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The conversion factor we need to determine is simply the number of µm/reticule units. This conversion factor can be calculated more accurately by counting the number of micrometers contained in several reticule units in the eyepiece. The procedure must be repeated for each objective, but only needs to be performed one time. • Returning to the specimen slide, the number of eyepiece reticule units spanning the diameter of a structure is determined and multiplied by the conversion factor to obtain the distance in micrometers.

How else (in fact, how should you) adjust the light intensity and produce an image of suitable brightness for viewing or photography? 19 CHAPTER 2 LIGHT AND COLOR OVERVIEW In this chapter, we review the nature and action of light as a probe to examine objects in the light microscope. Knowledge of the wave nature of light is essential for understanding the physical basis of color, polarization, diffraction, image formation, and many other topics covered in this book. The eye–brain visual system is responsible for the detection of light, including the perception of color and differences in light intensity that we recognize as contrast.

A) Finite microscope optical train showing focused light rays from the objective at the intermediate image plane. (b) Infinitycorrected microscope with a parallel light beam between the objective and tube lens. This is the region of the optical train that is designed for auxiliary components, such as DIC prisms, polarizers, and filters. microscopes is accomplished by modifying either the tube lens or the objective, or both. Infinity microscopes can maintain parfocality between objectives even when auxiliary components are introduced, and these components are designed to produce exactly 1× magnification to enable comparison of specimens using a combination of several optical techniques, such as phase contrast and DIC with fluorescence.