Abstract: Methods, apparatus, systems, and articles of manufacture are disclosed for triggerable data driven location determination. An example apparatus is to cause transmission of a sounding reference signal (SRS) configuration to a radio access network (RAN), the SRS configuration for a target device in communication with a radio unit (RU) associated with the RAN. Additionally, the example apparatus is to cause transmission of a value to cause the RAN to compute at least one set of time-of-arrival (TOA) measurements or time-difference-of-arrival (TDOA) measurements for the target device based on detection of SRS data in cellular data received by antennas of the RU from the target device, the at least set one of the TOA measurements or the TDOA measurements based on the SRS configuration. The example apparatus is to estimate a location of the target device based on the at least one set of the TOA measurements or the TDOA measurements.

Abstract: Described herein is a technique that provides a first robot associated with a first trust domain to identify and authenticate a second robot associated with a second trust domain. The identification and authentication technique described herein is based on a robot processing a variety of input signals obtained via sensors, in order to generate robot identification information that can be compared with known or trusted information. Advantageously, the identification technique occurs locally, for example, at the robot and at the location of the robot-to-robot interaction, eliminating any requirement for communicating with an authoritative remote or cloud-based service, at the time and place of the robot-to-robot interaction.

Abstract: Various systems and methods for implementing end-to-end quality of service (QoS) for network communications are provided using various network and compute technologies. In an example, managing Quality of Service (QoS) for end-to-end network data flows, includes: identifying QoS characteristics for data flows of a user equipment (UE), for data flows performed via multiple access networks; mapping the QoS characteristics to network functions of at least one of the multiple access networks; and controlling the network functions of the at least one of the multiple access networks, based on the QoS characteristics, as the network functions are implemented at respective resources located within at least one of the multiple access networks. Further examples for controlling the network functions using Access Traffic Steering, Switching and Splitting (ATSSS) functionality in an 3GPP multi-access network, and configuring a network exposure function of an 3GPP multi-access network, are also disclosed.

Abstract: Systems, apparatus, articles of manufacture, and methods are disclosed. An example edge compute device disclosed herein includes interface circuitry, machine readable instructions, and programmable circuitry to execute the machine readable instructions to configure compute resources of the edge compute device based on a first resource demand associated with a first location of the edge compute device, detect a change in location of the edge compute device to a second location, and in response to detection of the change in location, reconfigure the compute resources of the edge compute device based on a second resource demand associated with the second location.

Abstract: Methods, apparatus, systems, and articles of manufacture are disclosed for triggerable data driven location determination. An example apparatus is to cause transmission of a sounding reference signal (SRS) configuration to a radio access network (RAN), the SRS configuration for a target device in communication with a radio unit (RU) associated with the RAN. Additionally, the example apparatus is to cause transmission of a value to cause the RAN to compute at least one set of time-of-arrival (TOA) measurements or time-difference-of-arrival (TDOA) measurements for the target device based on detection of SRS data in cellular data received by antennas of the RU from the target device, the at least set one of the TOA measurements or the TDOA measurements based on the SRS configuration. The example apparatus is to estimate a location of the target device based on the at least one set of the TOA measurements or the TDOA measurements.

Abstract: Described herein is a technique that provides a first robot associated with a first trust domain to identify and authenticate a second robot associated with a second trust domain. The identification and authentication technique described herein is based on a robot processing a variety of input signals obtained via sensors, in order to generate robot identification information that can be compared with known or trusted information. Advantageously, the identification technique occurs locally, for example, at the robot and at the location of the robot-to-robot interaction, eliminating any requirement for communicating with an authoritative remote or cloud-based service, at the time and place of the robot-to-robot interaction.

Abstract: Systems, apparatuses, and methods for autonomous sensor placement discovery for RFID systems are disclosed. Sensors are deployed in a brick and mortar store that can scan for and receive signals from a plurality of locating tags as well as RFID tags. The locating tags may transmit ultra-wideband signals in response to a scan to provide precise determination of the location of each locating tag relative to a detecting sensor. Each sensor may also include a locating tag to enable determining the location of each sensor. The location information from the locating tags is provided to a gateway, which can provide a display of the locations of sensors and locating tags in the brick and mortar store and areas of no coverage, as well as autonomously control various parameters of the sensors to minimize or eliminate some or all areas of no coverage.

Abstract: Systems, apparatuses, and methods for autonomous sensor placement discovery for RFID systems are disclosed. Sensors are deployed in a brick and mortar store that can scan for and receive signals from a plurality of locating tags as well as RFID tags. The locating tags may transmit ultra-wideband signals in response to a scan to provide precise determination of the location of each locating tag relative to a detecting sensor. Each sensor may also include a locating tag to enable determining the location of each sensor. The location information from the locating tags is provided to a gateway, which can provide a display of the locations of sensors and locating tags in the brick and mortar store and areas of no coverage, as well as autonomously control various parameters of the sensors to minimize or eliminate some or all areas of no coverage.

Abstract: An example apparatus to monitor a space is disclosed. The example apparatus includes a database to record a time when a first data signal is received from a first RFID tag of a plurality of RFID tags and record data contained in the first data signal from the first RFID tag. The example apparatus further includes one or more processors to attempt to match the first RFID tag to sales information based on the time and the data contained within the first data signal.

Abstract: Methods, systems, apparatus, and articles of manufacture are disclosed to improve radio frequency identification (RFID) tag communication. An example disclosed apparatus includes an RFID reader monitor to activate a first RFID reader and deactivate a second RFID reader during a first tag data acquisition at a first time, and deactivate the first RFID reader and activate the second RFID reader during a second tag data acquisition at a second time, a tag logger to identify a first set of RFID tags detected by the first RFID reader at the first time, and identify a second set of RFID tags detected by the second RFID reader at the second time, and a group generator to improve RFID tag communication by identifying which one of the first RFID reader and the second RFID reader communicates with a common RFID tag.

Abstract: A radio frequency identification (RFID) reader is disclosed that allows for selective deep scans of RFID tags. The RFID reader may include a motion detection sensor, a radio frequency transceiver configured to transmit RF energy at first and second frequencies, and a processor. The processor may perform the following steps: (1) when motion is detected by the sensor, commanding the transceiver to transmit RF energy at the first RFID profile; and (2) when motion has not been detect for a predetermined time period, commanding the transceiver to transmit RF energy at the second RFID profile. A method for using the RFID reader to perform selective deep scanning is also disclosed.

Abstract: A radio frequency identification (RFID) system for monitoring a space is disclosed. The system may include a controller connected with a plurality of RFID readers, where each reader can detect data signals from a plurality of RFID tags attached with objects. The objects may be part of an object category. The system may also have a database connected with the controller that records a time when the data signal is received from each tag in the plurality, and the data contained in the data signal from each tag in the plurality. The system may include a processor that can perform an inventory analysis of the objects based on a confidence probability curve. This curve may be a decaying function that may be based on various probabilities. Methods for using the confidence probability curve are also disclosed.

Abstract: Methods, systems, apparatus, and articles of manufacture are disclosed to improve radio frequency identification (RFID) tag communication. An example disclosed apparatus includes an RFID reader monitor to activate a first RFID reader and deactivate a second RFID reader during a first tag data acquisition at a first time, and deactivate the first RFID reader and activate the second RFID reader during a second tag data acquisition at a second time, a tag logger to identify a first set of RFID tags detected by the first RFID reader at the first time, and identify a second set of RFID tags detected by the second RFID reader at the second time, and a group generator to improve RFID tag communication by identifying which one of the first RFID reader and the second RFID reader communicates with a common RFID tag.

Abstract: A radio frequency identification (RFID) system for monitoring a space is disclosed. The system may include a controller connected with a plurality of RFID readers, where each reader can detect data signals from a plurality of RFID tags attached with objects. The objects may be part of an object category. The system may also have a database connected with the controller that records a time when the data signal is received from each tag in the plurality, and the data contained in the data signal from each tag in the plurality. The system may include a processor that can perform an inventory analysis of the objects based on a confidence probability curve. This curve may be a decaying function that may be based on various probabilities. Methods for using the confidence probability curve are also disclosed.

Abstract: A radio frequency identification (RFID) reader is disclosed that allows for selective deep scans of RFID tags. The RFID reader may include a motion detection sensor, a radio frequency transceiver configured to transmit RF energy at first and second frequencies, and a processor. The processor may perform the following steps: (1) when motion is detected by the sensor, commanding the transceiver to transmit RF energy at the first RFID profile; and (2) when motion has not been detect for a predetermined time period, commanding the transceiver to transmit RF energy at the second RFID profile. A method for using the RFID reader to perform selective deep scanning is also disclosed.

Abstract: An improved method is provided for disseminating information in an ad hoc wireless network. The method includes: receiving an incoming message at a recipient node of the network; scheduling a retransmission of the message, where the schedule time for the retransmission is proportional to a signal strength at which the message was received by the recipient node; and canceling the retransmission of the message when the same message is received from a different node in the network prior to the schedule time for the retransmission. The effect is reduced network traffic on the network with minimized latency.

Abstract: A wireless station and associated method is provided for communicating digital messages. A first transceiver tunes to a first radio frequency. A digital controller enables the first transceiver to transmit on the first radio frequency during intermittent periods of varying durations. The intermittent periods are separated by a fixed duration.