Systems and methods for scanning multiple items in a single swipe are disclosed herein. An example method includes capturing, by an optical imaging assembly, a plurality of images of a field of view (FOV) of the optical imaging assembly. A processor identifies a plurality of indicia from one or more images of the plurality of images. The indicia are indicative of the location of one or more objects of interest within the FOV. The processor decodes each indicia to determine information associated with the one or more objects of interest. The processor further identifies, a frame of interest in one or more images and initiates a dynamic frame that includes each frame of interest. The processor identifies, from the dynamic frame, a background region in the one or more images of the plurality of images, and the processor further removes the background region from the one or more images.

Methods and systems include using three-dimensional imaging apparatuses to capture three-dimensional images and analyze resulting three-dimensional image data to enhance captured two-dimensional images for scanning related processes such as object identification, symbology detection, object recognition model training, and identifying improper scan attempts or other actions performed by an operator. Imaging systems such as bi-optic readers, handheld scanners, and machine vision systems are described using three-dimensional imaging apparatuses and described capturing three-dimensional images and using with captured two-dimensional images.

The disclosure relates to a self-checkout system including a base and a scan gate extending over at least a portion of the base, the scan gate having a field of view that encompasses 360-degree coverage of the items such that the scan gate is able to obtain and read encoded data on any surface of the item passing through the scan gate. The base may include one or more rails positioned along the periphery to help retain items on the surface of the base once they have been passed through the scan gate.

Example methods and apparatuses to mitigate specular reflections and direct illumination interference in bioptic barcode readers are disclosed. An example method includes creating a first sub-field of view passing through a first window, creating a second sub-field of view passing through a second window, while activating a first illumination source to illuminate the first sub-field of view and deactivating a second illumination source associated with the second sub-field of view, capturing first images of the first sub-field of view, while activating the second illumination source to illuminate the second sub-field of view and deactivating the first illumination source, capturing second images of the second sub-field of view, and attempting to decode a barcode within at least one of the first images and the second images.

Methods of detecting scan avoidance events are disclosed herein. An example method includes measuring, by a weighing scale associated with a barcode reader, an unstable weight over a timeframe having a duration that is greater than a threshold duration. The method further includes monitoring for (i) the barcode reader's failure, during the first timeframe, to transition from a first state in which an imager of the barcode reader does not transmit images for decoding to a second state in which the imager captures images over an FOV including a product scanning region and transmits the captured images for decoding; or (ii) the barcode reader's failure to decode a barcode from images captured over the FOV including the product scanning region during the first timeframe; and generating an alert indicating a potential scan avoidance event responsive to both the measured unstable weight over the timeframe and one of (i) or (ii).

The present technology relates to image signal processing. One aspect of the present technology involves analyzing reference imagery gathered by a camera system to determine which parts of an image frame offer high probabilities of—relative to other image parts—containing decodable watermark data. Another aspect of the present technology whittles-down such determined image frame parts based on detected content (e.g., a cereal box) vs expected background within such determined image frame parts.

A bioptic scanner optical arrangement with a single sensor split four ways is disclosed herein. An example bioptic scanner optical arrangement includes a housing, an imaging assembly having a primary FOV, a decode module, a generally horizontal window supported by the housing, a generally upright window supported by the housing, and a mirror arrangement positioned within the interior region. The mirror arrangement is configured to divide the primary FOV into a plurality of subfields, to redirect at least two of the plurality of subfields through the generally horizontal window, and to redirect at least another two of the plurality of subfields through the generally upright window. The bioptic barcode reader has no other imaging assembly communicatively coupled to the decode module and used to process images for decoding indicia.

A code reader and method thereof may include capturing monochrome images of a scene by a monochrome imager, and capturing color images of the scene by a color imager aligned with the monochrome imager. Stereo 3D images of the scene may be generated from the monochrome and color images.

The imaging system includes a rotating element that is configured to rotate about a central axis. A plurality of scanners are fixedly attached with the rotating element. Each scanner has a lens that faces generally towards the central axis, and the scanners are spaced apart from one another around the central axis. The scanners are configured to identify an optically readable machine readable code contained on the medication container. An actuator is operably connected with the rotating element and is configured to rotate the rotating element and the scanners around the central axis from respective e first positions to respective second positions to allow the scanners to image different areas of the medication container in response to a failure of the scanners to identify the machine readable code when the scanners were in the respective first positions.

A bioptic barcode reader is disclosed for selective use of illumination color to capture appropriate data. The bioptic barcode reader includes a housing and a primary imager positioned within the housing, configured to scan a target object during a first time period. The bioptic barcode reader further includes a primary illumination source positioned within the housing configured to emit primary illumination in a primary wavelength range during the first time period. The bioptic barcode reader further includes a secondary imager configured to capture one or more images of a target object during a second time period. The bioptic barcode reader further includes a secondary illumination source configured to emit secondary illumination in a secondary wavelength range during the second time period, wherein the second time period and first time period are interleaved and the secondary wavelength range is different from the primary wavelength range.