To provide high sensitivity to high frequency band signals, it is provided an antenna to be arranged on a window glass of a vehicle, the antenna comprising: a planar conductor to be arranged on the window glass; a slot formed as a rectangular region obtained by removing a conductor from the planar conductor; a power feeding unit arranged on a first side of the slot; and an element extending from a core-side terminal of the power feeding unit to a second side of the slot opposite to the first side, the slot being disposed at a position offset from a center of the planar conductor in a direction toward the first side.

A multi-mode antenna system include at least a first modal antenna and a second modal antenna. The first modal antenna is disposed on a ground plane of a circuit board and configurable in a plurality of different modes. The first modal antenna can include a driven element, at least one parasitic element and an active element configured to adjust a reactance of the at least one parasitic element. The multi-mode antenna system further includes a second modal antenna disposed on the ground plane and configurable in a plurality of different modes. The second modal antenna can include a driven element, at least one parasitic element, and an active element configured to adjust a reactance of the at least one parasitic element. The parasitic element of the second modal antenna is positioned such that adjusting the reactance of the parasitic element affects the radiation pattern associated with the first modal antenna.

A communication system where a central node (base-station or access point) communicates with multiple clients in its neighbourhood using transparent immediate beam-forming. Resource allocation and channel access is such that the central node does not necessarily know when each client starts its transmission. Receive beam-forming in such a system is not possible, as beam-forming coefficients for each client should be selected according to the particular channel realization from that client to the central node. Each client is detected early in its transmission cycle, based on either a signature that is part of the physical characteristics unique to that client, or based on a signature that is intentionally inserted in the clients' signal, and accordingly adjusts its beam-forming coefficients.

A communication system where a central node (base-station or access point) communicates with multiple clients in its neighbourhood using transparent immediate beam-forming. Resource allocation and channel access is such that the central node does not necessarily know when each client starts its transmission. Receive beam-forming in such a system is not possible, as beam-forming coefficients for each client should be selected according to the particular channel realization from that client to the central node. Each client is detected early in its transmission cycle, based on either a signature that is part of the physical characteristics unique to that client, or based on a signature that is intentionally inserted in the clients' signal, and accordingly adjusts its beam-forming coefficients.

The disclosed structures and methods are directed to transmission and reception of a radio-frequency (RF) wave. An antenna comprises a stack-up structure having a first control layer, a second control layer, a first and a second parallel-plate waveguides, and a plurality of through vias. The antenna further comprises a first central port and a second central port being configured to radiate RF wave into the two parallel-plate waveguides independently; vertical-polarization peripheral radiating elements integrated with the first control layer and configured to radiate RF wave in vertical polarization; and horizontal-polarization peripheral radiating elements integrated with the second control layer and configured to radiate RF wave in horizontal polarization. Each vertical-polarization peripheral radiating element is collocated with one of the horizontal-polarization peripheral radiating element such that they cross each other. A central port for transmission of RF wave into the stack-up structure of the antenna is also provided.

The techniques described herein relate to a Radio Frequency (RF) communication module for a hand-held mobile electronic device. The Radio Frequency (RF) communication module includes a circuit board and a plurality of antennas disposed on a top side and bottom side of the circuit board. The plurality of antennas comprise a first subset of antennas comprising end-fire antennas and a second subset of antennas comprising broadside antennas. The first subset of antennas and the second subset of antennas also have a bandwidth of approximately 40 percent. The Radio Frequency (RF) communication module also includes a shielded area comprising circuitry coupled to the circuit board for controlling the antennas.

The techniques described herein relate to a Radio Frequency (RF) communication module for a hand-held mobile electronic device. The Radio Frequency (RF) communication module includes a circuit board and a plurality of antennas disposed on a top side and bottom side of the circuit board. The plurality of antennas comprise a first subset of antennas comprising end-fire antennas and a second subset of antennas comprising broadside antennas. The first subset of antennas and the second subset of antennas also have a bandwidth of approximately 40 percent. The Radio Frequency (RF) communication module also includes a shielded area comprising circuitry coupled to the circuit board for controlling the antennas.

A pattern reconfigurable antenna includes a radiator, a first parasitic element, a second parasitic element, a ground plane, a first switch and a second switch. The radiator includes a feed portion and a radiating portion that are interconnected. The first and second parasitic elements are symmetrically located at two opposite sides of the radiating portion, and are closely adjacent to and spaced apart from the radiating portion. The ground plane is located at another side of the radiating portion, and is spaced apart from the first and second parasitic elements. Each of the first and second switches is connected between the ground plane and a respective one of the first and second parasitic elements, and is operable to establish connection between the same.

A pattern reconfigurable antenna includes a radiator, a first parasitic element, a second parasitic element, a ground plane, a first switch and a second switch. The radiator includes a feed portion and a radiating portion that are interconnected. The first and second parasitic elements are symmetrically located at two opposite sides of the radiating portion, and are closely adjacent to and spaced apart from the radiating portion. The ground plane is located at another side of the radiating portion, and is spaced apart from the first and second parasitic elements. Each of the first and second switches is connected between the ground plane and a respective one of the first and second parasitic elements, and is operable to establish connection between the same.

A method for controlling the lengths of length adjustable elements of an antenna includes engaging a motor drive assembly coupled to each length adjustable element and in response to signals from a motor controller for adjusting the length of the length-adjustable antenna elements to element lengths provided by element length tables coupled to the motor controller, running antenna modeling software coupled to the motor controller to generate antenna performance data as a function of antenna element lengths, and driving the motor controller for each motor drive assembly from data in the element length tables to adjust the lengths of the length-adjustable elements in response to commands entered into a user interface or commands generated by the antenna modeling software running in the processor.