Abstract: A method performed within a user device includes receiving at least one response signal corresponding to a respective tag. The method includes, identifying a directional location of the respective tag relative to the user device. The method includes estimating a distance of the respective tag relative to the user device. The method includes correlating the directional location and distance of the respective tag to generate corresponding position information. The position information provides more precise point location of the object. The method includes outputting the corresponding position information to an electronic display.

Abstract: A method for operating a parking facility includes accessing a data structure comprising an array of cells defined by a plurality of columns and a plurality of rows, wherein one of the plurality of columns and the plurality of rows is time of entry and the other of the plurality of columns and the plurality of rows is duration of parking session, and each cell of the array of cells comprises a cost, and determining a parking session cost for an individual vehicle by summing costs in a plurality of cells of the array of cells corresponding to a time of entry and a parking session duration for the individual vehicle.

Abstract: A computing device includes a control system that communicates with multiple sensors that capture data regarding a user. The control system communicates with each of the sensors to obtain information regarding the capabilities of each sensor, and uses this capability information to determine how to configure each of the sensors. The control system also selects one of the multiple sensors to be the master sensor, and the rest of the multiple sensors are slave sensors, and notifies the multiple sensors of whether they are a slave sensor or a master sensor. The master sensor collects sensor data for the multiple sensors, capturing data itself as well as receiving data captured by the slave sensors from the slave sensors. The master sensor sends an indication of the collected data (e.g., the collected data itself or data resulting from processing the collected data) to the control system for analysis and/or processing.

Abstract: A method performed within a user device includes receiving at least one response signal corresponding to a respective tag. The method includes, identifying a directional location of the respective tag relative to the user device. The method includes estimating a distance of the respective tag relative to the user device. The method includes correlating the directional location and distance of the respective tag to generate corresponding position information. The position information provides more precise point location of the object. The method includes outputting the corresponding position information to an electronic display.

Abstract: A computing device includes a control system that communicates with multiple sensors that capture data regarding a user. The control system communicates with each of the sensors to obtain information regarding the capabilities of each sensor, and uses this capability information to determine how to configure each of the sensors. The control system also selects one of the multiple sensors to be the master sensor, and the rest of the multiple sensors are slave sensors, and notifies the multiple sensors of whether they are a slave sensor or a master sensor. The master sensor collects sensor data for the multiple sensors, capturing data itself as well as receiving data captured by the slave sensors from the slave sensors. The master sensor sends an indication of the collected data (e.g., the collected data itself or data resulting from processing the collected data) to the control system for analysis and/or processing.

Abstract: A method and data processing device for receiving at least one response signal corresponding to a respective tag. The method includes, identifying a directional location of the respective tag relative to the user device. The method includes activating a camera device to focus on one or more focal points in an area in the directional location of the respective tag. The method includes estimating a distance of the respective tag relative to the user device. The method includes capturing an image of an object located within the area in the directional location of the respective tag. The method includes correlating the directional location, distance of the respective tag, and image of the object to generate corresponding position information. The position information provides more precise point location of the object. The method includes outputting the corresponding position information to an electronic display.

Abstract: In aspects of a wearable article for determining a task, a system includes a delivery device usable to administer a liquid responsive to an applied force, and includes a wearable article with multiple sensors to detect movements of the wearable article and handling of the delivery device. A task determination module is implemented to receive sensor data identifying the movements of the wearable article and the applied force, and can determine a task from a set of tasks associated with the delivery device that corresponds to the movements of the wearable article. The task determination module can then determine whether the task was performed correctly based on a comparison of the sensor data to a correct pattern of use for the task.

Abstract: A computing device includes a control system that communicates with multiple sensors that capture data regarding a user. The control system communicates with each of the sensors to obtain information regarding the capabilities of each sensor, and uses this capability information to determine how to configure each of the sensors. The control system also selects one of the multiple sensors to be the master sensor, and the rest of the multiple sensors are slave sensors, and notifies the multiple sensors of whether they are a slave sensor or a master sensor. The master sensor collects sensor data for the multiple sensors, capturing data itself as well as receiving data captured by the slave sensors from the slave sensors. The master sensor sends an indication of the collected data (e.g., the collected data itself or data resulting from processing the collected data) to the control system for analysis and/or processing.

Abstract: A computing device includes a control system that communicates with multiple sensors that capture data regarding a user. The control system communicates with each of the sensors to obtain information regarding the capabilities of each sensor, and uses this capability information to determine how to configure each of the sensors. The control system also selects one of the multiple sensors to be the master sensor, and the rest of the multiple sensors are slave sensors, and notifies the multiple sensors of whether they are a slave sensor or a master sensor. The master sensor collects sensor data for the multiple sensors, capturing data itself as well as receiving data captured by the slave sensors from the slave sensors. The master sensor sends an indication of the collected data (e.g., the collected data itself or data resulting from processing the collected data) to the control system for analysis and/or processing.

Abstract: In aspects of location correlation in a region, a mobile device implements a location module that determines a current location of the mobile device in a region within communication range of a radio system based on location data received in radio signals from the radio system. The location module determines region coordinates at the current location of the mobile device in the region. The location module can then associate the region coordinates at the current location of the mobile device in the region with pixel grid coordinates determined from a digital image view as captured by a camera system in the region, and generate a location mapping of the region based on the current location and subsequent locations of the mobile device in the region. The location mapping correlates the locations of the mobile device in the region based on the pixel grid coordinates at the respective locations.

Abstract: In aspects of location correlation in a region, a mobile device implements a location module that determines a current location of the mobile device in a region within communication range of a radio system based on location data received in radio signals from the radio system. The location module determines region coordinates at the current location of the mobile device in the region. The location module can then associate the region coordinates at the current location of the mobile device in the region with pixel grid coordinates determined from a digital image view as captured by a camera system in the region, and generate a location mapping of the region based on the current location and subsequent locations of the mobile device in the region. The location mapping correlates the locations of the mobile device in the region based on the pixel grid coordinates at the respective locations.

Abstract: A computing device includes a control system that communicates with multiple sensors that capture data regarding a user. The control system communicates with each of the sensors to obtain information regarding the capabilities of each sensor, and uses this capability information to determine how to configure each of the sensors. The control system also selects one of the multiple sensors to be the master sensor, and the rest of the multiple sensors are slave sensors, and notifies the multiple sensors of whether they are a slave sensor or a master sensor. The master sensor collects sensor data for the multiple sensors, capturing data itself as well as receiving data captured by the slave sensors from the slave sensors. The master sensor sends an indication of the collected data (e.g., the collected data itself or data resulting from processing the collected data) to the control system for analysis and/or processing.

Abstract: In aspects of a wearable article for determining a task, a system includes a delivery device usable to administer a liquid responsive to an applied force, and includes a wearable article with multiple sensors to detect movements of the wearable article and handling of the delivery device. A task determination module is implemented to receive sensor data identifying the movements of the wearable article and the applied force, and can determine a task from a set of tasks associated with the delivery device that corresponds to the movements of the wearable article. The task determination module can then determine whether the task was performed correctly based on a comparison of the sensor data to a correct pattern of use for the task.

Abstract: In aspects of a wearable article for determining a task, a system includes a delivery device usable to administer a liquid responsive to an applied force, and includes a wearable article with multiple sensors to detect movements of the wearable article and handling of the delivery device. A task determination module is implemented to receive sensor data identifying the movements of the wearable article and the applied force, and can determine a task from a set of tasks associated with the delivery device that corresponds to the movements of the wearable article. The task determination module can then determine whether the task was performed correctly based on a comparison of the sensor data to a correct pattern of use for the task.

Abstract: In aspects of a wearable article for determining a task, a system includes a delivery device usable to administer a liquid responsive to an applied force, and includes a wearable article with multiple sensors to detect movements of the wearable article and handling of the delivery device. A task determination module is implemented to receive sensor data identifying the movements of the wearable article and the applied force, and can determine a task from a set of tasks associated with the delivery device that corresponds to the movements of the wearable article. The task determination module can then determine whether the task was performed correctly based on a comparison of the sensor data to a correct pattern of use for the task.

Abstract: A computing device includes a control system that communicates with multiple sensors that capture data regarding a user. The control system communicates with each of the sensors to obtain information regarding the capabilities of each sensor, and uses this capability information to determine how to configure each of the sensors. The control system also selects one of the multiple sensors to be the master sensor, and the rest of the multiple sensors are slave sensors, and notifies the multiple sensors of whether they are a slave sensor or a master sensor. The master sensor collects sensor data for the multiple sensors, capturing data itself as well as receiving data captured by the slave sensors from the slave sensors. The master sensor sends an indication of the collected data (e.g., the collected data itself or data resulting from processing the collected data) to the control system for analysis and/or processing.

Abstract: A method includes detecting a first movement pattern of a first device using a camera of a second device and establishing a connection between the first and second devices responsive to detecting the first movement pattern. A device includes a camera and a processor coupled to the camera, wherein the processor is to detect a first movement pattern of a second device using the camera and establish a connection with the second device responsive to detecting the first movement pattern.

Abstract: In aspects of real-time augmented reality (AR) activity feedback, a system includes wearable sensors to monitor a musculoskeletal state of a person who engages in an activity. A sensor device hub includes an activity comparison module that is implemented to receive sensor information from the wearable sensors as the person engages in a session of the activity. The activity comparison module can determine activity data from the received sensor information, including a first form of how the person is performing the activity. The activity comparison module of the sensor device hub is also implemented to compare the first form of the person performing the activity to a representative form of the activity, and initiate a real-time comparison feedback that is an indication of how the first form of the person performing the activity compares to the representative form of the activity.

Abstract: In aspects of location correlation in a region, a mobile device implements a location module that determines a current location of the mobile device in a region within communication range of a radio system based on location data received in radio signals from the radio system. The location module determines region coordinates at the current location of the mobile device in the region. The location module can then associate the region coordinates at the current location of the mobile device in the region with pixel grid coordinates determined from a digital image view as captured by a camera system in the region, and generate a location mapping of the region based on the current location and subsequent locations of the mobile device in the region. The location mapping correlates the locations of the mobile device in the region based on the pixel grid coordinates at the respective locations.

Abstract: In aspects of location correlation in a region, a mobile device implements a location module that determines a current location of the mobile device in a region within communication range of a radio system based on location data received in radio signals from the radio system. The location module determines region coordinates at the current location of the mobile device in the region. The location module can then associate the region coordinates at the current location of the mobile device in the region with pixel grid coordinates determined from a digital image view as captured by a camera system in the region, and generate a location mapping of the region based on the current location and subsequent locations of the mobile device in the region. The location mapping correlates the locations of the mobile device in the region based on the pixel grid coordinates at the respective locations.