Embodiments described herein may be related to apparatuses, processes, and techniques related to contactless transmission within a package that combines radiating elements with vertical transitions in the package, in particular to a waveguide within a core of the package that is surrounded by a metal ring. A radiating element on one side of the substrate core and above the waveguide surrounded by the metal ring communicates with another radiating element on the other side of the substrate core and below the waveguide surrounded by the metal ring. Other embodiments may be described and/or claimed.

A wiring substrate includes: a first insulating layer; a first metal pattern formed on the first insulating layer; a second insulating layer formed on the first insulating layer so as to cover the first metal pattern; a second metal pattern formed on the second insulating layer; and an organic insulating film contacted with a portion of the second metal pattern. Also, the first metal pattern has: a first lower surface contacted with the first insulating layer; and a first upper surface contacted with the second insulating layer. Also, the second metal pattern has: a second lower surface contacted with the second insulating layer; and a second upper surface contacted with the organic insulating film. Further, a surface roughness of the second upper surface is larger than a surface roughness of each of the second lower surface, the first upper surface and the first lower surface.

Embodiments disclosed herein include coplanar waveguides and methods of forming coplanar waveguides. In an embodiment, a coplanar waveguide comprises a core, and a signal trace on the core. In an embodiment, the signal trace has a first edge and a second edge. In an embodiment, a first ground trace is over the core, and the first ground trace is adjacent to the first edge of the signal trace. In an embodiment, a first ground via plane is below the first ground trace. The coplanar waveguide may further comprise a second ground trace over the core, and the second ground trace is adjacent to the second edge of the signal trace. In an embodiment, a second ground via plane below the second ground trace.

A semiconductor device is disclosed. The semiconductor device includes a first die on a first substrate, a second die on a second substrate separate from the first substrate, a transmission line in a redistribution layer on a wafer, and a magnetic structure surrounds the transmission line. The first transmission line electrically connects the first die and the second die. The magnetic structure is configured to increase the characteristic impedance of the transmission line, which can save the current and power consumption of a current mirror and amplifier in a 3D IC chip-on-wafer-on-substrate (CoWoS) semiconductor package.

A method includes bonding an antenna substrate to a redistribution structure. The antenna substrate has a first part of a first antenna, and the redistribution structure has a second part of the first antenna. The method further includes encapsulating the antenna substrate in an encapsulant, and bonding a package component to the redistribution structure. The redistribution structure includes a third part of a second antenna, and the package component includes a fourth part of the second antenna.

A semiconductor device includes: a multilayer wiring substrate including a plurality of wiring layers; a first semiconductor chip disposed on the wiring substrate; and a bonding layer bonding the first semiconductor chip to the wiring substrate. A trace formed on the wiring substrate includes a first trace width portion and a second trace width portion, a width of the first trace width portion being greater than the second trace width portion.

A radio-frequency module includes a mounting board, a first electronic component, and a second electronic component. The second electronic component is lower in height than the first electronic component. The mounting board includes dielectric layers, conductive layers, and via-conductors. In the mounting board, the dielectric layers and the conductive layers are stacked in the thickness direction of the mounting board. The mounting board has a first region and a second region. The first region overlaps the first electronic component and extends from a first major surface to a second major surface. The second region overlaps the second electronic component and extends from the first major surface to the second major surface. In the mounting board, the conductive layers in the first region are fewer than the conductive layers in the second region. In the mounting board, the first region is thinner than the second region.

The present disclosure relates to a transition system, which includes a monolithic microwave integrated circuit (MMIC) package and a printed-circuit-board (PCB) with a number of PCB vias. The MMIC package has a laminate-based body, which includes a substrate integrated waveguide (SIW) structure with a number of SIW vias, and a MMIC die over the laminate-based body. Herein, the SIW structure faces the PCB and is separate from the PCB with a gap in between. The SIW structure is configured to radiate radio frequency (RF) signals received from the MMIC die to the PCB. An arrangement of the PCB vias is scaling-mirrored to an arrangement of the SIW vias, such that each PCB via and a corresponding SIW via have a same relative position. The arrangement of PCB vias is about aligned with the arrangement of the SIW vias.

In one embodiment, a semiconductor device includes a first substrate with a transistor formed in a first active are, a first bonding pad electrically connected to the transistor and a first metal pad surrounding the first active area. A second substrate of a type that is different from the first substrate includes a passive circuit element in a second active area on a front surface, a second bonding pad electrically connected to the passive circuit element, a second metal pad surrounding the second active area, and a mounting pad on a back surface of the second substrate with a through-via electrically connecting the second bonding pad to the mounting pad. A first interconnection extends from the first bonding pad to the second bonding pad, and a second interconnection extends from the first metal pad to the second metal pad and surrounds the region through which the first interconnection extends.

The invention relates to a flip-chip integrated circuit package of the ball array type, wherein: the underside of the package includes a plurality of receiving pads for signal, ground and solder balls; stacks of signal and ground vias, electrically connected to respective receiving pads, pass vertically through the package's dielectric body forming a quasi-coaxial structure. In an upper part of the package body: the signal vias are electrically connected to a lesser number of signal conductive bumps protruding from the upper surface of the package's dielectric body; and at least two ground vias are connected by means of conductive projections to respective ground conductive bumps, forming a ring around the signal conductive bumps.