Scanning devices, and related methods, for constraining RFID signals within a physical location are disclosed. An example scanning device includes a housing, an identification tag reader in the housing, the identification tag reader having an active mode in which the identification tag reader is configured to identify tags within a detection region about the housing and determine identification data for the identified tags, and the identification tag reader having an inactive mode in which the identification tag reader is prevented from detecting tags within the detection region, and a detector in the housing configured to detect a presence of a control item in an environment, the identification tag reader in the active mode when the control item is detected in the environment, and the identification tag reader in the inactive mode if the presence of the control item is not been detected.

This image processing device includes: a detection object including cells having first cells capable of reflecting emitted light and second cells incapable of reflecting the emitted light, the cells being squares or rectangles, the first cells and the second cells being arranged in an aa or ab (where a, b=3, 4, 5, 6, . . . ) matrix on a two-dimensional plane; and a detector including: an illuminator emitting light; imagers imaging, by a camera, light reflected from the first cells after the first cells and the second cells constituting the detection object are illuminated with the light emitted from the illuminator; and a calculator obtaining information set on the detection object 11, based on imaged data items taken by the imagers. Such a configuration can accurately identify a compact marker and measure the distance, and achieve a system inexpensively.

In a method for obtaining information from a coding body (1, 15), information is assigned to a three-dimensional form of at least one portion of the coding body (1, 15), at least one two-dimensional image of at least the portion of the coding body (1, 15) is generated, the form of the portion is identified on the basis of the image and the information that has been assigned to the identified form is accessed. A corresponding system comprises: at least one coding body (1, 15) having at least one portion with a three-dimensional form that has information assigned; at least one image-capture means (8, 19, 24) for generating two-dimensional images; and at least one processor (9, 21, 25) configured to identify the form of the portion on the basis of at least one two-dimensional image of at least the portion of the coding body (1, 15) and to access the information assigned to the identified form.

An object bearing a three-dimensional rotatably-readable encoding of data configured for optical rotational machine-reading, the object being a subject of the data, the encoding of data including a multiplicity of three-dimensional shapes formed on a label adhered to a surface of the object, the surface being arranged for rotation in a plane coinciding with the surface, the multiplicity of three-dimensional shapes being formed to reflect light impinging thereupon while the surface is rotated, characteristics of the reflected light representing data encoded within the multiplicity of three-dimensional shapes.

A radio-frequency identifier tunable by dielectric inserts (3), includes a fixed part (92) and a key (9), the fixed part (92) of includes an indication element (91) and a decoding device (8), which includes an electrical supply unit (84), an evaluation and control unit (83), a decoding device (82) and a control element (81), herein the decoding device (8) is connected to a receiver (7), which includes an antenna (71), an input amplifier (72) and a block (73) of filters and circuits. The decoding device (8) is further connected with a receiver (6), which includes an antenna (61), an output amplifier (63) and a signal generator (62). The key (9) includes at least one carrier (32) connected with at least one insert (3) having at least one additional dielectric block (20) modified on its surface or at least one opening (200) formed inside the insert (3). The dielectric block (20) includes an additional dielectric block (21).

Embodiments related to local tone mapping for symbol reading. A local pixel neighborhood metric is determined for at least one raw pixel in a region-of-interest, which identifies on one or more raw pixels near the at least one raw pixel. A local mapping function is determined for the at least one raw pixel that maps the value of the raw pixel to a mapped pixel value with a mapped bit depth that is smaller than the bit depth associated with the raw image. The local mapping function is based on a value of at least one other raw pixel near the at least one raw pixel within the local pixel neighborhood metric, and at least one parameter determined based on the raw image. A mapped image is computed for the region-of-interest by applying the local mapping function to the raw image.

An indicia reading device for decoding decodable indicia includes an illumination subsystem, an aimer subsystem, an imaging subsystem, a memory, and a processor. The illumination subsystem is operative for projecting an illumination pattern. The aimer subsystem is operative for projecting an aiming pattern. The imaging subsystem includes a stereoscopic imager. The memory is in communication with the stereoscopic imager and is capable of storing frames of image data representing light incident on the stereoscopic imager. The processor is in communication with the memory and is operative to decode a decodable indicia represented in at least one of the frames of image data. The stereoscopic imager is configured to capture multiple images at a baseline distance apart to create three-dimensional images with depth information of the decodable indicia.

The subject technology receives image data including a representation of a physical item. The subject technology analyzes the image data to recognize an object corresponding to an identification indicator of the physical item. The subject technology determines whether the identification indicator of the physical item includes a representation of a barcode. The subject technology extracts verification metadata from the representation of the barcode. The subject technology sends the verification metadata to determine verification information associated with the verification metadata. The subject technology receives the verification information. The subject technology sends the verification information and the verification metadata to determine provenance information associated with the physical item. The subject technology receives, from the second server, the provenance information associated with the physical item. Further, the subject technology causes display, at a client device, of a media overlay including the physical item based at least in part on the provenance information.

Ride-share status information of an autonomous ride-share vehicle is made available to potential passengers by transmitting a status data record an HMI device outside the vehicle. The data record (D) is projected onto a projection area selected outside the vehicle using a projection device (8) of the motor vehicle. The projected data record (D) is read-in using a reading device (10), such as a camera, of the HMI device. The HMI device decodes the read-in data record (D), and provides the status information to a potential passenger on the HMI device (4) based on the decoded data record (D).

A contrast sensor for evaluating identification markings and a method of evaluating identification markings on detecting objects using a contrast sensor, having at least one light transmitter and at least one light receiver, with the light receiver having a single photodiode; having a control and evaluation unit for evaluating the light receiver signal of the light receiver, and having an output for a sensor signal that is formed by the control and evaluation unit on the basis of the light receiver signal, wherein the identification marking has lettering or a marking; an elongate illumination field is projected by the light transmitter onto a region of the identification marking narrow in the direction of movement; and the control and evaluation unit compares a reception signal sequence having a plurality of contrast transitions with a stored reception signal sequence and outputs the sensor signal in dependence on the comparison.