A multilayer fringe capacitor includes first and second interdigitated capacitor electrodes, both parallel to and intersecting a first planar surface; third and fourth interdigitated capacitor electrodes, the first and second electrodes parallel to and separated by a non-zero distance from the third and fourth electrodes; a first set of coupling vias that electrically couples the first electrode to the third electrode; and a second set of coupling vias that electrically couples the second electrode to the fourth electrode.

A multilayer fringe capacitor includes first and second interdigitated capacitor electrodes, both parallel to and intersecting a first planar surface; third and fourth interdigitated capacitor electrodes, the first and second electrodes parallel to and separated by a non-zero distance from the third and fourth electrodes; a first set of coupling vias that electrically couples the first electrode to the third electrode; and a second set of coupling vias that electrically couples the second electrode to the fourth electrode.

An analog time delay filter circuit including a first delay circuit block arranged in a modular layout, having a first time delay filter, a first input, a first output, and first and second pass-throughs; a second delay circuit block arranged in the same modular layout, having a second time delay filter, a second input, a second output, and third and fourth pass-throughs; and an interposer circuit block that electrically couples the second input to the first pass-through and the second output to the second pass-through.

An analog time delay filter circuit including a first delay circuit block arranged in a modular layout, having a first time delay filter, a first input, a first output, and first and second pass-throughs; a second delay circuit block arranged in the same modular layout, having a second time delay filter, a second input, a second output, and third and fourth pass-throughs; and an interposer circuit block that electrically couples the second input to the first pass-through and the second output to the second pass-through.

An electrical resonance network comprising a first capacitor and a first inductor whose resonance frequency can be tuned by means of a second capacitor and/or a second inductor. The resulting effective capacitor- or inductor value of a network period is controlled by a variable coupling respectively decoupling interval by means of at least one coupling switch. The coupling respectively decoupling interval is synchronized by a sign change of a current and/or voltage in the network.

An electrical circuit can be formed at least in part using lumped or discrete circuit elements to provide an artificial transmission line structure that can mimic the electrical properties of a corresponding actual transmission line structure. Such an artificial transmission line structure can generally consume less area than an actual transmission line structure lacking such lumped or discrete elements. Such an artificial transmission line structure can be formed using two or more unit cells such as by cascading such cells as shown and described herein. The present inventors have recognized, among other things, that a unit cell of an artificial transmission line structure can include a t-coil section comprising magnetically-coupled inductors. Such an artificial transmission line structure can be used for applications such as phase shifting or to provide a delay line having a substantially constant group delay, among other applications.

A clock recovery circuit includes a first pulse circuit, a second pulse circuit, a state change circuit connected to the first pulse circuit and the second pulse circuit and a first delay circuit connected to the state change circuit and each of the first pulse circuit and the second pulse circuit. The first pulse circuit receives data inputs to generate a first pulse signal. The second pulse circuit receives the data inputs to generate a second pulse signal. The state change circuit receives the first pulse signal and the second pulse signal and generate a first clock signal for a first transition of one of the data inputs in a first unit interval (UI). The first delay circuit receives the generated first clock signal and mask other transitions of the data inputs in the first UI.

An electrical circuit can be formed at least in part using lumped or discrete circuit elements to provide an artificial transmission line structure that can mimic the electrical properties of a corresponding actual transmission line structure. Such an artificial transmission line structure can generally consume less area than an actual transmission line structure lac0ure can be formed using two or more unit cells such as by cascading such cells as shown and described herein. The present inventors have recognized, among other things, that a unit cell of an artificial transmission line structure can include a t-coil section comprising magnetically-coupled inductors. Such an artificial transmission line structure can be used for applications such as phase shifting or to provide a delay line having a substantially constant group delay, among other applications.

The disclosure disclosed herein provides a wireless power transmission device that wirelessly transmits power to electronic equipment coupled to a seat regardless of a position of the seat. According to an embodiment of the disclosure disclosed herein, a wireless power transmission device includes a power receiving unit coupled to a lower portion of a seat, and a power transmitting unit spaced apart from and below the power receiving unit, in which the power receiving unit is spaced apart from the power transmitting unit and slides into a moving direction of the seat, and the power receiving unit wirelessly receives power from the power transmitting unit and supplies power to electronic equipment installed in the seat.

The disclosure disclosed herein provides a wireless power transmission device that wirelessly transmits power to electronic equipment coupled to a seat regardless of a position of the seat. According to an embodiment of the disclosure disclosed herein, a wireless power transmission device includes a power receiving unit coupled to a lower portion of a seat, and a power transmitting unit spaced apart from and below the power receiving unit, in which the power receiving unit is spaced apart from the power transmitting unit and slides into a moving direction of the seat, and the power receiving unit wirelessly receives power from the power transmitting unit and supplies power to electronic equipment installed in the seat.