Abstract: As a technique to improve processing efficiency of defect inspection by quickly adjusting a position of a detection system, provided is a defect inspection apparatus including: a stage that moves with a sample and a pattern substrate placed thereon; an illumination optical system that irradiates an object on the stage from a direction inclined from the normal direction of the pattern substrate; a first detection optical system that detects scattered light in the normal direction; a second detection optical system that detects scattered light in a direction different from the scattered light detected by the first detection optical system; a signal processing unit that processes both scattered light signals; and a control unit.

Abstract: In a defect inspection device that irradiates a surface of a sample or a surface of a pattern chip with an illumination light shaped to extend in a first direction, and detects a scattered light generated from the surface of the sample or the surface of the pattern chip by the illumination light to detect a defect on the surface of the sample, the pattern chip has a dot pattern area in which multiple dots are arrayed in multiple rows and multiple columns, a minimum interval between the dots corresponding to the lines aligned in the first direction among the multiple dots arrayed in the dot pattern area in a second direction orthogonal to the first direction is smaller than a width of the illumination light, and a minimum interval between the multiple dots arrayed in the dot pattern area is larger than a resolution of the detection optical system.

Abstract: A method of inspecting a device under test for defects includes detecting intensity and directional information of radiation rays emanating from a device under test by a light field camera, generating synthesized images of the device under test detected by the light field camera, and determining a depth of a defect in the device under test from the synthesized images.

Abstract: A method of inspecting a device under test for defects includes detecting intensity and directional information of radiation rays emanating from a device under test by a light field camera, generating synthesized images of the device under test detected by the light field camera, and determining a depth of a defect in the device under test from the synthesized images.

Abstract: As a technique to improve processing efficiency of defect inspection by quickly adjusting a position of a detection system, provided is a defect inspection apparatus including: a stage that moves with a sample and a pattern substrate placed thereon; an illumination optical system that irradiates an object on the stage from a direction inclined from the normal direction of the pattern substrate; a first detection optical system that detects scattered light in the normal direction; a second detection optical system that detects scattered light in a direction different from the scattered light detected by the first detection optical system; a signal processing unit that processes both scattered light signals; and a control unit.

Abstract: In a defect inspection device that irradiates a surface of a sample or a surface of a pattern chip with an illumination light shaped to extend in a first direction, and detects a scattered light generated from the surface of the sample or the surface of the pattern chip by the illumination light to detect a defect on the surface of the sample, the pattern chip has a dot pattern area in which multiple dots are arrayed in multiple rows and multiple columns, a minimum interval between the dots corresponding to the lines aligned in the first direction among the multiple dots arrayed in the dot pattern area in a second direction orthogonal to the first direction is smaller than a width of the illumination light, and a minimum interval between the multiple dots arrayed in the dot pattern area is larger than a resolution of the detection optical system.

Abstract: Disclosed is a distance measuring device using an optical comb. In order for the absolute distance to an object to be measured which has a surface with low reflection ratio or a scattering surface and is approximately 10 m apart, to be easily measured with accuracy of 0.1 mm or more using an optical and contactless method, the distance measuring device which measures the distance to the object to be measured is configured such that the distance to the object to be measured is measured by comparing the phase of the beat signal between a light source and a plurality of CW lasers which are reflected or scattered by the object with the phase of the beat signal between the light source and a plurality of CW lasers prior to being irradiated onto the object.

Abstract: There is provided a pattern inspection device for a substrate surface which can inspect a substrate including a pattern whose size is equal to or smaller than light resolution limit at high speed. The pattern inspection device for the substrate surface includes: a near-field optical head 101 having a fine repetitive pattern; a ? driving unit 311 of scanning an inspected substrate 900 relatively to the near-field optical head 101; a space holding mechanism of holding a space between the near-field optical head 101 and the inspected substrate 900 constant; alight source 110 of irradiating light to the near-field optical head 101; a detection system 201 of detecting an intensity of scattered light generated by interaction between the fine repetitive pattern on the near-field optical head 101 and a fine pattern on a surface of the inspected substrate 900; and a signal processing unit 321 of inspecting the fine pattern on the inspected substrate 900 based on an output of the detection system 201.

Abstract: Disclosed are a spectroscopic optical system and a spectrometer both enabling vertical illumination by means of an optical system using only refractive lenses and enabling wide-band color correction in the DUV-UV (190 to 400 nm) range. The spectroscopic optical system and spectrometer each comprise a light source (100), a folding mirror (110), a field stop (120), an object-side focusing lens system (130) for focusing light onto a sample, an image-side focusing lens (140) disposed on the image forming plane of the object-side focusing lens system, and a spectroscope (150) for dispersing regularly reflected light from the sample. The object-side focusing lens system (130) and the image-side focusing lens system (140) are each a spectroscopic optical system corrected with respect to color in a broad band of wavelength from 190 to 400 nm and configured from only refractive lenses enabling vertical illumination.

Abstract: Measurement cannot be made when trying to measure a wavefront aberration of a wide-angle lens, being wide in a field of view, comparing to a focus distance, by a Shack-Hartmann sensor, since an inclination of the wavefront exceeds an allowable value of inclination of the Shack-Hartmann sensor. The Shack-Hartmann sensor is inclined at a position of a pupil of a lens, and is controlled so that it lies within the allowable value mentioned above. Photographing is made through step & repeat while overlapping at the same position, to compose in such a manner that overlapping spots are piled up, and thereby measuring the wavefront aberration of the lens having a large pupil diameter.

Abstract: A defect inspection system is disclosed for easily setting inspection conditions and providing an inspection condition and a defect signal intensity to an operator. The defect inspection system digitizes a defective image, and a reference image corresponding thereto and a mismatched portion of the defective image and the reference image as a defect signal intensity and accumulates them in association with the inspection condition. The inspection conditions are changed to repeat evaluations while repeating accumulating works until the evaluation of all the inspection conditions in a set range is completed. A recipe file including the accumulated conditions having the high defect signal intensity and an inspection condition item distribution as a inspection condition recipe is automatically outputted and provided to the operator.

Abstract: In a displacement measurement apparatus using light interference, a probe light path is spatially separated from a reference light path. Therefore, when a temperature or refractive index distribution by a fluctuation of air or the like, or a mechanical vibration is generated, an optical path difference fluctuates between both of the optical paths, and a measurement error is generated. In the solution, an optical axis of probe light is brought close to that of reference light by a distance which is not influenced by any disturbance, a sample is irradiated with the probe light, a reference surface is irradiated with the reference light, reflected light beams are allowed to interfere with each other, and a displacement of the sample is obtained from the resultant interference light to thereby prevent the measurement error from being generated by the fluctuation of the optical path difference.

Abstract: An inspection apparatus and method includes a light source, an illuminating unit having a polarization controller and an object lens for illuminating a specimen with light emitted from the light source and passed through the polarization controller and the object lens, a detection unit having a sensor for detecting light from the specimen illuminated by the illuminating unit, a processor which processes a signal output from the sensor so as to detect a defect on the specimen, and a display which displays information output from the processor. The processor processes an image formed from the signal output from the sensor in which the image is reduced in speckle pattern.

Abstract: A defect inspection device comprises an inspection optical system including a light source, a half mirror for reflecting illumination light emitted from the light source, a catadioptric objective lens for collecting reflected light from the sample by illumination light reflected by the half mirror, an imaging lens for focusing the reflected light transmitted through the catadioptric objective lens, a relay lens having a blocking member provided at a position at which specularly reflected light from the sample is focused by the imaging lens, and a detector for detecting specularly reflected light not blocked by the blocking member; and a computation processing unit for detecting defects of the sample on the basis of the signals detected by the detector.

Abstract: In a defect inspection apparatus for inspecting a wafer provided with a circuit pattern for defects, the illuminating direction of illuminating light rays is selectively determined such that an area containing a defect that scatters light of high intensity coincides with the aperture of a dark-field detecting system, and such that regularly reflected light regularly reflected by a pattern, which is noise to defect detection, does not coincide with the aperture of the dark field detecting system.

Abstract: To provide a defect inspection apparatus for inspecting defects of a specimen without lowering resolution of a lens, without depending on a polarization characteristic of a defect scattered light, and with high detection sensitivity that is realized by the following. A detection optical path is branched by at least one of spectral splitting and polarization splitting, a spatial filter in the form of a two-dimensional array is disposed after the branch, and only diffracted light is shielded by the spatial filter in the form of a two-dimensional array.

Abstract: An apparatus for inspecting a substrate surface is provided, which includes illumination optics for irradiating the substrate surface linearly with rectilinearly polarized light from an oblique direction, detection optics for acquiring images of the substrate surface, each of the images being formed by the light scattered from the light-irradiated substrate surface, and means for comparing an image selected as an inspection image from the plurality of substrate surface images that the detection optics has acquired to detect defects, and another image selected from the plural images of the substrate surface as a reference image different from the inspection image; the illumination optics being formed with polarization control means for controlling a polarizing direction of the light according to a particular scanning direction of the substrate or a direction orthogonal to the scanning direction.

Abstract: A defect inspection system is disclosed for easily setting inspection conditions and providing an inspection condition and a defect signal intensity to an operator. The defect inspection system digitizes a defective image, and a reference image corresponding thereto and a mismatched portion of the defective image and the reference image as a defect signal intensity and accumulates them in association with the inspection condition. The inspection conditions are changed to repeat evaluations while repeating accumulating works until the evaluation of all the inspection conditions in a set range is completed. A recipe file including the accumulated conditions having the high defect signal intensity and an inspection condition item distribution as a inspection condition recipe is automatically outputted and provided to the operator.

Abstract: Disclosed is a distance measuring device using an optical comb. In order for the absolute distance to an object to be measured which has a surface with low reflection ratio or a scattering surface and is approximately 10 m apart, to be easily measured with accuracy of 0.1 mm or more using an optical and contactless method, the distance measuring device which measures the distance to the object to be measured is configured such that the distance to the object to be measured is measured by comparing the phase of the beat signal between a light source and a plurality of CW lasers which are reflected or scattered by the object with the phase of the beat signal between the light source and a plurality of CW lasers prior to being irradiated onto the object.

Abstract: A defect inspection device comprises an inspection optical system including a light source, a half mirror for reflecting illumination light emitted from the light source, a catadioptric objective lens for collecting reflected light from the sample by illumination light reflected by the half mirror, an imaging lens for focusing the reflected light transmitted through the catadioptric objective lens, a relay lens having a blocking member provided at a position at which specularly reflected light from the sample is focused by the imaging lens, and a detector for defecting the reflected light of the specularly deflected light blocked by the blocking member; and a computation processing unit for detecting defects of the sample on the basis of the signals detected by the detector.