A portable optical reader is provided with LED light sources 2911 to 2914; a diffusion plate 23 diffusing the light emitted from the LED light sources 2911 to 2914; an opening 2431 formed on the diffusion plate 23 transmitting diffusion reflecting light; an imaging part 41 receiving the diffusion reflecting light through the opening 2431; a LED light source 2915 emitting the light to the symbol; a light projection polarizing element 242 polarizing the light emitted from the LED light source 2915; an opening 2432 formed in the diffusion plate 23 transmitting the polarized light emitted from the LED light source 2915; and a light reception polarizing element 241 polarizing the diffusion reflecting light which is the polarized light emitted from the LED light source 2915 and reflected on the symbol and transmitted through the opening 2431.

A camera device for reading optical codes is provided that has at least one first camera unit having a first camera controller and a first image sensor for recording image data from a first detection zone, that has second camera unit having a second camera controller and that has a second image sensor for recording image data from a second detection zone that overlaps at least partially with the first detection zone, and that has a common control unit, wherein the respective camera controller is configured to locate regions of interest having optical codes in the image data and to transmit the image data of the regions of interest to the common controller. In this respect, the common controller is configured to combine the image data in regions of interest recorded by more than one camera unit and to read an optical code in the region of interest therefrom.

An optical information code reading method, including reading an optical information code image by an optical information code scanner immediately after the optical information code image has been recorded onto an information recording medium, wherein the optical information code scanner includes an amplitude tuning unit configured to correct a detected amplitude level of reflectivity from the information recording medium on which the optical information code image has been recorded and to store the corrected detected amplitude level, and wherein the optical information code scanner reads the optical information code image in a state in which the optical information code scanner has read the information recording medium on which the optical information code image has been recorded, and the amplitude tuning unit has determined and stored a detected amplitude level optimum for reading.

Image processing for scanning devices based on laser aimer position, wherein a first frame and a second frame of image data related to an object associated with a barcode are captured using a scanning device. A difference between first pixel data for a first grouping of pixels associated with the first frame and second pixel data for a second grouping of pixels associated with the second frame is computed. Additionally, a location of a laser aimer pattern in the first frame or the second frame is determined based on a comparison between respective differences between the first pixel data for the first grouping of pixels and the second pixel data for the second grouping of pixels, where the laser aimer pattern is created by the scanning device.

Technologies for assessing a health condition of a light emission assembly and recalibrating the light emission assembly are disclosed. For example, health assessment and recalibration of an imaging system is performed by initially identifying absence of an object at the imaging system, before performing either the assessment or recalibration. For an imaging system having a weigh platter assembly and an off-platter detection assembly serving as the subject light emission assembly, the imaging system performs a health assessment of the detection assembly responsive to a zero weight condition measured at the platter assembly. The imaging system then selectively enters into recalibration, responsive to the health assessment finding a sufficiently degraded light intensity, by measuring reflected light from the detection assembly.