A computer-implemented method and system for tracking near-field communication (NFC)-enabled animals with a portable computing device (PCD) (i.e. mobile phone) may include providing an NFC-tag comprising memory in which the memory contains a unique identifier. The NFC-tag may be coupled to an animal and then the NFC-tag may be scanned with the PCD. A tag identification server may determine if data from the NFC-tag exists in a database and then transmits an animal production facility identifier and one or more animal records associated with data from the NFC-tag from the tag identification server if the data from the NFC-tag exists in the database. Access to a secure memory area on the portable computing device containing a complete set of animal records for an entire animal facility may be granted if the software identifier matches the animal production facility identifier received from the tag identification server.

A container arrangement (100) is disclosed, which is preferably destined for pharmaceutical products. The container arrangement includes a container body (110) and a first wireless communication systems (210) composed of a NFC system (210) including an NFC antenna (141). The container arrangement further includes a first and/or a second sensing-switching arrangement (143; 280) configured to include a preset status inhibiting a standardized operability of the first wireless communication system (210). The first sensing-switching arrangement (143) is configured to deregulate its preset status upon an initial opening event and the second sensing-switching arrangement (280) is configured to deregulate its preset status upon an unloading event.

An information presentation system includes an information presentation apparatus, a transmitter attached to a tire and configured to transmit tire ID information for identifying the tire, and a database configured to store tire ID information of tires which are genuine products, and the information presentation apparatus includes a reader configured to perform near field communication with the transmitter, to acquire the tire ID information transmitted by the transmitter, and a controller configured to cause an information presenter to present information indicating that the tire identified with the tire ID information is a genuine product in a case where the tire ID information is stored in the database, and/or cause the information presenter to present information indicating that the tire identified with the tire ID information is a counterfeit product in a case where the tire ID information is not stored in the database.

A radio frequency identification (RFID) tag includes an antenna, an analog front end, a processing circuit, and memory. The analog front end includes a power circuit, a tuning circuit, a transmitter, and a receiver. The power circuit is operably coupled to convert a radio frequency (RF) signal into a power supply voltage. The tuning circuit, when enabled, adjusts an RF characteristic of the analog front end to tune power harvesting from the RF signal. The transmitter is operably coupled to transmit a response signal to the RFID reader via the antenna. The receiver is operably coupled to receive a command signal from the RFID reader, wherein the command signal is contained within a portion of the RF signal. The processing circuit is operable to interpret the command signal and generate the response signal.

A RFID tag (1) for communicating with an external reader comprises: two antenna connections (LA, LB) for connecting the RFID tag (1) to an antenna (10), an active receiver switch circuit (5) for receiving two input sinusoidal signals from the two antenna connections (LA, LB) and generating a rectified waveform signal (8), a modulation detection circuit (12) for receiving two input sinusoidal signals from the two antenna connections (LA, LB) and generating a first demodulation signal (13) related to a 10% amplitude modulation of a RF field for communication between the reader and the RFID tag (1) and a second demodulation signal (14) related to a 100% amplitude modulation of a RF field for communication between the reader and the RFID tag (1).

In embodiments of the present disclosure improved capabilities are described for a tag operating system configured to manage asset data exchanged between an RF reader and one or more asset RF tags, and an IoT connector core integrated with the tag operating system, where the IoT connector core transfers asset data collected via the RF reader from the one or more asset RF tags and delivers the asset data to an IoT system of a cloud platform over a data exchange protocol, and where the asset data was generated at least in part based on an endpoint intelligence function stored on the one or more asset RF tags.

Example embodiments of systems and methods for data transmission between a contactless card and a receiving application are provided. The transmitting device may include a processor, memory, and communication interface. A receiving application may include instructions for execution on a receiving device having a processor, a memory, a communication interface configured to create a communication field for data communication with the transmitting device, and one or more sensors. Upon movement of the transmitting device, the receiving application is configured to receive, via one or more sensors, feedback information associated with the transmitting device, display one or more instructions regarding the position of the transmitting device relative to the receiving device until the transmitting device enters the communication field. Upon entry into the communication field, the transmitting device is configured to transmit data to the receiving device.

Example embodiments of systems and methods for data transmission system between transmitting and receiving devices are provided. In an embodiment, each of the transmitting and receiving devices can contain a master key. The transmitting device can generate a diversified key using the master key, protect a counter value and encrypt data prior to transmitting to the receiving device, which can generate the diversified key based on the master key and can decrypt the data and validate the protected counter value using the diversified key.

A packaging system comprises: a package forming a set of discrete compartments; and a film portion interfacing with the package. The film portion includes a set of one or more electrically conductive traces in which each electrically conductive trace is associated with a respective compartment of the set of discrete compartments. Each electrically conductive trace of the set of electrically conductive traces forms a respective circuit loop that has a terminal end that terminates within an interface region of the film portion to collectively form a termination pattern. At least one of the package or the film portion have two or more alignment ports defined therein that are arranged according to an alignment pattern, each alignment port passing through at least one of the package or film portion.

A wireless communication system includes a plurality of wireless sensors. A wireless sensor includes a radio frequency (RF) receiving circuit, and a sensing element, where the sensing element affects the resonant frequency of the RF receiving circuit. The wireless sensor further includes a processing module operable to determine a first value for an adjustable element of a plurality of elements for a known environmental condition, a second value for the adjustable element for an unknown environmental condition, a difference between the first and second values that corresponds to a change, and to generate a coded value representative of the change. The wireless communication system further includes one or more sensor computing devices coupled to the plurality of wireless sensors via a network. A sensor computing device includes a second processing module operable to receive the coded value and determine a sensed environmental condition based on the coded value.