A feed unit includes: a power transmission section configured to perform power transmission with use of a magnetic field or an electronic field; a power limiting section provided on a power supply line from an external power source to the power transmission section; and a control section provided on a side closer to the external power source than the power limiting section, and including a power transmission control section, the power transmission control section being configured to control the power transmission.

A medical apparatus having an application device which can be brought into contact with a patient to be treated, and a galvanic isolator which can be connected to the application device, the isolator having at least one application connector for connection to the application device and at least one supply connector for connection to a device. The isolator is configured to galvanically isolate the application connector from the supply connector. The isolator has at least one first radio unit connected to the application connector, and at least one second radio unit connected to the supply connector. The first antenna and second antenna are fixed on a carrier at a visible distance from each other. The at least one first radio unit and the at least one second radio unit are configured to transmit signals and/or data between the application connector and the supply connector.

A stackable connector interface with magnetic retention for electronic devices and accessories can allow power and data to be transferred between one or more stacked connectors. Each interconnected stackable connector includes one or more magnetic elements, which magnetic elements have poles arranged to facilitate mating with other stackable connectors. The magnetic elements provide a magnetic retention force that holds mated connectors in contact with each other. In some embodiments, the connectors include connection detection circuitry for determining whether the connectors are mated with other connectors, thereby allowing the connectors to prevent live contacts from being exposed at an unmated surface of the connectors. In some embodiments, routing circuitry is included to determine how signals should be transferred between the interconnected stackable connectors and/or corresponding devices.

A three-dimensional (3D) inductor structure comprising: a first semiconductor die including: a first conductive pattern; and a second conductive pattern spaced apart from the first conductive pattern; a second semiconductor die stacked on the first semiconductor die, the second semiconductor die including: a third conductive pattern; a fourth conductive pattern spaced apart from the third conductive pattern; a first through-substrate via (TSV) penetrating the second semiconductor die and electrically connecting the first conductive pattern with the third conductive pattern; and a second TSV penetrating the second semiconductor die and electrically connecting the second conductive pattern with the fourth conductive pattern, and a first conductive connection pattern included in the first semiconductor die and electrically connecting a first end of the first conductive pattern with a first end of the second conductive pattern, or included in the second semiconductor die and electrically connecting a first end of the third conductive pattern with a first end of the fourth conductive pattern.

A technique facilitates use of an inductive coupler assembly with casing, e.g. well casing. An inductive coupler is formed as a female inductive coupler with an inductive coil. The inductive coupler is constructed for sliding movement along an exterior of the casing so that it may ultimately be positioned and secured at a suitable location along the casing. The inductive coupler is designed for connection with an electrical device, e.g. a sensor. The inductive coupler facilitates the transfer of sensor data and/or power signals across the casing. Signal transfer across the casing is further enabled by a male inductive coupler positioned within the casing at a location which allows it to cooperate with the exterior, female inductive coupler.

A device for the inductive positioning comprises a signal generator, a coil connected with the signal generator, an element for influencing the inductance of the coil depending on its distance to the coil and an evaluator to determine the position of the element with regard to the coil on the basis of a voltage on the coil. The signal generator thereby provides a square wave signal.

According to various embodiments, a dual-band multi-receiver (DBMR) wireless power transfer (WPT) system is disclosed. The WPT system includes a transmitter including a first dc-dc converter coupled to a first inverter, a second dc-dc converter coupled to a second inverter, a reactance steering network (RSN) coupled to the first and second inverters, a high frequency transmitting coil coupled to the RSN, and a low frequency transmitting coil coupled to the first and second dc-dc converters. The WPT system further includes one or more receivers, each receiver including a high frequency receiving coil, a low frequency receiving coil, and a rectifier coupled to the high frequency receiving coil and low frequency receiving coil.

The present relates to a wireless power transmitter performing communication with a wireless power receiver, and a wireless power transfer method thereof. The wireless power transmitter includes a power conversion unit configured to transmit a wireless power signal transferred in a form of an energy field, such as an electric field, a magnetic field or an electromagnetic field, and a power transmission control unit configured to transfer power to the wireless power receiver using the wireless power signal, wherein the power transmission control unit is configured to control the power conversion unit to transmit a near-field communication (NFC) detection signal, other than the wireless power signal, when a preset condition is satisfied, and wherein the power transmission control unit controls the wireless conversion unit in a different manner according to whether or not a response signal to the NFC detection signal is detected.

The present application provides a coil for facilitating an electromagnetic coupling and method for increasing the degree of an electromagnetic coupling. The coil for facilitating an electromagnetic coupling includes one or more loops formed from a material through which an electric current can flow. At least one of the one or more loops is adjustable, including at least one of a size and a shape of the at least one of the one or more loops of the coil being selectively adjustable.

Aspects of the present disclosure are directed to an antenna, various implementations and methods therefor. Various embodiments are amenable to implementation with a receiver circuit that harvests power using energy from a radio frequency (RF) signal received, and a near-field communication (NFC) circuit. A first antenna collects and presents the RF signal to the receiver circuit, and a second antenna communicates NFC signals for the NFC circuit using an antenna portion shared with the first antenna.