An apparatus and method to produce a hologram of an object includes an electromagnetic radiation assembly configured to receive a received electromagnetic radiation, such as light, from the object. The electromagnetic radiation assembly is further configured to diffract the received electromagnetic radiation and transmit a diffracted electromagnetic radiation. An image capture assembly is configured to capture an image of the diffracted electromagnetic radiation and produce the hologram of the object from the captured image.

An apparatus and method to produce a hologram of an object includes an electromagnetic radiation assembly configured to receive a received electromagnetic radiation, such as light, from the object. The electromagnetic radiation assembly is further configured to diffract the received electromagnetic radiation and transmit a diffracted electromagnetic radiation. An image capture assembly is configured to capture an image of the diffracted electromagnetic radiation and produce the hologram of the object from the captured image.

Systems and methods for macro stereo time-lapse photography, producing a stereographic time-lapse digital video, and macro stereographic time-lapse digital videos. A method of producing a sequence of time-lapse stereographic images of a subject, by positioning a camera with a macro lens at a first position relative to the subject; using the camera to obtain a first stack of images of the subject from the first position; positioning the camera at a second position relative to the subject; using the camera to obtain a second stack of images of the subject from the second position; and storing the first stack of images and the second stack of images as a stack pair; and then selectively repeating.

Systems and methods for macro stereo time-lapse photography, producing a stereographic time-lapse digital video, and macro stereographic time-lapse digital videos. A method of producing a sequence of time-lapse stereographic images of a subject, by positioning a camera with a macro lens at a first position relative to the subject; using the camera to obtain a first stack of images of the subject from the first position; positioning the camera at a second position relative to the subject; using the camera to obtain a second stack of images of the subject from the second position; and storing the first stack of images and the second stack of images as a stack pair; and then selectively repeating.

A slit lamp microscope according to an embodiment example includes a scanner, a first assessing processor, and a controller. The scanner is configured to perform application of a scan to an anterior segment of a subject’s eye with slit light to collect an image group. The first assessing processor is configured to execute an assessment of a quality of the image group collected by the scanner. The controller is configured to selectively execute at least two control modes according to a result of the assessment of the quality obtained by the first assessing processor.

A computerized imaging system and method for creating a 3D imaging dataset of an object are disclosed. The computerized imaging system includes an object stage mounted on a system base plate, the object stage is configured to rotate 360 degrees around its axis perpendicular to the base plate plane. The computerized imaging system includes an elongated elevation arm positioned alongside the object stage, wherein the elongated elevation arm having an image sensor, at least one lens, and a mirror mounted thereon, and wherein the optical axis of the image sensor is parallel to the elongated elevation arm elevation axis. The image sensor is used to capture a plurality of images of the object in a plurality of rotation and elevation angles of the object stage and elongated elevation arm.

A computerized imaging system and method for creating a 3D imaging dataset of an object are disclosed. The computerized imaging system includes an object stage mounted on a system base plate, the object stage is configured to rotate 360 degrees around its axis perpendicular to the base plate plane. The computerized imaging system includes an elongated elevation arm positioned alongside the object stage, wherein the elongated elevation arm having an image sensor, at least one lens, and a mirror mounted thereon, and wherein the optical axis of the image sensor is parallel to the elongated elevation arm elevation axis. The image sensor is used to capture a plurality of images of the object in a plurality of rotation and elevation angles of the object stage and elongated elevation arm.

An apparatus and method to produce a hologram of an object includes an electromagnetic radiation assembly configured to receive a received electromagnetic radiation, such as light, from the object. The electromagnetic radiation assembly is further configured to diffract the received electromagnetic radiation and transmit a diffracted electromagnetic radiation. An image capture assembly is configured to capture an image of the diffracted electromagnetic radiation and produce the hologram of the object from the captured image.

An apparatus and method to produce a hologram of an object includes an electromagnetic radiation assembly configured to receive a received electromagnetic radiation, such as light, from the object. The electromagnetic radiation assembly is further configured to diffract the received electromagnetic radiation and transmit a diffracted electromagnetic radiation. An image capture assembly is configured to capture an image of the diffracted electromagnetic radiation and produce the hologram of the object from the captured image.

A camera unit that captures and generates a plurality of images of a subject and a setting unit that sets different image capturing positions of the camera unit are provided. The setting unit sets the different image capturing positions so that the distance between an n-th image capturing position and an n+1th image capturing position and the distance between an m-th image capturing position and an m+1th image capturing position among the different image capturing positions differ from each other, where n and m are different natural numbers.