Abstract: According to one embodiment, a sensor includes a supporter, a first film portion, a first sensing element, and a first magnetic portion. The first film portion is supported by the supporter, is deformable, and includes a first fixed end extending along a first fixed end direction. A first sensing element is fixed to the first film portion, and includes a first magnetic layer, a first opposing magnetic layer provided between the first magnetic layer and the first film portion, and a first intermediate layer provided between the first magnetic layer and the first opposing magnetic layer. A direction from the first opposing magnetic layer toward the first magnetic layer is aligned with a first element direction. The first magnetic portion includes a first end portion extending along a first end portion direction tilted with respect to the first fixed end direction, and overlaps a portion of the supporter.

Abstract: An electromagnetic (EM) position tracking system identifies the pose of objects based on detected strength values of an EM field. To address distortions in the field, the system employs a pose sensor to provide a second pose of the mobile unit. Under conditions where no distortion in the EM field has been detected, the HMD applies a nominal set of corresponding weights to the EM pose data and the IMU pose data, respectively, and combines the weighted pose value to identify a combined pose of the mobile unit. In response to detecting conditions that indicate distortion in the EM field, the HMD can apply different weights to the EM pose data and IMU pose data to, for example increase the influence of the IMU pose data on the combined pose.

Abstract: A magnetic detection unit includes: a first magnet configured to generate a first magnetic field; a second magnet arranged in parallel with the first magnet, the second magnet being configured to generate a second magnetic field in a direction opposite to a direction of the first magnetic field; and a hall element having a magnetic-flux detection surface, the hall element being configured to output a signal corresponding to a magnetic flux density passing through the magnetic-flux detection surface. The hall element is arranged at a position where a direction of a magnetic flux in a synthetic magnetic field of the first magnetic field and the second magnetic field is parallel to the magnetic-flux detection surface.

Abstract: A microelectronic device includes a vertical Hall sensor for measuring magnetic fields in two dimensions. In one implementation, the disclosed microelectronic device involves a vertical Hall plate with a cross-shaped upper terminal and a lower terminal which includes a buried layer. The cross-shaped upper terminal has a length-to-width ratio of 5 to 12 where it contacts the vertical Hall plate. The length is measured from one end of one arm of the cross-shaped upper terminal to an opposite end of an opposite arm. The width is an average width of both arms. Hall sense taps are located outside of the cross-shaped upper terminal. Current returns connect to the buried layer.

Abstract: The invention aims to provide a magnetic sensor that detects a Z-axis magnetic field via a yoke and that enhances the accuracy with which a magnetic field is detected. A magnetic sensor has a first magnetic field detecting element that is arranged in a plane that includes a first direction and a second direction that is perpendicular to the first direction, wherein the first magnetic field detecting element detects a magnetic field in the first direction; and a soft magnetic body that is adjacent to the first magnetic field detecting element in the first direction. L/W is equal to or more than 10, where W is a length of the soft magnetic body in the first direction, and L is a length of the soft magnetic body in the second direction.

Abstract: A nonlinear terahertz (THz) spectroscopy technique uses a sample illuminated by two THz pulses separately. The illumination generates two signals BA and BB, corresponding to the first and second THz pulse, respectively, after interaction with the sample. The interaction includes excitation of at least one ESR transition in the sample. The sample is also illuminated by the two THz pulses together, with an inter-pulse delay ?, generating a third signal BAB. A nonlinear signal BNL is then derived via BNL=BAB?BA?BB. This nonlinear signal BNL can be then processed (e.g., Fourier transform) to study the properties of the sample.

Abstract: A monolithic reusable microwire assembly can include a substrate and an electrically conductive thin-film wire formed on the substrate. The conductive thin-film wire can include a narrow segment forming an active area. A thermally and electrically insulating barrier can be formed on the electrically conductive thin-film wire. A roughness-reducing layer can be formed on the thermally and electrically insulating barrier and can have minimal surface roughness.

Abstract: Systems and methods are provided for automatically designing RF pulses using a reinforcement machine-learnt classifier. Data representing an object and a selected outcome is accessed. A reinforcement learnt method identifies the RF pulse sequence that generates a result within a predefined value of the selected outcome. An MRI scanner images the object using the RF pulse sequence.

Abstract: A stand assembly for an RF coil has a base, a slide carriage and a connection assembly. The slide carriage is slidably disposed on the base. The connection assembly comprises a first connecting member and a second connecting member. A first slide groove is formed in the first connecting member. The second connecting member comprises a first slider, the first slider being slidable along the first slide groove in a sliding direction and fixable at a preset position. One of the first connecting member and the second connecting member is in fixed connection with the slide carriage, and the other is in fixed connection with the RF coil. The stand is capable of being used universally for multiple types of RF coils.

Abstract: A telescoping magnetic resonance coil for a magnetic resonance imaging apparatus has a first coil half in a first coil housing, having a first coil support and a number of first coil units on the first coil support. The telescoping coil also has a second coil half in a second coil housing, having a second coil support and a number of second coil units on the second coil support. One end of the first coil housing is opposite to and slidable relative to one end of the second coil housing, and one end of the first coil support is opposite to and slidable relative to one end of the second coil support. The first coil units at the one end of the first coil support have connections to which sliding contacts of the second coil units at the one end of the second coil support are electrically connectable. The connections are slidable on the sliding contacts, and each of the sliding contacts is provided with a frequency compensation element that maintains a magnetic resonance frequency of the coil at a constant value.

Abstract: A dongle, and an apparatus to charge and replace components of the dongle are described. The dongle includes: a battery configured to provide direct current (DC) power to a device to which the dongle is electrically and mechanically connected, the battery being adapted to be removed, and replaced by another battery; and a heat sink configured to dissipate heat generated by the battery, the heat sink being adapted to be removed, and replaced by another heat sink.

Abstract: According to one embodiment, an RF coil apparatus includes coil elements and multiplexing circuitry. The coil elements each receive magnetic resonance signals. The multiplexing circuitry multiplexes the magnetic resonance signals received respectively by the coil elements, by using a local signal. The multiplexing circuitry includes mixer circuitry and matching circuitry. The mixer circuitry has a local port for inputting the local signal that includes a local frequency. The mixer circuitry converts at least one frequency among the magnetic resonance signals in accordance with the local frequency of the local signal input via the local port. The matching circuitry matches, in a narrow band, a local signal that is to be input to the local port with the local frequency.

Abstract: A gradient amplifier for use in a MRI system can be located in the scan room. The gradient amplifier includes pair of rails connected to a gradient power supply. The gradient amplifier also includes a H-bridge of switches which includes a first high side switch and a first low side switch connected in series between the pair of rails, and a second high side switch and a second low side switch connected in series between the pair of rails. The gradient amplifier further includes a first high side driver circuit, a first low side driver circuit, a second high side driver circuit, and a second low side driver circuit, each configured to drive the corresponding switch in the H-bridge. A common power source supplies power to all driver circuits, wherein power is supplied to the high side driver circuits through bootstrap circuits.

Abstract: In a method and apparatus for magnetic resonance (MR) fingerprinting, parameters that describe a starting k-space trajectory, along which measurement data are to be acquired in an MR fingerprinting sequence, are loaded into a computer, and at least one measurement k-space trajectory is created in the computer by fluctuating one of the parameters of the starting k-space trajectory. Measurement data are recorded along the measurement k-space trajectory, and the MR fingerprinting sequence is repeated with a different measurement trajectory in each repetition, produced by fluctuation of the at least one parameter of the starting k-space trajectory.

Abstract: A control apparatus for a magnetic resonance device, a system, a control system and a magnetic resonance system are disclosed. The control apparatus includes a control module, including a central coordination component, embodied to receive sequence commands calculated according to a scan sequence; a radio-frequency-control component, embodied to actuate a radio-frequency transmission unit of the magnetic resonance device in accordance with the sequence commands; and a gradient-coil-control component, embodied to actuate a gradient-coil unit of the magnetic resonance device in accordance with the sequence commands.

Abstract: A system and method for controlling noise in magnetic resonance imaging (MRI) are provided. In one aspect, the method incudes reconstructing a series of images of the target using the image data, with each image being defined using signal-to-noise (SNR) units, and selecting an image patch corresponding to the series of images. The method also includes forming a matrix by combining vectors generated using the image patch, and applying a local low rank denoising technique using the matrix and the series of images to generate at least one denoised image.

Abstract: According to some aspects, a method of suppressing noise in an environment of a magnetic resonance imaging system is provided. The method comprising estimating a transfer function based on multiple calibration measurements obtained from the environment by at least one primary coil and at least one auxiliary sensor, respectively, estimating noise present in a magnetic resonance signal received by the at least one primary coil based at least in part on the transfer function, and suppressing noise in the magnetic resonance signal using the noise estimate.

Abstract: A method and system for reducing Nyquist ghost artifact is provide. The method may include: obtaining a plurality of measured data sets; determining, based on the plurality of measured data sets, in a data space, a plurality of convolution kernels, each convolution kernel relating to all of the plurality of measured data sets; generating, based on the plurality of convolution kernels and the plurality of measured data sets, in the data space, a plurality of synthetic data sets; generating, based on the plurality of synthetic data sets and the plurality of measured data sets, in the data space, a plurality of combined data sets, each combined data set relating to one of the plurality of synthetic data sets and a corresponding measured data set of the plurality of measured data sets; and reconstructing, based on the plurality of combined data sets, an image.

Abstract: A magnetic resonance imaging apparatus according to the present embodiment includes processing circuitry and imaging control circuitry. The processing circuitry selects a human body model corresponding to a subject from human body models. The processing circuitry estimates local specific absorption rates (SARs) at evaluation points determined using the selected human body model, based on the selected human body model and an amplitude and/or phase of the RF pulse in an imaging protocol for magnetic resonance imaging scheduled to be performed on the subject. The processing circuitry determines whether or not the estimated local SARs fall below a local reference value. The imaging control circuitry executes the imaging protocol by using an amplitude and phase of the RF pulse which make the local SARs fall below the local reference value.

Abstract: In a method and magnetic resonance (MR) apparatus for data acquisition with fat-water separation in a resulting MR image, an MR data acquisition sequence is operated to acquire MR signals from a subject. Said MR signals comprise fat signals originating from fat in the subject and water signals originating from water in the subject, are acquired by executing a frequency-modulated balanced steady-state free-precession (bSSFP) sequence. The MR signals are entered as numerical values into a memory organized as k-space, the memory thereby containing k-space data. An image is reconstructed from the k-data and subjected to regional phase correction. The corrected image being composed of respective pixels having an intensity produced by the fat signals and an intensity produced by the water signals, with the respective pixels being readily distinguishable from each other in the image due to use of the frequency-modulated bSSFP sequence and the block regional correction.

Abstract: In a method and magnetic resonance (MR) apparatus for MR image reconstruction, an image reconstruction algorithm is used that operates on one calibration matrix that is formed by reorganizing a number of individual, undersampled k-space data sets respectively acquired by multiple reception coils in a parallel MR data acquisition from a subject exhibiting motion. The motion causes the k-space data sets to exhibit errors. In order to use the calibration matrix in the reconstruction algorithm, it is subjected to an iterative rank reduction procedure in which, in each iteration, a residual is calculated for each data point that represents how poorly, due to motion-induced corruptions, that data point satisfies the low rank constraint, and non-satisfying data points are removed from the data point for the next iteration. The resulting low rank matrix at the end of the iterations is then used to produce images with fewer motion-induced errors.

Abstract: Embodiments now disclosed herein provide an apparatus and method in which free radicals can be detected in a substance by MRI without changing the MRI static field.

Abstract: A tuner system for conducting measurements on a Device Under Test (DUT) includes at least one passive tuner, and calibration data for the at least one passive tuner including a set of s-parameters at a set of calibration frequencies. A measurement on the DUT is done at a measurement frequency at which the at least one passive tuner is not calibrated. The tuner s-parameters at the measurement frequency are determined by interpolation between or extrapolation from the s-parameters at calibration frequencies.

Abstract: Provided are a terminal positioning method, device and system, the method comprising: receiving three-dimensional positioning measurement information transmitted by a terminal; and acquiring the three-dimensional position information of the terminal according to the three-dimensional positioning measurement information.

Abstract: Certain aspects of the present disclosure provide methods and apparatus for estimating angular information, such as angle of arrival (AoA) information or angle of departure (AoD) information.

Abstract: Systems and methods for tracking a target depression angle relative to a reference location. In accordance with some embodiments, the system comprises a set of algorithms and pilot displays that use data from an onboard navigation system to calculate an asset's location relative to a reference location, allowing for precise control of relative geometry for the purposes of system measurement and performance assessment. The system provides a pilot with tracking error and steering cues along a flight profile, allowing for closed-loop tracking of target depression angle (body axis elevation) while sweeping look angle (body axis azimuth) relative to a static or dynamic reference location.

Abstract: A system may include at least one computer-readable storage medium including a set of instructions for locating a wireless device having wireless fidelity (WiFi) capability, and at least one processor in communication with the computer-readable storage medium, wherein when executing the set of instructions, the at least one processor is directed to: obtain a positioning request from the wireless device, the wireless device is in communication with at least one WiFi network; obtain WiFi data from the wireless device; and determine a default location associated with the WiFi data as a location of the wireless device.

Abstract: An electronic communications terminal records in a memory a sampled audio segment of sound sensed by a micro-phone. A time stamp associated with timing of the recording of the sampled audio segment is determined and stored in the memory associated with the sampled audio segment. The sampled audio segment and the time stamp are transmitted through a network interface toward a location service client of a network node that determines location of the electronic communications terminal based on correlating the sampled audio segment and other sampled audio segments of the sound received from other electronic communications terminals. A related network node and corresponding methods by terminals and network nodes are disclosed.

Abstract: Methods and systems are provided for controlling a radar system of a vehicle. One or more transmitters are configured to transmit radar signals. A plurality of antennas or arrays are configured to operate at a common frequency and a method and system for detecting mutual interference and for resetting the system in response to the mutual interference.

Abstract: The present invention concern a method for eliminating in a radar signal a first signal coming from an on-board radar (10), the method comprising the steps of: providing a replica of the signal emitted by the on-board radar (10), receiving a signal, the received signal being the sum of a first signal depending on the signal emitted by the on-board radar (10) and of a second signal independent of the signal emitted by the on-board radar (10), the first signal being a linear combination of elementary signals each having an amplitude coefficient and a delay relative to the signal emitted by the on-board radar (10), determining the amplitude coefficients and the delays of the elementary signals of the first signal, and eliminating, in the processed received signal, the first signal to obtain the second signal.

Abstract: If a vehicle surroundings monitoring apparatus is equipped with four radars disposed at each of the four corners of the body of a vehicle in order to detect an object around the vehicle, the interfere of the radio waves of the radars likely to occur. As a result, the accuracy for detecting an object by the radars will deteriorate. Specifically, if two of detection areas are adjacent to each other of the radars overlaps with each other and the two of the radars transmits radio waves at the same time, the interfere of the radio waves will occur in the overlapping area. In view of this, the four radars are divided into two groups such that the detection areas of two radars within the group aren't adjacent to each other and transmission period of one of the groups and that of the other of the groups are repeated alternately.

Abstract: Methods and systems are provided for controlling a radar system of a vehicle. One or more transmitters are configured to transmit radar signals. The system and method are operative to correct an expected transmission angle of a vehicular radar in response to a Doppler shift and a road surface measurement.

Abstract: The present application generally relates communications and hazard avoidance within a monitored driving environment. More specifically, the application teaches a system for improved target object detection in a vehicle equipped with a laser detection and ranging LIDAR system by simutaneously transmitting mutliple lasers in an array in response to a previously determined reception time, such that detection of light pulses from each laser are received in nonoverlapping time intervals.

Abstract: A ladar system can estimate intra-frame motion for an object within a field of view of the ladar system using a tight cluster of ladar pulses. For example, ladar pulses in a cluster can be spaced apart but overlapping with at least one of the other ladar pulses in that cluster at a specified distance in the field of view. A ladar receiver can then process the reflections from the cluster to computer intra-frame motion data, such as intra-frame velocity and intra-frame acceleration for an object.

Abstract: A lidar apparatus including a laser transceiver assembly, a wireless charging assembly and a driving assembly is provided. The wireless charging assembly is coupled to the laser transceiver assembly. The wireless charging assembly is configured to provide a charge power to the laser transceiver assembly. The driving assembly is configured to drive the laser transceiver assembly to rotate. The wireless charging assembly and the driving assembly are respectively located at two opposite sides of the laser transceiver assembly.

Abstract: An infrared range-measurement device includes an emitting module, a receiving module and a calculating module, the emitting module includes an emitting light source and a driving circuit, and the receiving module includes a planar array photosensitive chip. The emitting light source, under the drive of the driving circuit, emits a test light beam, the test light beam is reflected by an object in a test range and then is incident on the planar array photosensitive chip, and the calculating module outputs a test light intensity or a test distance; an emitting lens is provided in an emitting light path of the emitting module. By shaping the test light beam to control a divergence angle and a shape of the light beam, and to make it match with the set working area of the planar array photosensitive chip, the overall utilization ratio of the test light beam is increased.

Abstract: A detection system includes a signal transmitter for transmitting transmitted signals into a region and a receiver for receiving reflected signals generated by reflection of the transmitted signals and for generating receive signals indicative of the reflected signals. A processor coupled to the receiver receives the receive signals and processes the receive signals to generate detections of one or more objects in the region. The processing includes altering phase shift to generate phase-modulated signals from the receive signals and generating the detections from the phase-modulated signals.

Abstract: A LiDAR detection system includes optical sources generating a plurality of output optical signals disposed along a first direction. A modulation circuit applies an output signal from a signal generator to the optical sources to modulate the output optical signals such that the output optical signals are envelope-modulated output optical signals having frequency-modulated modulation envelopes. A scanning device scans the output optical signals into a region over a second direction. A receiver comprising a two-dimensional array of optical detectors receives return optical signals and generates receive signals indicative of the return optical signals. The return optical signals impinge on a mask between the region and the array, the mask comprising a plurality of apertures aligned with a first dimension of the array. The receive signals are generated for a set of detectors in the array disposed along the first dimension of the array and aligned with the mask apertures.

Abstract: A pixel is formed on a semiconductor substrate that includes a photosensitive area having a first doped layer and a charge collection area of a first conductivity type extending through at least part of the first doped layer. At least two charge storage areas, each including a well of the first conductivity type, are separated from the charge collection area at least by a first portion of the first layer. The first portion is covered by a first gate. Each charge storage area is laterally delimited by two insulated conductive electrodes. A second doped layer of the second conductivity type covers the charge collection area and the charge storage areas.

Abstract: A time of flight sensor device is provided that is capable of generating accurate information relating to propagation time of emitted light pulses using a small number of measurements or data captures. By generating pulse time of flight information using a relatively small number of measurement cycles, object distance information can be generated more quickly, resulting in faster sensor response times. Embodiments of the time of flight sensor can also minimize or eliminate the adverse effects of ambient light on time of flight measurement. Moreover, some embodiments execute time of flight measurement techniques that can achieve high measurement precision even when using relatively long light pulses having irregular, non-rectangular shapes.

Abstract: A time of flight sensor device is provided that is capable of generating accurate information relating to propagation time of emitted light pulses using a small number of measurements or data captures. By generating pulse time of flight information using a relatively small number of measurement cycles, object distance information can be generated more quickly, resulting in faster sensor response times. Embodiments of the time of flight sensor can also minimize or eliminate the adverse effects of ambient light on time of flight measurement. Moreover, some embodiments execute time of flight measurement techniques that can achieve high measurement precision even when using relatively long light pulses having irregular, non-rectangular shapes.

Abstract: A distance measuring device according to an embodiment includes a light source, an irradiation optical system, a light-receiving optical system, a sensor, an extractor, an adjuster, a signal generator, and a distance measurer. The light source intermittently emits laser light. The irradiation optical system reflects the laser light. The light-receiving optical system receives reflected light of the laser light via the mirror. The sensor includes a plurality of light receiving elements. The extractor extracts light receiving elements used for measurement of a distance to the measurement target object. The adjuster adjusts, according to an amplification factor corresponding to the light receiving elements extracted by the extractor, signal values of the electric signals of the light receiving elements. The signal generator generates time-series signals for measurement on the basis of the electric signals adjusted by the adjuster. The distance measurer measures the distance to the measurement target object.

Abstract: The device executes a method for determining the delay time of a first wavelet in a transmission path (I1). For this purpose, the first wavelet is transmitted into the transmission path (I1) at a time after a reference time. After passing through the transmission path (I1), the delayed and typically deformed transmission wavelet is scalar-multiplied with a second (analysis) wavelet. The result is compared to a reference value. The scalar product value adopts the reference value at a time (ts). The delay of the first and/or second wavelet in relation to the reference time is adjusted according to said time (ts) in relation to the reference time. An amplitude adjustment is not carried out.

Abstract: The method comprises: creating a 3D scenario model of a calibration scenario, based on data of the calibration scenario collected by an already-calibrated 3D scanner; obtaining point cloud data collected by a to-be-calibrated multi-line laser radar at a plurality of position points in the calibration scenario respectively; aligning the point cloud data collected by the multi-line laser radar at the respective point points and point cloud data in the 3D scenario model into the same coordinate system on a principle that the respective position points are aligned with corresponding position points in the 3D scenario model; building a target function between data of points collected by the multi-line laser radar and data of matching points nearest to the points in the 3D scenario model, under the same coordinate system; calibrating the parameters of the multi-line laser radar according to the target function.

Abstract: Methods and apparatus are described for implementing a coding scheme on ultrasound signals received by a plurality of ultrasonic transducers. The coding, and subsequent decoding, may allow for multiple ultrasonic transducers to be operated in a receive mode simultaneously while still differentiating the contribution of the individual ultrasonic transducers. Improved signal characteristics may result, including improved signal-to-noise ratio (SNR).

Abstract: Localization systems and methods are provided and include a first sensor configured to perform wireless communication with a portable device using a communication protocol that allows for communication over open advertising communication channels and that allows for communication using a secure communication connection. The first sensor communicates with the portable device using the secure communication connection and seconds sensor communicate with the portable device by transmitting or receiving broadcast signals over the open advertising communication channels. A control module receives first signal information about signals transmitted or received by the first sensor and second signal information about signals transmitted or received by the second sensors and determines a location of the portable device based on the first signal information and the second signal information.

Abstract: A method and system which enable the automatic activation and/or deactivation of the emission of radar wave signals from a radar system having a continuous rotating radar antenna. The automatic activation and/or deactivation of the emission of radar wave signal is controlled by a controller integrated with the radar system and is based on the bearing of the emitting antenna. The method relies on continuously reading the angular position of the antenna and allowing the flow of the electromagnetic wave frequency alternating current from the radar system's transmitter to the antenna only while the angle of the antenna is within a desired range. In some embodiments, the method and system may be provided with the desired range while in others, the method and system is operative to calculate the desired ranged based on the position and movement of the radar system relative to the position of a known target.

Abstract: A control device for a ceiling fan may have a motor drive circuit configured to control a rotational speed of a motor of the ceiling fan, an occupancy sensing circuit, and a control circuit configured to adjust the rotational speed of the motor in response to a detected occupancy or vacancy condition. The control circuit may process the signals generated by the occupancy sensing circuit to eliminate the effects of vibrations and/or wobbling of the ceiling fan. The control circuit may control the motor drive circuit to adjust the rotational speed of the motor in response to an accelerometer to minimize the magnitude of the wobble of the ceiling fan. The control circuit may be configured to learn a preferred rotational speed for the motor. The control circuit may also be configured to control the rotational speed of the motor to affect a thermal comfort level of an occupant.

Abstract: A radar system for an automated vehicle includes a digital-map, a radar, and a controller. The digital-map indicates a characteristic of a roadway traveled by a host-vehicle. The radar detects objects proximate to the host-vehicle. The radar is equipped with a range-setting that is selectively variable. The controller is in communication with the digital-map and the radar. The controller is configured to select the range-setting of the radar based on the characteristic of the roadway. The characteristic may be based on speed-limit, road-shape (e.g. curve-radius), a horizon-distance, and/or an obstruction (e.g. hill, sign, or building). The radar may be equipped with a frame-rate-setting (i.e. pulse repetition frequency or PRF) that is selectively variable, and the controller may be further configured to select the frame-rate-setting based on the characteristic of the roadway.

Abstract: A device for detecting frequency modulated continuous wave radar includes an antenna connected to a bandpass filter. The antenna is configured to receive frequency modulated continuous wave (FMCW) pulses within a predetermined frequency range. A frequency mixer is connected to the bandpass filter and a synthesizer and is configured to mix a signal from the synthesizer with an output of the bandpass filter to produce basebanded data. A high-pass filter is configured to isolate short pulses pertaining to the basebanded data, and a low-pass filter is configured to isolate long pulses pertaining to the basebanded data. A microprocessor is configured to set thresholds for comparison with the outputs of the high-pass filter and the low-pass filter.