The present disclosure provides an optical lens, glasses and a display device. The optical lens includes: a first surface, a second surface, a first lens portion and a second lens portion. The optical lens is a convex lens. The first surface and the second surface are at two side surfaces of the optical lens. The first surface is a convex aspheric surface, and the second surface is a Fresnel surface with a recessed curved base. The first lens portion and the second lens portion are adjacent each other and connected in a direction perpendicular to a main optical axis of the optical lens. A first focal point of the first lens portion and a second focal point of the second lens portion are on the main optical axis, and a focal length of the second lens portion is greater than a focal length of the first lens portion.

An optical imaging system including a first lens, a second lens, a third lens, a fourth lens, a fifth lens, and a sixth lens sequentially arranged from an object side toward an imaging plane, wherein an object-side surface of the sixth lens is convex, and wherein one of the first lens to the sixth lens is a variable focus lens configured to have a variable focal length.

An optical imaging system including a first lens, a second lens, a third lens, a fourth lens, a fifth lens, and a sixth lens sequentially arranged from an object side toward an imaging plane, wherein an object-side surface of the sixth lens is convex, and wherein one of the first lens to the sixth lens is a variable focus lens configured to have a variable focal length.

The imaging device includes a multiple-property lens that includes a first area having a first property and a second area having a second property different from the first property, an image sensor in which a first light receiving element 25A having a first microlens and a second light receiving element 25B having a second microlens having a different image forming magnification from the first microlens are two-dimensionally arranged, and a crosstalk removal processing unit that removes a crosstalk component from each of a first crosstalk image acquired from the first light receiving element 25A of the image sensor and a second crosstalk image acquired from the second light receiving element to generate a first image and a second image respectively having the first property and the second property of the multiple-property lens.

The imaging device includes a multiple-property lens that includes a first area having a first property and a second area having a second property different from the first property, an image sensor in which a first light receiving element 25A having a first microlens and a second light receiving element 25B having a second microlens having a different image forming magnification from the first microlens are two-dimensionally arranged, and a crosstalk removal processing unit that removes a crosstalk component from each of a first crosstalk image acquired from the first light receiving element 25A of the image sensor and a second crosstalk image acquired from the second light receiving element to generate a first image and a second image respectively having the first property and the second property of the multiple-property lens.

An objective lens system for an optical biopsy device has a lens that comprises a first part configured for viewing at a first magnification, and a second part configured for viewing at a second magnification. The second magnification is substantially different from the first magnification. The first magnification enables viewing a larger area of a target and the second magnification enables viewing the target at a cellular level with high sensitivity and specificity. Combining viewing at two different magnifications in a single objective lens results in a compact optical biopsy device.

An objective lens system for an optical biopsy device has a lens that comprises a first part configured for viewing at a first magnification, and a second part configured for viewing at a second magnification. The second magnification is substantially different from the first magnification. The first magnification enables viewing a larger area of a target and the second magnification enables viewing the target at a cellular level with high sensitivity and specificity. Combining viewing at two different magnifications in a single objective lens results in a compact optical biopsy device.

An imaging device includes a multifocal main lens having different focal distances for a plurality of regions, an image sensor having a plurality of pixels configured of two-dimensionally arranged photoelectric converting elements, a multifocal lens array having a plurality of microlens groups at different focal distances disposed on an incident plane side of the image sensor, and an image obtaining device which obtains from the image sensor, a plurality of images for each of the focal distances obtained by combining the multifocal main lens and the plurality of microlens groups at different focal distances.

An imaging device includes a multifocal main lens having different focal distances for a plurality of regions, an image sensor having a plurality of pixels configured of two-dimensionally arranged photoelectric converting elements, a multifocal lens array having a plurality of microlens groups at different focal distances disposed on an incident plane side of the image sensor, and an image obtaining device which obtains from the image sensor, a plurality of images for each of the focal distances obtained by combining the multifocal main lens and the plurality of microlens groups at different focal distances.

An actuator may be integrated into an optical element such as a liquid lens and configured to create spherical curvature as well as a variable cylinder radius and axis in a surface of the optical element. An example actuator may include a stack of electromechanical layers, and electrodes configured to apply an electric field independently across each of the electromechanical layers. Within the stack, an orientation of neighboring electromechanical layers may differ, e.g., stepwise, by at least approximately 10°.