This document describes techniques for radio frequency (RF) based micro-motion tracking. These techniques enable even millimeter-scale hand motions to be tracked. To do so, radar signals are used from radar systems that, with conventional techniques, would only permit resolutions of a centimeter or more.

A radar assembly includes a hollow drum and an antenna holding structure located inside the hollow drum so that the hollow drum can rotate around the antenna holding structure. An antenna is connected to the antenna holding structure and located inside the hollow drum so that the hollow drum can rotate around the antenna. The antenna holding structure is connected to a base frame and to which the hollow drum is connected via at least one axle so that the hollow drum can rotate around the antenna holding structure while the antenna holding structure and antenna remain stationary. A handle is connected to the base frame so that a user can direct the antenna towards a surface of interest which is to be radiated and can then roll the hollow drum over the surface while maintaining the antenna in a user selected orientation.

The methods and device disclosed herein provide an array such as a Radio Frequency (FR) antenna array for measuring the array movement or displacement of the array relative to a reference location. In some cases the array may be attached to or in communication with the device. The array comprises at least two transducers (e.g. RF antennas), wherein at least one of the at least two transducers is configured to transmit a signal towards the object, and at least one transceiver attached to said at least two transducers, the at least one transceiver is configured to repetitively transmit at least one signal toward an object and receive a plurality of signals affected or reflected while the array is moved in proximity to the object/medium or scene; and at least one processor unit, configured to: process the affected signals to yield a plurality of signal measurements and compare said signal measurements obtained at different locations over time of said second object and calculate a movement of the object relative to a reference location.

A system and bent-pipe transponder component for determining a location of an individual or object in three dimensional space. The system includes a transmitter configured to transmit a first wireless electromagnetic signal at a first frequency and at least one transponder that is configured to responsively emit a second wireless electromagnetic signal having a second frequency that is frequency-shifted from the first frequency. An included receiver detecting the first and second wireless electromagnetic signals is configured to provide an output of location information for the at least one transponder. A bent-pipe transponder component may include a receiving antenna, an emitting antenna, and a frequency shift stage comprising an oscillator and a first mixer, with the frequency stage mixing a received first wireless electromagnetic signal with the output of the oscillator via the first mixer to produce the emitted second wireless electromagnetic signal.

The present invention relates to a method for contactless determination of at least one property of an at least partially melted quasi-endless strand during a casting process of the quasi-endless strand, which cools down within a cooling zone, allowing successive hardening of the quasi-endless strand, comprising at least the following steps: Emitting a first signal, in particular a first radar signal, in the form of radiation by an emission device, in particular a radar emission device, Generating a second signal, in particular a second radar signal, at least partly by an interaction of the first signal with a region of the quasi-endless strand, receiving the second signal by a reception device, in particular by a reception device for radar signals, determining at least one property of the quasi-endless strand on the basis of the second signal, wherein at least the step of interacting takes place within the cooling zone or upstream of the cooling zone (K), in particular immediately after exit from a mold. The present invention further relates to a device for casting a material, in particular a metal, into a quasi-endless strand in the context of a continuous casting process and for contactless determination of at least one property of the at least partially molten quasi-endless strand during casting of the quasi-endless strand, comprising a mold adapted to form said quasi-endless strand, a cooling zone in which said quasi-endless strand cools down, whereby successive hardening of said quasi-endless strand is enabled, an emission device, in particular a radar transmitter, adapted to emit emitting a first signal in the form of radiation, in particular as a first radar signal, a reception device, in particular a radar receiver, which is arranged to receive a second signal, in particular a second radar signal, whereby the second signal being generated at least partially by interaction of the first signal with a region of the quasi-endless strand within in the cooling zone or upstream of the cooling zone (K), in particular immediately after exit from a mold, a data processing unit arranged to determine at least one property of the quasi-endless strand on the basis of the second signal. According to the invention, a corresponding use is also provided.

A vehicle configured to operate in an autonomous mode can obtain sensor data from one or more sensors observing one or more aspects of an environment of the vehicle. At least one aspect of the environment of the vehicle that is not observed by the one or more sensors could be inferred based on the sensor data. The vehicle could be controlled in the autonomous mode based on the at least one inferred aspect of the environment of the vehicle.

A vehicle configured to operate in an autonomous mode can obtain sensor data from one or more sensors observing one or more aspects of an environment of the vehicle. At least one aspect of the environment of the vehicle that is not observed by the one or more sensors could be inferred based on the sensor data. The vehicle could be controlled in the autonomous mode based on the at least one inferred aspect of the environment of the vehicle.

The present application relates to radio detection and ranging (radar) systems and, in particular, to a radar system having a photonics-based signal generator. Such a radar system comprises a stepped-frequency optical signal generator, an optical-to-electrical converter, and a transmitter. The stepped-frequency optical signal generator is configured for converting an optical signal into a stepped-frequency optical signal. The optical-to-electrical converter for converting the stepped-frequency optical signal into a stepped-frequency electrical signal. The transmitter for transmitting a microwave signal based on the stepped-frequency electrical signal.

There is provided with a radar unit that includes transmission/reception antennas, a holding unit that holds the transmission/reception antennas such that the transmission/reception antennas face the ground, a large spherical wheel that has an inside wall on which one end of the holding unit is fixed, three or more small spherical wheels that hold an upper half portion of the large spherical wheel such that the large spherical wheel is rollable, a movement amount sensor that detects a movement amount generated by rolling of the large spherical wheel, and a control unit that is connected to the radar unit and the movement amount sensor.

It is provided a method for detecting people, the method being performed by a people detector provided by a doorway. The method comprises the steps of: receiving an open signal indicating that a door of the doorway is open; setting a people sensor of the people detector in an active mode based on receiving the open signal; detecting when a person passes through the doorway, using the people sensor; receiving a closed signal indicating that the door of the doorway is closed; transmitting a result of the step of detecting, wherein the step of transmitting is performed based on receiving the closed signal; and setting the people sensor in a power save mode based on receiving the closed signal.