A coil-incorporated multilayer substrate includes base materials and a coil portion including conductor patterns that are wound a plurality of times on at least one of the base materials, and, in a predetermined direction along the surface of the base material of the coil portion, the width of outermost conductor patterns is larger than the widths of the conductor patterns between an innermost conductor pattern and an outermost conductor pattern, the width of the innermost conductor pattern is larger than the widths of the conductor patterns between the outermost conductor pattern and the innermost conductor pattern, and the width of the innermost conductor pattern is larger than the distance between the innermost conductor pattern and the conductor pattern adjacent to the innermost conductor pattern.

A coil component includes a support substrate, a coil portion including a first conductive layer being in contact with one surface of the support substrate, and a second conductive layer disposed on the first conductive layer to be spaced apart from the one surface of the support substrate, and a body including the support substrate and the coil portion embedded in the body. One side of the first conductive layer is closer to a center of the second conductive layer in a width direction of the coil portion than one side of the second conductive layer.

An inductive structure may be manufactured with in-situ characterization of dimensions by forming a metal line on a top surface of a semiconductor die, forming a passivation dielectric layer over the metal line, measuring a height profile of a top surface of the passivation dielectric layer as a function of a lateral displacement, forming a magnetic material plate over the passivation dielectric layer, measuring a height profile of a top surface of the magnetic material plate as a function of the lateral displacement, and determining a thickness profile of the magnetic material plate by subtracting the height profile of the top surface of the passivation dielectric layer from the height profile of the top surface of the magnetic material plate. An inductive structure including the magnetic material plate and the metal line is formed.

A coil electronic component includes a magnetic body having an internal coil part embedded therein, in which the internal coil part includes an insulating substrate, a first insulator, a coil conductor, and a second insulator. The first insulator is disposed on at least one of first and second main surfaces of the insulating substrate and has a groove formed therein. The coil conductor is formed inside the groove. The second insulator encloses the insulating substrate, the first insulator, and the coil conductor. The first insulator may be formed to a thickness larger than (and no more than 40 μm thicker than) a thickness of the coil conductor on the insulating substrate. The first insulator may be formed to a width of 3 μm to 50 μm. Further, the second insulator may extend to a thickness 1 μm to 20 μm larger than that of the first insulator on the insulating substrate.

A package comprising a substrate, a first integrated device coupled to a first surface of the substrate, and a second integrated device coupled to a second surface of the substrate. The substrate includes a dielectric layer and a plurality of interconnects. The plurality of interconnects includes a first plurality of interconnects configured as a first inductor and a second plurality of interconnects configured as a second inductor. The first integrated device is configured to be coupled to the first inductor. The second integrated device is configured to be coupled to the second inductor. The second integrated device is configured to tune the first inductor through the second inductor.

Methods and apparatus for producing helix windings used for a transformer are provided. For example, apparatus comprise an electrically conductive mandrel comprising an elongated body, a head comprising an eyelet detail, and a winding structure disposed along the elongated body.

The present disclosure relates to semiconductor structures and, more particularly, to series inductors and methods of manufacture. A structure includes a plurality of wiring levels each of which include a wiring structure connected in series to one another. A second wiring level being located above a first wiring level of the plurality of wiring levels. A wiring structure on the second wiring level being at least partially outside boundaries of the wiring structure of the first wiring level.

An electronic substrate may be fabricated having a dielectric material, metal pads embedded in the dielectric material with co-planar surfaces spaced less than one tenth millimeter from each other, and a metal trace embedded in the dielectric material and attached between the metal pads, wherein a surface of the metal trace is non-co-planar with the co-planar surfaces of the metal pads at a height of less than one millimeter, and wherein sides of the metal trace are angled relative to the co-planar surfaces of the metal pads. In an embodiment of the present description, an embedded angled inductor may be formed that includes the metal trace. In an embodiment, an integrated circuit package may be formed with the electronic substrate, wherein at least one integrated circuit devices may be attached to the electronic substrate. Other embodiments are disclosed and claimed.

One object is to suppress thermal shrinkage of a cover resin layer at the time of thermal curing. A laminated coil according to one embodiment of the present invention is provided with a magnetic substrate formed of a sintered magnetic material, an insulation resin layer formed on the magnetic substrate, a cover resin layer formed on the insulation resin layer, and a coil conductor embedded in the insulation resin layer. In one embodiment of the present invention, said insulation resin layer includes a first resin and first filler particles, and said cover resin layer includes a second resin and second filler particles. A filling factor of the second filler particles in the cover resin layer is higher than a filling factor of the first filler particles in the insulation resin layer.

A magnetic inlay includes a magnetic matrix and a plurality of electrically conductive vertical through connections extending vertically through the magnetic matrix. Further, a component carrier including the magnetic inlay and a method of manufacturing said magnetic inlay are described.