An apparatus is provided to mitigate the adverse effects of mutual coupling. The apparatus includes a ground plane and first and second active radiators spaced from the ground plane. The first and second active radiators are configured to the electrically coupled to at least one of a receiver, a transmitter or a transceiver. The antenna also includes a grounded radiator electrically coupled to the ground plane and positioned between the first and second active radiators. The ground plane defines a non-conductive slot positioned between the first and second active radiators and bounded by the ground plane.

An inflatable antenna may include an inflatable sock, an antenna, and an attachment port. The inflatable sock may have an inflated state and a deflated state, where the inflatable sock assumes an elongated inflated shape in the inflated state. The antenna may extend along the length of the inflatable sock. The attachment port may be configured for operable connection to an inflation mechanism.

A pit antenna includes an inner tube defining a first inner tube end and a second inner tube end, the first inner tube end disposed opposite from the second inner tube end, the inner tube defining an inner tube bore extending inward from the first inner tube end toward the second inner tube end, the inner tube configured to electromagnetically couple energy from an antenna inserted into the inner tube bore; and a top disc, the top disc connected to the second inner tube end of the inner tube, the top disc configured to radiate energy electromagnetically coupled by the inner tube.

A pit antenna includes an inner tube defining a first inner tube end and a second inner tube end, the first inner tube end disposed opposite from the second inner tube end, the inner tube defining an inner tube bore extending inward from the first inner tube end toward the second inner tube end, the inner tube configured to electromagnetically couple energy from an antenna inserted into the inner tube bore; and a top disc, the top disc connected to the second inner tube end of the inner tube, the top disc configured to radiate energy electromagnetically coupled by the inner tube.

A high-power electromagnetic source for HPEM pulses in a desired radiation direction includes at least three antennas fixed in relation to one another for pulse components, wherein at least two groups of antennas with a respective main direction are present, and a control unit for the activation and phase position of the pulse components for the superimposition for the HPEM pulse, wherein the current radiation direction of said pulse is selectable in an angle range around the main direction. A vehicle with an HPEM source has the antennas mounted in a fixed position or a support for the antennas is pivotably mounted on the vehicle. In a method for emitting the HPEM pulse, all antennas are controlled in order to select the radiation direction in the angle range of less than 360.

The present disclosure relates to base station antennas. One example base station antenna includes at least two antennas, at least two outer cover structures, a fastening assembly, a connection assembly, and an upper cover, and each antenna is independently packaged in a radome. The fastening assembly includes a pole and a base. A bottom of the pole is mounted on the base. The connection assembly includes an antenna connection assembly, an outer cover connection assembly, and a pole connection assembly. The pole connection assembly is disposed on the pole, a top of the antenna is connected to the pole by using the antenna connection assembly and the pole connection assembly, and a bottom of the antenna is fastened on the bottom of the pole. Each of the outer cover structures is connected to the pole by using the outer cover connection assembly and the pole connection assembly.

The present disclosure relates to base station antennas. One example base station antenna includes at least two antennas, at least two outer cover structures, a fastening assembly, a connection assembly, and an upper cover, and each antenna is independently packaged in a radome. The fastening assembly includes a pole and a base. A bottom of the pole is mounted on the base. The connection assembly includes an antenna connection assembly, an outer cover connection assembly, and a pole connection assembly. The pole connection assembly is disposed on the pole, a top of the antenna is connected to the pole by using the antenna connection assembly and the pole connection assembly, and a bottom of the antenna is fastened on the bottom of the pole. Each of the outer cover structures is connected to the pole by using the outer cover connection assembly and the pole connection assembly.

An electromagnetic phased array (100) is disclosed comprising a plurality of antenna elements (102), each antenna element (102) comprising at least three constituent antennae (104). A drive circuit (106) generates about an axis of each element (102) a radiation pattern that has a defined minima at or close to a null in at least one direction. The drive circuit (106) effects electronic steering of this minima through a range of angles around the axis of each antenna element (102) of the array (100) by appropriate setting of the vector currents associated with its constituent antennae (104). The axes of each of the antenna elements (102) are aligned in parallel with a central axis of the array (100) and at least a sub-set of the elements (102) lie substantially on a common helical surface. The elements (102) are spaced on this surface such that the array (100) has a substantially constant aperture.

An electromagnetic phased array (100) is disclosed comprising a plurality of antenna elements (102), each antenna element (102) comprising at least three constituent antennae (104). A drive circuit (106) generates about an axis of each element (102) a radiation pattern that has a defined minima at or close to a null in at least one direction. The drive circuit (106) effects electronic steering of this minima through a range of angles around the axis of each antenna element (102) of the array (100) by appropriate setting of the vector currents associated with its constituent antennae (104). The axes of each of the antenna elements (102) are aligned in parallel with a central axis of the array (100) and at least a sub-set of the elements (102) lie substantially on a common helical surface. The elements (102) are spaced on this surface such that the array (100) has a substantially constant aperture.

An antenna with pin header is provided, which may include a substrate, a feed point, a radiator and a metallic pin header. The feed point may be disposed on the substrate. The radiator may be printed on the substrate and connected to the feed point. The metallic pin header may penetrate through the radiator and the substrate. The metallic pin header may be connected to the feed point via the radiator, and the radiator and the metallic pin header may have a common feedline, whereby the metallic pin header can enhance the gain pattern, in the direction which the metallic pin header points in, of the radiator.