An EMI filter system includes a circuit board and a choke. The circuit board includes at least three capacitors. The choke mounts on the circuit board and includes a non-circular magnetic core and at least three windings. The at least three windings are wound on the non-circular magnetic core. The at least three capacitors are disposed adjacent to the choke, and first outlet ends of the at least three windings are respectively connected to the corresponding at least three capacitors.

A fully integrated gyrator with a high speed stack and networks of server farms and telecommunication modes incorporating the gyrator.

A vehicle, an inductor assembly for power electronics in a vehicle, and a method of providing and cooling an inductor assembly are provided. According to one example, the vehicle is provided with an inductor assembly in a vehicle electrical system with a variable voltage converter (VVC). The inductor assembly includes a core formed from a plurality of core segments spaced apart from one another to define gaps therebetween, with each of the plurality of core segments forming an internal fluid passage extending therethrough. The inductor assembly has a winding surrounding at least one of the plurality of core segments. A fluid system is connected to the core to provide pressurized fluid to the fluid passages of the plurality of core segments to circulate fluid through the core of the inductor assembly.

Embodiments for a multifilar inductor with at least three windings that are switchable, having a power assigned winding denoted as P1, a suppression assigned winding denoted as B, a containment assigned winding denoted as T, a switching apparatus to switch assignments between the P1, B and T windings; and a capacitor bank, wherein B suppresses the back EMF generated by a pulse power, T contains field emitted EMF generated by the pulse power, and wherein the input pulse power input is converted to a constant current output into the capacitor bank such that its time duration is extended by the combination of the inductor windings plus the capacitor bank to thereby minimize the peak inductance below the inductor's saturation point.

A method includes: forming an interconnect structure over a semiconductor substrate. The interconnect structure includes: a magnetic core and a conductive coil winding around the magnetic core and electrically insulated from the magnetic core, wherein the conductive coil has horizontally-extending conductive lines and vertically-extending conductive vias electrically connecting the horizontally-extending conductive lines, wherein the magnetic core and the conductive coil are arranged in an inductor zone of the interconnect structure. The interconnect structure also includes a dielectric material electrically insulating the magnetic core from the conductive coil, and a connecting metal line adjacent to and on the outside of the inductor zone. The connecting metal line is electrical isolated from the inductor zone. The connecting metal line includes an upper surface lower than an upper surface of the second conductive vias and a bottom surface higher than a bottom surface of the first conductive vias.

A coil component includes an annular core and a first coil and a second coil wound around the core. The first coil and the second coil include first wire members and second wire members. The second wire members have end surfaces and which are brought into contact with side surfaces of first and second joining portions at tips of the first wire members. The first wire members and the second wire members are joined to each other with welding portions between the side surfaces of the first and second joining portions at the tips of the first wire members and the end surfaces of the second wire members interposed therebetween.

A planar, in particular intrinsically safe transformer, having: a sandwich-type layer structure having a plurality of layers extending horizontally and arranged vertically on top of one another, including a first and a second conductive layer and at least one insulating inner layer disposed between the two conductive layers, a plurality of electrical circuits, wherein a first electrical circuit and at least a second electrical circuit are galvanically isolated from each other; and at least one ring-type magnetic core having a hole, which acts at least on the first electrical circuit and the second electrical circuit. The core is arranged within the at least one insulating inner layer, a conductor of the first electrical circuit and a conductor of the second electrical circuit each have a winding with at least one winding turn, and the at least one winding turn of the first electrical circuit and the at least one winding turn of the second electrical circuit each run along the first conductive layer and along the second conductive layer and through the at least one insulating inner layer and through the hole of the core.

There is provided an apparatus for pulse charging of a load capacitor, the apparatus comprising: a ferrous cored transformer having a primary winding and a secondary winding; a primary circuit connected to the primary winding; a secondary circuit connected to the secondary winding, the secondary circuit comprising the load capacitor; and an uncoupled inductance in the primary circuit or the secondary circuit, the uncoupled inductance reducing the coupling coefficient between the primary circuit and the secondary circuit.

A charger for charging a device to be inductively charged is described, comprising an excitation coil made of an electrical conductor wound around a toroidal core to excite a magnetic field inside the toroidal core, the toroidal core having an air-gap between two end-faces of the toroidal core, wherein the two end-faces are facing each other, and the winding density of the excitation coil along the toroidal length of the toroidal core is higher in the vicinity of the respective end-faces as compared to the remaining parts of the toroidal core.

An electromagnetic device and a method for manufacturing the same are disclosed. The electromagnetic device includes a base plate, a magnetic core, multiple transmission units, and connection layers. The base plate includes a central part defining multiple inner via holes and a peripheral part defining multiple outer via holes. An annular accommodating groove is defined between the central part and the peripheral part. The magnetic core is received in the annular accommodating groove. Transmission units are located on both sides of the base plate. Each transmission unit includes a transmission wire layer including multiple conductive wire patterns, and each conductive wire pattern bridges one inner via hole and one outer via hole. Each of the connection layers is set on one side of the transmission wire layer close to the base plate. At least one connection layer has a dielectric loss no larger than 0.02.