A traffic radar system comprises a first radar transceiver, a second radar transceiver, a speed determining element, and a processing element. The first radar transceiver transmits and receives radar beams and generates a first electronic signal corresponding to the received radar beam. The second radar transceiver transmits and receives radar beams and generates a second electronic signal corresponding to the received radar beam. The speed determining element determines and outputs a speed of the patrol vehicle. The processing element is configured to receive a plurality of digital data samples derived from the first or second electronic signals, receive the speed of the patrol vehicle, process the digital data samples to determine a relative speed of at least one target vehicle in the front zone or the rear zone, and convert the relative speed of the target vehicle to an absolute speed using the speed of the patrol vehicle.

A traffic radar system comprises a first radar transceiver, a second radar transceiver, a speed determining element, and a processing element. The first radar transceiver transmits and receives radar beams and generates a first electronic signal corresponding to the received radar beam. The second radar transceiver transmits and receives radar beams and generates a second electronic signal corresponding to the received radar beam. The speed determining element determines and outputs a speed of the patrol vehicle. The processing element is configured to receive a plurality of digital data samples derived from the first or second electronic signals, receive the speed of the patrol vehicle, process the digital data samples to determine a relative speed of at least one target vehicle in the front zone or the rear zone, and convert the relative speed of the target vehicle to an absolute speed using the speed of the patrol vehicle.

A proximity sensor and an electronic device. The proximity sensor includes a circuit board; an infrared emitter and an infrared receiver both arranged on the circuit board, wherein the infrared emitter includes a light emitting source arranged on the circuit board and a light transmitting element covering the light emitting source; the light emitting source has an emission optical axis, the light transmitting element includes a front light transmitting portion and a rear light transmitting portion connected to the front light transmitting portion; the front light transmitting portion is located on a front side of the emission light axis of the light emitting source, and the rear light transmitting portion is located on a rear side of the emission light axis of the light emitting source; and the infrared receiver is located on one side of the light emitting source; and a light shielding element, wherein the light shielding element covers at least a part of the rear light transmitting portion.

The present invention includes systems and methods for a continuous-wave (CW) radar system for detecting, geolocating, identifying, discriminating between, and mapping ferrous and non-ferrous metals in brackish and saltwater environments. The CW radar system generates multiple extremely low frequency (ELF) electromagnetic waves simultaneously and uses said waves to detect, locate, and classify objects of interest. These objects include all types of ferrous and non-ferrous metals, as well as changing material boundary layers (e.g., soil to water, sand to mud, rock to organic materials, water to air, etc.). The CW radar system is operable to detect objects of interest in near real time.

The present invention includes systems and methods for a continuous-wave (CW) radar system for detecting, geolocating, identifying, discriminating between, and mapping ferrous and non-ferrous metals in brackish and saltwater environments. The CW radar system generates multiple extremely low frequency (ELF) electromagnetic waves simultaneously and uses said waves to detect, locate, and classify objects of interest. These objects include all types of ferrous and non-ferrous metals, as well as changing material boundary layers (e.g., soil to water, sand to mud, rock to organic materials, water to air, etc.). The CW radar system is operable to detect objects of interest in near real time.

A method of generating and managing terrain awareness and warning system (TAWS) alerts including determining a number of warnings relating to terrain near an aircraft flight path, each warning indicating terrain above a threshold elevation and having a position associated with the warning. The method further including generating, for each warning, first alert data configured for display as an alert on a display device. The method further including sending the first alert data to the display device, receiving, from the display device, a user request to inhibit a first alert, the first alert based on the first alert data. The method further including generating second alert data for the first alert, wherein the second alert data is configured to inhibit the first alert, wherein inhibiting the first alert includes modifying a display of the first alert on the display device and sending the second alert data to the display device.

An operating method of an electronic apparatus, which is performed using a UWB communication module including a plurality of antennas, includes emitting a UWB transmission signal, receiving a UWB reflection signal reflected from an object, and obtaining three-dimensional information of the object based on the UWB transmission signal and the UWB reflection signal, wherein the plurality of antennas are respectively arranged in a vertical direction and a horizontal direction on a front surface of a display of the electronic apparatus.

A method with radio detection and ranging (radar) data processing may include: obtaining, by a radar sensor, input radar data; and generating, using a resolution increase model, output radar data from the input radar data and reference data, wherein the output radar data has a resolution greater than a resolution of the input radar data.

A method with radio detection and ranging (radar) data processing may include: obtaining, by a radar sensor, input radar data; and generating, using a resolution increase model, output radar data from the input radar data and reference data, wherein the output radar data has a resolution greater than a resolution of the input radar data.

The present invention discloses a scanning nonlinear junction detection method and device. The method comprises following steps: S1. dividing a detection region into multiple sub-regions, transmitting signals to all the sub-regions one by one; S2. receiving signals fed back from the sub-regions, obtaining amplitude of harmonic components measured from all the sub-regions according to the signals fed back; if a harmonic component of a certain sub-region exceeds a preset value, determining that a nonlinear junction is present in the sub-region. The device comprises a transmission unit, a reception unit, a detection signal control unit, a reception data processing unit, and a control and display unit. In the present invention, an accurate position and direction in which the nonlinear junction is located are quickly determined, an occurrence of missing scanning is avoided, and speed and efficiency of searching for the nonlinear junction are improved.