A biological tissue inspection apparatus is disclosed. The biological tissue inspection apparatus comprises a stage and a probe. The probe comprises an optical imaging device, an optical interference detector, and a light guide. The probe acquires data regarding optical images and optical interference, through the optical imaging device and the optical interference detector. The stage or the probe moves such that a selected area of the inspection object is positioned in the FOV of the optical imaging device and of the optical interference detector. The light guide is configured such that illumination light from the optical imaging device and measurement light from the optical interference detector are coaxially emitted to the inspection object.

A visual rendering apparatus such as a telescope, microscope or attached tablet/led displays a magnified subject using the mapped rendering medium, in which the rendering medium includes at least one of actual visual transmissions of the subject and stored, high resolution images of the magnified subject. In an educational context, equipment for displaying true magnified images of, for example, celestial bodies or molecular structures can be beyond reach. Augmented reality provided by supplementing the true, rendered magnified subject with stored images corresponding to successive, higher magnification levels provides effective visualization with common educational tools, avoiding the need for extravagant scientific equipment.

A portable kit for generating a digital image of a faecal sample suitable for microscopic analysis, comprises a faecal sample preparation device configured to receive a faecal sample and a faecal flotation fluid, filter a suspension comprising the faecal sample and the faecal flotation fluid to provide a filtrate, a translucent faecal sample support, and a portable digital imaging module. The portable digital imaging module comprises a housing, a camera/microscopic lens assembly configured to generate a digital image of the faecal sample on the sample support, an illumination system, a seat for receiving the faecal sample support disposed between the camera/microscopic lens assembly and illumination system, a memory for storing the digital image, a communication system for communicating the digital image to an off-site image processing module via a communications network, and a battery operatively connected to the camera and microscopic lens assembly, memory and communication system.

A microscope system includes: at least one microscope component with electrically adjustable component parameters; a controller for generating electrical signals and transmitting the electrical signals to the at least one microscope component to set the electrically adjustable component parameters; and a computer having at least one display unit, the computer generating an input unit having a graphical user interface on the at least one display unit, at least three setting parameters being adjustable by the graphical user interface. The input unit has an input pointer that is positionable in an input area so as to set a respective value for the at least three setting parameters. A coordinate axis is defined in the input area for each of the at least three setting parameters, with at least one coordinate axis not being perpendicular to another coordinate axis. Values of the at least three setting parameters are determined by the coordinates.

System for state monitoring of a microscope the system having at least one measuring sensor in each case for capturing at least one time-variable chemical and/or physical quantity, a camera for recording an image in a field of view and a processing unit. The at least one measuring sensor has a display area and displays thereon a measured value for the captured time-variable chemical and/or physical quantity. The camera is arranged so that the display areas of at least one measuring sensor are located in the field of view and the processing unit is configured to evaluate the image and to extract the display areas contained in the image therefrom. Also, a method for state monitoring of a microscope is disclosed, wherein at least one measuring sensor with a display area is provided in order to capture in each case at least one time-variable chemical and/or physical quantity, and an image is recorded. The image is recorded so that it contains the display areas of at least one measuring sensor. The display areas are identified in the image, the image is evaluated and the measured values contained in the image are extracted.

In general this device allows one to rapidly configure a mobile phone for use with a microscope. When using the device a person can take images or videos and rapidly share them, or have another user videoconference in and see the images in real time. Further, it saves both money and time when using a microscope in a laboratory (or other) setting. This device can also be used without microscope for a macro lens with illumination and light differential for purposes such as jewelry or medical examination.

A device may use a camera to capture an image of an end face of an optical fiber in a field of view of the camera. The device may monitor a focus metric associated with the image while the image is manually focused using an opto-mechanical assembly. The device may automatically initiate a test to inspect the image of the end face of the optical fiber for compliance with a set of criteria related to cleanliness and damage based on the focus metric satisfying a condition. The device may output a result from the test indicating whether the end face of the optical fiber satisfies the set of criteria related to cleanliness and damage.

The invention provides a microscope system including a correction-gain storage portion that calculates a correction gain for performing shading correction of an image related to optical images of a specimen, obtained by a microscope, and stores specimen information indicating features of the specimen and optical information at the time of obtaining the image in association with the correction gain; a correction-gain selecting portion that selects the correction gain for use when performing the shading correction of the image to be corrected; and a correction portion that performs the shading correction of the image to be corrected, on the basis of the selected correction gain, wherein the correction-gain selecting portion selects, on the basis of the specimen information or a result of the shading correction with the plurality of correction gains, the correction gain to be used in the shading correction of the image to be corrected.

A dual-configuration microscope is provided that may be converted into an upright or inverted microscope. The microscope includes a base and a body having a first portion and a second portion, wherein the body is rotatably coupled to the base. The microscope further includes an objective coupled to the first portion of the body, a condenser coupled to the second portion of the body and a stage positioned between the objective and the condenser. The microscope further includes a first and second knob configured to adjust the position of the objective, wherein the first knob is disposed proximal to the first portion of the body and the second knob is disposed proximal to the second portion of the body.

A confocal microscope is provided that includes one or more lasers focused by an optical system into a line on the surface of a sample mounted to a stage. The microscope further includes at least one linear array detector that is optically conjugated to the focused line. The stage permits movement of the sample with respect to all other components of the microscope, which remain stationary.