A detection method for a given mission comprises at least: one phase of analysing the environment using a waveform chosen beforehand, the signals acquired with this waveform being analysed by processing means in order to deduce therefrom environmental characteristics; and one phase of generating an optimal detection wave depending on the environmental characteristics and characteristics of the mission.

A Time Domain Return measurement system for measuring liquid level, linear movement or other measurements which includes a first and second electrode, the second electrode spaced from the first electrode to define a gap, and an electronics assembly connected to the first and second electrodes equipped with a generator for transmitting an electromagnetic signal for propagation along the electrodes. The signal generator has a first analog timing circuit for actuating a slow-rising function of voltage versus time, a second analog timing circuit associated with the first analog timing circuit for actuating a fast-rising function of voltage versus time, and a receive circuit electrically connected to the electrodes, the receive circuit being activated for receiving return echo data associated with the electromagnetic signal transmitted when the fast-rising function is equal or greater than the slow-rising function to determine the position of the second medium with respect to the electrodes.

A method for operating a stepped frequency radar system is disclosed. The method involves receiving digital frequency control signals that correspond to different frequencies of radio frequency (RF) signals, and performing stepped frequency scanning across a frequency range using at least one transmit antenna and a two-dimensional array of receive antennas and RF signals at the different frequencies that correspond to the digital frequency control signals.

A method for operating a stepped frequency radar system is disclosed. The method involves receiving digital frequency control signals that correspond to different frequencies of radio frequency (RF) signals, and performing stepped frequency scanning across a frequency range using at least one transmit antenna and a two-dimensional array of receive antennas and RF signals at the different frequencies that correspond to the digital frequency control signals.

Disclosed are various techniques for wireless communication. In an aspect, a user equipment (UE) identifies a set of positioning sources, each positioning source comprising a positioning reference signal (PRS) resource, a PRS resource set, a PRS frequency layer, and/or a transmission/reception point (TRP). From the set of positioning sources, the UE identifies a consistency group comprising a collection of positioning sources grouped based on expected values of at least one metric of a reference signal from each positioning source, measured values of the at least one metric for the reference signal from each positioning source, and an error threshold. The UE identifies one or more subsets of positioning sources within the consistency group, each subset having at least one metric error value. The UE reports, to a network entity, information about the consistency group and information about at least one of the subsets of positioning sources within the consistency group.

A radar apparatus includes a radar transmitter that transmits a radar signal in a predetermined transmission cycle and a radar receiver that receives a reflection wave signal being a reflection of the radar signal on a target. The radar transmitter includes a phase rotation controller that randomly varies a pattern of a phase rotation every period corresponding to a plurality of transmission cycles, the pattern being to be applied to the radar signal within a period, and a transmission phase rotator that assigns a first phase rotation to the radar signal in accordance with the pattern. The radar receiver includes a reception phase rotator that assigns a second phase rotation in a direction opposite to a direction of the first phase rotation to the reflection wave signal in accordance with the pattern.

A time domain reflectometer (TDR) transducer (10) for determining a level (24) of liquid (16) in a container (12) includes a first electrode (34) and a second electrode portion (36) with a measuring volume (114) therebetween for receiving material (16) to be measured. The second electrode portion (36) has a shielded electrode section (36A) isolated from the first electrode (34) and an unshielded electrode section (36B), such that an energy pulse propagates along the shielded electrode section (36A) without signal loss, and boomerangs along a second opposite direction across the first conductive electrode portion (34), the measuring volume (114) and the unshielded electrode section (36B) where partial reflection of the pulse occurs at least at the interface (24) of the material (16) to create a return echo that travels in reverse direction, boomeranging back through the shielded electrode section (36A) for analysis by an electronic assembly (32).

A communication apparatus using electromagnetic pulses comprising a signal generating means for generating and transmitting data in at least one non-oscillating electromagnetic pulse as a communication signal; a signal processing means for receiving at least one non-oscillating electromagnetic pulse, and processing the one or more pulses to derive useful information; at least one antenna for sending and/or receiving signals; a time keeping means for providing time spacing variation for transmitting said pulses; a time spacing pattern library for providing known spacing patterns; a comparator for comparing a received signal with signals from said spacing pattern library to thereby identify the communication pulse, whereby the communication pulse can be distinguished from sparks, radio, and background noise.

The invention is an iterative process for performing iteratively the phase retrieval of an adaptive signal x(t) matching two sets of constraint both concerning the time envelope u.sub.e(t) of signal x(t) and magnitude distribution U.sub.m(f) of its spectral representation. At each iteration k the process computes an estimate {tilde over (x)}.sub.k(t) of signal x(t) which is obtained from a first projection P.sub.A on a first set of constraint in time domain of a computed value x.sub.k(t) of x(t), x.sub.k(t) deriving from an estimate {tilde over (X)}.sub.k1(f) of the spectrum of signal x(t), said estimate {tilde over (X)}.sub.k1(f) being itself obtained from a second projection P.sub.B on a second set of constraints in spectral domain of the Fourier transform X.sub.k(f) of the estimate {tilde over (x)}.sub.k1(t) of x(t) computed at iteration k1. Iterative computation of estimate {tilde over (x)}.sub.k(t) is repeated until {tilde over (x)}.sub.k(t) meets a predefined criterion which indicates that estimate {tilde over (x)}.sub.k(t) is close enough to expected signal x(t).

A radar transmitter for emulsion measurement comprises a probe mountable to a bottom of a vessel and defining a transmission line extending upward into the vessel, in use, for sensing impedance. A pulse circuit is connected to the probe for periodically generating pulses on the transmission line and receiving a reflected signal from the transmission line, each reflected signal comprising a waveform of probe impedance over time. A controller is operatively connected to the pulse circuit and comprises a programmed processor and a memory. The memory stores trace data of a plurality of individual waveforms. The processor is programmed to profile a first section of the waveforms which does not change over time and a second section of the waveforms which changes over time, representing an emulsion moving in the vessel. The controller locates where the waveforms indicates motion to determine emulsion level.