A method for inserting information into a 3D structure and recognizing information in a non-destructive method is provided. A 3D printing method according to an exemplary embodiment of the present invention includes: generating a tag having specific information recorded thereon to be inserted into a 3D structure, and printing the tag on the inside of the 3D structure while printing the 3D structure. Accordingly, since the tag having information recorded thereon is printed on the inside of the 3D structure when the 3D structure is printed by a 3D printer, it is impossible to forge/falsify information.

An identification device that is attached to a target component and stores identification information of the target component; and a first communication device and a second communication device that wirelessly communicate with the identification device. The second communication device holds and transmits the identification information acquired by the second communication device as second-communication-device acquisition information. The first communication device includes: a first-communication-device holder that holds the identification information acquired by the first communication device and the received second-communication-device acquisition information as first-communication-device acquisition information and a first-communication-device judging unit that judges whether or not the identification information having the same contents is contained in the first-communication-device acquisition information. When the first-communication-device judging unit judges that the identification information having the same contents is contained in the first-communication-device acquisition information the first-communication-device holder merges the identification information judged to have the same contents.

A computer-implemented method leverages the capabilities present in common mobile communications devices—RF transceivers, Internet connectivity, payment system, geolocation system, notification system, and user interface—to simplify and reduce overhead from the parking experience. Furthermore, this method utilizes distributed authentication and authorization and multi-path queued message delivery to provide this experience when cellular or WiFi Internet connectivity is absent in the parking facility, simplifying and reducing the cost of deployment.

Systems and methods to perform verification of physical control of a security device by a user are disclosed. In one aspect, embodiments of the present disclosure include a method for identifying a symbol in a first image frame of a microlens array of the security device and/or determining a position of the symbol relative to a predetermined point on a 2D plane of the security device. In a further embodiment, a rate of change of the position of the symbol between a second image and the first image frame of the microlens array can be determined. The physical control of the security device by the user is, for example, ascertained if the user is in close proximity to the security device of if the security device is within a line of sight of the user.

The present invention discloses an optical anti-counterfeiting component and an optical anti-counterfeiting product. The optical anti-counterfeiting component comprises: a substrate; a sub-wavelength surface micro-structure and an optical reflection facet formed on an upper surface of the substrate; and a multi-layer structured coating formed on the sub-wavelength surface micro-structure and the optical reflection facet. In the case where the same multi-layer structured coating is used, a contrasting optical characteristic is formed between the region in which the sub-wavelength surface micro-structure and the multi-layer structured coating lie and the region in which the optical reflection facet and the multi-layer structured coating lie, so that the optical anti-counterfeiting component or the optical anti-counterfeiting product that includes the optical anti-counterfeiting component can be identified easily and has high anti-counterfeiting capability.

The present invention discloses an optical anti-counterfeiting component and an optical anti-counterfeiting product. The optical anti-counterfeiting component comprises: a substrate; a sub-wavelength surface micro-structure and an optical reflection facet formed on an upper surface of the substrate; and a multi-layer structured coating formed on the sub-wavelength surface micro-structure and the optical reflection facet. In the case where the same multi-layer structured coating is used, a contrasting optical characteristic is formed between the region in which the sub-wavelength surface micro-structure and the multi-layer structured coating lie and the region in which the optical reflection facet and the multi-layer structured coating lie, so that the optical anti-counterfeiting component or the optical anti-counterfeiting product that includes the optical anti-counterfeiting component can be identified easily and has high anti-counterfeiting capability.

A security feature and a method for creating a barcode are disclosed. Data is concatenating to be represented in the barcode. The concatenated data is partitioned into n-bit segments. The formatted data is encoded by assigning a respective code to each n-bit segment. The barcode is created using the encoded data.

A security feature and a method for creating a barcode are disclosed. Data is concatenating to be represented in the barcode. The concatenated data is partitioned into n-bit segments. The formatted data is encoded by assigning a respective code to each n-bit segment. The barcode is created using the encoded data.

A mobile robot is configured for operation in a commercial or industrial setting, such as an office building or retail store. The robot can patrol one or more routes within a building, and can detect violations of security policies by objects, building infrastructure and security systems, or individuals. In response to the detected violations, the robot can perform one or more security operations. The robot can include a removable fabric panel, enabling sensors within the robot body to capture signals that propagate through the fabric. In addition, the robot can scan RFID tags of objects within an area, for instance coupled to store inventory. Likewise, the robot can generate or update one or more semantic maps for use by the robot in navigating an area and for measuring compliance with security policies.

The present invention relates to the use of nanosystems as non deactivable security markers comprising metal atomic quantum clusters (AQCs) of at least two different size distributions encapsulated in a cavity with an inner diameter less than or equal to approximately 10 nm. These nanosystems are luminescence, particularly fluorescence after external excitation. The invention also relates to security documents, articles or elements incorporating these markers as well as to a method and a system for detecting the same.