Abstract: In one implementation, a method includes: obtaining a first depth estimation characterizing a distance between the device and a surface in a real-world environment, wherein the first depth estimation is derived from image data including a representation of the surface; receiving, using the audio transceiver, an acoustic reflection of an acoustic wave, wherein the acoustic wave is transmitted in a known direction relative to the device; and determining a second depth estimation based on the acoustic reflection, wherein the second depth estimation characterizes the distance between the device and the surface in the real-world environment; and determining a confirmed depth estimation characterizing the distance between the device and the surface based on resolving any mismatch between the first depth estimation and the second depth estimation.

Abstract: In one implementation, a method includes: obtaining a first depth estimation characterizing a distance between the device and a surface in a real-world environment, wherein the first depth estimation is derived from image data including a representation of the surface; receiving, using the audio transceiver, an acoustic reflection of an acoustic wave, wherein the acoustic wave is transmitted in a known direction relative to the device; and determining a second depth estimation based on the acoustic reflection, wherein the second depth estimation characterizes the distance between the device and the surface in the real-world environment; and determining a confirmed depth estimation characterizing the distance between the device and the surface based on resolving any mismatch between the first depth estimation and the second depth estimation.

Abstract: A vehicle information providing apparatus repeatedly acquires observation point information. The apparatus calculates at least one position of the predicted point. When the observation point information is acquired, the apparatus extracts a predicted point that can be connected to the observation point from the calculated predicted points. The apparatus calculates the position of the current filtered point based on the position of the current observation point and the position of the latest predicted point. When the observation point information of a new object (an object having no latest predicted point connectable to the observation point) is acquired, the device sets initial vectors. The apparatus calculates the position of the predicted point at time instants succeeding the current time instant for each of the traveling directions indicated by the initial vectors.

Abstract: Systems and methods for tracking the position of a head-mounted display (HMD) system component, such as a wearable HMD device or a hand-held controller. The HMD component may include a support structure that carries a plurality of angle sensitive detectors that are able to detect the angle of arrival of light emitted from a light source. A processor causes light sources to emit light according a specified pattern, and receive sensor data from the plurality of angle sensitive detectors. The processor may process the received sensor data using machine learning or other techniques to track a position of the head-mounted display component based on the processing of the received sensor data.

Abstract: An optical distance measurement method includes: acquiring a plurality of sensed values based on detecting light; performing a filtering operation to select a plurality of selected sensed values from the plurality of sensed values; determining a location of a centroid according to the plurality of selected sensed values; and calculating a plurality of depth values with respect to a plurality of detecting points according to the location of the centroid and a plurality of depth information transformation functions respectively corresponding to the detecting points.

Abstract: An optical base station including a base, a light source and a first MEMS scanning mirror is provided. The light source is disposed on the base for providing a light beam. The first MEMS scanning mirror is disposed at an optical path of the light beam to reflect the light beam for spatial scanning.

Abstract: Embodiments describe a solid state electronic scanning LIDAR system that includes a scanning focal plane transmitting element and a scanning focal plane receiving element whose operations are synchronized so that the firing sequence of an emitter array in the transmitting element corresponds to a capturing sequence of a photosensor array in the receiving element. During operation, the emitter array can sequentially fire one or more light emitters into a scene and the reflected light can be received by a corresponding set of one or more photosensors through an aperture layer positioned in front of the photosensors. Each light emitter can correspond with an aperture in the aperture layer, and each aperture can correspond to a photosensor in the receiving element such that each light emitter corresponds with a specific photosensor in the receiving element.

Abstract: An integrated camera, ambient light detection, and rain sensor assembly suitable for installation behind a windshield of a driver operated vehicle or an automated vehicle includes an imager-device. The imager-device is formed of an array of pixels configured to define a central-portion and a periphery-portion of the imager-device. Each pixel of the array of pixels includes a plurality of sub-pixels. Each pixel in the central-portion is equipped with a red/visible/visible/visible filter (RVVV filter) arranged such that each pixel in the central-portion includes a red sub-pixel and three visible-light sub-pixels. Each pixel in the periphery-portion is equipped with a red/green/blue/near-infrared filter (RGBN filter) arranged such that each pixel in the periphery-portion includes a red sub-pixel, a green sub-pixel, a blue sub-pixel, and a near-infrared sub-pixel.

Abstract: A coordinate measurement device sends a first light beam to a target which returns a portion as a second beam. The device includes: first and second motors that direct the first beam to a first direction determined by a first angle of rotation about a first axis and a second angle of rotation about a second axis, the first and second angles of rotation produced by the first and second motors, respectively; first and second angle measuring devices that measure first and second angles of rotation, respectively; a distance meter that measures a first distance from the device to the target based in part on a first portion of the second beam; a processor that provides a 3D coordinate of the target based in part on the first distance and the first and second angles of rotation; and a retractable handle at the device top side.

Abstract: Suspended or overhanging of obstructions are selectively signaled to an individual by a device that can worn by an individual. The device includes a first sensor that is oriented to selectively detect a suspended or overhanging obstruction at an elevation above the housing and a second distance sensor that is oriented to selectively detect an object at an elevation of the housing. A logic circuit within the housing is electrically connected to the first and second sensors and emits a response if the first sensor is activated, but emits no response if the first and second sensors are both activated. A signaling device electrically connected to the logic circuit is activated upon emission of a response from the logic circuit.

Abstract: The present invention provides an inexpensive range image sensor and etc. A range image sensor comprises diffractive optical elements and on which are formed diffractive gratings that change a traveling direction of incident parallel light so that in a coordinate space defined by a xyz-axis, the incident parallel light is split into split beams, and angles formed by the x-axis and line segments determined by projected light spots formed by the split beams on a predetermined projection plane intersecting the z-axis become predetermined angles. Furthermore, the range image sensor is provided with a distance determining unit for determining distances to the projected light spots on the basis of the tilting with respect to the x-axis of the line segments determined by the projected light spots formed on the object by the split beams.

Abstract: An infrared sensor module includes a first infrared sensor that includes a first light emitting unit configured to emit infrared light to an object and a first light receiving unit configured to detect an amount of infrared light reflected from the object, a second infrared sensor that includes a second light emitting unit configured to emit infrared light to the object and a second light receiving unit configured to detect an amount of the infrared light reflected from the object, and a controller to measure reflectivity of the object using a peak output voltage of the first light receiving unit, and to measure a distance to the object using not only the measured object reflectivity but also an output voltage of the second light receiving unit. As a result, the distance from the infrared sensor to the object can be correctly measured irrespective of the reflectivity of the object.

Abstract: Systems and methods for advanced monitoring and control using an LED driver in an optical processor are described. In an embodiment, a monitoring and control circuit may include a light-emitting diode (LED) driver including a control input, an output, and a node, wherein the output is coupled to an LED. The circuit may also include a multiplexer coupled to the node of the LED driver, an analog-to-digital converter coupled to the multiplexer, and a controller coupled to the analog-to-digital converter and to the control input of the LED driver, wherein the LED driver is coupled to drive the output with a first voltage supply that is independent from a second voltage supply that is coupled to drive the controller.

Abstract: According to one embodiment, an electronic apparatus includes a proximity sensor, a control module and an adjustment module. The proximity sensor is configured to emit light and to detect reflection of the emitted light. The control module is configured to control an operation of the electronic apparatus, based on an output signal of the proximity sensor. The adjustment module is configured to adjust an intensity of the emitted light by monitoring the output signal of the proximity sensor while varying the intensity of the emitted light, when an event indicating that a detection distance of the proximity sensor is to be adjusted has occurred.

Abstract: A method of increasing signal-to-noise ratio of a distance-measuring device includes a light-emitting component emitting a detecting light to a measured object during an emitting period for generating a reflected light, a delay period after the light-emitting component emitting the detecting light, a light-sensing component sensing the energy of the reflected light to generate a light-sensing signal, and obtaining a measured distance between the distance-measuring device and the measured object according to the energy of the detecting light and the light-sensing signal. Since the measured distance is longer than a predetermined shortest measured distance, the method can accordingly calculate a proper delay period for ensuring that the reflected light reaches the light-sensing component after the delay period. In this way, the light-sensing component does not sense the background light during the delay period, so that the signal-to-noise ratio of the light-sensing signal is improved.

Abstract: The subject disclosure is directed towards a distance sensor that outputs one or more (e.g., infrared) light patterns from a transmitting element. Signals from any reflective entity (e.g., a surface or object) within the sensor's range are captured by a receiving element. The captured image is digitized into digital data representing each light pattern, and the digital data is processed (e.g., including using triangulation) to determine distance data of the distance sensor relative to the reflective surface.

Abstract: A system for optical navigation includes a light source and an imaging system. The light source illuminates a navigation surface. The navigation surface reflects light from the light source. The imaging system is located approximately within a path of the reflected light. The imaging system includes a lens, a mask, and an image sensor. The lens receives reflected light from the navigation surface. The lens focuses a specular portion of the reflected light to a focus region. The mask is located at approximately the focus region. The mask filters out substantially all of the specular portion of the reflected light and passes at least some of a scatter portion of the reflected light outside of the focus region. The image sensor generates a navigation signal based on the scattered portion of the light that passes outside the focus region and is incident on the image sensor.

Abstract: A coordinate measurement device sends a first light beam to a target which returns a portion as a second beam. The device includes: first and second motors that direct the first beam to a first direction determined by a first angle of rotation about a first axis and a second angle of rotation about a second axis, the first and second angles of rotation produced by the first and second motors, respectively; first and second angle measuring devices that measure first and second angles of rotation, respectively; a distance meter that measures a first distance from the device to the target based in part on a first portion of the second beam; a processor that provides a 3D coordinate of the target based in part on the first distance and the first and second angles of rotation; and a retractable handle at the device top side.

Abstract: An optical blind-guide apparatus for detecting an object is provided. The optical blind-guide apparatus includes an illuminant module illuminating the object to form a reflection light from the object; a sensor sensing the reflection light to generate a digital message; a system module receiving and processing the digital message to obtain a blind-guide information; and an output device coupled with the system module and outputting the blind-guide information.

Abstract: The present invention provides an inexpensive range image sensor and etc. A range image sensor comprises diffractive optical elements and on which are formed diffractive gratings that change a traveling direction of incident parallel light so that in a coordinate space defined by a xyz-axis, the incident parallel light is split into split beams, and angles formed by the x-axis and line segments determined by projected light spots formed by the split beams on a predetermined projection plane intersecting the z-axis become predetermined angles. Furthermore, the range image sensor is provided with a distance determining unit for determining distances to the projected light spots on the basis of the tilting with respect to the x-axis of the line segments determined by the projected light spots formed on the object by the split beams.

Abstract: Methods and devices for calculating the position of a movable device are disclosed. The device may include multiple optical detectors (ODs) and the movable device may include light sources. Optics may be above the ODs. A controller may calculate the position of the light source based on data from the ODs and properties of the optics. The device may be a game console, and the light source may be a game controller. The roles of the OD and light sources may be interchanged. The rotation of the movable device may be determined using multiple light sources and/or multiple ODs on the movable device. The movable device may calculate its position and transmit it to a console. The light sources may be modulated by time or frequency to distinguish between the light sources. There may be two or more movable devices. There may be two or more consoles.

Abstract: A distance measurement system includes: an projection apparatus (1) which projects measurement beams (PL1, PL2) at least at first and second projection angles (?3, ?15, ?, ?) towards a detection area; an image pick-up apparatus (2) which picks up an image of a first reflected light (LB1) and an image of a second reflected light (LB2) from the detection area. The system further includes: a distance calculation unit (32) which calculates a first distance (d1) to a first measurement point (P2, P5) and a second distance (d2) to a second measurement point (P4, P7); a judgment unit (33) which judges that specular reflection is caused; and an operation unit (34) which, when it is judged by the judgment unit (33) that the specular reflection is caused, calculates a distance (d4) to a detection object (MB1, MB2) causing the specular reflection.

Abstract: A method of guiding a vehicle comprises sensing a position of a laser beam using a laser sensor and receiving a signal from the laser sensor wherein the signal is representative of the position of the laser beam. The method further includes interpreting the signal, generating a control signal in response to the laser beam being greater than a predetermined distance from a predetermined reference position and wherein the control signal is configured to control the vehicle to track the position of the laser beam. The method additionally comprises sending the control signal to a drive actuator.

Abstract: An optical blind-guide apparatus for detecting an object is provided. The optical blind-guide apparatus includes an illuminant module illuminating the object to form a reflection light from the object; a sensor sensing the reflection light to generate a digital message; a system module receiving and processing the digital message to obtain a blind-guide information; and an output device coupled with the system module and outputting the blind-guide information.

Abstract: A method for measuring the distance of an object is provided that includes irradiating a plurality of light beams having predetermined wavelengths and then in a first round, picking up an image under irradiation of the plurality of light beams and in another round picking up the image without irradiation using a camera. The difference of the image between the first and other round is fed to an observation region part and to an irradiation angle computing part and then the distance to the object is computed.

Abstract: Systems and techniques for laser metrology. Two or more fanned probe beams are scanned relative to a surface including one or more targets. A position detection module receives return beam information from the fanned probe beams, and determines a position of at least a first target of the one or more targets based on the return beam information.

Abstract: An optical body height measurement instrument is provided comprising: a lens configured to be movable along a direction parallel to the height of an object to be measured and form an image of the object; a photosensitive sensor arranged at an image side of the lens to sense the image; and a driving device configured to drive the lens along a direction parallel to the height of the object, wherein when the lens is moved across the height at which the head of the object is located, a hop occurs to an output of the photosensitive sensor; and wherein the height of the object is determined based on the height of the lens measured at the time of the occurrence of the hop. The optical body height measurement instrument can rapidly, conveniently and accurately measure the height based on the infrared rays emitted from the measured object or the light with a predetermined wavelength emitted from an auxiliary light source so long as the person to be measured stands within a certain region.

Abstract: A distance measurement system includes: an projection apparatus (1) which projects measurement beams (PL1, PL2) at least at first and second projection angles (?3, ?15, ?, ?) towards a detection area; an image pick-up apparatus (2) which picks up an image of a first reflected light (LB1) and an image of a second reflected light (LB2) from the detection area. The system further includes: a distance calculation unit (32) which calculates a first distance (d1) to a first measurement point (P2, P5) and a second distance (d2) to a second measurement point (P4, P7); a judgment unit (33) which judges that specular reflection is caused; and an operation unit (34) which, when it is judged by the judgment unit (33) that the specular reflection is caused, calculates a distance (d4) to a detection object (MB1, MB2) causing the specular reflection.

Abstract: A distance sensor with a method and device for compensating for mounting tolerances. Mounting tolerances may make distance sensors fail in correctly measuring the angle between the sensor and an object which will result in wrong lateral spacing to be computed. Sensor values therefore need to be corrected. Available methods of correction require quite a lot of memory capacity and processor power. The invention therefore aims at providing a method and a device that aid the compensation of mounting tolerances of a distance sensor, where compensation is provided with little effort and extremely quickly. This is achieved by having the distance sensor (1) emit its rays (2) at an aperture angle (a) of 0.1° to 10° and pick up data while the vehicle is moving straight forward, and determining an angle error (?) by comparing the data picked up during a chance of channels.

Abstract: A method for measuring the distance of an object is provided that includes irradiating a plurality of light beams having predetermined wavelengths and then in a first round, picking up an image under irradiation of the plurality of light beams and in another round picking up the image without irradiation using a camera. The difference of the image between the first and other round is fed to an observation region part and to an irradiation angle computing part and then the distance to the image is computed.

Abstract: A device for measuring the radius of curvature of a surface comprises a main body that is held above the surface being measured; and a non-contact sensor mounted to the main body that measures a distance between the surface being measured and the sensor, the device calculating the radius of curvature of the surface based on the measured distance. The device can further include a display mounted to the main body that displays the calculated radius of curvature. The non-contact sensor can be, for example, an acoustical distance sensor or an optical distance sensor. In one embodiment, the device includes two arms extending from the main body of the device and being substantially symmetric about the non-contact sensor, the arms terminating in contact points that make contact with the surface being measured.

Abstract: An optical position detection device capable of detecting a position of a light source with high accuracy and being low priced is provided. A transmission system 1 detects a position of the transmission system 1 relative to a reception system 2 based on a fixed distance L between a second light source 12 and a third light source 13, an incoming angle ?2 of signal light R2 from the second light source 12 relative to the transmission system 1, and an incoming angle ?3 of signal light R3 from the third light source 13 relative to the transmission system 1.

Abstract: A video sensor device is provided which incorporates a rangefinder function. The device includes a single video camera and a fixed laser spaced a predetermined distance from the camera for, when activated, producing a laser beam. A diffractive optic element divides the beam so that multiple light spots are produced on a target object. A processor calculates the range to the object based on the known spacing and angles determined from the light spots on the video images produced by the camera.

Abstract: A system comprises a two-dimensional photographing device and a three-dimensional measuring device that is removably attached to the two-dimensional photographing device. The two-dimensional photographing device and the three-dimensional measuring device can communicate with each other. Information indicating an operating condition of one of the devices is transmitted to the other device, which receives the information and sets own operating condition in accordance with the received information for photographing or measuring.

Abstract: An optical distance sensor includes a first substrate provided with a light emitting element and a light detecting element, a one-piece optical structure body on a second substrate, the optical structure body having optical elements for converging incident light in a direction parallel to a surface of the second substrate and for converging an outgoing light beam from the light emitting element and a light beam reflected by an object in the direction parallel to the surface of the second substrate, and lenses for converging incident light in a direction perpendicular to the surface of the second substrate and for converging the outgoing light beam from the light emitting element and the light beam reflected by the object in the direction perpendicular to the surface of the second substrate, respectively.

Abstract: A method for monitoring a protected zone in which a light ray is transmited by an apparatus in the direction of the protected zone, a light ray reflected/remitted by an object disposed in the protected zone is received and the distance between the apparatus and the object is determined. The arrangement is such that at least two light rays are transmitted which include an angle between them; that, with an object present inside the protected zone, a first light ray reflected/remitted by the object is received; that, with an object-free protected zone, a second light ray reflected/remitted from a location disposed outside the protected zone is received; and that the distance from the apparatus of both the object and the second location is determined. Furthermore the present invention relates to a corresponding apparatus.

Abstract: A device for the observation of passages on the sun of Venus and Mercury and more generally for observation of the solar disk by back projection of the solar image on a screen that also forms a sun screen for the protection of the eyes.

Abstract: In order to judge range with the laser range estimation aid the lasers (1, 2 and 3) should be activated via the switch (8) and directed at the target of range desired. The lasers (1, 2 and 3) should produce a triangle pattern of dots. If there is an upright triangle (10, 11), then the target is below or closer that the zero range. If there is a single dot, then target is substantially at the zero range (12). If there is an inverted triangle (13, 14), then the target is above or further away from the zero range. Also, the size of the pattern produced can be found relative to the terrain which allows for further range calculation.

Abstract: An apparatus for measuring the distance to a reflective surface. A first light source transmits a first light onto the reflective surface, the first light source being located on a first side of an axis. The reflective surface reflects at least a portion of the light onto a first light-detecting device having a first region operable to receive the reflected first light from the reflective surface. The first light-detecting device transmits a first and second signals as a function of the location of the received first light within the first region. A second light source transmits a second light onto the reflective surface, the second light source being located on a second side of the axis. The reflective surface reflects at least a portion of the second light onto a second light-detecting device having a second region operable to receive the reflected second light from the reflective surface.

Abstract: In a method, the light beams of two separated optical radar units (each of which are capable of emitting light pulses in a direction and receiving light pulses from the same direction) are directed to a point. The first optical radar unit emits a light pulse to the point and the second optical radar unit detects the light pulse reflected from the object at the point. After a time interval, the second optical radar unit emits a light pulse to the point and the first optical radar unit detects the light pulse reflected from the object at the point. If there is an object at the point, the time difference of the two detected signals from the two optical radar units is the switching time interval. By comparing the two detected signals from the two optical radar units, one can determine whether an object is at the point.

Abstract: An apparatus for determining the relative height between two targets is disclosed. The present invention also discloses a method for determining the relative height between two targets; the method is substantially similar to the operational aspects of the device of the present invention. The method requires no angular measurements in order to determine the different height between the two targets, but rather only distance measurements that can be performed simply and accurately. The apparatus for determining the relative height between two targets a disclosed.