Provided is a length measuring device having an automatic zero point adjusting function and a control method thereof. The length measuring device includes a line to which a hook part is attached at one end, a case having an opening formed therein, a rotating part to be rotated according to extraction or retraction of the line out of or into the case through the opening, a rotation sensing part which senses a rotation of the rotating part, and a control part which converts an amount of rotation of the rotating part into a length measurement value and resets the converted length measurement value to a predetermined value when the length measuring device is in a first state.

A sample shape measuring apparatus includes a light source unit, an illumination optical system, a detection optical system, a light detection element, and a processing apparatus. A scanning unit relatively moves a light spot and the sample. Illumination light applied to the sample is transmitted through the sample, and light transmitted through the sample is incident on the detection optical system. The light detection element receives light. The illumination optical system or the detection optical system includes an optical member. The processing apparatus obtains a quantity of light based on a received light, calculates at least one of a difference and a ratio between the quantity of light and a reference quantity of light, calculates an amount of tilt at a surface of the sample, and calculates a shape of the sample from the amount of tilt.

Three-dimensional (3D) measurement systems and methods are provided. The systems and methods include a 3D imager and a marker. The marker includes an adapter and a marker element, wherein the adapter is arranged to be at least one of installed, placed, and attached to a fixed object of a scanned environment and the marker element includes a coded identifier that is detectable by the 3D imager, wherein the coded identifier identifies the specific location of the fixed object within the scanned environment.

A method and system to measure a parameter associated with a component, device, or system with a specified accuracy, including: providing one or more sensors operably disposed to detect the parameter; obtaining a coarse measurement of the parameter within a first range using the one or more sensors, wherein the first range includes minimum and maximum values for the parameter; obtaining a fine measurement of the parameter within a second range using the one or more sensors, wherein the second range is smaller than the first range and has a specified ratio to the first range that provides the specified accuracy; determining a current value of the parameter by combining the coarse and fine measurements; and providing the current value of the parameter to a communications interface, a storage device, a display, a control panel, a processor, a programmable logic controller, or an external device.

An apparatus reads a value measured with an analog measuring tool. The apparatus includes an imaging unit for obtaining a captured image of the analog measuring tool that is indicating a measured value, a retaining unit for retaining a 3D model of the analog measuring tool, a matching unit for specifying a 3D model matching the captured image, a guidance unit for outputting guidance information for correcting orientation of the analog measuring tool based on the matched 3D model, a reading unit for reading the measured value from the captured image to generate a measurement result, and an output unit for outputting the measurement result.

A method for operating a confocal white light sensor on a coordinate measuring machine including a sensor carrier configured to couple a coordinate measurement sensor that is movable in a straight movement direction relative to a base of the coordinate measuring machine is provided. A confocal white light sensor is coupled to the sensor carrier and oriented in the straight movement direction toward a reference body. The sensor carrier and the reference body are moved relative to one another in the straight movement direction, and a measurement signal representing a distance between the confocal white light sensor and the reference body is generated at different movement positions. Information relating to a relationship between measurement signals of the confocal white light sensor and an actual distance of the white light sensor to a measurement object is obtained and a measurement value of the object distance is generated.

A coordinate measuring machine system has a base configured to support a workpiece, a movable portion configured to move relative to the base, and a control system configured to control movement of the base and/or the movable portion. The system also has a set of probes that each are configured to be removably couplable with the movable measurement portion. Each probe is configured to be removably couplable with the movable measurement portion, and has a shaft with a distal end and a proximal end. The proximal end has a region for coupling with the movable measurement portion, while the distal end has a region configured to interact with the workpiece. Each of the probes also has visual identifying indicia on the shaft. The visual identifying indicia are encoded to identify at least one characteristic of the probe. Specifically, the indicia are encoded as Base 3 or Base 4 indicia.

In one embodiment, a system includes a casing disposed within a wellbore, one or more data collection tools coupled to the casing, and one or more sensors disposed within an annulus of the wellbore. Each of the one or more sensors include a substrate, a strain-sensitive element coupled to the substrate, and a transceiver coupled to the substrate and configured to communicate with the one or more data collection tools.

A set of respective self-configuring probe interface circuit boards (SC-MPIC's) are disclosed for use with a measurement system comprising host electronics and respective interchangeable measurement probes. Member SC-MPICs each comprises: a local circuit (LS) for probe identification, signal processing and inter-board signal control; and higher-direction and lower-direction connectors pointing toward and away from the measurement probe, respectively. Member SC-MPICs establish a processing hierarchy by generating lower board present signals on their higher-direction connector, higher board present signals on their lower-direction connector, and determining whether they are the highest and/or lowest SC-MPIC based on receiving those signals from adjacent SC-MPICs. They can independently perform probe identification matching operations using probe identification data from compatible and incompatible probes, and the highest SC-MPIC does this first. Member SC-MPICs advantageously pass through or isolate signals from other members in the set depending on the hierarchy, various received signals, and internal processing.

A coordinate measuring unit includes a measuring probe and a processing device configured to compute the shape coordinates of an object to be measured on the basis of an output of the measuring probe. The measuring probe has a first identification code. The processing device includes a first determination portion configured to determine whether the first identification code outputted from the measuring probe is matched with a matching code, and a downstream determination portion configured to identify a second identification code outputted from the measuring probe to thereby recognize the measuring probe when the first identification code is matched with the matching code in the first determination portion and the measuring probe further has the second identification code. The coordinate measuring unit with the aforementioned configuration can efficiently recognize a number of measuring probes.