A method for ground to air communication includes receiving a first pilot signal on a first wide beam from a first ground base station by a first antenna element covering a first range of azimuth angles from an aircraft. Data is received on a directed data beam from the first ground base station by the first antenna element. A second pilot signal is received on a second wide beam from a second ground base station by a second antenna element covering a second range of azimuth angles different than the first range of azimuth angles. A signal strength of the second pilot signal is compared with a signal strength of the first pilot signal. Data reception is switched from the first antenna element to the second antenna element if the signal strength of the second pilot signal is greater than the signal strength of the first pilot signal.

Disclosed is a method for analog beamforming performed by a transmitter (110) of a wireless communication network (100). The transmitter (110) comprises a plurality of antenna branches (114, 115, 116), each antenna branch comprising an antenna element (111, 112, 113). The method comprises, for each antenna branch (114, 115, 116), obtaining a first and a second signal of an analog radio signal, the first and the second signal being split from the analog radio signal and the analog radio signal being the same at each of the antenna branches, and obtaining information indicating a branch-specific phase-shift angle and a branch-specific amplitude determined from information identifying a radiation pattern comprising at least two directions for wireless transmission to at least one receiver (120). The method further comprises phase-shifting the first signal according to a first phase-shift angle and the second signal according to a second phase-shift angle, the first and the second phase-shift angle being selected so that when the first and the second signals are combined, the combined signal has the branch-specific phase-shift angle and the branch-specific amplitude indicated by the obtained information, combining the phase-shifted first and second signals into a combined signal; and transmitting, wirelessly, the combined signal through the antenna element (111, 112, 113).

An antenna system has high capacity, continuous mobile coverage that is especially beneficial in stadium style venues. The use of a low profile, rail mounted antenna system and the abundance of hand and safety rails enable coverage throughout the venue. The system increases the density of communications antennas throughout the stadium providing significantly enhanced mobile voice and data service to a higher number of users over traditional stadium technology.

Systems and devices relating to antennas and antenna systems. A horizontal omnidirectional antenna has two dipoles with each dipole being in a V-configuration such that the arms of the dipole define an angle. The two dipoles are arranged so that the angles defined by each of the dipoles face and open toward each other. The horizontal omnidirectional antenna can be configured to operate with specific frequency bands. By nesting two instances of this antenna, with one configured for high band frequencies and one configured for low band frequencies, a dualband omnidirectional antenna can be obtained. The resulting antenna is physically compact and can be used in small MIMO systems along with vertical omnidirectional antennas.

Waveguide and/or antenna structures for use in RADAR sensor assemblies and the like. In some embodiments, an antenna module for a vehicle sensor may comprise a receive (RX) array of elongated RX antenna slots and a transmit (TX) array of TX antenna slots. The TX array may comprise both one or more vertically-shifted TX antenna slots and one or more high-gain and/or squinted TX antenna arrays, each comprising a plurality of high-gain antenna slots.

An antenna structure is provided. The antenna structure includes an insulating seat, a first antenna and a second antenna disposed on the insulating seat, and two feeding points electrically coupled to the first antenna and the second antenna. The first antenna includes a first body portion and a plurality of first extending portions non-parallel to the first body portion. The second antenna includes a second body portion and a plurality of second extending portions. The second body portion is spaced apart from the first body portion and non-parallel to each of the second extending portions. A length of one of the second extending portion adjacent to a diagonal line of the second body portion is less than a length of another one of the second extending portions. The second extending portions and the first extending portions are spaced apart from each other and jointly generate a capacitance effect.

Compact lacunated lenses having a lens body with a plurality of input ports, (which may correspond to a predetermined steering angle), a plurality of output ports, and a plurality of holes/openings in the lens body, wherein the openings are arranged through the lens body so that an electromagnetic signal entering the lens body from any one of the input ports will exit from each of the output ports at a time delay corresponding to the predetermined steering angle of the input port from which the electromagnetic signal entered the lens body. The lenses may be used for RF signals between 2 GHz and 30 GHz for beamforming, and may have a diameter of less than 10 cm. The lenses may also be used for amplification. Methods of using these lenses and phase array antennas including these lenses are also described.

A wireless electronic device includes dual radiating antennas, with each of the dual radiating antennas including a first radiating element and a second radiating element. The wireless electronic device includes power dividers, a respective one of which is associated with a respective one of the dual radiating antennas and is configured to divide the power of a signal into a first portion of the power and a second portion of the power. The first portion of the power is applied to a respective first radiating element and the second portion of the power is applied to the respective second radiating element. The wireless electronic device is configured to resonate at a resonant frequency corresponding to the first radiating element and/or the second radiating element of at least one of the plurality of dual radiating antennas when excited by a signal transmitted by at least one of the plurality of dual radiating antennas.

Methods and systems are described for providing end-to-end beamforming. For example, end-to-end beamforming systems include end-to-end relays and ground networks to provide communications to user terminals located in user beam coverage areas. The ground segment can include geographically distributed access nodes and a central processing system. Return uplink signals, transmitted from the user terminals, have multipath induced by a plurality of receive/transmit signal paths in the end to end relay and are relayed to the ground network. The ground network, using beamformers, recovers user data streams transmitted by the user terminals from return downlink signals. The ground network, using beamformers generates forward uplink signals from appropriately weighted combinations of user data streams that, after relay by the end-end-end relay, produce forward downlink signals that combine to form user beams.

A transceiver includes a vector modulator and a phased array antenna including a plurality of quad polarization antenna cells. The vector modulator is configured to modify an information signal to generate two excitation signals based on a selected polarization. The polarization is selected as one of at least vertical, horizontal, right hand circular, and left hand circular. The vector modulator is configured to drive at least one of the quad polarization antenna cells with the two excitation signals to achieve the selected polarity.