Embodiments discussed herein refer to connectors that enable two structures or devices to be coupled together in a manner that enables consistent and reliable operation of contactless communications and power transfer. The connector integrates power and alignment such that when two connectors are coupled together the power connections are also responsible for connector alignment. The connector alignment ensures that contactless communication channels, spanning between the connectors, are aligned to enable consistent and reliable operation of contactless communications.

A notch filter including an inductor-capacitor tuning circuit is disclosed. The inductor-capacitor tuning circuit may determine a frequency response of the notch filter in accordance with an associated resonant frequency. In some exemplary embodiments, the inductor-capacitor circuit may include a differential inductor divided at a symmetry point and a variable capacitor coupled to the differential inductor at the symmetry point.

A coupling device serves for the contact-free transmission of data signals between signal conductors of two signal lines with the aid of a coupling structure. At least one signal conductor is a signal core of a signal cable. Coupling portions of the two signal conductors are positioned parallel in relation to one another in a defined way with the aid of the coupling structure. At least a first signal conductor preferably being free from galvanically connected coupling elements lies in a coupling aid. The contact-free coupling dispenses with connecting additional coupling elements at the ends to a signal cable in an electrically conducting manner. By obviating the need for special connector fabrication, this achieves the effect of simplifying assembly and at the same time also improving data transmission reliability, since faults that occur for example in a crimping or soldering process are ruled out.

A switching control circuit alternately turns on/off, at a switching frequency at which the impedance of a multi-resonant circuit becomes inductive, switching elements with a dead time therebetween. In an operation in the third quadrant of current-voltage characteristics of the switching elements, the switching elements are turned on by supplying a control signal to control terminals of the switching elements, and a dead time is determined so as to satisfy tctd<(tc+ta), tc representing a commutation period in which the voltages across both ends of the switching circuits change, ta representing a period corresponding to the operation in the third quadrant, and td representing the dead time.

An irreversible circuit element includes first and second high pass isolators each including first and second center electrodes intersecting with and being insulated from each other on a ferrite to which a direct-current magnetic field is applied with a permanent magnet. One end of the first center electrode is an output port and the other end thereof is an input port, and one end of the second center electrode is another output port and the other end thereof is a ground port. A pass frequency band of the first isolator is higher than a pass frequency band of the second isolator. Respective output portions of the first and second isolators are electrically connected and defined as one output terminal, and a low pass filter LPF is inserted between the output terminal and the output port of the second isolator.

A switching control circuit alternately turns on/off, at a switching frequency at which the impedance of a multi-resonant circuit becomes inductive, switching elements with a dead time therebetween. In an operation in the third quadrant of current-voltage characteristics of the switching elements, the switching elements are turned on by supplying a control signal to control terminals of the switching elements, and a dead time is determined so as to satisfy tctd<(tc+ta), tc representing a commutation period in which the voltages across both ends of the switching circuits change, ta representing a period corresponding to the operation in the third quadrant, and td representing the dead time.

A power reception device includes a power reception unit having a first capacitor, receiving electric power in a non-contact manner from an externally provided power transmission unit, a first housing case housing the power reception unit inside, and a first anchor member anchoring the first capacitor. The first housing case includes a first shield defining a region where an electromagnetic field developed around the power reception unit is emitted. The first capacitor is anchored by the first anchor member at a position spaced apart from the first shield.

An irreversible circuit element includes first and second high pass isolators each including first and second center electrodes intersecting with and being insulated from each other on a ferrite to which a direct-current magnetic field is applied with a permanent magnet. One end of the first center electrode is an output port and the other end thereof is an input port, and one end of the second center electrode is another output port and the other end thereof is a ground port. A pass frequency band of the first isolator is higher than a pass frequency band of the second isolator. Respective output portions of the first and second isolators are electrically connected and defined as one output terminal, and a low pass filter LPF is inserted between the output terminal and the output port of the second isolator.

An impedance matching device is presented. The device includes an input terminal configured to receive a radio frequency signal, and an output terminal configured to couple to an amplifier. The device includes an impedance prematch network coupled to the input terminal and the output terminal. The impedance prematch network includes a first inductor, such as a first wire bond. The device includes a resonator structure including a second inductor, such as a wire bond, inductively coupled to the first inductor.

An impedance matching circuit (IMC) is described. The impedance matching circuit includes a first circuit. The first circuit has an input coupled to a kilohertz (kHz) radio frequency (RF) generator. The IMC includes a second circuit. The second circuit has an input coupled to a low frequency megahertz (MHz) RF generator. The IMC includes a third circuit. The third circuit has an input coupled to a high frequency MHz RF generator. The IMC includes an output of the first, second, and third circuits coupled to an input of an RF transmission line. The first circuit and the second circuit provide isolation between a kHz RF signal sent through the first circuit and a low frequency MHz RF signal sent through the second circuit.