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 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 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: Measuring with a system having retroreflector targets and a laser tracker includes storing a list of coordinates for three targets and at least one added point; capturing on a photosensitive array a portion of the light emitted by a light beam and reflected off the targets; obtaining spot positions on a photosensitive array of a tracker camera from the reflected light; determining a correspondence between three spot positions on the photosensitive array and the coordinates of the targets; directing a beam of light from the tracker to the targets based at least in part on the coordinates of the first target and the first spot position; measuring 3-D coordinates of the targets with the tracker; determining 3-D coordinates of the at least one added point based at least in part on the measured 3-D coordinates of the targets and the coordinates of the at least one added point.

Abstract: A method of conveying information with a portable articulated arm coordinate measuring machine (AACMM) is provided. The method includes the steps of providing a manually positionable articulated arm portion having opposed first and second ends, the arm portion including a plurality of connected arm segments with a measurement device coupled to the first end. A light source is coupled to the first end, the light source configured to emit a visible light pattern on a surface of an object. A first processor determines a location of a next measurement and a type of the next measurement to be performed by an operator, the type of the measurement selected from among a plurality of measurement types. The first processor determines the light pattern based at least in part on the type of the next measurement. The light pattern is projected proximal to the location.

Abstract: A method for optically communicating, from a user to a laser tracker, a command to direct a light beam from the tracker to a retroreflector and lock onto the retroreflector includes projecting a first light to the retroreflector. Also, moving by the user the retroreflector in a predefined spatial pattern which corresponds to the command; reflecting a second light from the retroreflector, the second light being a portion of the first light; obtaining first sensed data by sensing a third light which is a portion of the second light and imaging the third light onto a photosensitive array on the tracker and converting the third light on the photosensitive array into digital form. Further, determining the first sensed data corresponds to the predefined spatial pattern; pointing the light beam from the tracker to the retroreflector; and locking onto the retroreflector with the tracker light beam.

Abstract: A laser measurement system includes a laser tracker having a structure rotatable about first and second axes, a first light source that launches a light beam from the structure, a distance meter, first and second angular encoders that measure first and second angles of rotation about the first and second axes, respectively, a processor, and a camera system. Also, a communication device that includes a second light source and an operator-controlled device that controls emission of a light from the second light source; a retroreflector target not disposed on the communication device. Also, the camera system is operable to receive the second light and to convert it into a digital image, and the processor is operable to determine a command to control operation of the tracker based on a pattern of movement of the second light source between first and second times and the digital image.

Abstract: A target is provided having a retroreflector. A body is provided having a spherical exterior portion, the body containing a cavity. The cavity is sized to hold the retroreflector, the cavity open to the exterior of the body and having at least one surface opposite the opening, the retroreflector at least partially disposed in the cavity, wherein the retroreflector and at least one surface define a space therebetween. A transmitter is configured to emit an electromagnetic signal. A first actuator is configured to initiate emission of the electromagnetic signal, wherein the transmitter and the first actuator are affixed to the body.

Abstract: A method is provided of obtaining the characteristics of a target by a device. The method includes providing the target having a target frame of reference, a retroreflector and a body. Providing a contact element rigidly fixed with respect to the body. A device is provided having a frame of reference and a light source, the device configured to measure a distance and two angles from the device to the retroreflector reference point. An identifier element located on the body. A workpiece surface is provided. The contact element contacts the workpiece surface. The retroreflector is illuminated with light from the light source and returns a reflected light. A distance and two angles are measured based at least in part on the reflected light. The first information is read with a first reader attached to the device. A three-dimensional coordinate of a point on the workpiece surface is calculated.

Abstract: Embodiments of the present invention relate to a measurement machine for measuring an object, and more particularly to a measurement machine such as a portable articulated arm coordinate measuring machine or a laser tracker that measures an object according to a measurement or inspection plan that is identified by a machine readable information symbol located on the object to be measured or on a drawing (e.g., a CAD drawing) of the object.

Abstract: Measuring with a system having retroreflector targets and a laser tracker includes storing a list of nominal coordinates for three targets and at least one added point; capturing on a photosensitive array of the tracker a portion of the light emitted by a light beam and reflected off the three targets; obtaining spot positions on a photosensitive array of a tracker camera from light reflected off the three targets; determining a correspondence between three spot positions on the tracker photosensitive array and the nominal coordinates of the three targets; directing a beam of light from the tracker to the three targets based at least in part on the nominal coordinates of the first target and the first spot position; measuring 3-D coordinates of the three targets with the tracker; determining 3-D coordinates of the at least one added point based at least in part on the measured 3-D coordinates of the three targets and the nominal coordinates of the at least one added point.

Abstract: The present system, method, article of manufacture, software, and apparatus is an “intelligent” probe system and components thereof and may openly encompass, in at least an embodiment, an embedded IC chip located in an interchangeable probe(s) which offers repeatable, fast, easy, and error free probe swapping on a CMM.

Abstract: An optical encoder may include an encoder disk, an illumination system, and a detector to detect light diffracted from the encoder disk. The encoder disk may include a signal track comprising a diffraction grating, and an index track comprising a reflective index mark, wherein a width of the index mark is larger than a pitch of the diffraction grating. An indexing method may include providing an encoder disk, providing an illumination system to direct light to the encoder disk, providing a detector structured to detect light diffracted from the encoder disk, calculating an estimated count of quadrature states from a rising edge of an index pulse to a middle of the index interval, and calculating the quadrature state at an approximate center of the index pulse. A dynamic parameter correction method may include calculating a target gain and offset and correcting values based on the target gain and offset.

Abstract: An optical encoder may include an encoder disk, an illumination system, and a detector to detect light diffracted from the encoder disk. The encoder disk may include a signal track comprising a diffraction grating, and an index track comprising a reflective index mark, wherein a width of the index mark is larger than a pitch of the diffraction grating. An indexing method may include providing an encoder disk, providing an illumination system to direct light to the encoder disk, providing a detector structured to detect light diffracted from the encoder disk, calculating an estimated count of quadrature states from a rising edge of an index pulse to a middle of the index interval, and calculating the quadrature state at an approximate center of the index pulse. A dynamic parameter correction method may include calculating a target gain and offset and correcting values based on the target gain and offset.

Abstract: A portable articulated arm coordinate measurement machine is provided. An articulated arm is provided having a plurality of arm segments. Each arm segment includes an angular encoder for producing a signal corresponding to an angle of rotation. A shaft rotates which about an axis is attached to an inner portion of a first and second bearing. A patterned disk is attached to the shaft. A housing is attached to an outer portion of the first and second bearing. A read head is attached to the housing in proximity to the patterned disk which produces an electrical signal in response to an angle of rotation. The patterned disk and the first arm segment supported for rotation about the axis by only the first and second bearing. A circuit receives the electrical signal and provides an angle and data corresponding to a position of the probe.

Abstract: A portable articulated arm coordinate measurement machine is provided. The coordinate measurement machine includes a manually positionable articulated arm having opposed first and second ends. The articulated arm includes a plurality of arm segments, each including encoder configured to produce a signal corresponding to an angle of rotation. A base section is connected to the second end. A measurement probe is connected to the first end. The measurement probe receives an externally mounted sensor having an attachment ring, the measurement probe having an alignment surface and external threading. A retaining ring having internal threading is threadably receives the external threading; the retaining ring further couples the attachment ring to the surface. An electrical circuit is configured to receive the signal and to provide data corresponding to a coordinate of the externally mounted sensor, the data based at least in part on the signal.

Abstract: A method for optically communicating, from a user to a laser tracker, a command to control tracker operation includes providing a rule of correspondence between commands and temporal patterns, and selecting by the user a first command. Also, projecting a first light from the tracker to the retroreflector, reflecting a second light from the retroreflector, the second light being a portion of the first light, obtaining first sensed data by sensing a third light which is a portion of the second light, creating by the user, between first and second times, a first temporal pattern which includes a decrease in the third optical power followed by an increase in the third optical power, the first temporal pattern corresponding to the first command, determining the first command based on processing the first sensed data per the rule of correspondence and executing the first command with the tracker.