A reconfigurable radar unit is described that includes: a millimetre wave (mmW) transceiver (Tx/Rx) circuit; a mixed analog and baseband integrated circuit; and a signal processor circuit. The mmW Tx/Rx circuit and mixed analog and baseband integrated circuit and signal processor circuit are configured to support a plurality of radar operational modes. a radar sensitivity monitor and architecture reconfiguration control unit (260) is coupled to the signal processor circuit and is configured to monitor a radar performance and, in response thereto, initiate a change in the radar operational mode. In this manner, a large number of radar operational modes is supported and can be dynamically adopted by the reconfigurable radar unit dependent upon any prevailing radar performance condition

In some examples, a radar system is configured to mount on an ownship vehicle for interleaving a weather detection mode and an object detection mode. The radar system comprises a phased-array radar device configured to receive weather signals in the weather detection mode, receive sensing signals in the object detection mode, and interleave the weather detection mode and the object detection mode. The radar system further comprises processing circuitry configured to determine weather conditions based on the received weather signals and detect an object based on the received sensing signals.

Aspects of the present disclosure of may comprise an apparatus of a wireless device configurable for wireless communications and radar operations, the apparatus comprising memory. The apparatus may further comprise processing circuitry coupled to the memory, wherein when configured for the radar operations, the processing circuitry is configured to generate a plurality of scanning signals at different frequencies, configure a transceiver to transmit the scanning signals, configure the transceiver to detect radar return signals corresponding to the scanning signals, the radar return signals to be detected concurrently with transmission of the scanning signals, and configure a radar module to receive the scanning signals and the corresponding radar return signals and determine phase and gain differences between the scanning signals and the corresponding radar return signals.

A system and method for planning radar missions. The system includes a processing unit and a display. The method includes estimating the execution time of a plurality of radar tasks to be executed periodically at respective planned repetition rates, and assessing, using rate monotonic scheduling, whether the tasks can be executed at their respective planned repetition rates. The display may be employed to display a graphical representation of a path to be flown repeatedly by the aircraft, and, superimposed on the displayed path, symbols indicating whether at any point on the path the radar will be able to execute each task at its respective planned repetition rate, and whether each of a plurality of areas to be surveyed by the radar, each corresponding to a respective radar task, is in the field of view pattern of the radar.

A multi-function radio frequency (RF) system may include a shared phased array antenna subsystem for transmitting and receiving radar signals and communications signals. The system may also include an integrated electronics package configured for controlling operation of the shared phased array antenna subsystem. The integrated electronics package may include a modulator/demodulator subsystem. The modulator/demodulator subsystem may include a radar module that is selectively coupled to the shared phased array antenna subsystem for transmitting and receiving radar signals. The radar module is configured to transmit and receive radar signals through the shared phased array antenna subsystem. The modulator/demodulator subsystem may also include a communications module that is selectively coupled to the shared phased array antenna subsystem for transmitting and receiving communications signals. The communications module is configured to transmit and receive communications signals through the shared phased array antenna subsystem.

The present inventive concept relates to an apparatus and method for multiplexing tracking information output from a plurality of tracking radar systems that are operated upon testing the flight of guided weapons, converting the multiplexed tracking information into a single PCM stream signal, and processing the tracking information together with telemetry data in an integrated manner, thus enabling the tracking information to be simply and economically utilized for test control and measurement tasks. The apparatus for converting multi-channel tracking information for integrated processing of flight data, includes a signal receiver for receiving pieces of tracking information from tracking radar systems through a plurality of input channels, a programmable semiconductor for multiplexing the pieces of tracking information, and converting the multiplexed tracking information into a data stream-type Pulse Code Modulation (PCM) frame, and a line driver for outputting the PCM frame to another piece of equipment.

A radar antenna system includes a single transmitter for creating pulses from a wideband waveform. A splitter divides each pulse into half-power pulses, and sends them along respective paths. On one path, successive half-power pulses are alternately modulated with a phase shift .sub.A or .sub.F. On the other path, the half-power pulses are not modulated. Each modulated half-power pulse is then combined with an un-modulated half-power pulse to transmit pulses of a full aperture beam with either .sub.A or .sub.F. This establishes two degrees of freedom for the system. Two separate receivers then simultaneously receive the pulse echoes and a signal processor uses the consequent four degrees of freedom to create a radar indicator with mitigated clutter and useable azimuth estimation. A coherent processing interval can then be selected for multi-mode operation of the system.

A multi-role or multi-function system operable to perform a multi-role or a multi-function and configured to dynamically allocate requisite resources for performing antenna functions during a frame interval of the multi-role or the multi-function by determining whether the antenna functions are completely performable in the frame interval, based on a time-sharing resource allocation procedure; and if not, allocating the requisite resources for performing the antenna functions during the frame interval, based on a time-sharing resource allocation procedure and an antenna-sharing resource allocation procedure.

An antenna device for a vehicle, including a generating device for generating electromagnetic waves, a waveguide system for transmitting electromagnetic waves, the waveguide system including a plurality of waveguide set-ups. The waveguide set-ups each having an inlet for feeding in the generated electromagnetic waves, the waveguide set-ups each including a plurality of outlets connected to the respective inlet, in order to couple out the electromagnetic waves fed into the respective inlet. The plurality of respective outlets being connected to openings in a surface, from which the electromagnetic waves are able to radiate, so that the surface includes a plurality of regions, whose respective openings are connected to a separate inlet via a separate waveguide set-up.

A radar system and a method can utilize a radar antenna, such as, an active electronically scanned array antenna. The radar system can include a processor configured to scan a volume of space via the radar antenna to detect aircraft threats and to detect weather threats. The processing system can utilize a first pattern to detect the aircraft threats or obstacles and a second pattern to detect the weather threats.