Systems and techniques are described for tsunami detection and warning using coastal radar systems designed primarily for the real-time mapping of ocean surface currents. These radar systems are configured to detect an approaching tsunami in the system's “near field,” i.e., the near-shore region over which the radar system observes the sea surface.

The present invention essentially comprises a system, method, computer program and combinations thereof to utilize dual-polarization generated data generally associated with weather and non-weather events for mapping data, producing geo-referenced data, producing mosaics, generation of precipitation masks, non-precipitation mask, and classification masks in general, production of vertical cross sections and predetermined fly throughs, producing short term forecasting, prediction of specific weather phenomenon, correcting or adjusting rain gauge data as well as quantitative precipitation estimation, and combining other meteorological data to correct or adjust estimated rainfall accumulation gathered by dual-polarization radar.

A radar camera of a signalized traffic control system determines rain intensity, compares it to a threshold, then adjusts traffic signal operation. Rain intensity of a level relative to the threshold causes the traffic control system to operate in a rain intensity mode. The rain intensity mode has the system hold a call to a traffic light controller during the time when rain intensity is above the threshold. The traffic control system includes a radar camera, traffic controller, a computer with memory, and program instructions. A manner of operation includes sampling camera radar, counting the number of raindrops and raindrop size within a predetermined range, determining rain intensity using the measured raindrop parameters/characteristics, comparing the determined rain intensity with a rain intensity threshold, and operating the traffic controller accordingly while the rain intensity is above the threshold.

A radar system for a wind turbine is provided. The radar system comprises a first radar unit (42) and a control unit (41) arranged to receive an output from the radar unit, the control unit comprising a central processing unit. The central processing unit is configured to perform a first function of determining at least one property of aircraft within a monitoring zone in the vicinity of the wind turbine and controlling a warning device to output a warning signal to detected aircraft based on the determined property; and perform a second function of determining at least one parameter of prevailing weather in the vicinity of the wind turbine. A corresponding method is also provided.

A system for millimeter wave-based fire detecting and rescuing and a method thereof are provided, the system including: an environmental obtaining device, a millimeter wave detector, a wireless transmitter, and a monitoring terminal, which are interconnected and arranged in an environment. The environmental obtaining device is configured to collect environmental information and send the environmental information to the wireless transmitter when the environmental information is determined to include fire information. The millimeter wave detector is configured to perform all-weather scanning on the environment to obtain characteristics and location information of a living organism in the environment, and send the characteristics and location information to the wireless transmitter. The wireless transmitter is configured to report the above information to the monitoring terminal through a millimeter wave, and the monitoring terminal stores the characteristics and location information. The monitoring terminal is configured to continuously compare changes in the characteristics and location information.

Systems and methods are disclosed to determine an unambiguous radial velocity for weather phenomena using weather radar that is not limited by the Doppler Dilemma. Some embodiments include transmitting a complex waveform and using the returned electromagnetic signal to determine the unambiguous radial velocity.

A system for collecting and distributing meteorological data is disclosed the system comprising at least two mobile meteorological stations (MMS) and each of the stations comprising at least a controller, a sensors unit that comprises one or more sensors such as temperature sensor, humidity sensor, air pressure sensor, wind speed and/or wind direction sensor, a location sensor unit and a communication unit configured to enable communication with at least one other MMS. The controller may be configured to receive meteorological data from the sensors unit and location data from the location sensor unit and to send a meteorological data and location data to the at least one other MMS.

The present invention is directed to system and method of processing meteorological data. The system receives meteorological data corresponding to a geographic region for a storm event. A hail data indicator pair comprising a first hail data indicator and a second hail data indicator is selected, with hail data indicators being meteorological data which directly or indirectly indicates hail activity.

A storm event distribution is generated using the hail data indicator pair comprising the steps of configuring ranges for each of the hail data indicators, tabulating the number of occurrences of data points from the storm event data within the intersecting ranges of the first hail data indicator and the second hail data indicator, and calculating the proportion of occurrences within the intersecting ranges.

A hail intensity number display matrix is calculated for each of the second hail data indicator ranges using the storm event distribution comprising the steps of generating a summation of the proportional occurrences of the second hail data indicator over the first hail data indicator ranges, yielding a hail intensity number display for the respective range.

The instantaneous second hail data indicator value from the meteorological data of the corresponding time period and geographic location is retrieved, and the hail intensity display number from the hail intensity number display matrix using the instantaneous second hail data indicator value is further retrieved. A data packet of the hail intensity display numbers, each of the hail intensity display numbers corresponding to a local geographic point is generated.

Weather radar system which uses antennas constituted by the elongated aperture of waveguides, and form at least an array (510, 520) mounted on a rotating horizontal (502), and the said apertures are as wide as one wavelength (λ) and length higher than 20λ, wherein the small aperture in azimuth ranges from 0.5° to 2° and is synthesized by high rotational speeds together with signal processing techniques such as ROSAR.

A ground weather center may transmit information requests that carry at least one meteorological specific triggering command. An airborne system may translate the triggering command into detectable meteorological conditions and may arm the trigger(s) for specific weather sensors accordingly and downlink information upon the airborne system detects the triggering conditions. By using such a triggering command, the airborne system may be able transmit the same amount of valuable information with less bandwidth by reducing the number of redundant downlinked packets.