The present disclosure proposes an apparatus for determining a first three-dimensional shape of an object. The apparatus includes one or more first light sources configured to irradiate one or more first pattern lights to the object, a second light source configured to sequentially irradiate one or more second pattern lights having one phase range, a beam splitter and one or more lenses configured to change optical paths of the one or more second pattern lights, an image sensor configured to capture one or more first reflected lights and one or more second reflected lights, and a processor configured to determine the first three-dimensional shape of the object based on the one or more first reflected lights and the one or more second reflected lights.

A three-dimensional measurement system projects patterned light onto a target object, images the target object from different viewpoints to obtain a first image and a second image, obtains first depth information using the first image with a spatially encoded pattern technique, defines a search range for a corresponding point based on parallax between the first image and the second image predicted from the first depth information, and obtains second depth information by performing stereo matching for the defined search range using the first image and the second image. The second depth information has a higher spatial resolution than the first depth information. The patterned light has a combined pattern combining a spatially encoded pattern including a plurality of unit elements arranged regularly and a random pattern including a plurality of random pieces arranged randomly. Each of the plurality of unit elements is an area corresponding to a depth value.

A three-dimensional shape measuring method includes: projecting a first grid pattern based on a first light and a first full pattern based on a second light onto a target object, the first light and the second light being lights of two colors included in three primary colors of light; picking up, by a three-color camera, an image of the first grid pattern and the first full pattern projected on the target object, and acquiring a first picked-up image based on the first light and a second picked-up image based on the second light; and calculating height information of the target object, using the first picked-up image, and calculating position information of the target object, using the second picked-up image.

A three-dimensional shape measuring method includes: projecting a first grid pattern based on a first light and a second grid pattern based on a second light onto a target object in such a way that the first grid pattern and the second grid pattern intersect each other, the first light and the second light being lights of two colors included in three primary colors of light; picking up, by a three-color camera, an image of the first grid pattern and the second grid pattern projected on the target object, and acquiring a first picked-up image based on the first light and a second picked-up image based on the second light; and performing a phase analysis of a grid image with respect to at least one of the first picked-up image and the second picked-up image and calculating height information of the target object.

Provided is a three-dimensional measurement device, including an illumination system (I) and an imaging system (II). The illumination system includes, along an illumination light path, a light source (8), a light beam shaping apparatus (8), a pattern modulation apparatus (6), and a projection lens (2). The pattern modulation apparatus is configured to form a coded pattern. The light beam shaping apparatus is configured to shape light emitted by the light source into near-parallel light. The projection lens is configured to project the coded pattern onto a target object. The imaging system includes an imaging lens (3), a first beam-splitting system (12, 13), and an image sensor group including N image sensors (9, 10, 11). The first beam-splitting system is configured to transmit the coded pattern received by the imaging lens and projected onto the target object to the N image sensors of the image sensor group.

According to an embodiment, an optical device includes a light selection unit, an imaging element, and a deriving unit. The light selection unit splits an irradiated light beam into a plurality of spectral beams of different wavelength regions. The imaging element captures a subject irradiated with the spectral beams including beams of at least two different wavelengths to acquire a spectral image. The deriving unit derives a surface property or shape information of the subject from a specified result obtained by specifying, by the deriving unit, an irradiation region irradiated with each of the spectral beams on the subject based on a mixing ratio of the spectral beams and received light intensity of each of the spectral beams included in the spectral image.

A method of dimensioning an object includes: projecting, from a plurality of laser emitters disposed on a dimensioning device and having a predefined spatial arrangement forming a plane, respective laser beams onto a surface of the object, the laser beams oriented parallel to each other; controlling an image sensor of the dimensioning device, simultaneously with the projecting, to capture image data representing the surface and projections of the laser beams on the surface; detecting projection pixel coordinates in the image data representing the projections of the laser beams on the surface; detecting edge pixel coordinates in the image data representing edges of the surface; and determining a dimension of the surface based on the projection pixel coordinates, the edge pixel coordinates, and the predefined spatial arrangement.

The disclosure is related to a method and apparatus of scanning a target object in three dimensions (3D). The method may include projecting a color dashed line pattern onto a target object, scanning the target object with the color dashed line pattern projected thereto, and producing a 3D data of the target object by processing the scanning result. The color dashed line pattern may include multiple dashed line patterns each of which is individually used to calculate the 3D data of the target object.

A device for non-contact measurement includes a light source and a light pattern projector having a diffractive optical element. An imaging system images a target site illuminated by the light pattern projector. The light pattern projector and the imaging system are attached to a support in fixed relative positions. The support has a longitudinal axis parallel to an optical axis of the projector, and the projector and the imaging system are spaced apart along the longitudinal axis. The light source emits a plurality of light beams of different colors, each one being a coherent beam optically coupled to the diffractive optical element. The diffractive optical element diffracts the plurality of light beams according to different diffraction angles resulting in separate patterns. The processing unit determines a measurement based on at least two positions automatically recognized in data acquired from a single one of the separate patterns.

Disclosed is a portable 3-dimensional (3D) document scanning device and method. The portable 3D document scanning device includes a projector projecting light of a predetermined pattern onto a document, a 3D scanning camera capturing a pattern of the light projected onto the document and the document, and a control unit estimating a size of the captured document based on image data of the captured document, estimating a shape of the captured document based on the pattern of the projected light and the captured pattern of the light, and correcting the image data of the captured document based on the estimated size and the estimated shape.