An industrial tomography apparatus (1) comprising a tomography scan device (7) configured to perform tomography scans of the products (2) placed in the scanning zone (4) and an electronic processing unit programmed to generate a virtual three-dimensional tomography model (8) of a product (2) scanned by the tomography scan device (7), and to perform a procedure for inspecting industrial products (2) of known type, each comprising a packet (10) or a container (11). During the inspection procedure the electronic processing unit inspects the virtual three-dimensional tomography model (8) to assess internal features of the product (2) and/or the shape of the product (2) at predetermined zones and determines whether or not those internal features and/or respectively that shape, correspond to a product with intact packet (10) or container (11). The apparatus implements a corresponding method for checking the integrity of packets or containers of industrial products (2) which have known features.

A high-throughput optical sectioning three-dimensional imaging system which includes: a light beam modulation module configured to modulate a light beam into a modulated light beam capable of being focused on a focal plane of an objective lens and being defocused on a defocusing plane of the objective lens; an imaging module configured to employ a camera to image, in different rows of pixels, a sample under illumination of the modulated light beam; a cutting module configured to cut off an imaged surface layer of the sample; a demodulation module configured to demodulate a sample image of one sample strip of one surface layer into an optical sectioning image, and reconstruct the optical sectioning image of each sample strip of each surface layer into a three-dimensional image. The present disclosure achieves imaging of a whole sample by dividing the sample into at least one surface layer, dividing the at least one surface layer into at least one sample strip, and imaging each sample strip. When a multi-layer imaging cannot be performed, the imaged part can be cut off by the cutting module to realize imaging of any layer of the sample, thereby improving the imaging speed and efficiency.

Presented herein are systems and methods for tomographic imaging of a region of interest in a subject using short-wave infrared light to provide for accurate reconstruction of absorption maps within the region of interest. The reconstructed absorption maps are representations of the spatial variation in tissue absorption within the region of interest. The reconstructed absorption maps can themselves be used to analyze anatomical properties and biological processes within the region of interest, and/or be used as input information about anatomical properties in order to facilitate data processing used to obtain images of the region of interest via other imaging modalities. For example, the reconstructed absorption maps may be incorporated into forward models that are used in tomographic reconstruction processing in fluorescence and other contrast-based tomographic imaging modalities. Incorporating reconstructed absorption maps into other tomographic reconstruction processing algorithms in this manner improves the accuracy of the resultant reconstructions.

A high-throughput optical sectioning imaging method and imaging system. The method includes: modulating a light beam into a modulated light beam capable of being focused on a focal plane of an objective lens and being defocused on a defocusing plane of the objective lens, the modulated light beam having incompletely identical modulated intensities on the focal plane of the objective lens; imaging, in different rows of pixels, a sample under illumination of the modulated light beam to obtain sample images in the different rows of pixels; obtaining focal plane images of sample images in the different rows of pixels by demodulation of the sample images according to a demodulation algorithm. The system includes a light beam modulation module, an imaging module and a demodulation module.

The present disclosure relates to a confocal imaging apparatus using a chromatic aberration lens, which is capable of quickly implementing multiple tomographic images by making it possible to quickly scan the entire object without moving the light source or the object. Since the present invention is configured to generate a three-dimensional image using multiple tomographic images by a chromatic aberration lens without moving the light source or the object up and down, there is an effect of remarkably shortening the time it takes to implement the multiple tomographic images.

A method for determining properties of a laboratory sample contained in a laboratory sample container is presented. The method comprises measuring projections of the laboratory sample container comprising the laboratory sample by irradiating light to the laboratory sample container at different projection angle and determining the properties by tomographic reconstruction based on the projections.

The present disclosure provides a lens assembly, a terahertz wave tomography system and method, and a terahertz wave filter. The lens assembly includes: a first substrate and a second substrate that are oppositely disposed; a seal, wherein the seal, the first substrate and the second substrate enclose a cavity in which a magnetic fluid is filled; and a plurality of electromagnetic generating units disposed on at least one of a first side of the first substrate close to the second substrate or a second side of the first substrate away from the second substrate, wherein at least a part of the plurality of electromagnetic generating units are configured to generate a magnetic field in a case where a voltage is applied to make the magnetic fluid form a Fresnel zone plate pattern.

An optical inspection device 1A includes a light selection unit 30, a detection element 40, and a first image formation element 20. The light selection unit 30 has the plurality of wavelength selection regions 32 that selectively transmits or reflects the light rays L of mutually different wavelength regions. The detection element 40 detects scattering characteristic information of the light rays L having reached the light receiving surface 41 via the light selection unit 30. The first image formation element 20 causes scattered light scattered by a subject S to enter a light receiving surface 41 via the light selection unit 30. The plurality of wavelength selection regions 32 has different azimuth angles with respect to the optical axis Z of the first image formation element 20.

The present disclosure relates to a method and a device for measuring at least one atmospheric parameter (gas, temperature). The method includes implementing steps of acquiring spectral images in the ultraviolet and/or the visible and/or the infrared range and scanning according to a tomographic principle. The spectral images are acquired using a network of optical systems such as infrared cameras, and are used to estimate the air quality and/or meteorological and/or climate parameters in a geographic area, for example an urban agglomeration.

A light source, a standing wave forming unit, a detector, and an absorbance calculating unit. The light source irradiates a sample with light. The standing wave forming unit forms, in the sample, an acoustic standing wave perpendicular to a surface of the sample. A node of the acoustic standing wave is positioned at a predetermined distance from the surface of the sample, the light from the light source entering the surface of the sample. The detector detects light emitted from the surface of the sample, and is disposed on the surface of the sample on a side where the light source is disposed. The absorbance calculating unit obtains absorbance.