A method, apparatus and computer software for coding for tracks in a system is presented. At least one track of an object is determined on a detection display map, the track having an icon associated therewith. The icon is supplemented with a shape indicating additional information relating to attributes of the track, the shape providing perceptual visual awareness for an operator of said system. The shape includes an indicator of at least one of direction, velocity, path uncertainty, and a level of urgency of the track of the object.

A system and method for detecting and avoiding a collision includes measuring speed of one or more vehicles and at least one parameter indicating road surface and condition, weather, and tire pressure. Rear image dimensions are proportional to the speed of the trailing vehicle and front image dimensions are proportional to the speed of the index vehicle. The timing of the projected images will allow for safe deceleration of trailing and of the index vehicles

The images are projected either as flat images on the roadway or three-dimensional (holographic) images. The occurrence and severity of a collision is defined by the rate of change in dimensions of the projected images that exceeds a predetermined value corresponding to a deceleration or acceleration of more than 1.1 g. Collision data measured by vehicle or extra vehicular (such as GPS) sensors are instantly stored and transmitted to the police department and emergency medical services.

In an embodiment of the disclosed technology, a visual output of data from a ground-penetrating radar and magnetic field measuring device is displayed on a visual medium. The display has a first exhibition of output from the ground-penetrating radar device and a second from a magnetic field measuring device, such as a very low frequency (VLF) receiver. Using an identical axis, such as an X-axis measuring time or distance, output of each device is exhibited and overlaid over one another. In this manner, one can detect (using two different methodologies and uses) the visual exhibition of both to best determine the location of a metal or electrical target.

A method, apparatus and computer software for coding for tracks in a system is presented. At least one track of an object is determined on a detection display map, the track having an icon associated therewith. The icon is supplemented with a shape indicating additional information relating to attributes of the track, the shape providing perceptual visual awareness for an operator of said system. The shape includes an indicator of at least one of direction, velocity, path uncertainty, and a level of urgency of the track of the object.

A motorcycle radar system can include a radar sensor, a wireless interface, and an electronic device such as a smartphone or navigation device. The electronic device can receive radar data from the wireless interface of the radar sensor and present information on its display including a top view of the motorcycle and one or more vehicles proximate the motorcycle.

Real-time monitoring of surroundings of a marine vessel. One or more observation sensor modules are configured and positioned to generate sensor data extending around the marine vessel. One or more data processors are configured to map and visualize the sensor data in relation to a virtual model of the marine vessel. A user interface is configured to display the virtual model together with the visualized sensor data from a user selectable point of view to a mariner of the marine vessel.

Systems and methods of detecting type I ice crystals using an aircraft's onboard weather radar system are disclosed. An exemplary embodiment identifies radar returns having a return level signal strength less than a radar return sensitivity threshold level, determines if at least one of a weather condition and a flight condition concurrently exists with the identified radar returns having the return level signal strength less than the radar return sensitivity threshold level, and identifies a region of airspace potentially having type I ice crystals when the at least one of the weather condition and the flight condition concurrently exists with the identified radar returns having the return level signal strength less than the radar return sensitivity threshold level.

A method for presenting weather information onboard an aircraft is provided. The method obtains a first set of weather data from aircraft onboard radar system; obtains a second set of weather data from external sources including one or more external aircraft, a satellite, a remote server, and a ground-based weather station, wherein the communication device is compatible a communication protocol for the external sources, and wherein the communication protocol comprises at least one of a datalink communication protocol, a satellite communication protocol, a very high frequency (VHF) radio communication protocol, and a transponder communication protocol; and presents graphical elements comprising a first set of graphical elements associated with the first set of weather data and a second set of graphical elements associated with the second set of weather data, wherein the second set of graphical elements include visual characteristics distinguishable from the first set of graphical elements.

An active radio-frequency (RF) sensing technology for determining the relative and/or absolute state (e.g., position, velocity, and/or acceleration) of a target object (e.g., a person, a car, a truck a lamp post, a utility pole, a building) is described. The sensors described herein operate in the Terahertz band (300 GHz to 3 THz). An active RF sensing device comprises a substrate and first and second semiconductor dies mounted on the substrate. The first semiconductor die has an RF transmit antenna array integrated thereon, and the transmit antenna array comprises a first plurality of RF antennas configured to generate an RF signals having frequency content in the 300 GHz-3 THz band. The second semiconductor die has an RF receive antenna array integrated thereon, and the receive antenna array comprises a second plurality of RF antennas configured to receive RF signals having frequency content in the 300 GHz-3 THz band.

Systems and methods of detecting type I ice crystals using an aircraft's onboard weather radar system are disclosed. An exemplary embodiment identifies radar returns having a return level signal strength less than a radar return sensitivity threshold level, determines if at least one of a weather condition and a flight condition concurrently exists with the identified radar returns having the return level signal strength less than the radar return sensitivity threshold level, and identifies a region of airspace potentially having type I ice crystals when the at least one of the weather condition and the flight condition concurrently exists with the identified radar returns having the return level signal strength less than the radar return sensitivity threshold level.