A filter circuit includes an input node, an output node, a first filtering element and a second filtering element. The first filtering element has a first terminal coupled to the input node and a second terminal, and is configured to provide a first signal conducting path toward the second terminal for conducting a first signal received at the input node to the second terminal. The second filtering element has a first terminal coupled to the input node and a second terminal, and is configured to provide a second signal conducting path toward the output node for conducting a second signal received at the input node to the output node. The second terminal of the first filtering element and the second terminal of the second filtering element are open-circuit terminals.

An interposer for a processor includes: an electrically insulating material having a first main side and a second main side opposite the first main side; an electrical interface for a processor substrate at the first main side of the electrically insulating material; and a power device module embedded in the electrically insulating material and configured to convert a voltage provided at the second main side of the electrically insulating material to a lower voltage. The power device module has at least one contact configured to receive the voltage provided at the second main side of the electrically insulating material. Distribution circuitry embedded in the electrically insulating material is configured to carry the lower voltage provided by the power device module to the first main side of the electrically insulating material.

An improved distributed-output multi-cell-element power converter utilizes a multiplicity of magnetic core elements, switching elements, capacitor elements and terminal connections in a step and repeat pattern. Stepped secondary-winding elements reduce converter output resistance and improve converter efficiency and scalability to support the high current requirements of very large scale integrated (“VLSI”) circuits.

An inductor component includes a core base material, a magnetic body in the core, a first conductor pattern formed on primary surface of the core, a second conductor pattern formed on secondary surface of the core, and through-hole conductors formed in through holes through the core such that the conductors are connecting the first and second patterns. The first pattern, second pattern and conductors are positioned to form an inductor such that the magnetic body is positioned on inner side of the inductor, each conductor has a diameter k1, each pattern has conductor thickness in range of 50 μm to 200 μm and has line patterns each having width w1 and separated by line separation distance w2, and a ratio of cross-sectional area of each line pattern to cross-sectional area of each conductor along the diameter k1 in direction of the width w1 is in range of 0.8 to 2.0.

An embedded magnetic component transformer device includes primary, secondary, and auxiliary windings that are defined by conductive vias connected by conductive traces. The conductive traces and vias of the auxiliary winding are arranged between the conductive traces and vias of respective first and second portions of the primary winding, so that the auxiliary winding is provided substantially in the center of the width of the PCB. Power connections are provided at respective opposing edges of the device, and surface mounted transistors are provided close to the primary winding portions between the auxiliary winding and the edge of the device. The device provides an efficient utilization of the surface conductive traces such that large areas of the surface remain for other functions, such as ground plates. The thermal properties of the device are balanced by distributing the transistors and the power connections.

A fluid-cooled balun transformer that includes a substrate plate with a first and an opposite second face, a first and a second conductive element arranged on the first and the second face, respectively, wherein a first and a second signal port electrically is connected to the first and the second conductive element, respectively, and a cooling module, where the second conductive element is transformingly coupled to the first conductive element and electrically isolated therefrom, the cooling module includes a first tubular member, the first tubular member has a fluid inlet to receive a coolant fluid into the first tubular member, a flow channel to conduct a flow of coolant fluid within the first tubular member and a fluid outlet to release the coolant fluid from the first tubular member, and where the flow channel of the first tubular member is arranged in thermal contact with the first conductive element.

Disclosed are compositions, devices, systems and fabrication methods for stretchable composite materials and stretchable electronics devices. In some aspects, an elastic composite material for a stretchable electronics device includes a first material having a particular electrical, mechanical or optical property; and a multi-block copolymer configured to form a hyperelastic binder that creates contact between the first material and the multi-block copolymer, in which the elastic composite material is structured to stretch at least 500% in at least one direction of the material and to exhibit the particular electrical, mechanical or optical property imparted from the first material. In some aspects, the stretchable electronics device includes a stretchable battery, biofuel cell, sensor, supercapacitor or other device able to be mounted to skin, clothing or other surface of a user or object.

Disclosed are compositions, devices, systems and fabrication methods for stretchable composite materials and stretchable electronics devices. In some aspects, an elastic composite material for a stretchable electronics device includes a first material having a particular electrical, mechanical or optical property; and a multi-block copolymer configured to form a hyperelastic binder that creates contact between the first material and the multi-block copolymer, in which the elastic composite material is structured to stretch at least 500% in at least one direction of the material and to exhibit the particular electrical, mechanical or optical property imparted from the first material. In some aspects, the stretchable electronics device includes a stretchable battery, biofuel cell, sensor, supercapacitor or other device able to be mounted to skin, clothing or other surface of a user or object.

An electronic board, in particular for a power electronics circuit such as a converter, comprises: a planar substrate having a first side and a second side opposite the first side; at least two magnetic core elements, called the first elements, arranged on the first side of the substrate and each having at least two legs passing through the substrate; and at least two windings, arranged around at least one leg of each first magnetic core; wherein: it also comprises a second magnetic core element in the form of a plate, arranged on the second side of the substrate and in contact with respective ends of the legs of at least two first elements; the first elements, the windings and the second element forming at least two mutually decoupled magnetic circuits.

A method for fabricating printed electronics includes printing a trace of an electrical component on a first substrate to form a first layer. The method further includes printing a trace of an electrical component on at least one additional substrate to form at least one additional layer. The first layer is stacked with the at least one additional layer to create an assembled electrical device. At least one of the layers is modified after printing.