A metrology device with automated compensation and/or alert for orientation errors. The device may include a processor, a probe portion and at least one orientation sensor. The probe provides an output representative of a raw measurement of a characteristic of a device under test and the orientation sensor provides a sensor output representative of an orientation of the metrology device to the device under test. The processor applies a correction factor to the raw measurement in response to the sensor output to establish a compensated measurement to compensate for misalignment of the metrology device to the device under test. In addition, or alternatively, the processor provides an alert indicating the existence and/or extent of the misalignment.

The present disclosure uses a surface property measuring device that includes an arm swingably supported so as to displace a stylus vertically, and an arm lifter that holds the stylus at a predetermined height by rotating the arm. After arranging the arm lifter in a state where the arm can be held at a lower limit height that is only a predetermined drop amount below a predetermined measurement height, the arm is arranged at the measurement height and the stylus contacts a measured object, and in this state surface properties of the measured object are measured.

A method system of reducing operator-induced error in measurements comprises a measurement tool, such as a diameter gage, that is configured to communicate electrical signals representative of measurements to a computing device, which is configured to receive the signals and to determine a value for the measurement without the operator having to interact with the tool to zero the gage, acquire the data or transmit the data.

There is provided an automatic measurement device that automates a contact type measuring instrument, which is inexpensive and good usability. An automatic measurement device includes a measuring instrument support base portion that supports a measuring instrument and a workpiece holding base portion that holds a workpiece in a measurement region of the measuring instrument. The measuring instrument support base portion includes a measuring instrument holder that holds a fixed element of the measuring instrument and an automatic operation unit attachable to and detachable from the measuring instrument. The automatic operation unit is configured to automate advance and retreat of the movable element of the measuring instrument by a power from a motor.

There is provided an automatic measurement device that automates a contact type measuring instrument, which is inexpensive and good usability. An automatic measurement device includes a measuring instrument support base portion that supports a measuring instrument and a workpiece holding base portion that holds a workpiece in a measurement region of the measuring instrument. The measuring instrument support base portion includes a measuring instrument holder that holds a fixed element of the measuring instrument and an automatic operation unit attachable to and detachable from the measuring instrument. The automatic operation unit is configured to automate advance and retreat of the movable element of the measuring instrument by a power from a motor.

A measuring arm is made up of a pair of main links pivotally connected together at one end, and a pair of shorter end links each pivotally connected at one end to an other end of each main link. A distance sensor is able to be attached to an end of one of the end links, and to either of a pair of support bases mounted at different locations on a relatively fixed structure. The measuring arm is particularly useful in inspecting contoured surfaces of seals installed on an automobile to aid in detecting defective seals.

A surface processing equipment using energy beam including a multi-axis platform, a surface profile measuring device, an energy beam generator and a computing device is provided. The multi-axis platform is configured to carry a workpiece and move the workpiece to the first position or the second position. The surface profile measuring device has a working area, and the first position is located on the working area. The surface profile measuring device is configured to measure the workpiece to obtain surface profile. The energy beam generator is configured to provide an energy beam to the workpiece for processing, and the second position is located on a transmission path of the energy beam. The computing device is connected to the surface profile measuring device and the energy beam generator. The computing device adjusts the energy beam generator according to the error profile.

A method for extracting a gear tooth profile edge based on an engagement-pixel image edge tracking method includes defining a transmission ratio relationship between a cutter and an envelope tooth profile, setting a cutter profile step size and an envelope step size, acquiring instantaneous contact images at different engaging times, and performing a binarization processing on each curve envelope cluster image; sweeping a boundary of an envelope curve cluster, acquiring pixel points of the edge; preliminarily tracking a tooth profile edge, and then performing a secondary extraction and compensation on the pixel points; calibrating coordinates of a cutter profile; extracting a pixel coordinate of an instantaneous engaging point; converting the pixel points among different instantaneous engaging images; extracting a final tooth profile coordinate of the gear, and performing a tooth shape error analysis and a contact line error analysis.

A method including: a) causing a tool mounted on a machine tool to work on a workpiece, and at least one sensor, which is configured to measure one or more aspects of the tool and/or machine tool, collecting sensor data during said working; b) a measurement device inspecting the part of the workpiece that was worked on at step a) to obtain measurement data; and c) calculating sensor-to-workpiece data calibration information from the sensor data and the measurement data.

A method including: a) causing a tool mounted on a machine tool to work on a workpiece, and at least one sensor, which is configured to measure one or more aspects of the tool and/or machine tool, collecting sensor data during said working; b) a measurement device inspecting the part of the workpiece that was worked on at step a) to obtain measurement data; and c) calculating sensor-to-workpiece data calibration information from the sensor data and the measurement data.