A system that may be used to detect objects in front and behind of a barrier, such as a wall. The system includes a processor, a radar device, a thermal image device, and a display each being connected to the processor. The system detects objects based on reflected signals from the radar device and objects based on infrared light. The display shows at the same time objects detected by either the radar device or the thermal image device. A size of a displayed objects may be reduced based on the distance the object is from the system. The processor may be configured to discard objects detected by the radar device that are located in front of the barrier. The system may display objects located in front of the barrier detected by the thermal image device overlaid with objects located behind the barrier detected by the radar device.

A system that may be used to detect objects in front and behind of a barrier, such as a wall. The system includes a processor, a radar device, a thermal image device, and a display each being connected to the processor. The system detects objects based on reflected signals from the radar device and objects based on infrared light. The display shows at the same time objects detected by either the radar device or the thermal image device. A size of a displayed objects may be reduced based on the distance the object is from the system. The processor may be configured to discard objects detected by the radar device that are located in front of the barrier. The system may display objects located in front of the barrier detected by the thermal image device overlaid with objects located behind the barrier detected by the radar device.

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.

Methods and systems are provided for guiding or otherwise assisting energy management of an aircraft radar vectoring en route to a runway. A method involves determining a predicted lateral trajectory for the radar vectoring in accordance with interception criteria, wherein the lateral trajectory comprises a sequence of segments for satisfying the interception criteria from a current location of the aircraft and each navigational segment of the sequence is associated with an anticipated aircraft heading assignment. The method determines a reference vertical trajectory corresponding to the lateral trajectory, determines a target value for an energy state parameter of the aircraft at the current location on the lateral trajectory using the reference vertical trajectory, and provides indication of a recommended action to reduce a difference between a current value for the energy state parameter and the target value.

A synthetic aperture radar image analysis system 20 includes: a phase correlation determination means 21 which determines a strength of the phase correlation between a plurality of pixels in an image selected from among a plurality of images on the basis of the plurality of images that have been photographed by a synthetic aperture radar and show the same point; a shape determination means 22 which determines a degree of similarity between the shape of the distribution of the plurality of pixels and an object shape indicated by geospatial information; and an association means 23 which associates the plurality of pixels with the object on the basis of the determined strength of the phase correlation and the determined degree of similarity.

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.

A radio detection and ranging (radar) signal processing device obtains radar data by compensating for a change in a carrier frequency of a sensed radar signal, and outputs a radar image map based on the obtained radar data. The radar signal processing method includes obtaining a beat frequency signal based on a radar transmission signal generated based on a frequency modulation model and a radar reflection signal obtained from the radar transmission signal being reflected from an object, and generating radar data by compensating the beat frequency signal for a carrier frequency change by the frequency modulation model.

A radio detection and ranging (radar) signal processing device obtains radar data by compensating for a change in a carrier frequency of a sensed radar signal, and outputs a radar image map based on the obtained radar data. The radar signal processing method includes obtaining a beat frequency signal based on a radar transmission signal generated based on a frequency modulation model and a radar reflection signal obtained from the radar transmission signal being reflected from an object, and generating radar data by compensating the beat frequency signal for a carrier frequency change by the frequency modulation model.

Systems and method are provided for three-dimensional (3D) imaging by using Doppler and interferometric processing techniques for general planar phased arrays. Systems and methods according to embodiments of the present disclosure incorporate motion compensation techniques in a way that utilizes the full aperture of a phase array. Embodiments of the present disclosure can be applied to a variety of different radar imaging modalities, including X-band and millimeter wave (MMW) regimes.