A printed circuit assembly (PCA) that provides for a method of rebuilding an electrically operated automatic transmission solenoid module. The PCA allows for a repairable yet rugged interconnection of several solenoids that reside within the span of the module assembly.

An inductor is integrated into a multilevel wiring network of a semiconductor integrated circuit. The inductor includes a planar magnetic core and a conductive winding. The conductive winding turns around in generally spiral manner on the outside of the planar magnetic core. The conductive winding is piecewise constructed of wire segments and of VIAs. The wire segments pertain to at least two wiring planes and the VIAs are interconnecting the at least two wiring planes. Methods for such integration, and for fabricating laminated planar magnetic cores are also presented.

A method reduces an area of a mounting electrode provided on a first surface of a multilayer body and connected to a specific component is reduced and decreases a pitch between mounting electrodes. A plating film is formed on the mounting electrodes with the reduced area. The mounting electrodes for connection to specific components are defined by first end surfaces of first via conductors, and hence, the areas of the mounting electrodes are significantly reduced, and the pitch between the mounting electrodes is significantly decreased. Also, the mounting electrodes defined by the first end surfaces of the first via conductors are connected to plane electrodes at end surfaces of second via conductors exposed from a surface of the multilayer body with internal wiring electrodes interposed therebetween. Thus, a plating film is able to be reliably provided on the mounting electrodes.

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.

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 metal member includes a plate-shaped portion provided on an upper main surface of a substrate, and includes a front main surface and a back main surface arranged in a front-back direction when viewed in an up-down direction. A first electronic component is mounted on the upper main surface of the substrate and is disposed in front of the metal member. A second electronic component is mounted on the upper main surface of the substrate and is disposed behind the metal member. A sealing resin layer is provided on the upper main surface of the substrate and covers the metal member and the one or more electronic components. The plate-shaped portion is provided with one or more lower notches extending upward from the lower side. The metal member further includes a plurality of foot portions. All of the plurality of foot portions extend backward from the lower side.

A module includes a substrate, a component mounted on a top surface that is one principal surface of the substrate, a first shielding film provided on a top surface and a side surface of the component, a sealing resin provided on the top surface of the substrate and seals the component, and a second shielding film provided on a top surface of the sealing resin. A hole is provided on a top surface of the sealing resin, to reach at least a part of the first shielding film. The second shielding film disposed in the hole is brought into contact with the first shielding film at positions facing a top surface and a side surface of the component.

A high-frequency module includes: a module board that has main surfaces which are opposed to each other; a plurality of high-frequency components that are arranged on at least one of the main surfaces; a resin member that covers at least one of the main surfaces and has a plurality of side surfaces along an outer edge of the module board; and a shield electrode layer that covers some of the side surfaces without covering other side surfaces.

Provided are a circuit structure, a battery, and an electronic device. The circuit structure comprises: a battery, comprising a first positive electrode, a first negative electrode, and a battery cell, wherein the battery cell is connected between the first positive electrode and the first negative electrode, and the battery cell is configured to generate a first induced magnetic field when a changing current flows therethrough; and an electromagnetic inductor, configured to generate a second induced magnetic field when the changing current flows therethrough, wherein the second induced magnetic field is superposed on the first induced magnetic field.

Embodiments disclosed herein include microelectronic boards and electronic systems. In an embodiment, a microelectronic board comprises aboard substrate, where the board substrate has a first thickness between a first surface and a second surface opposite from the first surface. In an embodiment, a recess is formed into the first surface of the board substrate, where the recess comprises a third surface between the first surface and the second surface. In an embodiment, the board substrate has a second thickness between the third surface and the second surface. In an embodiment, the microelectronic board further comprises a voltage regulator (VR) module attached to the third surface.