An asset verification system, comprising: a reader comprising a holder configured to hold an asset in a tag-reading position, a light source consisting of at least one light to provide illumination to the asset, magnifying optics configured with an effective magnification for both sufficiently separating dots in a tag in the body of the asset and viewing the tag at an effective magnification greater than 10×, reflective optics for conveying an image of the tag through the reader, and, position controls for adjusting the positioning of the asset with respect to the magnifying optics; a multi-function hardware device comprising an optical sensor for reading the tag of the asset projected to the optical sensor by the reader; and, a database having information related to the asset including an association of the tag to the asset stored thereon.

Systems and methods are provided for acquiring images of objects using an imaging device and a controllable mirror. The controllable mirror can be controlled to change a field of view for the imaging device, including so as to acquire images of different locations, of different parts of an object, or with different degrees of zoom.

The disclosure includes a fixed retail scanner including a data reader comprising a main board, one or more camera modules, and a multi-port network switch disposed within a housing of the data reader. The multi-port network switch is configured to provide a network backbone for at least some internal devices within the housing of the data reader and for at least some external devices positioned external to the housing of the data reader and operably coupled with the data reader through the multi-port network switch. Related systems may include a remote server operably coupled to the fixed retail scanner through the multi-port network switch such that image data to the remote server may be communicated via the multi-port network switch from at least one of the main board or the at least one camera coupled to the multi-port network switch.

Embodiments of the present disclosure provide an alternative illuminator assembly and corresponding imaging assemblies utilizing the alternative illuminator assembly. The alternative illuminator assembly may provide alternative illuminations from those produced by an imager engine, such that the alternative illuminations may provide specific illuminations at specific illumination angles to illuminate a field of view for a desired purpose. In an example context, the alternative illuminator assembly provides one or more alternative illuminations for improving the likelihood of successfully reading specific direct part marking indicias of various types. Embodiments are provided using overlapping subassemblies that enable a small form factor assembly that can fit into mobile apparatus chasses, for example within conventional cell phone housings of around 7 millimeters. The alternative illuminator assembly may be provided together with a small form factor imaging engine, having one or more imager, to improve the direct part marking reading capabilities of the multi-sensor imaging apparatus.

A machine readable symbol reader can include a variable orientation scan engine and features to vary the orientation of the scan engine with respect to a housing of the reader to maintain an orientation of the scan engine in a global sense while an orientation of the rest of the reader including the housing changes. Such a machine readable symbol reader can be used in machine-readable symbol readers such as laser scanning machine readable symbol readers, smartphones with barcode readers attached, barcode scanners, optical imaging scanners, cameras, mobile computers, or for machine vision generally.

Disclosed is a barcode scanner. The barcode scanner can include a top plate and a first illumination source. The top plate can include a surface. The surface can define a scanning window and a first edge of the top plate. The first illumination source can be located proximate the first edge of the top plate. The first illumination source can be arranged to direct light in a direction of the scanning window. The light can have a strobe sequence.

Barcode readers with transflective mirrors are disclosed herein. An example barcode reader includes a housing and a window positioned within the housing, an imaging sensor and an illumination source positioned within the housing, and a transflective mirror positioned within the housing. The field-of-view of the imaging sensor is directed through the window along a first central axis of the field-of-view of the imaging sensor and the illumination pattern from the illumination source is directed through the window along a second central axis of the illumination pattern that is substantially parallel to the first central axis of the field-of-view of the imaging sensor.

A barcode-reading system for a mobile device may include a camera assembly. The barcode-reading system may include a barcode-reading enhancement accessory and a barcode-reading application. The barcode-reading enhancement accessory may be securable to the mobile device and may be configured to provide an indication of license entitlement to the mobile device. The barcode-reading application may be stored in memory of the mobile device and executable by a processor of the mobile device. The barcode-reading application may also be configured to enable an enhanced mode of operation of the barcode-reading application conditional upon determining obtaining the license entitlement from the accessory.

Bioptic barcode readers with multiple imaging devices are disclosed herein. An example bioptic barcode reader includes a housing with a generally horizontal window and an upright window, a barcode reading device positioned within the housing, a first imaging device positioned within the housing, and a second imaging device positioned within the housing below the first imaging device. The first imaging device has a first field-of-view directed out of the upright window, the second imaging device has a second field-of-view directed out of the upright window, and a first central imaging axis of the first field-of-view intersects a second central imaging axis of the second field-of-view at an intersecting angle that is greater than or equal to 15 degrees and less than or equal to 55 degrees. The second central imaging axis of the second field-of-view extends upward above the generally horizontal window at a second angle that is greater than 0 degrees.

A method and apparatus for illuminating at least one object appearing in a field of view (FOV). An illumination system includes an illumination source configured to provide illumination to illuminate a target of the object. A collimating lens is configured to collimate the illumination and to provide the illumination to a fixed multiple lens array (MLA). The fixed multiple lens array provides the illumination to a movable MLA. The movable MLA is configured to provide the illumination to the target to illuminate the target. The position of the movable MLA may be adjusted to alter the illumination full field angle.