Abstract: A method for calibrating a time difference of arrival-based local positioning system for k?D localization, k=2 or 3, includes collecting N sets of time difference of arrival measurements related to a mobile node, N?2, each nth set of measurements being performed by Bn beacon nodes among B beacon nodes of the positioning system while the mobile node is located is a nth position within a region covered by the positioning system, Bn?k+2, and determining optimal beacon positions that minimize an objective function depending on N residual error vectors, the calculation of each nth position of the mobile node using beacon positions and the nth set of measurements, the calculation allowing the calculation of the nth residual error vector.

Abstract: A method comprising: receiving a radio map of an indoor venue using survey data collected by a survey device positioned throughout the venue, the radio map including a boundary; receiving harvest data from a mobile device, wherein at least some of the harvest data are obtained by the mobile device while the mobile device is positioned at locations that are outside of the boundary; determining, based on the harvest data, a trajectory of the mobile device, wherein at least some of the trajectory resides outside of the boundary; identifying one or more locations on or proximate to the trajectory; and extending the radio map using the survey data and the one or more identified locations, wherein the extended radio map is defined at least in part by an extension of the boundary to encompass the one or more identified locations.

Abstract: Embodiments are disclosed for compressing radio maps of fingerprint-based positioning systems. In an embodiment, a method comprises: receiving access point (AP) data from a plurality of mobile devices operating in a geographic region, the AP data including signal strength measurements of AP signals received at a plurality of reference locations in the geographic region; filtering the AP data to remove outlier AP data; fitting a surface to the AP data; projecting AP data at surface control points onto a two-dimensional image grid; determining a boundary surrounding locations of the AP data at the surface control points; encoding the boundary; encoding the AP data at the surface control points included within the boundary; generating compressed radio maps from the encoded AP data; and responsive to a request from a mobile device operating in the geographic region, sending a data packet including the compressed radio maps to the mobile device.

Abstract: A wireless positioning system for detecting a positioning coordinate of a person comprises a wireless positioning device for sending a wireless broadcast signal comprising a device identity code and a motion vector; a plurality of wireless base stations for receiving the wireless broadcast signal and sending a positioning signal comprising a wireless broadcast signal and an RSSI; and a positioning server for receiving the positioning signal and calculating the positioning coordinates of the wireless positioning device according to the positioning signal. Wherein, when the received positioning signal is insufficient to calculate the positioning coordinates, the positioning coordinates are calculated based on the last positioning coordinate plus the motion vector. Compared with the prior art, the wireless positioning system of the present invention uses the RSSI to cooperate with the motion vector. The wireless positioning range is expanded with more accuracy.

Abstract: Methods for locating electromagnetic pulse emission sources in an environment including reflectors is disclosed. In one aspect, the method includes receiving, by a detector, for each source to be located, at least one same emitted pulse, received directly from said source and received by reflection on one of the reflectors. The method also includes identifying direct subsets and reflected subsets, regrouping by pairs of direct subsets with reflected subsets, calculating, for each pair, differences in dates of arrival between the pulses of the reflected subset and the pulses of the direct subset of the pair, and determining the distance of each source from the detector from calculated differences in dates of arrival of the pulses of each pair.

Abstract: A wireless telecommunications system that employs a distributed-antenna system is described in which different combinations of radio signals are assigned to antennas so as to facilitate locating a wireless terminal based on the identity of the radio signals it receives above a threshold signal strength.

Abstract: Various embodiments disclosed herein include a method for determining the position of a computing device. The method may include obtaining, by the computing device, an image of a subset of luminaries from a plurality of luminaires located in an indoor environment, in which each subset grouping of luminaires in the plurality of luminaires is uniquely identifiable. The computing device may then compare the subset of luminaires to a database storing each uniquely identifiable subset grouping of luminaires in the plurality of luminaires, in which the database includes position information for each luminaire in the plurality of luminaires, and determine the position of the computing device based on the comparison of the subset of luminaries to the database.

Abstract: Techniques and apparatuses are described that enable radar modulations for radar sensing using a wireless communication chipset. A controller initializes or controls modulations performed by the wireless communication chipset. In this way, the controller can enable the wireless communication chipset to perform modulations for wireless communication or radar sensing. In some cases, the controller can further select a wireless communication channel for setting a frequency and a bandwidth of a radar signal, thereby avoiding interference between multiple radar signals or between the radar signal and a communication signal. In other cases, the controller can cause the wireless communication chipset to modulate a signal containing communication data using a radar modulation. This enables another device that receives the signal to perform wireless communication or radar sensing. By utilizing these techniques, the wireless communication chipset can be used for wireless communication or radar sensing.

Abstract: Techniques and apparatuses are described that enable full-duplex operation for radar sensing using a wireless communication chipset. A controller initializes or controls connections between one or more transceivers and antennas in the wireless communication chipset. This enables the wireless communication chipset to be used as a continuous-wave radar or a pulse-Doppler radar. By utilizing these techniques, the wireless communication chipset can be re-purposed or used for wireless communication or radar sensing.

Abstract: Embodiments of the present invention implement a novel methodology for processing radar image data from a radar system having one or more transmitter and receiver antenna pairs. The novel methodology deliberately operates on spectrally-notched radar data. It uses a specially-adapted version of the CLEAN algorithm to mitigate the effects of frequency-band notching. Following that, it performs a non-linear sidelobe-reduction algorithm to further eliminate artifacts and produce radar imagery of much higher quality. In some cases, it exploits a specific version of the recursive sidelobe minimization (RSM) algorithm which operates in the frequency and aperture (spatial) domain.

Abstract: A cascaded radar system is provided that includes a master radar system-on-a-chip (SOC) with transmission signal generation circuitry and a slave radar SOC coupled to an output of the master radar SOC to receive a signal from the transmission signal generation circuitry of the master SOC. In this system, the slave radar SOC is operable to measure phase noise in the signal received from the transmission signal generation circuitry of the master SOC.

Abstract: Examples disclosed herein relate to an Intelligent Metamaterial (“iMTM”) radar for target identification. The iMTM radar has an iMTM antenna module to radiate a transmission signal with an iMTM antenna structure and generate radar data capturing a surrounding environment. An iMTM interface module detects and identifies a target in the surrounding environment from the radar data and controls the iMTM antenna module.

Abstract: Disclosed herein are techniques for affecting the resolution of an optical scanning system. More specifically, a receiver of the optical scanning system includes a set of photodetectors and an optical beam directing subsystem. The optical beam directing subsystem is configured to, in each scan step of a plurality of scan steps, receive light reflected from a target region illuminated by a scanning beam and including a plurality of areas, and direct light reflected from each area of the plurality of areas to a corresponding photodetector in the set of photodetectors. Each photodetector of the set of photodetectors receives light reflected from a corresponding area of the plurality of areas to generate a detection signal.

Abstract: An optical distance measurement system includes a transmission circuit and a receive circuit. The transmission circuit is configured to generate narrowband intensity modulated light transmission signals over a first band of frequencies and direct the narrowband light transmission signal toward a target object. The receive circuit is configured to receive reflected light off the target object, convert the reflected light into a current signal proportional to the intensity of the reflected light, filter frequencies outside a second band of frequencies from the current signal to create a filtered current signal, and convert the filtered current signal into a voltage signal. The second band of frequencies corresponds with the first band of frequencies.

Abstract: Systems and methods for detecting and classifying objects proximate to an autonomous vehicle can include a sensor system and a vehicle computing system. The sensor system includes at least one LIDAR system configured to transmit ranging signals relative to the autonomous vehicle and to generate LIDAR data. The vehicle computing system receives the LIDAR data from the sensor system. The vehicle computing system also determines at least a range-view representation of the LIDAR data and a top-view representation of the LIDAR data, wherein the range-view representation contains a fewer number of total data points than the top-view representation. The vehicle computing system further detects objects of interest in the range-view representation of the LIDAR data and generates a bounding shape for each of the detected objects of interest in the top-view representation of the LIDAR data.

Abstract: A scanning display system includes two detectors for rangefinding. Round trip times-of-flight are measured for reflections of laser pulses received at the detectors. A proportional correction factor is determined based at least in part on the geometry of the scanning display system. The proportional correction factor is applied to the measured times-of-flight to create estimates of more accurate times-of-flight.

Abstract: A lidar system comprising a laser light source for emitting laser light, a light modulator unit, and a detector, the laser light emitted by the laser light source and reflected by an object being directed first through the light modulator unit and thereupon onto the detector, and the light modulator unit being designed to modify over time a light output that strikes the detector.

Abstract: An ultrasound imaging system probe comprises an imaging transducer head and a reception circuit for processing received reflected ultrasound signals. The reception circuit comprises an analogue to digital sigma delta converter which comprises a closed loop which comprises a tunable band pass filter. This enables the analog to digital converter to process only the desired frequency band. The ADC conversion bandwidth and ENOB are in this way programmable giving a more efficient probe design, and also enabling analog to digital conversion early in the signal processing chain.

Abstract: An electronic device for determining a distance of a drone from an obstacle, the electronic device comprising: an emission module to command the emission of an ultrasound signal toward the obstacle; a reception module to receive a signal representative of an ultrasound signal reflected by the obstacle; a calculation module to calculate the distance of the drone from the obstacle, from the received signal; and a filtering module comprising at least one filter matched to a respective Doppler offset, each matched filter generating a respective filtered signal as a function of a convolution product of the emitted ultrasound signal, to which the respective Doppler offset is applied, with the received ultrasound signal; the calculation module then calculating the distance of the drone from the obstacle, from the filtered signal(s) from the filtering module.

Abstract: An indoor positioning method includes: obtaining, by a terminal, all predicted locations of a current location, predicting, according to historical movement information of the terminal, a first probability that the terminal passes through each predicted location at a next moment, and obtaining, based on strength of a received signal, a second probability that the terminal passes through each predicted location at the next moment; and generating a corresponding third probability according to the first probability and the second probability that are corresponding to each predicted location, and determining a predicted location point with a highest third probability as a location of the terminal at a second moment.

Abstract: A method and apparatus for determining the location of an object with a sensor positions an instrument at a first location, controls the instrument to transmit a first omnidirectional signal during a first time, and determines a first distance from the instrument to the static object using the first omnidirectional signal. The method and apparatus repeats this process in a serial manner at two other locations, and uses the respective distances from each location to determine the location of the object. Other embodiments are disclosed.

Abstract: Techniques and apparatuses are described that enable digital beamforming for radar sensing using a wireless communication chipset. A controller initializes or causes the wireless communication chipset to use multiple receiver chains to receive a radar signal that is reflected by a target. A digital beamformer obtains baseband data from the wireless communication chipset and generates a spatial response, which may be used to determine an angular position of the target. The controller can further select which antennas are used for receiving the radar signal. In this way, the controller can further optimize the wireless communication chipset for digital beamforming. By utilizing these techniques, the wireless communication chipset can be used for wireless communication or radar sensing.

Abstract: A controller for a FMCW radar system configured to: provide for emission by the FMCW radar system of a plurality of consecutive frequency modulated detection signals for detection and ranging, each of the frequency modulated detection signals varying between an initial frequency and a final frequency over a period of time extending from a start time to an end time; wherein at least one of said consecutive frequency modulated detection signals is provided with an offset to one or more of; the start time of the detection signal relative to a predetermined start time schedule; the end time of the detection signal relative to a predetermined end time schedule; the initial frequency of the detection signal relative to a predetermined initial frequency schedule; and the final frequency of the detection signal relative to a predetermined final frequency schedule; the offset based on a random value.

Abstract: Provided is a narrow-band radar device including an orthogonal code generator configured to generate a plurality of orthogonal generators, a pseudo-noise code generator configured to generate a plurality of pseudo-noise codes, a radar transmitter configured to spread-modulate transmission data using the plurality of orthogonal codes and pseudo-noise codes, and a radar receiver configured to demodulate a reception signal using the plurality of orthogonal codes and pseudo-noise codes, and calculate at least one of an azimuth angle, elevation angel, speed, or range of a target from the demodulated reception signal.

Abstract: A frequency-modulated continuous wave (FMCW) coded aperture radar (CAR) implemented on an integrated circuit (IC) to step through a range of frequencies in each sweep and a method of assembling the FMCW CAR implemented on an IC are described. The CAR implemented on the IC includes an antenna element to transmit or receive at a given time duration, a transmit channel to process a signal for transmission, the transmit channel including a transmit switch configured to change a state of a transmit phase shifter between two states based on a first code, and a receive channel to process a received signal, the receive channel in including a receive switch configured to change a state of a receive phase shifter between two states based on a second code. A switch controller controls the first code and the second code and controls the first code to remain constant within the sweep.

Abstract: A method includes using a receiver of a first device, receiving from a second device, radio frequency (RF) signals. The method also includes using a processor of the first device, determining and storing, based on the RF signals, a set of angle-estimation values of an angle between a plurality of antenna elements of one of the first device and the second device and an antenna element of the other of the first device and the second device, a set of confidence measurements, and at least one of an Area-of Arrival (ARoA) value and an Area-of Departure (ARoD) value. Each of the set of confidence measurements indicates a confidence of an angle-estimation value of the set of angle-estimation values.

Abstract: For measuring an area of interest based on a sensor task, a method generates a sensor task comprising a sensor type and an area of interest. The method further routes the sensor task to a sensor of the sensor type and with a sensor motion track that includes the area of interest. The method measures the area of interest with the sensor based on the sensor task.

Abstract: A system, method and device for tracking at least one of objects, vehicles and personnel at a scene by determining a distance between a first node and a remote node are disclosed. In some embodiments, a method is provided for tracking emergency responders at an emergency incident scene by determining a distance between nodes positioned on the emergency responders and enabling mapping of the relative positions of the emergency responders.

Abstract: A target recognition system includes: a first recognition device which recognizes a target; a second recognition device which recognizes a target and differs from the first recognition device; a first processing unit which determines whether the target recognized by the first recognition device or the second recognition device is a new target which has not been recognized in the past on the basis of recognition results of the first recognition device and the second recognition device; a second processing unit which predicts a future position and speed of the target recognized by the first recognition device or the second recognition device when the first processing unit determines that the target recognized by the first recognition device or the second recognition device is not a new target; and a third processing unit which determines whether excessive detection has occurred in the first recognition device or the second recognition device on the basis of the recognition results of the first recognition devic

Abstract: Synthetic aperture (SA) imaging methods and systems are assisted by three-dimensional (3D) beam scanning imaging, for example scanning lidar. The methods can include concurrently acquiring an SA image and a 3D scanning image of a target region, determining an elevation map of the target region from the 3D scanning image, and processing the SA image based on the elevation map to provide or enhance 3D imaging capabilities in the SA image. In some implementations, the SA image is a two-dimensional (2D) SA image and the elevation map is used to orthorectify the 2D SA image. In other implementations, the SA image is a phase-wrapped 3D SA image resulting from the combination of two or more 2D SA images and the elevation map is used to perform phase unwrapping on the phase-wrapped 3D SA image.

Abstract: RADAR assemblies and related structures for vehicles. In some embodiments, a RADAR assembly may be provided comprising a RADAR module, a bracket coupled with the RADAR module, and a conformal layer comprising a surface configured to conform with and be positioned adjacent to a surface of a portion of vehicle fascia. The conformal layer may be configured to decrease the reflectivity of electromagnetic radiation from the RADAR module relative to the vehicle fascia. The RADAR assembly may be configured to be coupled with the vehicle fascia such that the conformal layer is spaced apart from the vehicle fascia to define an air gap between the conformal layer and the vehicle fascia, and the air gap may be configured to further decrease the reflectivity of electromagnetic radiation from the RADAR module relative to the vehicle fascia.

Abstract: An object detection apparatus includes a radar apparatus, an image capture device, a radar-detection target position detection section, and an image-detection target position detection section. In the apparatus, it is determined that the radar-detection target and the image-detection target are identical when a positional relationship between the targets corresponds to a predetermined relationship. Mitigation control for mitigating a collision between the own vehicle and an identical target is executed when the radar-detection target and the image-detection target are determined to be identical and the distance between the own vehicle and the identical target is smaller than a predetermined distance. Execution of the mitigation control is prevented from being executed, when the distance between the radar-detection target and the image-detection target has increased or decreased monotonically for an interval longer than a predetermined interval.

Abstract: A radar signal processing apparatus includes: clutter detection area setting circuitry acquiring profile information indicating reflected power of received power of reflected signal, per unit area obtained by dividing, at determined intervals, an area defined by the transmission direction of radar signal acquired by and distance from an radar apparatus, and sets a clutter detection area in the profile information; clutter characteristic calculation circuitry calculating a first representative value of reflected power of clutter in the clutter detection area and corresponding first distance; suppression filter setting circuitry calculating, based on these first representative value and distance, a parameter indicating a correspondence relation between the reflected power of clutter and a distance from the radar apparatus; and suppression processing circuitry calculating threshold based on the parameter, and determines an area in the profile information having a value of reflected power at or below the threshol

Abstract: The present invention is a nodal radar system having a metamaterial-based object detection system. An intelligent antenna metamaterial interface (IAM) associates specific metamaterial unit cells into sub-arrays to adjust the beam width of a transmitted signal. The nodal radar system is positioned on infrastructure to complement sensor information from mobile vehicles and devices within an environment.

Abstract: A subject information acquisition apparatus of the present invention includes a transmission/reception unit including a plurality conversion elements which transmit an elastic wave to the subject and receive a reflected wave that is reflected at each position in the subject, a scan line signal acquisition unit which acquires a plurality of signals corresponding to the reflected waves from each position in the subject as scan line signals by using a plurality of reception signals outputted from the conversion elements, and a processing unit which acquires moving information of the object by using the plurality of scan line signals. The processing unit acquires the moving information of the object on the basis of a distribution of cross-correlation values on a plane represented by two axes including an axis of time difference and an axis of distance difference by using a plurality of cross-correlation values between scan line signals at different positions.

Abstract: Additive manufacturing systems (AMS) are disclosed. The AMS may include a build plate positioned directly on a movable build platform, and a recoater device positioned above the build plate. The recoater device may include a blade. Additionally, the AMS may include a calibration system operably connected to the recoater device. The calibration system may include at least one measurement device coupled or positioned adjacent to the recoater device, and at least one computing device operably connected to the measurement device(s). The computing device(s) may be configured to calibrate the recoater device by adjusting a height of the blade of the recoater device relative to a reference surface of a component of the AMS in response to determining a pre-build distance between the blade of the recoater device and the reference surface differs from a desired distance. The pre-build distance may be determined using the measurement device(s).

Abstract: Arrangements (e.g., apparatus, system, method, article of manufacture) for reconstructing a depth image of a scene. Some embodiments include: a processor; and a non-transitory computer readable medium to store a set of instructions for execution by the processor, the set of instructions to cause the processor to perform various operations. Operations include: collecting multiple data sets for a code-modulated light pulse reflected from an object in a scene, with each data set associated with a direction in a set of directions for the reflected code-modulated light pulse; assigning a fitness value to each data set based on one or more parameters of a model; and reconstructing a depth image providing a depth at each direction based on a corresponding data set and fitness value, the depth to correspond with a round-trip delay time of the code-modulated light pulse.

Abstract: A distance is accurately measured by a ranging system that performs ranging by a ToF method. A ranging module includes a light receiving unit, a determination unit, and a ranging unit. The light receiving unit receives reflection light from an object and detects a received light quantity of the reflection light within a predetermined detection period every time the predetermined detection period elapses. The determination unit determines whether the object is moved during each of the predetermined detection periods. The ranging unit measures a distance to the object on the basis of received light quantity within a predetermined detection period during which it is determined that the object is not moved.

Abstract: The distance information acquisition apparatus includes: a measurement light source that emits measurement light to a measurement object; a distance image sensor in which a plurality of light receiving elements are two-dimensionally arranged; a jetting section that jets a reflection suppressing agent to the measurement object; an imaging lens that images the measurement light reflected on a surface of the measurement object to which the reflection suppressing agent jetted from the jetting section is attached on the distance image sensor; and a distance information acquisition section that acquires distance information of the surface of the measurement object, which is first distance information corresponding to a time of flight of the measurement light reflected from the reflection suppressing agent on the surface of the measurement object, on the basis of an output signal of each light receiving element of the distance image sensor.

Abstract: This disclosure is directed to methods for acquiring distance data using optical ranging systems. Optical ranging systems include one or more reference pixels and one or more object pixels. The methods employ operations for optimizing reference-pixel integration times and object-pixel integration times such that accurate distance data can be collected.

Abstract: Techniques of tracking an object's motion involve using a LIDAR system that is configured to track an object over a period of time in which the object is moving using a single scanning motion. Using the LIDAR system, tracking of the object can be performed while eliminating visible imaging hardware (e.g., video camera hardware). Accordingly, the LIDAR system can be configured to operate in total darkness, into the sun, etc. The LIDAR system can be less susceptible to motion of the object than conventional systems. Accordingly, the motion of the object 110 be determined in some implementations solely from LIDAR measurements, without, for example, video.

Abstract: A tracking device including an image sensor, a light source and a processor is provided. The image sensor senses reflected light or scattered light formed by the light source illuminating a work surface. The processor calculates a trace of the tracking device according to one of the reflected light and the scattered light that generates more apparent image features so as to increase the adaptable work surfaces.

Abstract: Systems and methods for detecting and classifying objects that are proximate to an autonomous vehicle can include receiving, by one or more computing devices, LIDAR data from one or more LIDAR sensors configured to transmit ranging signals relative to an autonomous vehicle, generating, by the one or more computing devices, a data matrix comprising a plurality of data channels based at least in part on the LIDAR data, and inputting the data matrix to a machine-learned model. A class prediction for each of one or more different portions of the data matrix and/or a properties estimation associated with each class prediction generated for the data matrix can be received as an output of the machine-learned model. One or more object segments can be generated based at least in part on the class predictions and properties estimations. The one or more object segments can be provided to an object classification and tracking application.

Abstract: The present disclosure is of an atmospheric characterization system that has a central processing board that has a first and a second communication interface. Further, the atmospheric characterization system further has a first precision temperature sensor that is communicatively coupled to the central processing board via the first communication interface and positioned a distance from a first side of the processing board, wherein the precision temperature measures a first temperature and transfers data indicative of the first temperature to the central processing board.

Abstract: Determination of one or more timing (phase) and/or frequency corrections to be made to a local time base of a receiver device to synchronize the local time base with the time of GPS or other highly accurate time base. Timing packets from one or more grandmaster devices whose time bases are substantially the same as that of GPS or the like and/or positioning system signals (e.g., GPS signals) directly from a positioning system are received and manipulated to determine the timing and/or frequency corrections. The corrected time base may be used to assist in acquiring such positioning signals to allow for higher accuracy correction and/or for downstream communication operation. The present utilities are advantageous such as when a sufficient number of channels (e.g., four) from the receiver device to positioning system satellites are unavailable to synchronize the local time base to the GPS or other accurate time base.

Abstract: System for estimating carrier phases, including a receiver that receives radio signals from satellites; the radio signals are converted into digital signals; a plurality of channels, each including a correlator receives digital signals and outputs (I, Q) components for one satellite; a reset accumulator that receives (I, Q) components, accumulates them over multiple cycles of a pseudorandom code and outputs accumulated (Is, Qs); a discriminator that generates a tracking error signal; a CCLF (common controlled loop filter) receives the tracking error signal and outputs a frequency control signal and a phase control signal; NCO receives the frequency and phase control signals, and outputs a reference signal. CCLF also receives correction signals based on the radio signals due to shock, vibration or acceleration. NCO control signals depend on the correction signals due to a change in an effective bandwidth of the CCLF to reduce coordinate measurement dynamic distortions.

Abstract: A radiation imaging apparatus that has a detection unit that detects radiation and outputs image data determines whether or not a grid for scattered ray reduction is installed on the detection unit, and changes a radiation detection range of the detection unit based on the determination result.

Abstract: Alpha particle detecting devices are disclosed that have a chamber that can hold a fluid in a tensioned metastable state. The chamber is tuned with a suitable fluid and tension such that alpha emitting materials such as radon and one or more of its decay products can be detected. The devices can be portable and can be placed in areas, such as rooms in dwellings or laboratories and used to measure radon in these areas, in situ and in real time. The disclosed detectors can detect radon at and below 4 pCi/L in air; also, at and below 4,000 pCi/L or 300 pCi/L in water. When the fluid is tensioned the presence of radon can be determined by the formation of bubbles which give off detectable signals including a shock wave, light-beam cutoff, or a light burst, any of which can be measured to derive information on radon and progeny radioactivity levels in air or water.

Abstract: An apparatus including a detector configured to detect electromagnetic radiation where the detector includes a first portion and a second portion; a deformable substrate configured to support the detector such that the first portion of detector is moveable relative to the second portion of the detector; and a sensor configured to detect deformation of the substrate and provide information indicative of the detected deformation to image processing circuitry.

Abstract: The present technology relates to an imaging element and a driving method, and an electronic device that enable stable driving with low voltage and low power consumption and furthermore make it possible to ensure a time resolution of detection. A light detector includes a pixel array section including a plurality of first pixels and a second pixel. The first pixel includes a photoelectric conversion section that photoelectrically converts incident light, a floating diffusion section that generates a voltage in accordance with the amount of charge carriers obtained by photoelectric conversion, and a transfer section that transfers charge carriers from the photoelectric conversion section to the floating diffusion section; the readout of a signal is performed intermittently from the first pixel. Further, the output of the second pixel is monitored continuously to detect the incidence of light. The present technology can be applied to a radiation counter.