Abstract: A method for managing a digital image of a biological specimen is disclosed. The method includes storing image data in a storage device. The image data is data for showing the image on a display. The method also includes identifying a portion of the image to be processed and transferring a first portion of the image data from the storage device to a working memory. The first portion of the image data is a portion of the image data for displaying the identified portion of the image on the display.

Abstract: A system and method of assembling an application for processing image or image-derived data is disclosed. The system includes a base operator configured to interface with one or more derivative operator classes, each operator class including an operator object for executing a processing function on the image or image-derived data. A base multiport node class is provided, which is configured to provide a multiport node for each operator object. The multiport nodes instantiates a pluggable operator for connecting the multiport nodes together at runtime according to user-defined parameters. The connection of multiport nodes implements the processing functions of the operator objects to execute the application.

Abstract: An analog circuit for an autofocus microscope system measures a degree of focus of an object directly from the video signal of a microscope CCD camera. The circuit then returns an index to a host computer for the purpose of adjusting the position of the microscope's objective lens to bring the object in focus. Best focus is found by comparing indices at several different vertical positions. The criterion adopted for determining the degree of focus is derived from the energy distribution of the video signal spectrum. The high frequency energy of the video spectrum is a maximum at best focus and as the optics defocus, the distribution shifts to lower frequencies. Low cost, real time autofocus is achieved with the analog circuitry of this invention, replacing more expensive dedicated, real time image processing hardware.

Abstract: An analog circuit for an autofocus microscope system measures a degree of focus of an object directly from the video signal of a microscope CCD camera. The circuit then returns an index to a host computer for the purpose of adjusting the position of the microscope's objective lens to bring the object in focus. Best focus is found by comparing indices at several different vertical positions. The criterion adopted for determining the degree of focus is derived from the energy distribution of the video signal spectrum. The high frequency energy of the video spectrum is a maximum at best focus and as the optics defocus, the distribution shifts to lower frequencies. Low cost, real time autofocus is achieved with the analog circuitry of this invention, replacing more expensive dedicated, real time image processing hardware.