An inspection system configured to scan internal surfaces of manufactured components includes an optical probe, a light source, a conical mirror, and an imaging sensor. The optical probe has a field of view. The light source is spaced apart from the optical probe and is positioned within the field of view of the optical probe. The conical mirror is secured to the light source and is configured to transform light emitted from the light source into a light disc. The light disc is configured to be projected onto the internal surfaces of the manufactured components while scanning the internal surfaces. The imaging sensor is configured to receive reflections of the light disc from the internal surfaces via the optical probe while scanning the internal surfaces.

An inspection system (1) includes: a probe (12) that is hollow, extends in a rod shape along a center axis (11), and rotates around the center axis; an optical system (30) that, through the probe, supplies laser light for inspection purposes along the center axis and receives reflected light from a surface of an inspection target that has returned along the center axis; an optical element (50) that, through an opening at a front end of the probe, emits the laser light for inspection purposes toward the inspection target with respect to the center axis and guides the reflected light in the direction of the center axis; and a gas supplying system (80) that discharges gas (89) from the opening through the probe.

Materials, methods of making, and methods of sensing liquid droplets with high spatial resolution as a signature of the on-set of corrosion using a hierarchical sensor network A hierarchical sensor network for sensing liquid droplets with high spatial resolution as a signature of the on-set of corrosion, including an interrogation system; and an intermediate sensor array layer in communication with the interrogation system. The network includes an interrogation system and an intermediate sensor array layer in communication with the interrogation system.

Disclosed are an endoscopic reflection microscope using an optical fiber bundle and an image acquisition method using the same. The endoscopic reflection microscope includes an incident wave output unit configured to output an incident wave to a target object through any one optical fiber in an optical fiber bundle, a reflected wave receiver configured to receive a reflected wave output from the target object in response to the incident wave through a plurality of corresponding optical fibers in the optical fiber bundle, and an image acquirer configured to establish a reflection matrix corresponding to the reflected wave and to acquire an image in which at least one of phase retardation of the incident wave or phase retardation of the reflected wave is compensated for based on the established reflection matrix.

This application relates to tools, systems, and methods for stimulating hydrocarbon bearing formations using energy from sonoluminescence.

A measurement system includes an optical probe array including the m-number of optical probe groups arranged, each including the n-number of optical probes, the m-number of optical signal selectors each corresponding one of the optical probe groups, and a control circuit configured to control the optical signal selectors. The respective optical signal selectors select and output one of optical signals output from the n-number of the optical probes of the corresponding optical probe groups. The measurement system causes the control circuit to control the optical signal selectors to repeat the selection of the optical signals until the optical signals output from all of the optical probes included in the respective optical probe groups are selected.

An imaging apparatus according to an aspect of the present disclosure includes: a waveguide that transmits light emitted from a light source; a detector that detects power of a speckle pattern generated by the light passing through the waveguide and applied to an object; at least one memory storing a set of instructions; and at least one processor configured to execute the set of instructions to reconstruct an image of the object based on the power obtained by making the light enter the waveguide under different conditions.

This application relates to tools, systems, and methods for stimulating hydrocarbon bearing formations using energy from sonoluminescence.

There is described an inspection device for inspecting a slot of a gas turbine engine. The inspection device comprises: an insert for insertion into the slot; a plurality of imaging devices coupled to the insert; and a processor. The insert is movable along a longitudinal axis of the slot. Each of the plurality of imaging devices is positioned adjacent an external surface of the insert and is configured to capture an image of a portion of the slot adjacent the imaging device. The processor is configured to receive data corresponding to the images captured by the plurality of imaging devices. There is also described a method of inspecting a slot using the inspection device.

An in-situ, non-destructive sensor device, system and method are provided to detect or assess fouling at a very early stage of development. They can be used to detect or assess fouling on a surface of an aquatic system. They can be used to obtain a depth profile of the fouling. Data concerning the depth profile can be extracted and used to assess the fouling on the surface. In one or more aspects, the method can include providing an optical tomography spectrometer; optically positioning the optical tomography spectrometer in association with a surface of an area to be assessed for fouling in an aqueous system; irradiating the surface; acquiring, from irradiating the surface, a plurality of signals as a function of a distance from the surface at different times; extracting data from the signals as a function of the distance to obtain a depth profile of the surface at the different times; and determining a change in the depth profile between the different times to assess fouling on the surface.