Tags comprising marks arranged in a predetermined pattern are applied to an item. The marks are made with an ink that fluoresces under infrared (IR) light. A camera with a filter acquires an image of the light emitted by the fluorescence of the ink. This image is processed to determine a portion of the image in which the tag is located. Once located, that portion is processed to rectify and align the tag. This rectified image is then processed to read out tag data that is encoded by the arrangement of marks. The tag data may then be used to identify the item, designate shipping information, and so forth.

A housing includes a first tubular portion being tubular, arranged to extend along a central axis extending in a vertical direction, and having a first cavity defined radially inside of the first tubular portion; and a second tubular portion being tubular, connected to a lower portion of the first tubular portion directly or indirectly, and having a second cavity defined radially inside of the second tubular portion. The first cavity is arranged to define a light path along which the incoming light travels, and is connected to the second cavity. The second tubular portion is arranged to house at least a portion of the optical component therein. The first and second tubular portions are defined by a single monolithic member.

A system and method of imaging barcodes may include generating a first light beam from an illumination surface having first dimensions. The first light beam may be directed into an input aperture of an optical component to form a second light beam. The input aperture has second dimensions, where the first dimensions are at least as large as the second dimensions. The second light beam having irradiation spatially distributed across the second light beam may be projected to read a machine-readable indicia.

An imaging system (100) including at least one camera (3), a background element (4) and a pair of mirrors (2a, 2b), where the mirror surfaces of the mirrors in the pair are angled from each other at an angle , where the imaging system (100) is intended to receive a sample along a main axis extending between the mirrors. The camera (3) is directed towards the mirror pair (2a, 2b) and the background element (4) includes a surface directed towards the mirror pair, where the background element (4) is formed as a cylinder portion with a cylinder axis deviating from the main axis, and the mirrors are arranged with a respective mirror surface edge to edge with each other.

A control system for controlled access to a user by means of verifying a physical element defined in an optical and low level of power context, which includes: a setup (1) for the creation of arbitrary spatial light patterns, with control of amplitude and phase; which includes: a source of light (9) which emits a Laser beam; toward a first microscope objective (11); a spatial light modulation set (2) which receives the light of the first microscope objective (11) and said spatial light modulator set (2) sends a profile modulated in amplitude and phase which form an image to a beam splitter BS (17) which divides the image into an initial CCD camera (6) and to a second microscope objective (12); a defined physical element (7) which receives the initial image from the second microscope objective (12), and transmits the image without diffracting it as a final image to a third microscope objective (13); a final CCD camera (8), that receives the final image of the third microscope objective (13) and sends it to a computer (300) which compares that final image with the initial image, and performs a calculation of similarity between both images to decide to grant access to the user, if the similarity is greater than a predefined value, and deny it if the similarity is less than a predefined value; a control procedure of controlled access which compares a pattern of dots transmitted through the defined physical element, which code the numbers 0 to 9 and decides to grant or deny access if it matches with the key entered by user.

An electronic device may be attached to an external item. The electronic device may include an optical identification sensor configured to sense a color-encoded tag in the external item when the item is attached to the device. The optical identification sensor may include a board layer, a protective filter layer, wall structures for supporting the protective filter layer on the board layer, a linear array of photodetectors disposed between the board layer and the protective filter layer, a field-of-view restriction filter interposed between the photodetectors and the protective filter layer, and a light source having multiple emitters for illuminating the color-encoded tag. The emitters may be activated sequentially to produce multiple images that are combined to reconstruct an accurate reading of the color-encoded tag, which can then be used to identify the type of external item currently attached to the electronic device.

A barcode reader, an imaging engine, and an optical assembly and method for assembling such to maintain stability through physical shock and to control decentration are disclosed herein. An example optical assembly includes an actuator, adjustable lens group, and rear lens group. The actuator includes an inner carriage, wherein one or more inner walls of the inner carriage are at least partially threaded. The adjustable lens group includes a first lens element, wherein the first lens element is threaded and held in place by the at least partially threaded one or more inner walls of the inner carriage, and a second lens element, wherein the second lens element is coupled to the first lens element, and further wherein the second lens element is fixedly co-located to the first lens element. The front lens group is actively aligned to the rear lens group, which includes one or more fixed optical elements.

Imaging devices and illuminating devices are provided. In one exemplary implementation, an imaging device comprises an optical sensor and an illuminator. The illuminator comprises a support frame and a plurality of light emitting diodes (LEDs) connected to the support frame. A first set of LEDs of the plurality of LEDs is configured to provide dark field illumination at a high angle of incidence with respect to an object. The first set of LEDs is configured to provide illumination without the use of a light pipe, diffuser, or reflector. A second set of LEDs of the plurality of LEDs is configured to provide bright field illumination at a low angle of incidence with respect to the object. The second set of LEDs is configured to provide illumination without the use of a light pipe, diffuser, or reflector.

Imaging devices and illuminating devices are provided. In one exemplary implementation, an imaging device comprises an optical sensor and an illuminator. The illuminator comprises a support frame and a plurality of light emitting diodes (LEDs) connected to the support frame. A first set of LEDs of the plurality of LEDs is configured to provide dark field illumination at a high angle of incidence with respect to an object. The first set of LEDs is configured to provide illumination without the use of a light pipe, diffuser, or reflector. A second set of LEDs of the plurality of LEDs is configured to provide bright field illumination at a low angle of incidence with respect to the object. The second set of LEDs is configured to provide illumination without the use of a light pipe, diffuser, or reflector.

A light pipe for an electronic device, such as a barcode-reading device, can include a plurality of light-redirecting surfaces that are each positioned to receive light from a light source within the interior portion of the barcode-reading device and to redirect the light toward an optical element positioned on an exterior surface of the barcode-reading device. The plurality of light sources and the plurality of light-redirecting surfaces can collectively produce a uniform light output at the optical element when all of the plurality of light sources are activated. The light pipe can also include a plurality of optical barriers interspersed between the plurality of light-redirecting surfaces to isolate light from individual light sources. This allows for a segmented light output to be projected onto the optical element. The light pipe can be made from a flexible and resilient material, thereby allowing the light pipe to provide shock absorption.