Abstract: A system and method tracks a user's eye for a data trigger arrangement. The method includes obtaining first image data within a first vision field of a first data capturing sensor. The method includes determining a first area viewed by a user's eye as a function of the first image data. The method includes obtaining second image data within a second vision field of a second sensor. The method includes determining a second area captured within the second field of vision as a function of the second image data. The method includes determining disposition data of the first area within the second area. When a trigger command is captured, the method includes data capturing a machine readable representation of data (MRRoD) using the second sensor as a function of the disposition data.

Abstract: In a single operation executed by a mobile device, operation is executed on at least two data capture devices housed in the mobile device with a single trigger operation. The mobile device receives information captured by at least one of a first data capture device and a second data capture device; instructs adjustment of the other of the first data capture device and the second data capture device based on the received information and receives information captured by at least one of the first data capture device and the second data capture device subsequent to the adjustment. The mobile device analyzes the received information, repeats instructing adjustment until appropriated details are retrieved from the received information; and directs data capture and/or an image capture by at least one of the first data capture device and the second data capture device in accordance with the retrieved details.

Abstract: An example disclosed apparatus includes memory configured to store a mapping of items to respective ones of a plurality of minimum pixel-resolutions, wherein the minimum pixel-resolutions correspond to an image resolution required to identify a corresponding one of the items using an image; and a processor configured to obtain identifying information corresponding to one of the items; select, using the mapping and based on the identifying information, one of the plurality of minimum pixel-resolutions; determine a value of an output parameter based on the selected one of the plurality of minimum pixel resolutions and a camera position relative to a shelf, wherein the output parameter is at least one of an elevation angle of the camera, a vertical resolution, a horizontal resolution, a vertical field of view, and a horizontal field of view; and output the determined value of the output parameter to facilitate positioning of the camera.

Abstract: A charging device may include firmware configured to execute and control charging functions and updating functions performed by the charging device. The firmware includes a first section configured to store instructions associated with the charging functions and a second section configured to store instructions associated with updating the first section. The charging device may also include a charging slot for insertion of one of a rechargeable device and an updating device. The charging device may further include a micro-controller configured to execute instructions stored on the firmware. Responsive to the updating device being inserted into the charging slot, the charging device executes instructions stored in the second section to enter an updating mode and update the firmware.

Abstract: An apparatus for electro-optically reading targets is mounted in an orientation on a head of a human operator having eyes for directly viewing a calibration target along a sightline. A light source directs a visible light beam away from the apparatus. A calibration assembly adjustably moves the light source, no matter the orientation of the apparatus, to visually position the light beam on the calibration target that is simultaneously being directly viewed along the sightline in a calibration mode of operation. A data capture assembly is operative, subsequent to the calibration mode, for electro-optically reading the targets on which the light beam is visually positioned in a reading mode of operation.

Abstract: An electronic article surveillance (EAS) assembly is installable in a workstation that processes products associated with targets to be electro-optically read. The assembly includes a radio frequency (RF) antenna having a pair of RF feed lines and a conductive loop for generating an electromagnetic field to deactivate EAS tags associated with the products to be processed, and a protective carrier for supporting and protecting the antenna during the installation in a predetermined position in the workstation.

Abstract: A mobile device can be found and recovered by executing a recovery action indicative of at least one location of the mobile device. An interface displays the location of the mobile device.

Abstract: An imaging sensor of an imaging reader senses return light from a target to be read by image capture along an imaging axis over a field of view that extends along mutually orthogonal, horizontal and vertical axes. Two aiming light assemblies are offset from the sensor and are spaced apart along the horizontal axis at opposite sides of the sensor, and direct two aiming light marks, each having a predetermined brightness, at the target. The aiming marks are collinear along the horizontal axis and have inner end regions that overlap on the target to form a bright aiming mark having a brightness greater than the predetermined brightness to visually indicate a center zone of the field of view, as well as outer end regions that visually indicate approximate end limits of the field of view, over a range of working distances.

Abstract: Objects associated with targets to be read by image capture are detected without any additional hardware in an imaging module. Return light is captured over a field of view of the module. Images are processed, during an object detection mode, to determine their image brightness from the captured return light. Illumination is emitted from an illumination light assembly at a first power level to determine a first image brightness from a first processed image, and at a different, reduced, second power level to determine a second image brightness from a second processed image. An object is determined to be in the field of view when a difference between the first image brightness and the second image brightness equals or exceeds a detection threshold value.

Abstract: An optical assembly for an electro-optical reader includes a lens mounted in a stepped barrel. The stepped barrel has a barrel step between first and second barrel portions. The optical assembly is installed along an optical axis in a stepped chassis having a first chassis section that receives the first barrel portion with a slip fit in which a mechanical clearance exists between the first chassis section and the first barrel portion, a second chassis section that receives the second barrel portion with an engagement fit in which the second barrel portion frictionally moves against the second chassis section, and a chassis step between the first and second chassis sections. The chassis step is spaced away from the barrel step after installation of the optical assembly to bound a debris compartment to trap any debris resulting from the frictional movement of the second barrel portion against the second chassis section.

Abstract: Sensor calibration relative to common coordinates with depth, height and shift dimensions includes obtaining, via a mobile apparatus camera, an image of a calibration target. The calibration target includes first and second surfaces at first and second predefined depths, bearing first and second sets of indicia at heights encoded by the indicia and having predefined shifts.

Abstract: A method and apparatus for (a) receiving a three-dimensional (3D) point cloud from a depth sensor that is oriented towards an open end of a shipping container, the point cloud comprising a plurality of points that each have a respective depth value, (b) segmenting the received 3D point cloud among a plurality of grid elements, (c) calculating a respective loaded-container-portion grid-element volume for each grid element, (d) calculating a loaded-container-portion volume of the shipping container by aggregating the calculated respective loaded-container-portion grid-element volumes, (e) calculating an estimated fullness of the shipping container based on the loaded-container-portion volume and a capacity of the shipping container; and (f) outputting the calculated estimated fullness of the shipping container.

Abstract: Apparatus and method for coverage hole detection in a wireless local area network (WLAN) using a mobile communication device. The method includes a first step of providing a plurality of access points distributed within the WLAN and at least one mobile communication device operable within the WLAN. A next step includes downloading triggers for respective coverage measurement conditions to the at least one associated mobile communication device from an associated access point. A next step includes detecting a coverage measurement condition by the at least one mobile communication device that activates one of the triggers, whereupon a next step includes sending a coverage measurement indicating the triggered condition from the at least one mobile communication device to an associated access point, which forwards a coverage incident report to a Central Report Manager.

Abstract: A transmitter subsystem periodically transmits ranging signals at transmit times, and a receiver subsystem receives the ranging signals at receive times within a receiver window having an adjustable time duration. A real-time position of a mobile device supporting one of the subsystems is determined based on differences between the receive and transmit times. An expected arrival time for the transmitted ranging signals is determined based on the real-time position of the mobile device. Each receive time is compared with the expected arrival time to obtain a consistency rate of the ranging signals that are received by the receiver subsystem directly from the transmitter subsystem. The time duration of the receiver window is dynamically adjusted based on the consistency rate.

Abstract: A workstation has a metallic housing for supporting an electro-optical reader for reading bar code symbols. A radio frequency (RF) antenna of an RF identification (RFID) reader for reading RFID tags is mounted in a metallic container that is connected to the housing. The RF antenna radiates RF energy at a frequency greater than 900 MHz through RF excitation slots formed between the container and the housing.

Abstract: One light source is energized and another light source is simultaneously deenergized during one frame of an imager that captures return light from an illuminated target as a first image portion having a first target portion. The other light source is energized and the one light source is simultaneously deenergized during another frame to capture the return light from the illuminated target as a second image portion having a second target portion. Either the target portions are combined to form the target to be read, or the image portions are combined to form a composite image from which the target is read.

Abstract: A Bluetooth low energy (BLE)-based asset tag transmits a code that identifies an asset. A device is attached to the asset. The code is scanned with a scanner supported by the device. An advertising beacon is transmitted in an advertising packet having a payload with a Bluetooth low energy (BLE)-based radio supported by the device. The scanned code is automatically loaded into the payload. The advertising packet with the scanned code in the payload is periodically transmitted as a series of beacon pulses.

Abstract: An antenna includes a ground support, an electrically conductive, endless element mounted at a distance relative to the ground support, and a trio of ports arranged along the endless element for conveying radio frequency signals in an operating band of frequencies. The antenna is compact and has high port isolation and low pattern correlation due to successively spacing the ports apart along the endless element by a spacing of one-half of a guided wavelength at a center frequency of the operating band.

Abstract: A Bluetooth low energy (BLE) beacon in a BLE network is electrically powered by a battery, broadcasts messages, and listens for a network communication indicative of whether a mobile device is present in a venue. A beacon controller controls the beacon to periodically broadcast the messages and to periodically listen for the network communication during an active mode of operation, to not broadcast the messages to conserve power from the battery and to listen for the network communication during a power save mode of operation, and to switch from the power save mode to the active mode when the network communication received during the power save mode indicates that a mobile device is present in the venue.