Abstract: A tracker includes a retro-follow mode that causes a beam of light from the tracker to follow a retroreflector while locked onto the retroreflector with the beam of light turned on or, alternatively, using target cameras with the beam of light turned off.

Abstract: A system and method for performing noncontact three-dimensional (3D) coordinates. The system including a system includes a noncontact three-dimensional (3D) measuring device operable to measure 3D coordinates of an object. A stage is operable to rotate the object. A mechanical arm is coupled to the 3D measuring device, the mechanical arm being operable to rotate the 3D measuring device in a first arc about a first axis and in a second arc about a second axis, the first arc larger than the second arc.

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

Abstract: A method and system of combining 2D images into a 3D image. The method includes providing a coordinate measurement device and a triangulation scanner having an integral camera associated therewith, the scanner being separate from the coordinate measurement device. In a first instance, the coordinate measurement device determines the position and orientation of the scanner and the integral camera captures a first 2D image. In a second instance, the scanner is moved, the coordinate measurement device determines the position and orientation of the scanner, and the integral camera captures a second 2D image. A common feature point in the first and second images is found and is used, together with the first and second images and the positions and orientations of the scanner in the first and second instances, to create the 3D image.

Abstract: A method and apparatus for correcting errors in a bearing cartridge used in a portable articulated arm coordinate measurement machine (AACMM) is provided. The method includes providing a cartridge having a first bearing and a second bearing arranged in a fixed relationship to define an axis, the cartridge further including an angle measurement device configured to measure a rotation of a portion of the cartridge about the axis. A plurality of angles is measured with the angle measurement device. A first plurality of displacements is determined at a first position along the axis, each of the first plurality of displacements being associated with one of the plurality of angles. Compensation values are determined based at least in part on the plurality of angles and the first plurality of displacements.

Abstract: A three-dimensional (3D) scanner having two cameras and a projector is detachably coupled to a device selected from the group consisting of: an articulated arm coordinate measuring machine, a camera assembly, a six degree-of-freedom (six-DOF) tracker target assembly, and a six-DOF light point target assembly.

Abstract: A method and system are provided for controlling a measurement device remotely through gestures performed by a user. The method includes providing a relationship between a command and a gestures. A gesture is performed by the user with the user's body that corresponds to the user gesture. The gesture performed by the user is detected. A command is determined based at least in part on the detected gesture. Then the command is executed with the laser tracker.

Abstract: A method for optically communicating, from a user to a laser tracker, a command to direct a beam of light from the laser tracker to a retroreflector with steps including: projecting a first light from a light source disposed on the laser 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, the third light being a portion of the second light, wherein the first sensed data is obtained by imaging the third light onto a photosensitive array disposed on the laser tracker and converting the third light on the photosensitive array into digital form; generating by the user, between a first time and a second time, a predefined temporal pattern, the predefined temporal pattern including at least a decrease in optical power of the third light followed by an increase in the optical power of the third light, the predefined temporal pattern corresponding to the command; determining by the

Abstract: A three-dimensional (3D) measuring device includes a cooling fan and an enclosure attached to a projector and a camera. The camera images a pattern of light projected by the projector onto an object to determine 3D coordinates points on the object. A fan draws air through an opening in the front of the enclosure, across a plurality of components in the enclosure and out a second opening in the enclosure.

Abstract: A three-dimensional (3D) scanner having two cameras and a projector is detachably coupled to a device selected from the group consisting of: an articulated arm coordinate measuring machine, a camera assembly, a six degree-of-freedom (six-DOF) tracker target assembly, and a six-DOF light point target assembly.

Abstract: A three-dimensional (3D) coordinate measurement device combines tracker and scanner functionality. The tracker function is configured to send light to a retroreflector and determine distance to the retroreflector based on the reflected light. The tracker is also configured to track the retroreflector as it moves, and to determine 3D coordinates of the retroreflector. The scanner is configured to send a beam of light to a point on an object surface and to determine 3D coordinate of the point. In addition, the scanner is configured to adjustably focus the beam of light.

Abstract: An apparatus includes a kinematic nest that supports an element having a spherical surface, a rotation mechanism that rotates the element, and processor that activates the rotation mechanism.

Abstract: A three-dimensional (3D) coordinate measuring system is provided. The system includes an aerial measuring device that has an aerial drone and a 3D measurement device. The 3D measurement device being rotatably attached to the aerial drone, the aerial drone is movable from a first position to a stationary second position. The 3D measurement device being configured to optically measure points on the surface of an object. The system further includes one or more processors configured to execute nontransitory computer readable instructions. The computer readable instructions comprise: moving the aerial measuring device from the first position; landing the aerial measuring device at the second position; rotating the 3D measurement device to optically measure a first object point; and determining a first 3D coordinates of the first object point with the 3D measuring device.

Abstract: At each of three different locations, a tracker captures a 2D image an object and measures three points in space at each of three tracker locations relative to the object. Based on this information, the tracker determines, in an object frame of reference, three-dimensional coordinates of an arbitrary point on an edge line common to the three 2D images.

Abstract: A coordinate measuring device includes: a light source operable to emit a first light, the first light being visible light having a first wavelength; a fiber launch operable to receive the first light through a first optical fiber, to launch the first light into free space, and to collimate the launched first light into a first beam of light having a diameter_defined by the fiber launch, the first beam of light operable to leave the coordinate measuring device absent an intervening beam expander, the fiber launch being further coupled through the first optical fiber to a distance meter operable to measure a first distance to a retroreflector illuminated by the first beam of light; a first motor and a second motor operable to direct the first beam of light to a first direction, the 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 angle of rotation produced by the first motor and the second angle of rotation produced by the

Abstract: A method for verifying performance of a light projector includes establishing a reference artifact that include reflective makers and an interior edge line, determining with a laser-tracker-based three-dimensional (3D) measuring system 3D coordinates of the reflective targets and the interior edge line, determining with the light projector angles to the reflective markers with the light projector, and projecting with the light projector a pattern of light onto the interior edge line.

Abstract: A tracker includes a retro-follow mode that causes a beam of light from the tracker to follow a retroreflector while locked onto the retroreflector with the beam of light turned on or, alternatively, using target cameras with the beam of light turned off.

Abstract: A method for optically communicating, from a user to a laser tracker, a command to direct a beam of light from the laser tracker to a retroreflector with steps including: projecting a first light from a light source disposed on the laser 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, the third light being a portion of the second light, wherein the first sensed data is obtained by imaging the third light onto a photosensitive array disposed on the laser tracker and converting the third light on the photosensitive array into digital form; generating by the user, between a first time and a second time, a predefined temporal pattern, the predefined temporal pattern including at least a decrease in optical power of the third light followed by an increase in the optical power of the third light, the predefined temporal pattern corresponding to the command; determining by the

Abstract: A mobile three-dimensional (3D) measuring system includes a 3D measuring device, a multi-legged stand coupled to the 3D measuring device, and a motorized dolly detachably coupled to the multi-legged stand.

Abstract: A measurement device having a camera captures images of an object at three or more different poses. A processor determines 3D coordinates of an edge point of the object based at least in part on the captured 2D images and pose data provided by the measurement device.