenna is a multi-filar antenna comprising a primary filar and a set of secondary filars and a resistor is connected in series with at least one of the filars in the multi-filar antenna; and setting the Q-factor of the resonant antenna at a first value during the transmission of an activation signal comprises incorporating at least two filars in the multi-filar antenna into the resonant antenna circuit so that the resistor is not incorporated within the resonant antenna circuit; decreasing the Q-factor of the resonant antenna during receipt of a data signal from any full duplex transponders present during the transmission of the activation signal by incorporating the primary filar into the resonant antenna so that the resistor is not incorporated in the resonant antenna; increasing the Q-factor of the resonant antenna to the first value during the remainder of the transmission of the activation signal; capturing data from the received data signal; and decreasing the Q-factor of the resonant antenna upon stopping the transmission of the activation signal by incorporating the primary filar and the resistor into the resonant antenna circuit. - View Dependent Claims (11, 12, 13, 14, 15, 16, 17, 18, 19)
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Specification
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- Resources
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Current AssigneeAllflex Australia Pty. Ltd. (Merck & Co., Inc.)
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Original AssigneeAleis Pty. Ltd. (Merck & Co., Inc.)
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InventorsBateman, Leigh
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Primary Examiner(s)Ghayour, Mohammad
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Assistant Examiner(s)RUSHING, MARK S
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Application NumberUS12/901,952Publication NumberTime in Patent Office1,016 DaysField of Search340/572, 340/10, 343/745US Class Current340/10.1CPC Class CodesG06K 7/0008 General problems related to...G06K 7/10198 setting parameters for the ...G06K 7/10316 using at least one antenna ...
