Abstract: Method and apparatus are provided for calibration or verification of accuracy specification of a computed tomographic system. In one embodiment, the apparatus can include a base structure, a first set of test objects arranged along a first axis and coupled to the base structure, and a second set of test objects arranged along a second axis and coupled to the base structure. The first set of test objects and the second set of test objects have a first geometry. The apparatus can also include a third set of test objects and a fourth set of test objects. The third set of test objects, and the fourth set of test objects have a second geometry different from the first geometry. Locations of the first, second third and fourth set of test objects are spatially fixed with respect to the base structure. The apparatus is a test specimen adapted for calibration or accuracy verification of computed tomography system.

Abstract: Method and apparatus are provided for calibration or verification of accuracy specification of a computed tomographic system. In one embodiment, the apparatus can include a base structure, a first set of test objects arranged along a first axis and coupled to the base structure, and a second set of test objects arranged along a second axis and coupled to the base structure. The first set of test objects and the second set of test objects have a first geometry. The apparatus can also include a third set of test objects and a fourth set of test objects. The third set of test objects, and the fourth set of test objects have a second geometry different from the first geometry. Locations of the first, second third and fourth set of test objects are spatially fixed with respect to the base structure. The apparatus is a test specimen adapted for calibration or accuracy verification of computed tomography system.

Abstract: A method for measuring structures of an object using a feeler element assigned to a coordinate measuring instrument and extending from an elastic-to-bending feeler extension is disclosed wherein the feeler element is brought into contact with an object having structures to be measured and the position of the feeler is then determined by comparing the position of the feeler as determined by the coordinate measuring instrument with the position determined by the optical sensor.

Abstract: A method for measuring structures of an object using a feeler element associated with a coordinate measuring instrument and extending from an elastic bendable feeler extension is disclosed, and wherein the feeler element is brought into contact with an object having structures to be measured and the position of the feeler is then determined by comparing the position of the feeler as determined by the coordinate measuring instrument with the position determined by the optical sensor.

Abstract: The invention relates to a low-cost, low-weight, highly stable reference object, easy to handle, for the measurement of the errors of geometry of coordinate measuring machines and machine tools. The reference object consists of an array of probing elements in the form of rings, spheres, or flats, each representing reference points by means of their surface geometry. The probing elements are glued between two panes of a geometrically stable material, establishing a firm connection between these panes. Holes in the panes enable the measuring probe of the machine under inspection to probe the reference elements' surfaces. The resulting box-type structure of the reference object gives it the said advantages of low weight, low price, and high stability.

Abstract: The method is used to determine the elastic bending behavior of coordinate measuring machines as a result of the measuring force and the position of measuring slides in the measuring range of the machine. Correction values are determined, which are used to compensate for measuring errors caused by machine bending. The correction values are a function of the position of the measuring slides and on the measuring force between the probe of the coordinate measuring machine and workpieces within the measuring range, and are established and stored for several positions. The method can be combined very advantageously with known methods for the correction of guideway errors, which were developed on the basis of a rigid model, and with methods for the dynamic correction of machine deviations caused by vibration of machine components.

Abstract: The invention relates to the construction of specimens for coordinate measuring instruments. According to the invention, these consist of touchable reference elements, and rods, in particular of ball-rod structures, balls and rods being held in contact by spring forces, and the contact surfaces of the rods being adapted to the radius of the balls. This construction enables the specimens to be disassembled. It guarantees a high reproducibility of the dimension embodied by the center-to-center distance between the balls in conjunction with ease of disassembly of the complete specimen The advantages are that one-dimensional specimens of very great length can be formed by joining to one another rods and interposed balls, while in the case of two- and three-dimensional specimens the transport volume is substantially reduced. The calibration of the reference object is possible in a simple and accurate fashion via the separate one-dimensional calibration of the segments.