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Voxelviewer
Z-sectioning, the acquisition of images at different focal positions is used to image three-dimensional specimens. cell^P’s VoxelViewer renders three-dimensional images and iso-surfaces that can be rotated freely. The rotation can be animated as well. 3-dimensional measurements such as position and distance are integrated. |
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Time Lapse Experiments
When using time-lapse to help analyse dynamic processes, it is necessary to automate the entire experiment flow, from the interplay of all microscope parts to image acquisition and data archiving. cell^P makes it possible to create image sequences in multiple dimensions (X, Y, Z, time, multi-channel fluorescence). |
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Deconvolution
The spatial resolution of wide field microscopy is limited by out-of-focus blur. The algorithms (no neighbour, nearest neighbour and inverse filter) – implemented in cell^P – remove stray light from unfocused areas above and below the focus plane and yield images of higher clarity. |
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Automation
cell^P supports automated analysis sequences which are defined using the integrated „Automater“ without any programming required. Entire sequences of steps can be automated, from sample positioning and focusing, to image acquisition, image processing and evaluation, subsequent results display and archiving. Frequently recurring tasks can thus be standardised and executed at the click of a button.
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Intensity and Kinetic Measurements
cell^P charts intensity and kinetic measurements of image stacks. It graphs and displays intensity measurements over time or z-distance. With measurement functions such as horizontal or vertical distance, first and second derivation, mathematical and others, a detailed analysis of individual graphs can be accomplished. |
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Analysis of multi-channel fluorescence images
cell^P offers several functions for analysing multi-colour fluorescence images. These include co-localisation, delta F / F and ratio measurements. The evaluated data will be displayed graphical and in sheets. Further processing, archiving and reporting is supported. |
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Programming
The programming language Imaging C offers advanced users a complete, integrated development environment. This includes a programming library with unrestricted access to the wide range of image acquisition and processing functions. Imaging C consists of a compiler, an interpreter, a macro recorder, a multiple-document (MDI) text editor, a symbol and function browser, and an interactive debugger with single-step processing, conditional breakpoints and a browser for variables and constants. |
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Intuitive application control
Thanks to its intuitive user control, the 3.0 Workflow Assistant allows routine documentation and imaging tasks to be accomplished with just a few logical mouse clicks. |
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Olympus Camera Control
The Olympus Camera Control (OCC) tool window provides an intuitive and flexible control for all aspects of acquisition – from the Olympus cameras to the software. With OCC you can display and access the controls that you need and store and retrieve your application-specific camera settings. Simple, clear and precise!
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Olympus True Color
Olympus True Colour (OTC) technology gives you the real image – from the specimen through the PC to the monitor. OTC uses internal ICC profiles to govern the relationship between the input colours from the specimen and through the camera, with the output colours from a display device, such as a monitor or printer.
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Complete process automation
