This invention provides a system and method for detecting and acquiring one or more in-focus images of one or more barcodes within the field of view of an imaging device. A measurement process measures depth-of-field of barcode detection. A plurality of nominal coarse focus settings of a variable lens allow sampling, in steps, of a lens adjustment range corresponding to allowable distances between the one or more barcodes and the image sensor, so that a step size of the sampling is less than a fraction of the depth-of-field of barcode detection. An acquisition process acquires a nominal coarse focus image for each nominal coarse focus setting. A barcode detection process detects one or more barcode-like regions and respective likelihoods. A fine focus process fine-adjusts, for each high-likelihood barcode, the variable lens near a location of the barcode-like regions. The process acquires an image for decoding using the fine adjusted setting.

Systems and methods of conducting a bar code scan using an imaging-based bar code scan device are provided. In one exemplary embodiment, a method is performed by an imaging-based bar code device that includes processing circuitry, an optical lens assembly having an image sensor and an optical lens with a focused region at a certain distance in front of the optical lens along an optical axis of the optical lens, a plurality of light emitting elements configured proximate the optical lens and laterally offset from the optical axis. The method includes sending, by the processing circuitry, to each light emitting element, an indication to enable that light emitting element to project a light beam towards the optical axis in the focused region so that the light beams overlap when a target bar code is in the focused region and non-overlap when a target bar code is outside the focused region.

A slot scanner illumination system for a convertible slot scanner assembly includes a chassis having an optical cavity and a front opening. The optical cavity has an optical axis therethrough, with the optical axis being an axis along which light may be received by the chassis through the front opening. The front opening further has a first edge and a second edge opposite the first edge. A scanning window is configured to at least partially cover the front opening of the chassis, and the scanning window has a normal axis orthogonal to a flat surface of the scanning window. An illumination element is disposed inside of the optical cavity of the chassis. The illumination element is disposed proximal the first edge of the front opening. The illumination element is configured to provide illumination along an illumination axis, wherein the illumination axis is non-parallel with the optical axis and at an angle directed toward the second edge of the front opening.

An imaging device includes a housing having an optically transmissive window, a first imaging assembly, and a second imaging assembly. A second imaging sensor of the second imaging assembly is positioned within a bottom portion of the housing height and a front portion of the housing depth. The second imaging sensor may be positioned in either a landscape orientation or a portrait orientation. A downstream region is defined between a downstream side of a first field of view of the first imaging sensor and a downstream side of a second field of view of the second imaging sensor to allow the imaging device to determine whether an indicia associated with a product captured within the downstream region was previously captured in the first field of view, thereby facilitating detection of scan avoidance or ticket switching.

The present disclosure relates to the field of information identification. Disclosed are a method and terminal for identifying a barcode. The method comprises: obtaining an image of a barcode, and according to the calibration information of a preset calibration region, identifying the position of the calibration region in the image; identifying the position of an information code region in the image according to the position of the calibration region in the image, and a preset position relationship between the calibration region and the information code region in the image; and acquiring information on the position of the information code region in the image to obtain the information of the information code region.

Systems and methods are described for implementing scanner configuration based on focus of one or more host application screens. Example systems and methods comprise detecting a focus event of an application (app) as executing on one or more processors. An active focus module (AFM) detects the focus event. The AFM or a scanner device is configured to receive data in a first data app format. Scan data is scanned by the scanner device and is formatted, at the AFM or at the scanner device, into app data having the data app format. The app data is then provided to the app.

A scan engine for capturing at least one image of an object appearing in an imaging field of view (FOV) is provided that includes an imaging system, illumination system, aiming system, and a first and second chassis. The imaging system includes a lens holder and at least one lens disposed within the lens holder and both a far imaging system and a near imaging system for capturing images across multiple fields of view at different distances. The illumination system and aiming system are physically positioned to provide illumination of a target in the near and/or far fields of view, and provide an aiming pattern to the near and/or far fields of view.

There is provided in one embodiment an apparatus having an image sensor array. In one embodiment, the image sensor array can include monochrome pixels and color sensitive pixels. The monochrome pixels can be pixels without wavelength selective color filter elements. The color sensitive pixels can include wavelength selective color filter elements.

There is provided in one embodiment an apparatus having an image sensor array. In one embodiment, the image sensor array can include monochrome pixels and color sensitive pixels. The monochrome pixels can be pixels without wavelength selective color filter elements. The color sensitive pixels can include wavelength selective color filter elements.

Methods and apparatus for locating small indicia in large images are disclosed herein. An example method includes: identifying an aiming pattern zone that includes a detected or presumed location of an aiming light pattern, wherein an offset between the location and a center of image data varies due to a parallax; determining one or more coordinates of the aiming pattern zone; capturing image data representing an image of an environment appearing within a field of view (FOV) of a handheld scanner including the indicia; encoding the one or more coordinates into a tagline of the image; and providing the image with the tagline to an indicia decoder such that the indicia decoder attempts to decode the indicia from the image data starting in a region of the image data selected based upon the one or more coordinates.