A method for fabricating an electrical or electronic device package includes providing a first plateable encapsulation layer; activating first selective areas on a main surface of the first plateable encapsulation layer; forming a first metallization layer by electrolytic or electroless plating on the first activated areas; and fabricating a passive electrical component on the basis of the first metallization layer.

New types of circuit elements for integrated circuits include structures wherein a thickness dimension is much greater than a width dimension and is more closely spaced than the width dimension in order to attain a tight coupling condition. The structure is suitable to form inductors, capacitors, transmission lines and low impedance power distribution networks in integrated circuits. The width dimension is on the same order of magnitude as skin depth. Embodiments include a spiral winding disposed in a silicon substrate formed of a deep, narrow, conductor-covered spiral ridge separated by a narrow spiral trench. Other embodiments include a wide, thin conductor formed in or on a flexible insulative ribbon and wound with turns adjacent one another, or a conductor in or on a flexible insulative sheet folded into layers with windings adjacent one another Further, a method of manufacture includes directional etching of the deep, narrow spiral trench to form a winding in silicon.

A circuit includes a semiconductor substrate and an integrated passive device. The integrated passive device is on a surface of the semiconductor substrate. The integrated passive device is in a metal layer on the semiconductor substrate. The metal layer is at least tens of micrometers thick. The integrated passive device may be an inductor or a capacitor in some examples.

Disclosed are a device and techniques for fabricating the device. The device may include a top substrate including a plurality of top vias coupled to a first top metal layer that forms a top winding portion of a first inductor. The device also includes a middle substrate including one or more middle metal layers. The top substrate is disposed on the middle substrate. The one or more middle metal layers form a middle winding portion of the first inductor. The device also includes a bottom substrate electrically coupled to the middle substrate opposite the top substrate, where a first bottom metal layer of the bottom substrate forms a bottom winding portion of the first inductor.

A device includes an integrated inductor and metal interconnect formed in an integrated circuit (IC) structure. The integrated inductor includes an inductor wire having a portion defined by an inductor element stack including (a) a metal layer inductor element formed in a metal layer in the IC structure and (b) a multi-component via layer inductor element formed in a via layer in the IC structure vertically adjacent the metal layer, and conductively connected to the metal layer inductor element. The multi-component via layer inductor element includes a via layer inductor element cup-shaped component formed from a first metal, and a via layer inductor element fill component formed from a second metal in an opening defined by the via layer inductor element cup-shaped component. The metal interconnect includes a metal layer interconnect element formed in the metal layer, and an interconnect via formed in the via layer from the first metal.

A device includes (a) an integrated inductor having an inductor wire and (b) a metal interconnect arrangement, both formed in an integrated circuit layer stack of alternating metal layers and via layers. At least a portion of the inductor wire is defined by an inductor element stack including multiple metal layer inductor elements formed in multiple respective metal layers, and multiple via layer inductor elements formed in multiple respective via layers and conductively connected to the metal layer inductor elements. Each via layer inductor element has a length of at least 1 μm in each of two lateral directions orthogonal to each other and perpendicular to the vertical direction. The metal interconnect arrangement includes metal layer interconnect elements formed in the respective metal layers, and interconnect vias formed in the respective via layers.

New types of circuit elements for integrated circuits include structures wherein a thickness dimension is much greater than a width dimension and is more closely spaced than the width dimension in order to attain a tight coupling condition. The structure is suitable to form inductors, capacitors, transmission lines and low impedance power distribution networks in integrated circuits. The width dimension is on the same order of magnitude as skin depth. Embodiments include a spiral winding disposed in a silicon substrate formed of a deep, narrow, conductor-covered spiral ridge separated by a narrow spiral trench. Other embodiments include a wide, thin conductor formed in or on a flexible insulative ribbon and wound with turns adjacent one another, or a conductor in or on a flexible insulative sheet folded into layers with windings adjacent one another Further, a method of manufacture includes directional etching of the deep, narrow spiral trench to form a winding in silicon.

A semiconductor device includes a semiconductor substrate, an interconnection layer and an inductor pattern. The interconnection layer is disposed on the semiconductor substrate. The inductor pattern is electrically connected to the interconnection layer. The inductor pattern includes a first conductive line joined with a first terminal, a second conductive line joined with a second terminal, and a plurality of conductive coils. The conductive coils are joining the first conductive line to the second conductive line, and includes an outer coil joined with the first conductive line, an inner coil joined with the second conductive line and the outer coil. The second conductive line is spaced apart from a first side of the inner coil in a first direction by distance Y, the second terminal is spaced apart from a second side of the inner coil in a second direction by distance X1, wherein X1>1.25Y.

An inductor includes a semiconductor substrate provided with a plurality of wiring levels including a first wiring level and a second wiring level, a straight conductive line, at the first wiring level of the semiconductor substrate, having a first end, a conductive coil of a spiral pattern, at the second wiring level over the first wiring level, having a second end, and a conductive via vertically connecting the first end of the straight conductive line to the second end of the conductive coil. When viewed in a plan view, a plurality of dummy patterns are arranged in a first area defined by an innermost turn of the spiral pattern.

Coil structures and methods of forming are provided. The coil structure includes a substrate. A plurality of coils is disposed over the substrate, each coil comprising a conductive element that forms a continuous spiral having a hexagonal shape in a plan view of the coil structure. The plurality of coils is arranged in a honeycomb pattern, and each conductive element is electrically connected to an external electrical circuit.