Abstract: A mobile device having a camera is adapted to serve as an electro-optical reader for electro-optically reading targets. The device is received and held in a housing having a rear wall. A top extension extends away from the rear wall at a top region of the device. A fold mirror is mounted on the top extension and is spaced away from a camera lens of the device. The fold mirror is inclined relative the rear wall and is operative for receiving at least a portion of a field of view imaged by the camera from each target along a first direction, and for folding and redirecting the field of view along a second direction generally perpendicular to the rear wall through the camera lens to the camera. A handle having a trigger assembly may be connected to the housing.

Abstract: A reader for electro-optically reading a target in the presence of ambient light, includes a scan component for scanning a laser beam across the target, a first filter for passing return laser light from the target and the ambient light to a first photodetector system for generating a first output signal constituted of an information signal and a first ambient light signal, a second filter for passing the ambient light to a second photodetector system for generating a second output signal constituted of a second ambient light signal, and signal processing circuitry for measuring a difference between the first and second ambient light signals, for equalizing the first and second ambient light signals when the difference exceeds a threshold, and for subtracting the second output signal from the first output signal to obtain a receiver output signal substantially constituted only of the information signal.

Abstract: A method for controlling a workstation includes the following: (1) energizing a first illuminator to illuminate a first subfield of view with a first illumination pulse and subsequently energizing the first illuminator to illuminate the first subfield of view with a second illumination pulse; (2) exposing the array of photosensitive elements in the imaging sensor for a first sensor-exposure time and subsequently exposing the array of photosensitive elements in the imaging sensor for a second sensor-exposure time; and (3) processing an image captured by the imaging sensor to decode a barcode in the image. The first illumination pulse overlaps with the first sensor-exposure time for a first overlapped-pulse-duration, and the second illumination pulse overlaps with the second sensor-exposure time for a second overlapped-pulse-duration. The first overlapped-pulse-duration is different from the second overlapped-pulse-duration.

Abstract: An optical slot scanner (10) and method includes a housing (12) supporting a scanning arrangement (22) within an interior region (14) of the housing. The scanning arrangement (22) includes an imaging camera (26) and light source (24) disposed within a recess compartment (80) located in the interior region of the housing. The imaging camera defines an imaging field (40) of view for reading indicia located on a target object. The light source defines an illumination field (42) for illuminating indicia located on a target object, such that the illumination field is substantially coaxial with the imaging field during a reading of indicia located on a target object.

Abstract: An apparatus includes (1) an imaging lens arrangement having an optical axis, (2) an aiming light source configured to project visible light through the imaging lens arrangement to create an aiming pattern on a target object, (3) an imaging sensor detecting light from the target object through the imaging lens arrangement, and (4) a folding mirror tilted relative to the optical axis of the imaging lens arrangement. The folding mirror is positioned both on the optical path from the imaging lens arrangement to the imaging sensor and on the optical path from the aiming light source to the imaging lens arrangement. Both the imaging arrangement and the aiming arrangement share the same imaging lens.

Abstract: A method of decoding using an imaging scanner having multiple object sensors each associated with an object field of view. The method includes determining a moving direction of the object using at least two of the multiple object sensors. The moving direction of the object points from a first side to a second side of the imaging scanner. The method includes detecting whether a new object is presence with the object sensor located on the first side of the imaging scanner, and upon detecting the presence of the new object within the object field of view of the object sensor located on the first side of the imaging scanner, capturing an image of the new object in memory with the solid-state imager.

Abstract: A workstation electro-optically reads targets by image capture, and includes a housing, a generally planar window, an imaging module, and a generally planar fold mirror between the window and the module. The module has an illuminating light assembly for directing illumination light along an illumination path through the window at a target for return therefrom during reading, and an image sensing assembly for detecting return illumination light through the window along an imaging path over an imaging field of view during reading. The fold mirror folds the illumination and the imaging paths. The fold mirror and the window lie in planes that are substantially parallel to each other to prevent reflections of the illumination light off of the fold mirror and the window from entering the imaging field of view as virtual images that degrade target detection by the image sensing assembly.

Abstract: A reader for electro-optically reading a target in the presence of ambient light, includes a scan component for scanning a laser beam across the target, a first filter for passing return laser light from the target and the ambient light to a first photodetector system for generating a first output signal constituted of an information signal and a first ambient light signal, a second filter for passing the ambient light to a second photodetector system for generating a second output signal constituted of a second ambient light signal, and signal processing circuitry for measuring a difference between the first and second ambient light signals, for equalizing the first and second ambient light signals when the difference exceeds a threshold, and for subtracting the second output signal from the first output signal to obtain a receiver output signal substantially constituted only of the information signal.

Abstract: A method of decoding a barcode includes generating a first illumination towards a target object with a first illumination level, capturing a first image during a first exposure time period, and determining a first location and a second location on a scan line in the first image to find a switchover condition. If the switchover condition indicates the presence of a mobile display device, the method further includes generating a second illumination towards the target object with a second illumination level, capturing a second image during a second exposure time period, and decoding the barcode in the second image. Here, at least one of the second illumination level and the second exposure time period is determined based on values of pixels on the scan line between the first location and the second location.

Abstract: An arrangement for, and a method of, electro-optically reading a target by image capture, employ a scan engine in a handheld housing having a tilted handle. A single tilted printed circuit board (PCB) in the handle has front and rear surfaces that respectively face toward and away from the target during reading. An optical assembly having a pair of fold mirrors is mounted on the rear surface, for receiving return light from the target through an aperture in the PCB along the horizontal, and for directing the return light along a folded path. An imaging lens assembly projects the return light onto a solid-state, two-dimensional, image sensor to enable the return light to be detected over a field of view, and to generate an electrical signal indicative of the detected return light.

Abstract: A workstation includes a first window located in an upright plane, a second window located in a generally horizontal plane that intersects the upright plane, and a controller operative to read a barcode, and a weighing system having a horizontal platter operative to measure the weight of produce exerting gravitational force on the horizontal platter. The workstation also includes a four-bar apparatus having a front bar, a back bar, a first side bar, and a second side bar all atop the horizontal platter. The four-bar apparatus is operative to be settled into one of a first configuration and a second configuration. The upper edge of each of the front bar, the back bar, the first side bar, and the second side bar has an average height at the second configuration larger than its average height at the first configuration.

Abstract: A method of decoding using an imaging scanner having multiple object sensors each associated with an object field of view. The method includes determining a moving direction of the object using at least two of the multiple object sensors. The moving direction of the object points from a first side to a second side of the imaging scanner. The method includes detecting whether a new object is presence with the object sensor located on the first side of the imaging scanner, and upon detecting the presence of the new object within the object field of view of the object sensor located on the first side of the imaging scanner, capturing an image of the new object in memory with the solid-state imager.

Abstract: A method for controlling a workstation includes the following: (1) energizing a first illuminator to illuminate a first subfield of view with a first illumination pulse and subsequently energizing the first illuminator to illuminate the first subfield of view with a second illumination pulse; (2) exposing the array of photosensitive elements in the imaging sensor for a first sensor-exposure time and subsequently exposing the array of photosensitive elements in the imaging sensor for a second sensor-exposure time; and (3) processing an image captured by the imaging sensor to decode a barcode in the image. The first illumination pulse overlaps with the first sensor-exposure time for a first overlapped-pulse-duration, and the second illumination pulse overlaps with the second sensor-exposure time for a second overlapped-pulse-duration. The first overlapped-pulse-duration is different from the second overlapped-pulse-duration.

Abstract: An arrangement for, and a method of, electro-optically reading a target by image capture, employ a scan engine in a handheld housing having a tilted handle. A single tilted printed circuit board (PCB) in the handle has front and rear surfaces that respectively face toward and away from the target during reading. An optical assembly having a pair of fold mirrors is mounted on the rear surface, for receiving return light from the target through an aperture in the PCB along the horizontal, and for directing the return light along a folded path. An imaging lens assembly projects the return light onto a solid-state, two-dimensional, image sensor to enable the return light to be detected over a field of view, and to generate an electrical signal indicative of the detected return light.

Abstract: An apparatus for, and a method of, electro-optically reading a target by image capture, employ a scan engine in a handheld housing having a tilted handle. A single tilted printed circuit board (PCB) in the handle has front and rear surfaces that respectively face toward and away from the target during reading. An optical assembly having a pair of fold mirrors is mounted on the rear surface, for receiving return light from the target through an aperture in the PCB along the horizontal, and for directing the return light along an internal folded optical path. An imaging lens assembly is mounted between the fold mirrors and has an imaging axis that extends generally parallel to the PCB. The imaging lens assembly projects the return light onto a solid-state, two-dimensional, image sensor to enable the return light to be detected over a field of view, and to generate an electrical signal indicative of the detected return light.

Abstract: An efficient multicamera imaging-based bar code reader for imaging a target bar code on a target object. An imaging system has a plurality of camera assemblies coupled to an image processing system. Each camera assembly includes a sensor array and an imaging lens assembly for focusing a field of view of the camera assembly onto a sensor array as well as including one or more light emitting diodes for illuminating a field of view of that camera assembly. One camera is activated or energized to detect an object and then all cameras are activated for generating images suitable to decode a bar code on the detected object.

Abstract: An optical scanner (600) and method of operating same includes a housing (16) supporting first (34) and second scanning systems (202), the first scanning system for scanning indicia on a target object, the housing defining an interior region of the scanner. The first scanning system comprises one of an imaging camera (208/209) and a laser light source (38) disposed within the housing interior region defining a first field of view for reading indicia located on a target object. The second scanning system (202) comprises a separate imaging camera (602) disposed in the housing interior region for reading auxiliary data from an auxiliary object relating to one or more target objects being scanned, the second scanning system defining a second field of view (604). A locator platform (620) is recessed within the housing for positioning an auxiliary object within the second field of view during use of the scanner.

Abstract: An apparatus includes (1) an imaging lens arrangement having an optical axis, (2) an aiming light source configured to project visible light through the imaging lens arrangement to create an aiming pattern on a target object, (3) an imaging sensor detecting light from the target object through the imaging lens arrangement, and (4) a folding mirror tilted relative to the optical axis of the imaging lens arrangement. The folding mirror is positioned both on the optical path from the imaging lens arrangement to the imaging sensor and on the optical path from the aiming light source to the imaging lens arrangement. Both the imaging arrangement and the aiming arrangement share the same imaging lens.

Abstract: An optical slot scanner (10) and method includes a housing (12) supporting a scanning arrangement (22) within an interior region (14) of the housing. The scanning arrangement (22) includes an imaging camera (26) and light source (24) disposed within a recess compartment (80) located in the interior region of the housing. The imaging camera defines an imaging field (40) of view for reading indicia located on a target object. The light source defines an illumination field (42) for illuminating indicia located on a target object, such that the illumination field is substantially coaxial with the imaging field during a reading of indicia located on a target object.

Abstract: A multicamera imaging-based bar code reader 10 for imaging a target bar code 30 on a target object 32 features: a housing 20 supporting a plurality of transparent windows H, V and defining an interior region, an imaging system including a plurality of camera assemblies C1-C5 coupled to an image processing system, each camera assembly of the plurality of camera assemblies being positioned within the housing interior. Each camera assembly includes a sensor array. One or more light reflecting fold mirrors M1-M14 define a camera assembly field of view positioned with respect to said light source and the sensor array at locations along a light path to transmit light from light source to the field of view and transmit light that bounces from a target in the field of view back along said light path to the image capture sensor array.