Embodiments of the invention include a dispersion reduced dielectric waveguide and methods of forming such devices. In an embodiment, the dispersion reduced dielectric waveguide may include a first dielectric material that has a first Dk-value, and a second dielectric material that has a second Dk-value that is greater than the first Dk-value. In an embodiment, the dispersion reduced dielectric waveguide may also include a conductive layer formed around the first and second dielectric materials. According to an embodiment, a first portion of a bandwidth of a signal that is propagated along the dispersion reduced dielectric waveguide is primarily propagated along the first dielectric material, and a second portion of a bandwidth of the signal that is propagated along the dispersion reduced dielectric waveguide is primarily propagated along the second dielectric material.

Embodiments of the invention include an electromagnetic waveguide and methods of forming the electromagnetic waveguide. In an embodiment the electromagnetic waveguide includes a first spacer and a second spacer. In an embodiment, the first and second spacer each have a reentrant profile. The electromagnetic waveguide may also include a conductive body formed between in the first and second spacer, and a void formed within the conductive body. In an additional embodiment, the electromagnetic waveguide may include a first spacer and a second spacer. Additionally, the electromagnetic waveguide may include a first portion of a conductive body formed along sidewalls of the first and second spacer and a second portion of the conductive body formed between an upper portion of the first portion of the conductive body. In an embodiment, the first portion of the conductive body and the second portion of the conductive body define a void through the electromagnetic waveguide.

Radio frequency (RF) data transfer between components in rack mounted systems is facilitated through the use of dielectric waveguides and millimeter Wave (mm-Wave) transceivers. A signal generator provides one or more data signals to a serializer/deserializer (SERDES) which serializes a plurality of parallel data signals to produce a single, serialized, signal containing data from each of the input signals to the SERDES. A mm-Wave die upconverts the serialized signal to a mm-Wave signal and a mm-Wave launcher launches the signal into the dielectric waveguide. At the receiving end the process is reversed such that the mm-Wave signal is first downconverted and passed through a SERDES to provide the original one or more signals to a recipient signal generator. Some or all of the components may be formed directly in the semiconductor package.

A waveguide includes a core and an electrically-conductive transmission line. The core includes an electrically-insulating material that is transmissive at millimeter-wave frequencies. The core is configured to receive a millimeter-wave signal at a first end of the waveguide, and to guide the millimeter-wave signal to a second end of the waveguide. The electrically-conductive transmission line is coupled in propinquity to the core and is configured to conduct an electrical signal between the first end of the waveguide and the second end of the waveguide, in parallel with the millimeter-wave signal guided in the core.

A connection arrangement comprises an antenna adapted to transmit and/or receive electromagnetic waves and a waveguide member adapted to transport the electromagnetic waves. An end section of the waveguide member is arranged at the antenna in a transmission state such that an electromagnetic radiation can be transmitted between the antenna and the waveguide member. The waveguide member has a recess extending from a free end of the waveguide member into the waveguide member. The antenna is at least partially inserted in the recess in the transmission state.

Technologies for a long-lived 3D multimode microwave cavity are disclosed. In the illustrative embodiment, a series of overlapping holes are drilled into a monolithic block of aluminum forming a cavity. The dimensions of the cavity formed by the overlapping holes can be made long by drilling a long series of holes in a row and can be made high by drilling holes a certain depth into the cavity. If two dimensions of the cavity are bigger than the diameter of the holes used to create the cavity, then the cavity can support electromagnetic waves that cannot propagate through the holes, leading to a long lifetime in the cavity. A superconducting qubit or other non-linear element can be inserted into the cavity, which can controllably interact with each of several modes of the cavity. In this way, the modes of the cavity can act as components in a quantum memory.

Embodiments of the invention include an electromagnetic waveguide and methods of forming electromagnetic waveguides. In an embodiment, the electromagnetic waveguide may include a first semiconductor fin extending up from a substrate and a second semiconductor fin extending up from the substrate. The fins may be bent towards each other so that a centerline of the first semiconductor fin and a centerline of the second semiconductor fin extend from the substrate at a non-orthogonal angle. Accordingly, a cavity may be defined by the first semiconductor fin, the second semiconductor fin, and a top surface of the substrate. Embodiments of the invention may include a metallic layer and a cladding layer lining the surfaces of the cavity. Additional embodiments may include a core formed in the cavity.

Aspects of the subject disclosure may include, for example, a cable can include a core, a plurality of strips of cladding disposed on the core, and a coupler that facilitates inducing electromagnetic waves that propagate along the core, where a first dielectric constant of the core exceeds a second dielectric constant of each strip of cladding of the plurality of strips of cladding, and where the electromagnetic waves propagate along the core without requiring an electrical return path. Other embodiments are disclosed.

An overmoded dielectric-lined waveguide, particularly for the 0.03 to 3 terahertz frequency range, is disclosed with performance advantages relative to prior dielectric-lined waveguides, cost and size advantages relative to corrugated waveguides, and with coupling, bandwidth, and cost advantages relative to micro-structured-fiber waveguides. The waveguide comprises a single-clad flexible microwave laminate rolled into a cylinder with said copper surface on an outside of said guide tube and said dielectric surface on an inside of said guide tube. The rolled laminate is supported inside a metal tube. The same method of achieving the structure needed for efficient guiding of HE.sub.11 mode may be applied to a conical tube to make a low-cost efficient overmoded tapered waveguide transition for the 0.03-3 THz range.

A connector device according to the present disclosure includes a first connector section and a second connector section. The first connector section includes a waveguide for transmitting a high-frequency signal. The second connector section includes a waveguide for transmitting a high-frequency signal, a yoke disposed to cover the waveguide, and a magnet forming a magnetic circuit with the yoke, and is couplable to the first connector section by the attractive force of the magnet. A communication system according to the present disclosure includes two communication devices and a connector device. The connector device has the above-described configuration and transmits a high-frequency signal between the two communication devices.