Abstract: A method and system are directed to calibrating a radio frequency identification (RFID) printer, the method comprising retrieving frequency hopping capability from an RFID module coupled to the RFID printer, performing a plurality of calibration read and write operations to the calibration RFID label at a plurality of given positions using the RFID module based on a plurality of combinations comprising one or more field strengths, one or more sets of EPCC1G2 standard-based RFID parameters, and the frequency hopping capability, determining best one or more of a plurality of results associated with the plurality of calibration read and write operations, determining a tag antenna orientation of the calibration RFID label based on the plurality of results, and storing one or more optimal configuration settings in printer firmware of the RFID printer based on the tag orientation and the best one or more of the plurality of results.

Abstract: An example system is provided. In some embodiments, the system may include a coupler. In some embodiments, the coupler may include a first ground layer. In some embodiments, the coupler may include a conductive layer. In some embodiments, the conductive layer is substantially infinite shaped. In some embodiments, the coupler may include a first dielectric layer positioned between the first ground layer and the conductive layer. In some embodiments, the coupler may include a second ground layer having an aperture. In some embodiments, the coupler may include a second dielectric layer positioned between the conductive layer and the second ground layer. In some embodiments, the system may include a feed path configured to transport a plurality of radio frequency identification transponders through a defined region proximate the coupler. In some embodiments, the system may include a controller.

Abstract: A radio frequency identification (RFID) tag comprising a tag integrated circuit (IC), an antenna coupled to the tag IC, and an impedance tuned circuit coupled to the antenna, wherein the impedance tuned circuit configured to tune a circuit impedance of the antenna based on power received by the impedance tuned circuit. The RFID tag further comprises a piezo electric energy harvesting module coupled to the impedance tuned circuit, wherein the piezo electric energy harvesting module is configured to supply the power to the impedance tuned circuit.

Abstract: A radio frequency identification (RFID) antenna is provided. The RFID antenna includes, but not limited to, a printed circuit board (PCB). The PCB includes, but not limited to: a substrate; an etched metal layer on the substrate, where the etched metal layer comprises: a radiating element positioned on the substrate having a loop structure, where the loop structure comprises two first chamfered edges, and the first chamfered edges are position in opposing corners of the loop structure; and a ground element positioned on the substrate having comprising a slotted structure that is concentric with the loop structure and is positioned in an inner region of the loop structure.

Abstract: A method and system are directed to identifying, locating, and track locations of assets and actors within a local environment. The system comprises a millimeter wave (mmWave) antenna circuit coupled to a beam steering antenna (BSA). The mmWave antenna circuit comprises an mmWave processing unit (MPU) coupled to an RFID integrated circuit. An RFID reader may be configured to scan and locate RFID tags attached to assets within particular zones/beams of the local environment by communicating with the RFID integrated circuit. The MPU is configured to scan for actors in the particular zones/beams, generate a point cloud to determine actor positions within the point cloud, and communicate point cloud position data to the RFID integrated circuit.

Abstract: Various embodiments illustrated herein disclose a radio-frequency identification (RFID) reader having a first RFID tag having a first antenna element operating at a first transmit power. The first RFID tag receives, in a first time interval, a first interrogation command from a first RFID reader through the first antenna element. The first RFID tag transmits, in the first time interval, a first response signal to the first RFID reader. The RFID reader comprises a second antenna element that operates at a second transmit power and a processor communicatively coupled to the second antenna element. The processor transmits, in the first time interval, a second interrogation command to one or more second RFID tags through the second antenna element. The first RFID tag transmits, in a second time interval, a third interrogation command to a first RFID tag of a second RFID reader through the first antenna element.

Abstract: Method, apparatuses, and computer program products for automatically configuring one or more rotation angles for one or more associated locator units. An example method comprising receiving, from the one or more locator units, one or more dimensional values pertaining to the orientation of the one or more locator units; determining, based at least in part on the one or more received dimensional values for each of the one or more locator units and a configuration table pertaining to the locator unit type, one or more rotation angles for each of the one or more locator units; storing the one or more rotation angles for the each of the one or more locator units in an associated memory; and determining a location for one or more objects in an environment based at least upon the one or more rotation angles for each of the one or more locator units.

Abstract: A repeating switch antenna comprising a transmission signal amplifier configured to amplify a transmission signal based on a power control signal, a first coupler configured to receive (i) the amplified transmission signal, (ii) a reception signal, and (iii) a load impedance, a noise cancelation circuit configured to generate the load impedance based on an in-phase channel input and a quadrature channel input, a digital acquisition system configured to (i) generate the power control signal, (ii) generate the in-phase channel input and the quadrature channel input, and (iii) generate a select signal, reception signal amplifier configured to receive the reception signal from the first coupler and amplify the reception signal, and a radio frequency (RF) switch configured to (i) route the amplified transmission signal from the first coupler to the RF connector or to an antenna based on the select signal, and (ii) route the reception signal to the first coupler.

Abstract: Methods, apparatuses and systems for an RFID system are disclosed herein. An example system may include one or more of antennas, each antenna including an RF power comparator for comparing the power level indicator of the RF signal of the antenna with an RF signal power threshold, a bias voltage comparator for comparing a bias voltage of the antenna with a bias voltage threshold, an RF fault bypass circuit functioning as an approximate open circuit when the bias voltage of the antenna is equal to or higher than the bias voltage threshold, and as an approximate short circuit when the bias voltage of the antenna is lower than the bias voltage threshold. The RFID system may include an RFID reading circuitry for determining a fault in the RFID system using any of the RF power comparison, bias voltage comparison, and function of the RF fault bypass circuit.

Abstract: Various embodiments illustrated herein disclose a radio-frequency identification (RFID) reader having a first RFID tag having a first antenna element operating at a first transmit power. The first RFID tag receives, in a first time interval, a first interrogation command from a first RFID reader through the first antenna element. The first RFID tag transmits, in the first time interval, a first response signal to the first RFID reader. The RFID reader comprises a second antenna element that operates at a second transmit power and a processor communicatively coupled to the second antenna element. The processor transmits, in the first time interval, a second interrogation command to one or more second RFID tags through the second antenna element. The first RFID tag transmits, in a second time interval, a third interrogation command to a first RFID tag of a second RFID reader through the first antenna element.

Abstract: Various embodiments illustrated herein disclose a radio-frequency identification (RFID) reader having a first RFID tag having a first antenna element operating at a first transmit power. The first RFID tag receives, in a first time interval, a first interrogation command from a first RFID reader through the first antenna element. The first RFID tag transmits, in the first time interval, a first response signal to the first RFID reader. The RFID reader comprises a second antenna element that operates at a second transmit power and a processor communicatively coupled to the second antenna element. The processor transmits, in the first time interval, a second interrogation command to one or more second RFID tags through the second antenna element. The first RFID tag transmits, in a second time interval, a third interrogation command to a first RFID tag of a second RFID reader through the first antenna element.

Abstract: Method, apparatuses, and computer program products for automatically configuring one or more rotation angles for one or more associated locator units. An example method comprising receiving, from the one or more locator units, one or more dimensional values pertaining to the orientation of the one or more locator units; determining, based at least in part on the one or more received dimensional values for each of the one or more locator units and a configuration table pertaining to the locator unit type, one or more rotation angles for each of the one or more locator units; storing the one or more rotation angles for the each of the one or more locator units in an associated memory; and determining a location for one or more objects in an environment based at least upon the one or more rotation angles for each of the one or more locator units.

Abstract: Method, apparatuses, and computer program products for automatically configuring one or more rotation angles for one or more associated locator units. An example method comprising receiving, from the one or more locator units, one or more dimensional values pertaining to the orientation of the one or more locator units; determining, based at least in part on the one or more received dimensional values for each of the one or more locator units and a configuration table pertaining to the locator unit type, one or more rotation angles for each of the one or more locator units; storing the one or more rotation angles for the each of the one or more locator units in an associated memory; and determining a location for one or more objects in an environment based at least upon the one or more rotation angles for each of the one or more locator units.

Abstract: Apparatuses, methods and systems for unlocking a tracking apparatus that is affixed to an asset are disclosed herein. In one example, a method of unlocking a tracking apparatus that is affixed to an asset is provided. The tracking apparatus may comprise an electronic tag electronically coupled to a securing component comprising an actuating element. The method may comprise: receiving asset information associated with the tracking apparatus; generating and storing a secure machine-readable code in conjunction with the asset information; in response to receiving a request to unlock the tracking apparatus, determining whether a received input corresponds with the stored secure machine-readable code; and providing an indication to cause an electronic reader in electronic communication with the tracking apparatus to trigger deactivating the actuating element.

Abstract: Various embodiments illustrated herein disclose a method. The method includes receiving, by a first radio-frequency identification (RFID) tag in an RFID reader, a first interrogation command from another RFID reader. The method includes transmitting, by the first RFID tag in the RFID reader, a first response signal to the other RFID reader in response to the reception of the first interrogation command. The method further includes transmitting, by a processor in the RFID reader, a second interrogation command to one or more second RFID tags, where the transmission of the second interrogation command is concurrent to the reception of the first interrogation command or the transmission of the first response signal.

Abstract: Apparatuses, methods and systems for unlocking a tracking apparatus that is affixed to an asset are disclosed herein. In one example, a method of unlocking a tracking apparatus that is affixed to an asset is provided. The tracking apparatus may comprise an electronic tag electronically coupled to a securing component comprising an actuating element. The method may comprise: receiving asset information associated with the tracking apparatus; generating and storing a secure machine-readable code in conjunction with the asset information; in response to receiving a request to unlock the tracking apparatus, determining whether a received input corresponds with the stored secure machine-readable code; and providing an indication to cause an electronic reader in electronic communication with the tracking apparatus to trigger deactivating the actuating element.

Abstract: Embodiments are generally directed to wireless parallel scanning apparatus(es) and process(es) with reduced time to identify a location associated with a data identifier from a plurality of possible locations. Embodiments perform and process the results of various wireless (e.g., RFID) scans via antenna chains, the wireless scans performed in parallel and scan data representing the results of the wireless scans received in parallel. Some embodiments include a single multi-core processor, the multi-core processor including multiple cores that each independently (1) activate a wireless scanning chain including a transceiver communicable with a switch, the switch associated with controlling a signal transmitted to one of a plurality of antenna chains, and (2) receive scan data received via the wireless scanning chain. Some embodiments include the single multi-core processor including a core that aggregates the scan data from other cores and identifies a location identifier for a target data identifier.

Abstract: Method, apparatuses, and computer program products for automatically configuring one or more rotation angles for one or more associated locator units. An example method comprising receiving, from the one or more locator units, one or more dimensional values pertaining to the orientation of the one or more locator units; determining, based at least in part on the one or more received dimensional values for each of the one or more locator units and a configuration table pertaining to the locator unit type, one or more rotation angles for each of the one or more locator units; storing the one or more rotation angles for the each of the one or more locator units in an associated memory; and determining a location for one or more objects in an environment based at least upon the one or more rotation angles for each of the one or more locator units.

Abstract: Apparatuses, methods and systems for unlocking a tracking apparatus that is affixed to an asset are disclosed herein. In one example, a method of unlocking a tracking apparatus that is affixed to an asset is provided. The tracking apparatus may comprise an electronic tag electronically coupled to a securing component comprising an actuating element. The method may comprise: receiving asset information associated with the tracking apparatus; generating and storing a secure machine-readable code in conjunction with the asset information; in response to receiving a request to unlock the tracking apparatus, determining whether a received input corresponds with the stored secure machine-readable code; and providing an indication to cause an electronic reader in electronic communication with the tracking apparatus to trigger deactivating the actuating element.

Abstract: Various embodiments illustrated herein disclose a radio-frequency identification (RFID) reader having a first RFID tag having a first antenna element operating at a first transmit power. The first RFID tag receives, in a first time interval, a first interrogation command from a first RFID reader through the first antenna element. The first RFID tag transmits, in the first time interval, a first response signal to the first RFID reader. The RFID reader comprises a second antenna element that operates at a second transmit power and a processor communicatively coupled to the second antenna element. The processor transmits, in the first time interval, a second interrogation command to one or more second RFID tags through the second antenna element. The first RFID tag transmits, in a second time interval, a third interrogation command to a first RFID tag of a second RFID reader through the first antenna element.