Abstract: A method for calibrating an optical scanner device implemented by a calibration management apparatus, includes providing instructions to the optical scanner device to scan a calibration surface in a scan pattern based on one or more scan parameters, wherein the one or more scan parameters vary over the scan pattern. The scanning angle for each of the plurality of points in the scan pattern is computed based on an obtained image of a light source emitted from the optical scanner device at a scanning angle for a plurality of points in the scan pattern. A calibration relationship between the computed scanning angles and the corresponding scan parameters is determined for each of the plurality of points in the scan pattern.

Abstract: A measuring device includes a rotatable stage configured to receive and rotate an object long a rotational axis of the object. A housing is located adjacent to the rotatable stage and is movable along the rotational axis of the object. The housing has a pivoting arm located between a pair of opposing compression springs which are configured to provide a preload force in a direction parallel to the rotational axis of the object. A probe tip is coupled to the pivoting arm and extends from the housing, the probe tip configured to contact a portion of the object. A displacement measuring device is coupled to the pivoting arm and is configured to measure displacement of the probe tip in the direction parallel to the rotational axis of the object based on movement of the pivoting arm against one of the opposing compression springs.

Abstract: An optical scanner includes a light source located within a housing. A reticle having an aperture is positioned within the housing to receive a first light beam emitted from the light source. The reticle is configured to transmit a second light beam through the aperture. A mirror is positioned within the housing to receive the second light beam transmitted from the reticle and reflect the second light beam through a first window in the housing onto a surface of interest of an object. A light receiver is configured to receive a third light beam from the surface of interest of the object through a second window in the housing, wherein the light receiver is configured to obtain one or more light position values to determine a parameter of the surface of interest of the object. Methods for generating three-dimensional images of an object utilizing the optical scanner are also disclosed.

Abstract: A laser ablation method is used to polish a bearing surface of an automotive crankshaft. A laser ablation device generates a laser according to parameters such as wavelength, pulse duration, pulse repetition rate, and beam quality. The laser is applied to the surface of a rotating engine component, such as a crankshaft, as the component is rotated in order to polish the surface according to the parameters. The laser substantially improves tribological performance of the bearing surface by changing the waviness and form of the surface profile. Further, oil-retention reservoirs are formed in the surface. As a result, the friction coefficient of the crankshaft surface is reduced while the roughness of the crankshaft surface is maintained, reduced, or increased.