Active alignment of pancake lens based display assemblies

What is claimed is: 1. A method comprising: positioning a first lens of a display assembly, the first lens in optical series with a second lens that is coupled to a lens housing; rotating, using an alignment system, the first lens about an optical axis of a pancake lens display assembly to position a first orientation axis of a quarter-wave plate on the first lens such that the first orientation axis is at an angle relative to a second orientation axis of a reflective polarizer on the second lens, wherein the angle is such that light transmitted through the second lens and then through the first lens is substantially circularly polarized; and mounting the first lens to the lens housing, wherein the first lens is mounted to the lens housing such that the quarter-wave plate is at the angle relative to the reflective polarizer. 2. The method of claim 1 , wherein rotating the first lens about the optical axis of the pancake lens display assembly to position the first orientation axis of the quarter-wave plate on the first lens such that the first orientation axis is at the angle relative to the second orientation axis of the reflective polarizer on the second lens, further comprises: directing test light through the first lens, wherein a portion of the directed test light is transmitted by the reflective polarizer of the second lens to a camera, imaging, using the camera, the portion of the directed test light, wherein the portion of the directed test light forms a ghost image, wherein the angle is such that a brightness of the ghost image is less than a threshold value. 3. The method of claim 2 , wherein the test light is directed through the first lens from an illumination source, wherein the illumination source is a chrome-on glass target or a display of the pancake lens display assembly. 4. The method of claim 2 , wherein an illumination source of the test light includes a film stack configured to emit circularly polarized test light, wherein the circularly polarized test light passes through the quarter-wave plate of the first lens, the quarter-wave plate changes the circularly polarized test light to linearly polarized test light that allows at least a portion of the linearly polarized test light to pass through the reflective polarizer of the second lens to be imaged by the camera as the ghost image. 5. The method of claim 1 , wherein rotating the first lens about the optical axis of the pancake lens display assembly to position the first orientation axis of the quarter-wave plate on the first lens such that the first orientation axis is at the angle relative to the second orientation axis of the reflective polarizer on the second lens, further comprises: directing, from an illumination source, test light through the second lens such that the test light then is transmitted by the first lens to a stokes snapshot polarimeter; and determining an amount of circularly polarized light in the test light using the stokes snapshot polarimeter, wherein the angle is such that an amount of circular polarized light received at the stokes snapshot polarimeter is at least some threshold value. 6. The method of claim 5 , further comprising: positioning, using a rotation stage, an electronic display of the pancake lens display assembly in optical series with the first lens and the second lens, the electronic display configured to emit circularly polarized light; displaying a test image on the electronic display, wherein a camera is focused on the optical axis at the electronic display with the first lens and the second lens between the camera and the electronic display, wherein a portion of the circularly polarized light from the electronic display forms a ghost image at the camera; rotating, via the rotation stage, the electronic display through a range of angles; determining an angle of the electronic display such that a brightness of the ghost image is less than a threshold value. 7. The method of claim 1 , wherein positioning the first lens in optical series with the second lens comprises: mounting the second lens to the lens housing; and positioning the first lens a predetermined distance from a mounting location for the first lens on the lens housing. 8. The method of claim 1 , further comprising: applying pressure sensitive adhesive between the first lens and the lens housing; and generating, using the alignment system, pressure on the pressure sensitive adhesive between the first lens and the lens housing to mount the first lens to the lens housing. 9. The method of claim 1 , further comprising: applying pressure sensitive adhesive between an electronic display and a display housing; determining alignment of the electronic display on the display housing; and mounting the electronic display to the display housing via the pressure sensitive adhesive. 10. The method of claim 9 , further comprising: attaching the display housing to the lens housing; display a test image on the electronic display viewable through the first lens and the second lens by a plurality of optical alignment cameras each covering a different field angle; and adjusting the electronic display along at least one of the optical axis, tip, and tilt based on images from plurality of optical alignment cameras. 11. A system comprising: a central mount; a rotating collar connected to the central mount and configured to rotate about the central mount; two or more holding prongs attached to the rotating collar, the two or more holding prongs configured to hold a first lens while the rotating collar rotates the first lens about an optical axis of a pancake lens display assembly including a second lens in optical series with the first lens, wherein the rotating collar rotates the first lens to position a first orientation axis of a quarter-wave plate on the first lens such that the first orientation axis is at an angle relative to a second orientation axis of a reflective polarizer on the second lens; an illumination source configured to emit test light through the first lens and the second lens; and a sensor configured to receive the test light emitted by the illumination source, wherein the angle is such that light transmitted through the second lens and then through the first lens is substantially circularly polarized. 12. The system of claim 11 , wherein the illumination source is coupled to the mount and further configured to emit circularly polarized test light through the first lens and then through the second lens, wherein the circularly polarized test light passing through the first lens and then through the second lens is imaged by the sensor as a ghost image, and wherein the angle is such that a brightness of the ghost image is less than a threshold value. 13. The system of claim 12 , wherein the circularly polarized test light from the illumination source passes through the quarter-wave plate of the first lens, the quarter-wave plate changes the circularly polarized test light to linearly polarized test light that allows at least a portion of the linearly polarized test light to pass through the reflective polarizer of the second lens to be imaged by the sensor as the ghost image. 14. The system of claim 12 , wherein the illumination source is a chrome-on glass target or a display of the pancake lens display assembly. 15. The system of claim 11 , wherein the sensor is a stokes snapshot polarimeter configured to receive the light emitted from the illumination source after the light passes through the second lens and then through the first lens, wherein the illumination source is further configured to emit linearly polarized