A viewing apparatus for producing a stereoscopic image for an observer, the viewing apparatus comprising: first and second video projectors for projecting respective ones of first and second video images of an object, the first and second images being different images which are one or both of spatially and angularly shifted in relation to the object so as to convey parallax between the images; a mirror arrangement comprising a concave mirror which receives light from the first and second video projectors, the mirror arrangement being located in relation to the first and second video projectors such that focussed images of the object are produced at the mirror arrangement; and a viewing lens for relaying exit pupils corresponding to each of the focussed images as reflected by the mirror arrangement to a viewing plane so as to be viewable at the respective eyes of the observer as a stereoscopic image without use of adapted eyewear; wherein the video projectors comprise first and second video displays which are driven by first and second video signals to display respective ones of the first and second video images, and first and second optical arrangements for focussing light from the respective images as displayed by the first and second displays to the mirror arrangement.

Provided are systems and methods related to hybrid reflective microscope objectives and lens systems used in a spectroscopy system. The objective lens system includes a primary aspheric mirror having a first R-value; and a secondary aspheric mirror having a second R-value smaller than the first R-value, where in the objective lens system has a working distance of at least 20 mm and a numerical aperture of 0.29-0.65, and wherein surfaces of the primary and secondary aspheric mirrors have a non-zero sixth order aspheric parameter.

Provided are systems and methods related to hybrid reflective microscope objectives and lens systems used in a spectroscopy system. The objective lens system includes a primary aspheric mirror having a first R-value; and a secondary aspheric mirror having a second R-value smaller than the first R-value, where in the objective lens system has a working distance of at least 20 mm and a numerical aperture of 0.29-0.65, and wherein surfaces of the primary and secondary aspheric mirrors have a non-zero sixth order aspheric parameter.

The invention relates to a correction objective (10), comprising a first lens group (12) of positive optical power, a second lens group (14) of positive optical power, a third lens group (16) of negative optical power, and a fourth lens group (18) of positive optical power, which are arranged in this order from the object side, the second lens group (14) being movable along the optical axis (O) in such a way that the sum of the distance (V1) between the second lens group (14) and the first lens group (12) and the distance (V2) between the second lens group (14) and the third lens group (16) is constant. The image scale of the second lens group (14) lies in a range of −0.9 to −1.1.

The invention relates to a correction objective (10), comprising a first lens group (12) of positive optical power, a second lens group (14) of positive optical power, a third lens group (16) of negative optical power, and a fourth lens group (18) of positive optical power, which are arranged in this order from the object side, the second lens group (14) being movable along the optical axis (O) in such a way that the sum of the distance (V1) between the second lens group (14) and the first lens group (12) and the distance (V2) between the second lens group (14) and the third lens group (16) is constant. The image scale of the second lens group (14) lies in a range of −0.9 to −1.1.

Methods for imaging a sample using fluorescence microscopy, systems for imaging a sample using fluorescence microscopy, and illumination systems for fluorescence microscopes. In some examples, a method includes positioning a dual convex paraboloidal mirror enclosure around the sample. The dual convex paraboloidal mirror enclosure includes an upper paraboloidal mirror and a lower paraboloidal mirror oriented antiparallel to each other. An aperture is defined in the lower paraboloidal mirror, a hemispherical dome is mounted in the aperture, and the sample is surrounded by the hemispherical dome. The method includes directing excitation light onto the sample to form a primary image at an upper vertex of the upper paraboloidal mirror and a secondary image at a lower vertex of the lower paraboloidal minor. The method includes imaging the sample through a detection objective of a microscope.

The invention relates to a tube for a surgical microscope. The tube has a base part, an intermediate part, which is pivotable about a rotational axis on the base part, and an ocular part which is pivotable about a rotational axis on the intermediate part. The imaging beam path is guided through the base part, the intermediate part and the pivotable ocular part. The tube has a tube lens system which transfers a parallel imaging beam paths into an intermediate image. The parallel imaging beam path enters via an opening in a connecting piece of the base part. The tube has a first displaceable mirror element which can be moved about the rotational axis on the base part. The tube lens system is a telesystem which has a lens unit having positive refractive power and a lens unit having negative refractive power.

The invention relates to a tube for a surgical microscope. The tube has a base part, an intermediate part, which is pivotable about a rotational axis on the base part, and an ocular part which is pivotable about a rotational axis on the intermediate part. The imaging beam path is guided through the base part, the intermediate part and the pivotable ocular part. The tube has a tube lens system which transfers a parallel imaging beam paths into an intermediate image. The parallel imaging beam path enters via an opening in a connecting piece of the base part. The tube has a first displaceable mirror element which can be moved about the rotational axis on the base part. The tube lens system is a telesystem which has a lens unit having positive refractive power and a lens unit having negative refractive power.

A microscope apparatus provided with: a disk unit obtained by integrally forming a pinhole array disk in which pinholes are arranged and a microlens array disk in which microlenses are arranged; a dichroic mirror focusing illumination light that has been transmitted through the microlenses of the disk unit, on the corresponding pinholes and splitting off fluorescence from a specimen that has passed through the pinholes in the reverse direction from the illumination light; an objective lens radiating the illumination light that has passed through the pinholes onto the specimen and focusing the fluorescence from the specimen on the pinholes; an illumination-light-axis adjustment mechanism adjusting the position and the angle of the optical axis of the illumination light; an installation-angle adjustment mechanism adjusting the installation angle of the disk unit; and a unit insertion/removal mechanism removably supporting the disk unit onto the optical axis of the illumination light.

A microscope apparatus provided with: a disk unit obtained by integrally forming a pinhole array disk in which pinholes are arranged and a microlens array disk in which microlenses are arranged; a dichroic mirror focusing illumination light that has been transmitted through the microlenses of the disk unit, on the corresponding pinholes and splitting off fluorescence from a specimen that has passed through the pinholes in the reverse direction from the illumination light; an objective lens radiating the illumination light that has passed through the pinholes onto the specimen and focusing the fluorescence from the specimen on the pinholes; an illumination-light-axis adjustment mechanism adjusting the position and the angle of the optical axis of the illumination light; an installation-angle adjustment mechanism adjusting the installation angle of the disk unit; and a unit insertion/removal mechanism removably supporting the disk unit onto the optical axis of the illumination light.