A microplate reader and a method for operating the microplate reader are disclosed. The microplate reader includes a housing, a first NFC reader/writer, a filter tray positioning device, a filter tray, an optical filter disposed in the filter tray, and a controller. The filter tray has a filter tray NFC tag disposed thereon and the filter has a filter NFC tag disposed thereon. The controller receives information about an assay protocol to be undertaken, wherein the assay protocol specifies a filter to be used. The first NFC reader/writer reads filter information stored in the filter NFC tag, the controller directs the NFC reader/writer to store the filter information in the filter tray NFC tag, and the controller enables operation of the microplate reader to undertake the assay protocol only if filter information indicates that the optical filter is in accordance with the filter specified in the assay protocol.

A housing is arranged to house therein at least a portion of a rotary drive apparatus arranged to rotate an optical component arranged to reflect incoming light coming from a light source. The 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.

The present invention relates to a method for checking an identity of an individual, which method comprises the following steps: a) presenting an optically readable code (14) with a mobile device (10); b) reading the optically readable code (14) with an optical reading device (20); c) extracting the data contained in the optically readable code (14); d) verifying the data contained in the optically readable code (14); and e) displaying at least a portion of the data on the optical reading device (20). The steps c) to e) are executed by the optical reading device (20).

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.

A security substrate has: a polymer substrate having first and second surfaces; array of focussing elements; an optical adjustment layer and masking layer. The array is formed of a surface relief. The optical adjustment layer is on the transparent base layer across a second region including the first. The optical adjustment layer has a first surface contacting the surface relief and an opposing second surface having a profile not operative to focus visible light. The optical adjustment layer has a first transparent material extending across a first sub-region of the array, the first transparent material having a refractive index different from that of the transparent base layer. The security substrate has a masking layer over the optical adjustment layer across a third region of the polymer substrate, the third region defining a gap in the masking layer(s), such that functional focusing elements of the array are revealed through the gap.

An image capture device capable of forming an aiming pattern according to a shape of a grating includes a body, an image capture module, and a light source. The body includes a tubular chamber and a light source chamber. One end of the tubular chamber is connected to the light source chamber, and the other end is connected to a first surface of the body. In addition, a grating is disposed between the tubular chamber and the light source chamber, and the grating has a shape capable of forming an aiming pattern. The image capture module is disposed on the body. The light source is disposed in the light source chamber, and a light beam emitted by the light source may pass through the grating and the tubular chamber and exit through the first surface to generate an aiming pattern corresponding to the shape of the grating.

An image capture device capable of forming an aiming pattern according to a shape of a grating includes a body, an image capture module, and a light source. The body includes a tubular chamber and a light source chamber. One end of the tubular chamber is connected to the light source chamber, and the other end is connected to a first surface of the body. In addition, a grating is disposed between the tubular chamber and the light source chamber, and the grating has a shape capable of forming an aiming pattern. The image capture module is disposed on the body. The light source is disposed in the light source chamber, and a light beam emitted by the light source may pass through the grating and the tubular chamber and exit through the first surface to generate an aiming pattern corresponding to the shape of the grating.

A bar code reader device (10) having a bar code reader apparatus (12) with: a) a light emitter system (14); b) a light recovery system (28) capable of recovering light reflected from a working viewing zone through a reflected light conditioning system (30); and c) a photoelectric sensor. The device (10) includes an auxiliary optical system (36) that is arranged permanently in the working viewing zone at a distance from the sensor (26) and in series with the reflected light conditioning system (30) in such a manner that a fraction, but not all, of the working viewing zone is intercepted by the auxiliary optical system (36).

A microplate reader and a method for operating the microplate reader are disclosed. The microplate reader includes a housing, a first NFC reader/writer, a filter tray positioning device, a filter tray, an optical filter disposed in the filter tray, and a controller. The filter tray has a filter tray NFC tag disposed thereon and the filter has a filter NFC tag disposed thereon. The controller receives information about an assay protocol to be undertaken, wherein the assay protocol specifies a filter to be used. The first NFC reader/writer reads filter information stored in the filter NFC tag, the controller directs the NFC reader/writer to store the filter information in the filter tray NFC tag, and the controller enables operation of the microplate reader to undertake the assay protocol only if filter information indicates that the optical filter is in accordance with the filter specified in the assay protocol.

The present disclosure discloses a handheld scanner and a scanning method for the handheld scanner. The handheld scanner includes a texture camera, a first black-and-white camera and a second black-and-white camera, where the first black-and-white camera and the second black-and-white camera are spaced apart from each other; and the handheld scanner further includes a laser projector, and the texture camera and the first black-and-white camera are respectively arranged at two sides of the laser projector. When a highly reflective or dark object is scanned, textures are obtained by the texture camera while laser scanning is performed; and after point cloud fusion is completed, texture images are screened and fused according to a shooting angle and the highlight degree of the image, so that the overall texture image of point cloud is obtained.