Waveguides and methods for manufacturing a waveguide that include forming a first channel in a first layer of dielectric material, the first channel comprising one or more walls; forming a second channel in a second layer of dielectric material, the second channel comprising one or more walls; depositing electrically conductive material on the one or more walls of the first channel; depositing electrically conductive material on the one or more walls of the second channel; arranging the first layer adjacent to the second layer to form a stack with the first channel axially aligned with and facing the second channel; and heating the stack so that the conductive material on the one or more walls of the first channel and the conductive material on the one or more walls of the second channel connect to form the waveguide.

Embodiments may relate to a semiconductor package that includes a package substrate coupled with a die. The package may further include a waveguide coupled with the first package substrate. The waveguide may include two or more layers of a dielectric material with a waveguide channel positioned between two layers of the two or more layers of the dielectric material. The waveguide channel may convey an electromagnetic signal with a frequency greater than 30 gigahertz (GHz). Other embodiments may be described or claimed.

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.

Embodiments may relate to a semiconductor package that includes a die and a package substrate. The package substrate may include one or more cavities that go through the package substrate from a first side of the package substrate that faces the die to a second side of the package substrate opposite the first side. The semiconductor package may further include a waveguide communicatively coupled with the die. The waveguide may extend through one of the one or more cavities such that the waveguide protrudes from the second side of the package substrate. Other embodiments may be described or claimed.

Waveguides and methods for manufacturing a waveguide that include forming a first channel in a first layer of dielectric material, the first channel comprising one or more walls; forming a second channel in a second layer of dielectric material, the second channel comprising one or more walls; depositing electrically conductive material on the one or more walls of the first channel; depositing electrically conductive material on the one or more walls of the second channel; arranging the first layer adjacent to the second layer to form a stack with the first channel axially aligned with and facing the second channel; and heating the stack so that the conductive material on the one or more walls of the first channel and the conductive material on the one or more walls of the second channel connect to form the waveguide.

A method of fabricating and tuning a surface integrated waveguide (SIW) filter incudes covering upper and lower surfaces of a dielectric substrate with a metallic layer. The method includes drilling a plurality of vias on the dielectric substrate and covering the vias with the metallic layer, wherein a first group of vias forms one or more cavity resonators, a second group of vias defines coupling channels between the cavity resonators, a third group of vias defines an effective width and a fourth group of vias defines an effective length of the cavity resonators. The method includes varying a center frequency by increasing diameters of the second group of vias to decrease the width of the coupling channels and varying a roll-off by increasing diameters of the third and fourth groups of vias to decrease the effective width and the effective length of the resonators.

A method of fabricating an RF filter on a semiconductor package comprises forming a first dielectric buildup film. A second dielectric buildup film is formed over the first dielectric buildup film, the second dielectric buildup film comprising a dielectric material that contains a metallization catalyst, wherein the dielectric material comprises one of an epoxy-polymer blend dielectric material, silicon dioxide and silicon nitride, and a low-k dielectric. A trench is formed in the second dielectric buildup film with laser ablation, wherein the laser ablation selectively activates sidewalls of the trench for electroless metal deposition. A metal selectively is plated to sidewalls of the trench based at least in part on the metallization catalyst and immersion in an electroless solution. A low-loss buildup film is formed over the metal that substantially fills the trench.

A method of forming a semiconductor structure is provided. A first inter-level dielectric (ILD) layer is formed overlying a molding layer. The first ILD layer is patterned to form a plurality of first openings. A first lower transmitter electrode and a first lower receiver electrode are formed by depositing a first metal material within the plurality of first openings. A first dielectric waveguide is formed overlying the first ILD layer, the first lower transmitter electrode and the first lower receiver electrode. A second ILD layer is formed overlying the first dielectric waveguide and includes a plurality of second openings. A second lower transmitter electrode and a second lower receiver electrode are formed by depositing a second metal material within the plurality of second openings. A second dielectric waveguide is formed overlying the second ILD layer, the second lower transmitter electrode and the second lower receiver electrode.

An antenna arrangement comprising a SIW with at least one radiating arrangement. The SIW comprises a dielectric material, a first and second metal layer and a first and second electric wall element running essentially parallel and electrically connecting the metal layers. For each radiating arrangement, the antenna arrangement comprises at least one coupling aperture in the first metal layer, and for each coupling aperture there is a third wall element running between the first and second electric wall elements, across a SIW longitudinal extension (e.sub.s). For each radiating arrangement, the antenna arrangement further comprises an at least partly electrically conducting antenna component which comprises at least four radiating elements and is surface-mounted on the first metal layer, enclosing at least one coupling aperture. For each radiating arrangement, electromagnetic signals are arranged to be transmitted between said coupling aperture and said radiating elements.

Waveguides and methods for manufacturing a waveguide that include forming a first channel in a first layer of dielectric material, the first channel comprising one or more walls; forming a second channel in a second layer of dielectric material, the second channel comprising one or more walls; depositing electrically conductive material on the one or more walls of the first channel; depositing electrically conductive material on the one or more walls of the second channel; arranging the first layer adjacent to the second layer to form a stack with the first channel axially aligned with and facing the second channel; and heating the stack so that the conductive material on the one or more walls of the first channel and the conductive material on the one or more walls of the second channel connect to form the waveguide.