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Line 109: The pupil function of an ideal optical system with a circular aperture is a disk of unit radius. The optical transfer function of such a system can thus be calculated geometrically from the intersecting area between two identical disks at a distance of <math>2\nu</math>, where <math>\nu</math> is the spatial frequency normalized to the highest transmitted frequency.<ref name=Williams2002/> In general the optical transfer function is normalized to a maximum value of one for <math>\nu = 0</math>, so the resulting area should be divided by <math>\pi</math>. The intersecting area can be calculated as the sum of the areas of two identical [[circular segment]]s: <math> \theta/2 - \sin(\theta)/2</math>, where <math>\theta</math> is the circle segment angle. By substituting <math> \|\nu\| = \cos(\theta/2) </math>, and using the equalities <math> \sin(\theta)/2 = \sin(\theta /2)\cos(\theta /2) </math> and <math> 1 = \nu^2 + \sin(\arccos(\|\nu\|))^2 </math>, the equation for the area can be rewritten as <math>\arccos(\|\nu\|) - \|\nu\|\sqrt{1 - \nu^2} </math>. Hence the normalized optical transfer function is given by: : <math>\operatorname{OTF}(\nu) = \frac{2}{\pi} \left(\arccos(\|\nu\|)-\|\nu\|\sqrt{1-\nu^2}\right).</math>

Optical transfer function: Difference between revisions