Abstract: Embodiment of the present invention generally relate to bi-optic barcode readers. In an embodiment, the disclosure describes a barcode reader for use in a checkout workstation having a surface. The barcode reader includes: a lower housing portion having a top portion; a first optically transmissive window positioned in the top portion, a top surface of the first optically transmissive window defining a horizontal plane, the top portion of the lower housing being substantially parallel with the surface of the checkout workstation when the barcode reader is used in the checkout workstation; a raised housing portion having a second optically transmissive window, the raised housing portion extending at least partially above the top portion; and a PCB positioned substantially upright relative to the horizontal plane, the PCB having a first imaging assembly and a decode assembly, the barcode reader having no other printed circuit boards with another imaging assembly.

Abstract: A mobile device is described. The mobile device includes a housing having a pistol grip portion. A display is coupled to the housing such that the display is viewable by a user of the mobile device when the pistol grip portion is held in a hand of the user. A trigger-like control switch is located on the pistol grip portion of the mobile device. A pointing device is located on the trigger-like control switch such that the pointing device is accessible to an index finger of a hand of the user when the pistol grip portion is held in the hand of the user. The pointing device controls at least one function of the mobile device.

Abstract: A method and apparatus for detecting a bulk quantity of RFID tags in a presentation area such as a point-of-sale device. Bulk quantity of RFID tags may be detected according to input to the point-of-sale device including through input from a symbolic barcode scanner, a conveyor belt, a weight scale, and/or via an RF antenna driven at a first power level. After the bulk quantity of RFID tags is detected, the RF antenna is driven at a second, higher power level temporarily to increase bulk RFID tag detection accuracy. “Fringe” tags may be detected by the RF antenna when it is driven at the higher power level that are in the environment but not presented at the point-of-sale device. Fringe tags may be filtered based on RF characterization of the presentation area including driving the RF antenna outside of presentation sessions and/or filtering RFID tags detected across multiple presentation sessions.

Abstract: Spaced-apart light spots are projected in a light pattern on a target surface lying in a target plane. A range spot is projected at a position on the target surface to find a target distance to the target surface. An image of the target surface, light pattern, and range spot is captured along an imaging axis that is perpendicular to an imager plane of an imager. A controller determines an angular relationship between the imager and target planes based on the light pattern in the captured image, determines a scale relationship between the target surface and the imager based on the position of the range spot in the captured image, displays a compensated image of the target surface that is corrected in tilt by the angular relationship and in scale by the scale relationship, and determines dimensions of the target surface based on dimensions of the displayed compensated image.

Abstract: Targets to be electro-optically read by image capture are illuminated with illumination light emitted from an illumination light source and directed along an illumination path through a window to the targets, and return light from the targets is captured through the window and projected along an imaging path to an array of light sensors of an imaging system. An optical element is located in both the illumination path and the imaging path, and has a light-reflecting, non-diffusing portion for directing the captured return light incident on the light-reflecting portion along a folded imaging path to the array, and a light-diffusing portion for diffusing the illumination light incident on the light-diffusing portion along a folded illumination path to scatter and blur an image of the illumination light source, to increase an apparent size of the illumination light source, and to reduce a perceived brightness of the illumination light source.

Abstract: An imaging module for reading targets by image capture is mounted as a unitary assembly within an imaging reader. An imager is mounted on a first printed circuit board (PCB), and an interface connector is mounted on a second PCB. The first PCB is in supporting contact with first chassis walls of a chassis and is positioned to lie in a generally upright, first predetermined plane. The second PCB is in supporting contact with second chassis walls of the chassis and is positioned to lie in a generally tilted, second predetermined plane that is inclined at a tilt angle relative to the first predetermined plane. The first and second chassis walls are constituted as a one-piece support that maintains the tilt angle between the PCBs.

Abstract: A mobile device with wrist neutral data capture is provided. The device comprises: a housing; a data capture component configured to change an aiming pattern; a display; an orientation sensor configured to detect an orientation; one or more touch sensors at the housing; a memory storing wrist neutral touch data associated with a wrist neutral grip corresponding to predetermined grip position locations at the touch sensor(s); and a controller configured to: when touch data received at the touch sensor(s) matches the wrist neutral touch data stored in the memory, control the aiming pattern of the data capture component according to the orientation detected by the orientation sensor; and when the touch data does not match the wrist neutral touch data, control a notification device to provide an indicator of the housing being out of the wrist neutral grip.

Abstract: A method and apparatus are disclosed for improving RFID coverage using an antenna array having an adaptive antenna beam. The apparatus includes an RFID reader including an antenna array having a plurality of antenna elements. Subsets of the plurality of antenna elements are selectively activating in order to direct an antenna beam to communicate with at least one RFID tag. The method includes transmitting an interrogation signal from an antenna array by activating one or more subsets of a plurality of antenna elements forming the antenna array. In this way, the interrogation signal is directed thereby improving antenna coverage.

Abstract: A control method includes: storing, at a control server, respective identifiers for a plurality of sub-regions in a facility; for each sub-region identifier, a location of the sub-region in the facility and an operational constraint associated with a mobile automation apparatus; at the control server: obtaining a job definition indicating a set of the sub-region identifiers and a task; retrieving the locations and the operational constraints corresponding to the set of sub-region identifiers from the repository; allocating the set of sub-region identifiers to a plurality of subsets of sub-region identifiers, each subset having a shared common operational constraint; for each subset of sub-region identifiers, generating a task fragment containing the subset of sub-region identifiers, and the common operational constraint; and sending the task fragments and an identifier of the task to the mobile automation apparatus for performance of the task at each of the set of sub-region identifiers.

Abstract: A method and apparatus for a co-located Radio Frequency Identification (RFID) device and ultrasonic device includes an RFID reader loop antenna element oriented parallel to a reflector panel. An ultrasonic emitter is disposed through an aperture in the reflector panel with a horn that extends through the loop element. The horn can serve as a mounting structure for the antenna element. A diameter of the aperture is less than one-quarter wavelength of an operating frequency of the RFID reader loop antenna element. The aperture is located in the reflector panel near a minimum E-field area of the RFID reader loop antenna element.

Abstract: Successive products associated with targets to be electro-optically read are swiped, in their respective turns, past a window in a point-of-transaction workstation. A motion detector detects movement of each product. A reader electro-optically reads a target associated with each moving product. If the target associated with each moving product has not been read, then this event is deemed suspicious, and the event is flagged for a security investigation designed to deter product theft by sweethearting.

Abstract: An imaging reader captures and analyzes image data, including raw captured image data, and analyzes that capture image data to decode indicia contained therein. The indicia may be one or more two-dimensional barcodes. A dedicated front-end controller of the imaging reader generates decode data for the indicia and combines the decode data with the image data using a combinational protocol, after which a resulting decode enhanced image data frame is communicated to a host processor for processing.

Abstract: Ultrasonic transmitters periodically transmit ultrasonic ranging signals, and an ultrasonic receiver receives the ultrasonic ranging signals on a mobile device in order to locate the mobile device in a venue. A controller determines a noise level in the venue, and varies a sound level of the periodically ranging signals based on the determined noise level, thereby optimizing the position of the mobile device.

Abstract: An imaging reader has near and far imagers for imaging illuminated targets to be read over a range of working distances. A range finder determines a distance to a target. A default imager captures a minor portion of an image of the target, and rapidly determines its light intensity level. At least one of the imagers is selected based on the determined distance and/or the determined light intensity level. The exposure and/or gain of the selected imager is set to a predetermined value, and an illumination level is determined, also based on the determined light intensity level and/or the determined distance. The selected imager, which has been set with the predetermined value, captures an image of the target, which has been illuminated at the illumination light level.

Abstract: A method and system for charging a battery is provided. A group charging policy specifying a conditional charging behavior for charging a battery of a computing device is stored in a memory of the computing device. The computing device is coupled to a power source. Battery status data is received, via a communications interface of the device, for each of at least one other computing device coupled to the power source. A power draw rate for charging the battery of the computing device is throttled according to the group charging policy and the battery status data of the computing device and the at least one other computing device.

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.