Abstract: An apparatus and method for correcting errors in measurement of three-dimensional coordinates of a retroreflector by a coordinate measurement device is provided. The method includes measuring a plurality of first angles, a plurality of first and second displacements along an axis, sending a beam of light to the retroreflector target, measuring two angles and a distance to the retroreflector, and determining the three-dimensional coordinates of the retroreflector.

Abstract: A method of measuring spherically mounted retroreflector (SMR) with a 3D coordinate measurement device such as a laser tracker. The SMR includes an open-air cube corner retroreflector having a vertex point located near a sphere center of the SMR. Measurements of the SMR to the vertex point are corrected to indicate 3D coordinates of the SMR sphere center by accounting for SMR depth error and SMR runout error.

Abstract: A coordinate measurement device sends a first beam of light having first and second wavelengths to a target point. The device includes a fiber-optic coupler that combines the first and second wavelengths and launches them through an achromatic optical element to produce collimated and aligned light. The device also includes first and second motors, first and second angle measuring devices, a distance meter, and a processor that determines 3D coordinates of the target point based on the measured distance and two angles.

Abstract: A method is provided for determining the three dimensional coordinates of points on the surface of an object. The method includes providing a structured light scanner and a coordinate measurement device. The coordinate measurement device tracks the location and orientation of the structured light scanner during operation. The location and orientation data is combined with image frames captured by the scanner to allow registration of the image frames relative to each other. The three-dimensional coordinates of points on the surface of the object may then be determined in the frame of reference of the coordinate measurement device.

Abstract: A noncontact optical three-dimensional measuring device that includes a projector, a first camera, and a second camera; a processor electrically coupled to the projector, the first camera and the second camera; and computer readable media which, when executed by the processor, causes the first digital signal to be collected at a first time and the second digital signal to be collected at a second time different than the first time and determines three-dimensional coordinates of a first point on the surface based at least in part on the first digital signal and the first distance and determines three-dimensional coordinates of a second point on the surface based at least in part on the second digital signal and the second distance.

Abstract: An optical measurement device is provided includes a tracker device configured to emit a first beam of light and receive a portion of the first beam of light reflected off of a target. The first beam of light being emitted from a gimbal location, the tracker device further including an absolute distance meter configured to determine the distance to the target. A scanner device is provided that is configured to emit a second beam of light along a pathway without reversing direction and receive a portion of the second beam of light reflected off an object. The second beam of light being emitted from the gimbal location, the scanner further being configured to determine the distance to the object based at least in part on the speed of light.

Abstract: A method is provided for determining the three dimensional coordinates of points on the surface of an object. The method includes providing a structured light scanner and a coordinate measurement device. The coordinate measurement device tracks the location and orientation of the structured light scanner during operation. The location and orientation data is combined with image frames captured by the scanner to allow registration of the image frames relative to each other. The three-dimensional coordinates of points on the surface of the object may then be determined in the frame of reference of the coordinate measurement device.

Abstract: A laser scanner has a light emitter, a rotary mirror, a light receiver, a first beam splitter to send electromagnetic energy from an electromagnetic energy generator into the environment, a second beam splitter to send reflected electromagnetic energy to a spectroscopic energy detector, and a control and evaluation unit, the spectroscopic energy detector configured to determine wavelengths in the reflected electromagnetic energy.

Abstract: An optical measurement device is provided includes a tracker device configured to emit a first beam of light and receive a portion of the first beam of light reflected off of a target. The first beam of light being emitted from a gimbal location, the tracker device further including an absolute distance meter configured to determine the distance to the target. A scanner device is provided that is configured to emit a second beam of light along a pathway without reversing direction and receive a portion of the second beam of light reflected off an object. The second beam of light being emitted from the gimbal location, the scanner further being configured to determine the distance to the object based at least in part on the speed of light.

Abstract: A portable articulated arm coordinate measuring machine (AACMM) for measuring three-dimensional coordinates of an object in space is provided including a base and a positionable arm coupled to the base. The arm has at least one arm segment including a position transducer for producing a position signal. An electronic circuit receives the position signal from the at least one position transducer. A non-articulated measurement device, coupled to the arm, includes a flexible member having at least one sensing element configured to sense deflection of the flexible member. A probe of the flexible member contacts a surface of an object. A processing unit coupled to the sensing element determines the position and shape of the flexible member. A processor, coupled to the electronic circuit, determines the three-dimensional coordinates of a point on the object in response to position signal from the position transducer and the position signals from the processing unit.

Abstract: A device for optically scanning and measuring an environment is provided. The device includes at least one projector for producing at least one uncoded pattern on an object in the environment. A first camera is provided for recording at least one first image of the object provided with the pattern, the first camera having a first image plane. A second camera is provided for recording at least one second image of the object provided with the uncoded pattern, the second camera being spaced apart from the first camera in order to acquire the uncoded pattern on a second image plane. A controller is provided having a processor configured to determine the three-dimensional coordinates of points on the surface of the object based at least in part on the uncoded pattern, the at least one first image and the at least one second image.

Abstract: A device for optically scanning and measuring an environment is provided. The device includes a movable scanner having at least one first projector for producing at least one uncoded first pattern on an object in the environment. The scanner includes at least one camera for recording images of the object provided with the pattern and a controller coupled to the first projector and the camera. The device further includes at least one second projector which projects a stationary uncoded second pattern on the object while the scanner is moved. Wherein the controller has a processor configured to determine a set of three-dimensional coordinates of points on a surface of the object from a set of images acquired by the camera based at least in part on the first pattern. The controller is further configured to register the set of images relative based in part on the stationary second pattern.

Abstract: A portable articulated arm coordinate measurement machine (AACMM) having opposed first and second ends and a plurality of connected arm segments each having at least one position transducer for producing a position signal; an electronic circuit configured to receive the position signals; a first bus for communication with the electronic circuit, wherein at least a portion of the first bus is an optical communication bus configured to transmit light; and a rotary coupler having a first portion and a second portion, the second portion configured to rotate relative to the first portion, the first portion affixed to the first arm segment, the rotary coupler configured to transfer signals on the optical communication bus between the first portion and the second portion.

Abstract: A method of dynamically adjusting an angular speed of a light beam emitted by a scanner in measuring three-dimensional (3D) coordinates of a surface or of dynamically adjusting an acquisition rate of 3D coordinates of a surface.

Abstract: A laser scanner for optically scanning and measuring an environment is provided. The laser scanner includes a light transmitter for emitting a light beam to measure a plurality of points in the environment, the light transmitter coupled to the rotating unit. A receiver is provided for receiving a reflected light beam reflected from the plurality of measurement points, the receiver being coupled to the rotating unit. A first image acquisition unit is configured to record a visible image of an area of the environment that includes the plurality of points. A sensing device is configured to record data of the area. A processor is operably coupled to the receiver, the first image acquisition unit and the sensing device, the processor is configured to associate a color value from the visible image and a recorded data value from the sensing device with each of the plurality of points.

Abstract: A line scanner configured to measure an object is provided. The scanner includes a non-laser light source, a beam delivery system and a mask. The beam delivery system is configured to deliver the light from the light source to the mask. The mask includes an opaque portion and a transmissive region in the shape of a line. A first lens system is configured to image the light from the mask onto the object. A camera that includes a second lens system and a photosensitive array, wherein the second lens system is configured to collect the light reflected by or scattered off the object as a first collected light and image the first collected light onto the photosensitive array. A housing is provided and an electronic circuit including a processor. The electronic circuit is configured to calculate three dimensional coordinates of a plurality of points of light imaged on the object.

Abstract: An apparatus and method for correcting errors in measurement of three-dimensional coordinates of a retroreflector by a coordinate measurement device is provided. The method includes measuring a plurality of first angles, a plurality of first and second displacements along an axis, sending a beam of light to the retroreflector target, measuring two angles and a distance to the retroreflector, and determining the three-dimensional coordinates of the retroreflector.

Abstract: A laser line probe (LLP) configured to measure an object is provided. The LLP includes a projector, a camera, a bracket, and an electronic circuit. The projector includes a light source, a first lens system and a continuously varying neutral density filter. The projector is configured for generating a line of light having a substantially even intensity distribution and for projecting the line of light onto the object. The camera includes a second lens system and a photosensitive array. The second lens system is configured to collect the light reflected by or scattered off the object as a first collected light and to image the first collected light onto the photosensitive array. The electronic circuit includes a processor and is configured to determine three-dimensional coordinates of a plurality of points of light projected on the object by the projector.

Abstract: A laser based coordinate measuring device measures a position of a remote target. The laser based coordinate measuring device includes a stationary portion, a rotatable portion, and at least a first optical fiber. The stationary portion has at least a first laser radiation source and at least a first optical detector, and the rotatable portion is rotatable with respect to the stationary portion. The first optical fiber system, which optically interconnects the first laser radiation source and the first optical detector with an emission end of the first optical fiber system, has the emission end disposed on the rotatable portion. The emission end emits laser radiation to the remote target and receives laser radiation reflected from the remote target with the emission direction of the laser radiation being controlled according to the rotation of the rotatable portion.