Abstract: A microstrip antenna is disclosed. The microstrip antenna includes a dielectric substrate with a first relative permittivity, a metal patch, and a magneto-dielectric superstrate. The metal patch is printed on the dielectric substrate, and the magneto-dielectric superstrate is placed above the metal patch.

Abstract: Base station antennas are provided herein. A base station antenna includes first and second wiper phase shifters. In some embodiments, the base station antenna includes first and second wiper supports that are on the first and second wiper phase shifters, respectively, and the first wiper support includes a portion that is beside and interlocked with a portion of the second wiper support. In some embodiments, the base station antenna includes a first linkage that is on the second wiper phase shifter, and a second linkage that intersects, and is coupled to, the first linkage and is configured to adjust the first and second wiper phase shifters via the first linkage. In some embodiments, the first and second wiper phase shifters are a mirror-image pair of wiper phase shifters. Related methods of operating a base station antenna are also provided.

Abstract: A vehicular system includes a body panel having an aperture and a radar unit at least partially aligned with the aperture. The radar unit includes a housing encapsulating a printed circuit board operable to generate radar waves. The housing includes a first wall through which the radar waves are directed. The first wall of the housing is visible within the aperture and the body panel does not extend across the first wall.

Abstract: A deployable reflectarray has a plurality of strips arranged in quadrants forming the reflectarray. The copper ground plane and the copper dipoles are supported by facesheets made of epoxy reinforced by quartz fibers. The copper ground plane is separated from the copper dipoles by S-shaped springs made of epoxy reinforced by quartz fibers, which allow folding and deployment of the reflectarray.

Abstract: The application disclose an antenna. The antenna includes a first radiating element, a second radiating element, a third radiating element, and a closed ring, where the first radiating element is connected to a first feed point, the second radiating element is connected to a second feed point, and the third radiating element is connected to a third feed point; the closed ring is configured to be disposed in a clearance area of a ground plate, and configured to connect to the ground plate; the first radiating element, the second radiating element, and the third radiating element are connected by using a microstrip, to form a radiator; the third radiating element is disposed between the first radiating element and the second radiating element.

Abstract: An RF antenna system includes a first unit that further includes first attachment means that secures the first unit to a window, and an antenna. The first unit additionally includes an RF transceiver, coupled to the antenna, that receives, via the antenna, incoming RF signals and converts the RF signals to first electrical signals; and first optical means that transmits the first electrical signals as first optical signals through the first surface of the window. The RF antenna system also includes a second unit that includes second attachment means that secures the second unit to the window. The second unit also includes second optical means that receive the first optical signals through the second surface of the window, convert the first optical signals to first digital signals, and transmit the first digital signals to a device connected to the second unit.

Abstract: An electronic device includes a first antenna configured to transmit and receive a first signal of a first frequency band, and a housing in which the first antenna is accommodated, wherein the housing includes a first conductor having a first slit that at least partially overlaps the first antenna, wherein the first conductor is formed of a metal and at least a portion of the first slit is filled with a metal oxide. Additionally, the electronic device includes a second conductor configured to transmit and receive a second signal of a second frequency band, and a second slit formed between the first conductor and the second conductor, and wherein the second slit is filled with a material that has an external appearance that is different from that of the second conductor.

Abstract: An adjustable antennal mount has a base bracket, an upper bracket, multiple fasteners, and a leveling instrument. The base bracket has a slanting surface not perpendicular to an assembling axis of base bracket and a rotating axis perpendicular to the slanting surface. The upper bracket is adjustably mounted on the base bracket along the rotating axis and has a diagonal surface and a top surface. The diagonal surface is attached to the slanting surface of the base bracket and is not parallel to the top surface of the upper bracket. The fasteners are connected with the base bracket and the upper bracket and are arranged at spaced intervals. The leveling instrument is mounted in the upper bracket and indicates levelness of the top surface of the upper bracket.

Abstract: An antenna device as described herein includes a first metal layer and a second metal layer. The second metal layer is spaced apart from the first metal layer. The first metal layer includes an opening through which to transmit RF (Radio Frequency) energy to the second metal layer. The second metal layer is operable to reflect the RF energy received through the opening back to a surface of the first metal layer. The first metal layer is operable to reflect the RF energy (received from the reflection off the second metal layer) in a direction past the second metal layer through a communication medium. The surface area of the first metal layer is sufficiently larger than a surface area of the second metal layer to reflect the RF energy past the second metal layer into the communication medium. This ensures that the antenna device operates in a reflective mode as opposed to a resonant mode, resulting in high gain.

Abstract: Disclosed is an antenna, in particular array antenna. The antenna includes an antenna top surface (1a) and an antenna bottom surface (1b). The antenna further includes a waveguide channel structure with a plurality of waveguide end branches (111). Each waveguide end branch (111) opens into an associated waveguide opening (100) in the antenna top surface (1a) in a one-to-one relation, wherein the waveguide openings (100) are arranged in a pattern of rows and columns. A plurality of recesses (101) extends from the antenna top surface (1a) towards the antenna bottom surface (1b), the plurality of recesses (101, 101b) being arranged such that a recess (101b) is present between pairs of neighboring waveguide openings (100) of the same row and/or column.

Abstract: The invention relates to a method for producing a heatable radome, a flexible printed circuit board having a metallic structure being used. Said flexible printed circuit board is embossed and is back-molded with a thermoplastic material.

Abstract: The invention relates to a method for producing a radome, a flexible printed circuit board having a metallic structure being used. Said flexible printed circuit board is embossed and is back-molded with a thermoplastic material and electric contact elements are connected to the flexible printed circuit board. A connector skirt is placed on the contact elements prior to back-molding.

Abstract: A system and method of using a transceiver antenna formed on a fixed outer panel of a cubesat includes electrically coupling an RF feed to a first edge of the outer panel and electrically coupling an RF return to a second edge of the outer panel, the second edge being opposite from the first edge. The RF feed and the RF return being disposed approximately one half a height of the outer panel. An RF distribution plane is electrically coupled to the RF feed and the RF return by substantially equal length circuits. A communication system is electrically coupled to the RF distribution plane. The transceiver antenna does not require deployment and thus improves reliability.

Abstract: A technique is described where the switch and/or tunable control circuit for use with an active multi-mode antenna is positioned remote from the antenna structure itself for integration into host communication systems. Electrical delay and impedance characteristics are compensated for in the design and configuration of transmission lines or parasitic elements as the active multi-mode antenna structure is positioned in optimal locations such that significant electrical delay is introduced between the RF front-end circuit and multi-mode antenna. This technique can be implemented in designs where it is convenient to locate switches in a front-end module (FEM) and the FEM is located in vicinity to the transceiver.

Abstract: A GNSS RHCP stacked patch antenna with wide dual band, high efficiency and small size is made of a molded high-permittivity material, such as ceramics, with a patterned cavity in the dielectric substrate. The perforated cavities in the substrate reduce the effective dielectric constant, increase the bandwidth and efficiency. The high-order modes can be manipulated through the design of cavities.

Abstract: The present invention relates to a combo type antenna module capable of maximizing performance of all antennas while minimizing a thickness of the antenna module by laminating a magnetic sheet having different thicknesses according to an antenna pattern formed on a base sheet. The combo type antenna module includes: a first antenna pattern formed on one surface and the other surface of the base sheet; a second antenna pattern formed on one surface of the base sheet; and a magnetic member laminated on the other surface of the base sheet, wherein the magnetic member is formed so that a thickness of a region corresponding to the second antenna pattern is formed thicker than that of a region corresponding to the first antenna pattern.

Abstract: A mobile electronic device includes a ground plane, a first slot, a plurality of first inductive elements, a first antenna, a second antenna, a first signal source, and a second signal source. The first slot is disposed in the ground plane to form a first ground portion and a second ground portion separated from each other. The first inductive elements are respectively connected to the first ground portion and the second ground portion. The first antenna and the second antenna respectively receive a radio-frequency signal in a predetermined band. The first signal source is electrically connected between the first antenna and the first ground portion and receives the radio-frequency signal from the first antenna. The second signal source is electrically connected between the second antenna and the second ground portion and receives the radio-frequency signal from the second antenna.

Abstract: An interleaved array of electronically steerable antennas is capable of simultaneously operating and/or independently beam scanning at different frequencies from a single aperture. An antenna system may comprise a plurality of electronically steerable antennas configured to be operable at different frequencies, each of the antennas comprising a feed launching a surface wave and surface-wave waveguides connected to the feed. The surface-wave waveguides of the antennas operable at different frequencies may be interleaved with each other.

Abstract: An electronic device includes a first body, a second body, and a rotating shaft structure connected to the first body and the second body. The rotating shaft structure includes a first shaft and a second shaft arranged opposite to each other and fixedly connected to the first body and the second body. The rotating shaft structure further includes an antenna radiator including a plurality of metal shafts electrically coupled to each other and provided in an interspace between the first shaft and the second shaft.

Abstract: The invention relates to the technical field of communication and discloses a phased array antenna system and a mobile terminal. In the invention, the phased array antenna system includes a first group of antenna unit arrays and a second group of antenna unit arrays, wherein the beam radiated by the first group of antenna unit arrays covers the a first half space, and the beam radiated by the second group of antenna unit arrays covers a second half space, the first half space and the second half space constitutes an omnidirectional space. The phased array antenna system provided by the invention and the mobile terminal achieve the full coverage of the phased array antenna around the mobile terminal, thereby improving the signal sending-receiving efficiency of the mobile terminal.