The disclosed systems, structures, and methods are directed to a mm-Wave communication structure employing a first transmission structure employing a first ring transition structure followed by a first ground structure and a second ground structure configured to carry a ground signal, a second transmission structure employing a second ring transition structure followed by a third ground structure and a fourth ground structure configured to carry the ground signal, a third transmission structure configured to carry a mm-Wave signal, wherein the third transmission structure begins at the center of the first ring transition structure and the second ring transition structure and the third transmission structure is coplanar with the second transmission structure, and a fourth transmission structure configured to operatively couple an IC and the first transmission layer, the second transmission layer, and the third transmission structure.

The disclosed systems, structures, and methods are directed to a mm-Wave communication structure employing a first transmission structure employing a first ring transition structure followed by a first ground structure and a second ground structure configured to carry a ground signal, a second transmission structure employing a second ring transition structure followed by a third ground structure and a fourth ground structure configured to carry the ground signal, a third transmission structure configured to carry a mm-Wave signal, wherein the third transmission structure begins at the center of the first ring transition structure and the second ring transition structure and the third transmission structure is coplanar with the second transmission structure, and a fourth transmission structure configured to operatively couple an IC and the first transmission layer, the second transmission layer, and the third transmission structure.

A package structure includes a plurality of sub-package structures, a second encapsulant, a second RDL structure and a second conductive terminal. The sub-package structure includes a die, first TIVs, a first encapsulant and an antenna element. The die has a first side and a second side. The first TIVs are laterally aside the die. The first encapsulant encapsulates sidewalls of the die and sidewalls of the TIVs. The antenna element is on the first side of the die, and on the TIVs and the first encapsulant. The second encapsulant encapsulates sidewalls of the sub-package structures. The second RDL structure is electrically connected to the plurality of sub-package structures. The second conductive terminal is electrically connected to the sub-package structures through the second RDL structure.

A package structure includes a plurality of sub-package structures, a second encapsulant, a second RDL structure and a second conductive terminal. The sub-package structure includes a die, first TIVs, a first encapsulant and an antenna element. The die has a first side and a second side. The first TIVs are laterally aside the die. The first encapsulant encapsulates sidewalls of the die and sidewalls of the TIVs. The antenna element is on the first side of the die, and on the TIVs and the first encapsulant. The second encapsulant encapsulates sidewalls of the sub-package structures. The second RDL structure is electrically connected to the plurality of sub-package structures. The second conductive terminal is electrically connected to the sub-package structures through the second RDL structure.

A photonic integrated circuit is disclosed comprising: a dielectric substrate (110); a dielectric waveguide arrangement (120) on the substrate (110) for guiding terahertz (THz) waves; and a local functionalization (130) having a metallization in a surface area of the dielectric waveguide arrangement (120). The metallization is localized along a propagation direction of the THz waves to allow a metallization-free propagation of the THz wave outside of the local functionalization.

A photonic integrated circuit is disclosed comprising: a dielectric substrate (110); a dielectric waveguide arrangement (120) on the substrate (110) for guiding terahertz (THz) waves; and a local functionalization (130) having a metallization in a surface area of the dielectric waveguide arrangement (120). The metallization is localized along a propagation direction of the THz waves to allow a metallization-free propagation of the THz wave outside of the local functionalization.

Conduit structures for guiding extremely high frequency (EHF) signals are disclosed herein. The conduit structures can include EHF containment channels that define EHF signal pathways through which EHF signal energy is directed. The conduit structures can minimize or eliminate crosstalk among adjacent paths within a device and across devices. Launch structures that interface with waveguides are also disclosed herein. Launch structures can control the EHF interface impedance between a contactless communication unit and the waveguide. Waveguide structures discussed herein are designed to provide maximum bandwidth with minimal jitter over a desired distance.

Conduit structures for guiding extremely high frequency (EHF) signals are disclosed herein. The conduit structures can include EHF containment channels that define EHF signal pathways through which EHF signal energy is directed. The conduit structures can minimize or eliminate crosstalk among adjacent paths within a device and across devices. Launch structures that interface with waveguides are also disclosed herein. Launch structures can control the EHF interface impedance between a contactless communication unit and the waveguide. Waveguide structures discussed herein are designed to provide maximum bandwidth with minimal jitter over a desired distance.

A pipe has a longitudinal axis. A flex board extends along the longitudinal axis within the pipe and curls around the longitudinal axis. A cross-section of the flex board perpendicular to the longitudinal axis has a flex-board curve shape that has a first section on a first side of a line perpendicular to the longitudinal axis and a second section on a second side of the line perpendicular to the longitudinal axis. The first section has a first section shape and the second section has a second section shape. A first conductive stripe is coupled to the flex board, extends along the longitudinal axis, and follows the contour of the first section of the flex board. A second conductive stripe is coupled to the flex board, extends along the longitudinal axis, and follows the contour of the second section of the flex board.

A pipe has a longitudinal axis. A flex board extends along the longitudinal axis within the pipe and curls around the longitudinal axis. A cross-section of the flex board perpendicular to the longitudinal axis has a flex-board curve shape that has a first section on a first side of a line perpendicular to the longitudinal axis and a second section on a second side of the line perpendicular to the longitudinal axis. The first section has a first section shape and the second section has a second section shape. A first conductive stripe is coupled to the flex board, extends along the longitudinal axis, and follows the contour of the first section of the flex board. A second conductive stripe is coupled to the flex board, extends along the longitudinal axis, and follows the contour of the second section of the flex board.