A confocal optical protractor for simultaneously measuring roll angle, pitch angle and yaw angle of an element that includes a tunable laser source generating a laser beam and an SPPR device responsive to the laser beam. The protractor also includes a beam splitter receiving and splitting an output beam from the SPPR device, and a lens being responsive to and projecting the split beam onto the element and being responsive to a reflected beam from the element. The protractor further includes a measurement detector responsive to the reflected beam from the element, where the reflected beam is imaged by the lens onto the measurement detector, and a processor receiving and processing image data from the measurement detector and generating the pitch, yaw and roll angles from the data, where the image data includes an orientation of an vortex intensity pattern in the split beam.

A confocal optical protractor for simultaneously measuring roll angle, pitch angle and yaw angle of an element that includes a tunable laser source generating a laser beam and an SPPR device responsive to the laser beam. The protractor also includes a beam splitter receiving and splitting an output beam from the SPPR device, and a lens being responsive to and projecting the split beam onto the element and being responsive to a reflected beam from the element. The protractor further includes a measurement detector responsive to the reflected beam from the element, where the reflected beam is imaged by the lens onto the measurement detector, and a processor receiving and processing image data from the measurement detector and generating the pitch, yaw and roll angles from the data, where the image data includes an orientation of an vortex intensity pattern in the split beam.

A method for simultaneously measuring roll angle, pitch angle and yaw angle of an element. The method includes directing a laser beam into a spiral phase plate resonator (SPPR) device to generate an optical vortex intensity pattern having a centroid and radial light peaks. The method reflects the laser beam off of the element after it has propagated through the SPPR device so that the laser beam is directed onto a camera that generates images of the optical vortex intensity pattern. The method determines a location of the centroid in the images, determines integrated counts along a radial direction from the centroid in the images, and determines a location of the radial light peaks in the images using the integrated counts. The method changes the frequency of the laser beam to rotate the radial light peaks, and estimates the roll angle of the element from the change in frequency.

A contact lens inspection system, in particular for soft contact lenses, comprises a light source (40) for illuminating a contact lens to be inspected; a plenoptic camera (1) for producing an electronic plenoptic image; a processing unit (103) adapted for electronically processing the electronic plenoptic image of the contact lens and configured for refocusing the image.

A measuring instrument is configured to detect a displacement of a contact point provided to be movable and to digitally display a measured value on a display unit provided on an outer surface of a case. The measuring instrument includes an input unit. The input unit is provided on the outer surface of the case and is configured to allow a user to input to the input unit through a manual operation. The input unit includes a sensor which is configured to detect an amount of operation and a speed of operation. The amount of operation is converted into a conversion value in view of the speed of operation and then is displayed on the display unit.

A measuring instrument is configured to detect a displacement of a contact point provided to be movable and to digitally display a measured value on a display unit provided on an outer surface of a case. The measuring instrument includes an input unit. The input unit is provided on the outer surface of the case and is configured to allow a user to input to the input unit through a manual operation. The input unit includes a sensor which is configured to detect an amount of operation and a speed of operation. The amount of operation is converted into a conversion value in view of the speed of operation and then is displayed on the display unit.

Embodiments for managing photographic capture by one or more processors are described. An image is received. The image includes at least one individual and is associated with a location. A signal indicative of a recommendation with respect to a posture of the at least one individual in the image is generated based on information associated with the at least one individual, the location, or a combination thereof.

Embodiments for managing photographic capture by one or more processors are described. An image is received. The image includes at least one individual and is associated with a location. A signal indicative of a recommendation with respect to a posture of the at least one individual in the image is generated based on information associated with the at least one individual, the location, or a combination thereof.

A beam irradiation unit (a collimator unit, a processing head, and a nozzle) includes a plurality of optical components, and is configured to convert a laser beam, which is divergent light, to collimated light and then to condense the light to irradiate a sheet metal. A photodetection element (a photodiode) detects intensity of reflected light reflected by an inspected optical component that is one of the plurality of optical components. A control device (an NC device) controls irradiation of a pierced hole with the laser beam as inspection light, subsequently to piercing the portion of the sheet metal to be cut to manufacture a product, and compares, with a threshold, the intensity of the reflected light detected by the photodetection element during the irradiation with the inspection light, to detect whether the inspected optical component is deteriorated, or a degree of the deterioration.

An apparatus for obtaining oceanographic information includes a controllable coherent light source providing light to an aquatic region. A telescope receives backscattered light that is filtered by an ambient light filter. A first interferometer receives filtered, backscattered light and provides a particulate backscatter output and a Brillouin backscatter output. A second interferometer accepts the Brillouin backscattered light and spatially disperses it according to frequency into a fringe pattern. An image sensor receives the fringe pattern. A processor joined to the image sensor utilizes image sensor output properties to determine oceanographic information concerning the aquatic region.