A system for verifying the authenticity of physical goods uses an NFC tag embedded in the product. An NFC reader positioned within range of the tag reads a unique identification number from the tag. The unique identification number may be used to generate an authentication code. During production, the manufacturer generates a blockchain record as a function of the authentication code. The blockchain record includes at least one additional identifier corresponding to the manufacturer. A consumer uses a mobile device to read the NFC tag and obtains the authentication code as a function of the unique identification number. Having the authentication code, the mobile device accesses the record in the blockchain and obtains the identifier corresponding to the manufacturer. Based upon scanning the NFC tag, the consumer is thereby able to obtain an identifier of the manufacturer to ensure authenticity of the product being purchased.

A personal identification device for physical access control systems, including: at least one reader capable of reading data from an identification badge, the data including at least identification data; a processing unit; a data storage member; at least one wireless communication module; and an internal battery arranged to supply power to the components of the device. The processing unit is arranged for: acquiring data from at least one identification badge by way of the reader; storing the acquired data in the data storage member; if the acquired data are encrypted, decrypting the data; and transmitting at least a portion of the acquired data, via the wireless communication module and on request from a reader external to the device.

The present invention discloses a computing platform (100) for movement of one or more containers (102) and method thereof. The present invention provides an improved platform and method for use in an industrial automation environment. Each container (102) includes a chip (104) having container related data. A scanner (108) scans the chip (104), and detect placement related data, and information pertaining to quality parameters of associated material filled in the container (102). A measurement module (110) measures the quality of material. The processing unit (112) assigns the characteristics of the carding machine (106) to the chip (104), and process the container (102) from the assigned carding machine (106) to a second carding machine. The indicator (114) generates an indicating signal. The output generation module (116) generates an output based on the signal, the measured quality, and the characteristics. The report generation module (118) generates a report.

System and method of managing one or more surgical articles, wherein the surgical article can include a surgical sponge comprising an identification element, and wherein managing can include counting, locating, or both. The identification element can be a RFID tag. The RFID tag stores unique identification information relative to the surgical sponge. The system and method for detecting RFID tags may include a hand-held RFID reader operable in a first count-in mode and in a second count-out mode; the hand-held RFID reader may be receivable in a cradle that can determine the presence of the hand-held RFID reader in the cradle; and where operation of the hand-held RFID reader in the second count-out mode is enabled when the hand-held RFID reader is present in the cradle and the second count-out mode is disabled when the hand-held RFID reader is absent from the cradle.

According to one embodiment, a radio tag reading device includes: a body portion including a radio tag reading unit that reads a radio tag; a grip portion detachably connected to the body portion; a magnet provided in the grip portion; a magnet detection unit provided in the body portion and configured to detect magnetism generated by the magnet; a state detection unit configured to detect a state of the grip portion based on the magnetism detected by the magnet detection unit; and a reading control unit configured to control the radio tag reading unit.

A peripheral device at startup selectively activates one of a plurality of connection profiles for low-energy communication with a central device. The profiles determine the behavior of the peripheral device as viewed by the central device, such as a selected one of a HID, a Reader/Scanner, and a PC/SC-like device. The activated profile is selected based on connection profile state maintained across power cycle events and in view of special button combination events at startup. According to embodiment, the profile can also be selected (in conjunction with a reboot) as commanded under select circumstances by an application running on the central device or based on the peripheral reading a configuration card. According to embodiment, the activated profile corresponds to selected sub-portions of a unified database file of the peripheral device. The unified database includes profile components enabling activation of a selected one a plurality of low-energy communication profiles.

A system includes a handheld-computer case and a sled adapter. The handheld-computer case includes a body portion adapted to receive a handheld computer. The sled adapter includes a pedestal adapted to receive the handheld-computer case and a base portion adapted to mount the sled adapter to a sled. The body portion is positioned at a 45-90° angle relative to the base portion.

A computing system can include a radio transceiver and tracking manager software for tracking the location of objects such as tools. Radio frequency identification tags are attached to the objects and can communicate with the radio transceiver. During an initial registration process, the tracking manager software sends an initial registration signal to each object so that the object can be identified in a registered objects file. In one instance, the tracking manager software subsequently sends periodic interrogation signals to the objects to confirm that the objects are within a certain proximity. In another instance, after completing a task a worker can check-in each object wherein the tracking manager software sends interrogation signals to the objects to confirm that all of the objects are accounted for.

Devices for identification and marking of electrical cables and apparatuses in an industrial cabinet include a plate on which is present a bidimensional code, wherein the code presents a possible number of combinations equal to at least 10.sup.6. A system for the identification and marking of electric cable in industrial cabinets includes a set of devices; an apparatus capable of reading the bidimensional codes; and a processor capable of exchanging data with the reading apparatus, and wherein the electrical scheme of the industrial cabinet is charged. A method for identification and marking of electrical cables and apparatuses in an industrial cabinet making use of the above defined system includes installing a device a cable apparatus reading the bidimensional code using the reading apparatus; associating the bidimensional code to an alpha-numeric code defined in the electrical scheme.

Systems and methods for linking real world activity, such as real world commercial activity or real world data collection activity, with a location-based parallel reality game are provided. In particular, a game server hosting a parallel reality game can modify, update, or add to game data stored in a game database associated with the parallel reality game to include certain game features in the parallel reality game linked with real world activity in the real world. The game features can be linked with activities in the real world such that player actions associated with the game features in the virtual world can lead to or encourage activity in the real world, such as commercial activity and/or data collection activity in the real world. A one-time password may be used to validate a player's location in the real world and to enable controlled access to game features in the virtual world.