Measuring ophthalmic lens using a prism with phase shifting mirror and a fluid in reference arm

What is claimed is: 1. A system for characterizing the surface properties of one or both surfaces of a contact lens, the system comprising: an optics assembly including a light source configured to generate a low coherence light beam; a beam splitter configured to create a first light beam and a second light beam from the light beam generated by the optics assembly; a test arm configured to receive the first light beam from the beam splitter, the test arm comprising a diverger assembly including at least one lens to produce a focal point and spherical wavefronts while minimizing the introduction of wavefront aberrations, a cuvette including at least one chamber configured to hold a first fluid and having a window to allow light from the diverger into the chamber, a mounting structure with an opening for light from the diverger, the mounting structure aligning the contact lens with the diverger assembly and supports the contact lens in the fluid, a controller capable of moving the mounting structure such that the distance between the contact lens and the output of the diverger assembly is known based on feedback from a distance measuring device connected to the mounting structure, the first light beam travelling a first distance through the test arm reaching at least one surface of the contact lens and reflecting off the at least one surface and travelling back to the beam splitter through the elements in the test arm; a reference arm configured to receive the second light beam from the beam splitter, the reference arm comprising a phase shifting PZT mirror to alter the path of the second light beam and direct it to a tank for holding a second fluid, wherein the first and second fluids are the same, the tank having a window to allow light from the phase shifting PZT mirror to enter the tank pass through the fluid and reach a moveable reference prism having a front surface and a back surface and designed to allow the dispersion of the reference arm to match the dispersion of the test arm and to allow the coherence length of the second light beam passing through the reference arm to be equal to that of the coherence length of the first light beam passing through the test arm, the second light beam travelling a second distance through the reference arm reaching the back surface of the moveable reference prism and reflecting off the second surface and travelling back to the beam splitter through the elements in the reference arm; and an imaging assembly configured to optically combine a portion of the light beam from the test arm with a portion of the light beam from the reference arm to create interference, the imaging assembly comprising a lens system having at least two lenses arranged and a detector to capture the interference associated with the desired measurement plane as determined by the location of the contact lens in the test arm.