A method of operating a near-field communication (NFC) circuit, the method including: receiving an interference signal and a data signal through an antenna; adjusting magnitudes of the received interference signal and the received data signal; down-converting frequencies of the interference signal and the data signal, the magnitudes of which are adjusted; filtering the data signal by removing the frequency down-converted interference signal; and adjusting a magnitude of the filtered data signal. The adjusting of the magnitudes of the received interference signal and the received data signal may include adjusting the magnitudes of the interference signal and the data signal such that linearity of the data signal is maintained during signal processing performed on the interference signal and the data signal in the down-converting of the frequencies of the interference signal and the data signal, the filtering of the data signal, and the adjusting of the magnitude of the filtered data signal.

A transaction card may monitor an amount of electric current induced in a first near-field communication (NFC) component of a transaction card. Electric current may be induced in the first NFC component when the first NFC component is within an electromagnetic field generated by a second NFC component of a transaction terminal. The transaction card may dynamically activate one or more output components associated with the transaction card based on the amount of electric current induced in the first NFC component. The one or more output components may indicate whether the transaction card can communicate with the transaction terminal. The transaction card may perform an action related to completing a transaction after determining that the amount of electric current induced in the NFC component satisfies a first threshold. The first threshold may indicate that the transaction card can communicate with the transaction terminal.

A portable object includes a near-field communication device. The communication device includes an electronic chip provided with two terminals connected to an electrical circuit including an antenna and a filter. The communication device is provided to receive and transmit at a defined frequency corresponding to the resonance frequency of the electrical circuit. The portable object includes a control element which is able to be displaced between two predefined positions, i.e. an active position in which the communication device is activated and a passive position in which the communication device is deactivated. The electrical circuit includes, furthermore, a bypass branch provided with a mechanical switch which is able to switch between an open state and a closed state in response to a displacement of the control element from one to the other of its predefined positions causing a modification in the resonance frequency of the electrical circuit.

An electronic device includes a housing antenna formed from a conductive material. At least parts of a side member and a rear cover that constitute the housing of the electronic device are used as an antenna. Accordingly, radiation patterns generated by this antenna are formed on the rear surface of the electronic device as well as at the upper portion of the electronic device. It is therefore possible to perform wireless communication with higher accuracy.

This invention is related to structures of contactless smart cards. The essence of this invention is in that it represents a device containing a microchip installed on a substrate, and an antenna, the leads of which are connected to the leads of the microchip, and a capacitor, connected in parallel to the frame antenna and forming together with the latter the antenna of the contactless smart card in the form of a resonance circuit, while the substrate represents a ring, the outer surface of which carries electrically conductive loops, which form the frame antenna and are coated with open-circuit screening foil, which is coated with a protecting coating that forms a hermetically sealed body. The device achieves the required technological result, related to improved service reliability.

A data transmission unit includes a transmit unit and a receive unit. The transmit unit and the receive unit are relatively movable with respect to another of the receive unit and the transmit unit. The data transmission unit further includes a coupler, the receive unit being configured to receive data from the transmit unit via the coupler even during a relative movement between transmit unit and receive unit. The coupler includes a first dielectric waveguide including a conductor body and a retaining structure.

A chip card body including a metal plate, a reception region in the metal plate for receiving a chip and configured for inductive coupling of the metal plate to a chip received in the reception region; and at least one through-opening in the metal plate and configured such that at least a part of the metal plate acts as an antenna for delivering an electromagnetic signal to the reception region.

An electronic business card information exchange method and device are provided in the present invention. The electronic business card exchange is achieved by way of by way of receiving by a first terminal in a power-off state an induced electric energy provided by a second terminal, sending by the first terminal the first electronic business card information stored locally to the second terminal under the driving of the induced electric energy, then receiving and storing second electronic business card information written by the second terminal. The technical problem in the prior art that the electronic business card information exchange can not be achieved when one of two terminals is in a power-off state is solved.

Server information handling system deployment and maintenance is enhanced with peer-to-peer configuration information transfers that allow a configuration from an existing server information handling system to be copied, modified and then pasted to another server information handling system. In one embodiment, the selection and use of peer-to-peer communications media is managed by a mobile telephone information handling system, such as with one or more of NFC, Bluetooth, and WLAN interfaces.

A stationary communication unit is adapted to be mounted to a headwall of a healthcare facility and enable wireless communication between a patient support apparatus and a nurse call system. The unit also performs one or more additional functions, such as, but not limited to: determining when a healthcare worker enters/exits the room; determining when the patient support apparatus exits/enters the room; storing/retrieving medical device data associated with a patient; directing medical device data to one or more displays in the room; auto-updating, auto-retrieving, and/or auto-displaying data upon healthcare worker entry into the room; auto-muting room sounds during nurse-patient communication; and auto-directing a healthcare workers electronic device to data associated with the patient in that room. In alternative embodiments, one or more of these additional functions are incorporated into a patient support apparatus.