Compressed closed circuit circularly polarized (CLCP) omni-directional antennas and methods of fabrication are described. Such an antenna reduces the size of conventional circularly polarized antennas while also allowing increased axial ratio. An antenna comprises a plurality of conductive elements at an angle of between 5 and 52 degrees spaced radially around a multi-element feed system. The multi-element feed system may be made from a PCB and fed from a coaxial cable. The plurality of conductive elements may contain between 2 and 8 individual conductive elements. Each element in the plurality of conductive elements is a closed loop. The antenna may be covered by a protective housing which may also further reduce the size of the antenna.

A method and system facilitate communication between a constellation of satellites and a mobile platform-mounted mobile communicator. The method and system may include the use of a first antenna suited for operation using a first frequency band in a first geographic region and a second antenna suited for operation using either the first or a second frequency band in a second geographic region. The method and system may use a controller to determine which antenna to activate based on one or more of a geographic indicator or a signal indicator. The system used by the method to facilitate the communication may have one or more enclosures over the antennas and controller for mounting to a mobile platform.

A method and system facilitate communication between a constellation of satellites and a mobile platform-mounted mobile communicator. The method and system may include the use of a first antenna suited for operation using a first frequency band in a first geographic region and a second antenna suited for operation using either the first or a second frequency band in a second geographic region. The method and system may use a controller to determine which antenna to activate based on one or more of a geographic indicator or a signal indicator. The system used by the method to facilitate the communication may have one or more enclosures over the antennas and controller for mounting to a mobile platform.

One example includes a digital communications converter. The converter includes at least one analog signal port configured to couple to at least one radiating element associated with an antenna structure coupled to an exterior surface of a vehicle. The at least one analog signal port can be configured to at least one of transmit and receive analog radio frequency (RF) signals respectively to and from the at least one radiating element. The converter also includes a digital interface configured to at least one of receive the analog RF signals or transmit the analog RF signals via the respective at least one analog signal port. The converter is also configured to convert between the analog RF signals and digital communication signals on a digital transmission medium that are at least one of transmitted to the digital communications converter via a digital communications cable and transmitted from the digital communications converter via the digital communications cable.

A method of making a part comprising stacking a plurality of uncured composite sheets to form an uncured composite stack. The method also comprises interposing a resistor wire between an adjacent two of the uncured composite sheets of the uncured composite stack. The method further comprises applying heat to the uncured composite stack externally of the uncured composite stack to at least partially cure the plurality of uncured composite sheets. The method additionally comprises transmitting an electric current through the resistor wire to generate heat, from the resistor wire, internally within the uncured composite stack to at least partially cure the plurality of uncured composite sheets. Applying heat to the uncured composite stack externally and generating heat internally converts the plurality of uncured composite sheets into a plurality of cured composite sheets and converts the uncured composite stack into a cured composite stack.

In one embodiment, a method includes determining a received power at a receiving antenna mounted to an antenna measurement system from a transmitting antenna mounted to a device under test (DUT) in motion relative to the antenna measurement system; determining one or more first orientation parameters of the antenna measurement system; determining one or more second orientation parameters of the DUT; and determining an antenna pattern of the transmitting antenna based on the received power, the first orientation parameters, and the second orientation parameters.

The invention is directed to an antenna structure for producing a horizontally polarized beam. In one embodiment, the antenna structure includes a first quarter-wave patch antenna and a second quarter-wave patch antenna that are positioned such that the ground planes of the patch antennas or a ground plane shared by the patch antennas is disposed between the patches of the two antennas and the shorting structures associated with the antennas are substantially aligned. In operation, the antenna structure is capable of processing an omni-directional, horizontally polarized beam.

A microwave-doppler detecting module and device thereof are provided, wherein the microwave-doppler detecting module includes an electromagnetic reflecting surface and at least a pair of antithetical dipoles spacingly disposed to the electromagnetic reflecting surface. When the first and second radiating source poles respectively extended from a first and second feed ends of the pair of antithetical dipoles are respectively fed by the same excitation signal feed source at the first feed end and the second feed end, the current and the potential distribution of the first radiating source pole and the second radiating source pole can present an antithetical distribution state and antithetically coupled to the midpoint of the connection of the first feed end and the second feed end, so as to reduce the size requirement of the microwave-doppler detecting module and to avoid detection dead zone from occurring.

One example includes a digital communications converter. The converter includes at least one analog signal port configured to couple to at least one radiating element associated with an antenna structure coupled to an exterior surface of a vehicle. The at least one analog signal port can be configured to at least one of transmit and receive analog radio frequency (RF) signals respectively to and from the at least one radiating element. The converter also includes a digital interface configured to at least one of receive the analog RF signals or transmit the analog RF signals via the respective at least one analog signal port. The converter is also configured to convert between the analog RF signals and digital communication signals on a digital transmission medium that are at least one of transmitted to the digital communications converter via a digital communications cable and transmitted from the digital communications converter via the digital communications cable.

A microwave-doppler detecting module and device thereof are provided, wherein the microwave-doppler detecting module includes an electromagnetic reflecting surface and at least a pair of antithetical dipoles spacingly disposed to the electromagnetic reflecting surface. When the first and second radiating source poles respectively extended from a first and second feed ends of the pair of antithetical dipoles are respectively fed by the same excitation signal feed source at the first feed end and the second feed end, the current and the potential distribution of the first radiating source pole and the second radiating source pole can present an antithetical distribution state and antithetically coupled to the midpoint of the connection of the first feed end and the second feed end, so as to reduce the size requirement of the microwave-doppler detecting module and to avoid detection dead zone from occurring.