A variable aperture lens and methods of forming such lenses are disclosed. More particularly, embodiments of the variable aperture lens include an electro-optic aperture sandwiched between a front lens and a rear lens along an optical axis. The front lens or the rear lens may include multiple lens layers having different optical properties to provide for a low z-height, optically aligned, variable aperture lens.

A variable aperture lens and methods of forming such lenses are disclosed. More particularly, embodiments of the variable aperture lens include an electro-optic aperture sandwiched between a front lens and a rear lens along an optical axis. The front lens or the rear lens may include multiple lens layers having different optical properties to provide for a low z-height, optically aligned, variable aperture lens.

A soft contact lens designed to improve visual performance with reduced pupil edge wavefront aberration, reduced halo and reduced light scattering. The soft contact lens is designed with pupil apodization for modulating the lens amplitude transmission profile.

A soft contact lens designed to improve visual performance with reduced pupil edge wavefront aberration, reduced halo and reduced light scattering. The soft contact lens is designed with pupil apodization for modulating the lens amplitude transmission profile.

A method and system provide a multifocal ophthalmic device. The ophthalmic lens has an anterior surface, a posterior surface and at least one diffractive structure including a plurality of echelettes. The echelettes have at least one step height of at least one wavelength and not more than two wavelengths in optical path length. The diffractive structure(s) reside on at least one of the anterior surface and the posterior surface. The diffractive structure(s) provide a plurality of focal lengths for the ophthalmic lens.

A method and system provide a multifocal ophthalmic device. The ophthalmic lens has an anterior surface, a posterior surface and at least one diffractive structure including a plurality of echelettes. The echelettes have at least one step height of at least one wavelength and not more than two wavelengths in optical path length. The diffractive structure(s) reside on at least one of the anterior surface and the posterior surface. The diffractive structure(s) provide a plurality of focal lengths for the ophthalmic lens.

A super resolution bore imaging system is disclosed for imaging a cylindrical bore. The system includes a controller, a photodetector configuration having a known pixel geometry, and an imaging arrangement that images bore surface segments onto the photodetector. In one embodiment, the controller is configured to acquire respective combinable sets of raw bore segment image data using the pixels of the photodetector configuration positioned, relative to the bore segment, at respective imaging-Z coordinates which are separated along the bore axial direction by a subpixel shift. In some embodiments, the pixel geometry is configured to provide super resolution along the circumferential direction without a change in position along the circumferential direction between acquiring the respective sets of image data. The controller combines the sets of raw image data to form a super resolution image data for the bore segment.

Techniques are described for reducing the number of angles needed in structured illumination imaging of biological samples through the use of patterned flowcells, where nanowells of the patterned flowcells are arranged in, e.g., a square array, or an asymmetrical array. Accordingly, the number of images needed to resolve details of the biological samples is reduced. Techniques are also described for combining structured illumination imaging with line scanning using the patterned flowcells.

Provided are a tiling light sheet selective plane illumination microscope (TLS-SPIM), a use method thereof and a microscope system. The use method includes loading a corresponding phase map to each group of pupil subsections of a pupil by a spatial light modulator, and performing phase modulation on an excitation beam to create at least two coaxial excitation beam arrays scanning the created at least two coaxial excitation beam arrays to generate discontinuous light sheets accordingly; and tiling at least one of the generated discontinuous light sheets in the propagation direction of the excitation light to obtain tiling light sheets for selective plane illumination of a sample. The method of using the TLS-SPIM, the TLS-SPIM and the system including same enables significant increasing of imaging speed, improvement of resolution, and reduction of source data amount.

Electromagnetic wave focusing devices and optical apparatuses including the same are provided. An electromagnetic wave focusing device may include a plurality of material members located at different distances from a reference point. The intervals and/or widths of the material members may vary with distance from the reference point. For example, the intervals and/or widths of the material members may increase or decrease with distance from the reference point. The intervals and/or widths of the material members may be controlled to satisfy a spatial coherence condition with the electromagnetic wave.