RFID tags for enabling batch reading of stacks of cartons
First Claim
1. A radio-frequency identification (RFID) tag for use with a reader that generates activation energy, the RFID tag comprising:
- an RFID circuit for modulating tag energy when activation energy is received and for modulating tag energy when tag energy is received from another RFID tag;
a first antenna configured to receive and provide activation energy to the RFID circuit and radiate modulated tag energy received from the RFID circuit;
a second antenna configured to radiate activation energy received by the first antenna and receive and provide tag energy radiated by antenna from another RFID tag to the RFID circuit;
a transmission line for operatively coupling the RFID circuit to the first and second antennas;
whereby when a plurality of the RFID tags are positioned in sequence in operative proximity with each other, activation energy is propagated through the sequence from one RFID tag to another in one direction, and tag energy is propagated through the sequence from one RFID tag to another in another direction;
wherein the RFID circuit comprises an RFID chip having a variable input impedance, the variable input impedance including a first state in which the RFID chip absorbs energy from the transmission line, a second state in which energy from the transmission line is reflected back, and a third state in which the amount of energy absorbed by the RF chip is minimized, thereby maximizing the amount of energy passed on to a next RFID tag.
1 Assignment
0 Petitions
Accused Products
Abstract
A radio-frequency identification (RFID) system including an RFID tag and an RFID-enabled object. The RFID tag may include a pair of antennas and an RFID circuit. The antennas receive activation energy from a reader, and the RFID circuit modulates tag energy when activation energy is received by one of the antennas. The tag may also include a transmission line for operatively coupling the RFID circuit to the antennas. A first one of the antennas may receive activation energy which, in turn, may be radiated by a second one of the antennas. The second antenna may also receive tag energy radiated by an antenna of another RFID tag. The received tag energy may then be radiated by the first antenna. Accordingly, when a plurality of the RFID tags are positioned in sequence in operative proximity with each other, activation energy may be propagated through the sequence from one RFID tag to another in one direction, and tag energy may be propagated through the sequence from one RFID tag to another in another direction.
36 Citations
22 Claims
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1. A radio-frequency identification (RFID) tag for use with a reader that generates activation energy, the RFID tag comprising:
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an RFID circuit for modulating tag energy when activation energy is received and for modulating tag energy when tag energy is received from another RFID tag; a first antenna configured to receive and provide activation energy to the RFID circuit and radiate modulated tag energy received from the RFID circuit; a second antenna configured to radiate activation energy received by the first antenna and receive and provide tag energy radiated by antenna from another RFID tag to the RFID circuit; a transmission line for operatively coupling the RFID circuit to the first and second antennas; whereby when a plurality of the RFID tags are positioned in sequence in operative proximity with each other, activation energy is propagated through the sequence from one RFID tag to another in one direction, and tag energy is propagated through the sequence from one RFID tag to another in another direction; wherein the RFID circuit comprises an RFID chip having a variable input impedance, the variable input impedance including a first state in which the RFID chip absorbs energy from the transmission line, a second state in which energy from the transmission line is reflected back, and a third state in which the amount of energy absorbed by the RF chip is minimized, thereby maximizing the amount of energy passed on to a next RFID tag. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19)
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20. A radio-frequency identification (RFID)-enabled object for use with a reader, the RFID-enabled object comprising:
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an object having a top, a bottom, and four sides each having four edges; and
an RFID tag including;a first antenna disposed at or near one of the edges of one of the sides of the object; a second antenna disposed at or near another one of the edges of the one of the sides of the object, the first and second antenna being mounted to the one of the sides of the object; a transmission line electrically coupled to the first antenna and the second antenna; and an RFID circuit electrically coupled to the transmission line for communicating with the reader when activated by energy from the reader system, wherein the RFID circuit comprises an RFID chip having a variable input impedance, the variable input impedance including a first state in which the RFID chip absorbs energy from the transmission line, a second state in which energy from the transmission line is reflected back, and a third state in which the amount of energy absorbed by the RF chip is minimized, thereby maximizing the amount of energy passed on to a next RFID-enabled object; the object being stackable with another RFID-enabled object such that either one of the first and the second antennas is positioned within communicative proximity with an antenna of the other RFID-enabled object.
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21. A method of reading radio-frequency identification (RFID)-enabled objects, the method comprising:
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providing a load of a plurality of RFID-enabled objects stacked together, each of the objects including; an object having a top, a bottom, and four sides each having four edges; and a RFID tag including; a first antenna disposed at or near one of the edges of one of the sides of the object; a second antenna disposed at or near another one of the edges of one of the sides of the object; a transmission line electrically coupled to the first antenna and the second antenna; an RFID circuit electrically coupled to the transmission line for communicating with the reader when activated by energy from the reader system; the objects being stacked with one another such that the RFID tags are positioned sequentially in operative proximity with one another; transmitting activation energy to the load; sequentially propagating activation energy from one RFID tag to another; and sequentially modulating tag energy from one RFID tag to another by a corresponding RFID circuit; wherein the RFID circuit comprises an RFID chip having a variable input impedance, the variable input impedance including a first state in which the RFID chip absorbs energy from the transmission line, a second state in which energy from the transmission line is reflected back, and a third state in which the amount of energy absorbed by the RF chip is minimized, thereby maximizing the amount of energy passed on to a next RFID tag. - View Dependent Claims (22)
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Specification