Retinal cameras having movable optical stops

What is claimed is: 1. An optical stop unit for a retinal camera to which an eye is presented for imaging of a retina, the optical stop unit comprising: a liquid crystal display (LCD) layer with pixels that are individually controllable and that is arranged parallel to a capturing medium of the retinal camera; and a power component that is able to separately apply a voltage to each of the pixels and, in operation, is configured to: apply voltages to a first subset of the pixels to define an optical stop through which light returning from the eye passes along an axis toward the capturing medium of the retinal camera, receive input that indicates a position of the eye has changed, and apply voltages to a second subset of the pixels to reposition the optical stop along a plane that is substantially orthogonal to the axis, wherein at least some pixels in the first subset are also in the second subset. 2. The optical stop unit of claim 1 , wherein applying the voltages to the first subset of the pixels causes a first plurality of contiguous pixels to become substantially transparent to a visible spectrum of light, and wherein applying the voltages to the second subset of the pixels causes a second plurality of contiguous pixels to become substantially transparent to the visible spectrum of light. 3. The optical stop unit of claim 1 , further comprising: a unit housing that is adapted to fit within the retinal camera. 4. The optical stop unit of claim 1 , further comprising: a communication interface configured to: receive a command from a controller of the retinal camera, and select a voltage to apply based on the command. 5. The optical stop unit of claim 1 , wherein the LCD layer includes a substantially transparent substrate patterned with a grid defining the pixels that are arranged in rows and columns. 6. The optical stop unit of claim 5 , wherein the substantially transparent substrate is comprised of indium tin oxide (ITO). 7. The optical stop unit of claim 1 , wherein the LCD layer includes a polarizing layer, a first conductor layer, a second conductor layer, and a polymer layer with liquid crystal droplets dispersed therein, wherein the polymer layer is interposed between the first and second conductor layers, and wherein the first and second conductor layers are electrically coupled to the power component. 8. The optical stop unit of claim 7 , wherein continual application of power to the first and second conductor layers causes the liquid crystal droplets in the polymer layer to become aligned, which causes a corresponding segment of the LCD layer to become substantially transparent. 9. An optical stop unit for a retinal camera to which an eye is presented for imaging of a retina, the optical stop unit comprising: a variable transparency stack that has multiple liquid crystal display (LCD) layers that are individually controllable and that is arranged parallel to a capturing medium of the retinal camera; and a power component that is able to separately apply a voltage to each LCD layer of the multiple LCD layers and, in operation, is configured to: apply voltages to a first subset of the multiple LCD layers to define an optical stop through which light returning from the eye passes along an axis toward the capturing medium of the retinal camera, receive input that indicates a position of the eye has changed, and apply voltages to a second subset of the multiple LCD layers to reposition the optical stop along a plane that is substantially orthogonal to the axis, wherein at least some LCD layers in the first subset are also in the second subset. 10. The optical stop unit of claim 9 , wherein each LCD layer of the multiple LCD layers partially overlaps at least one other LCD layer. 11. The optical stop unit of claim 9 , wherein each LCD layer of the multiple LCD layers is offset from the other LCD layers of the multiple LCD layers, such that none of the multiple LCD layers overlap each other. 12. The optical stop unit of claim 9 , wherein each LCD layer of the multiple LCD layers is an identical geometrical shape. 13. The optical stop unit of claim 9 , wherein each LCD layer of the multiple LCD layers is an identical size. 14. The optical stop of claim 9 , wherein each LCD layer of the multiple LCD layers includes a substantially transparent substrate that is not patterned. 15. The optical stop unit of claim 9 , wherein the variable transparency stack includes at least six LCD layers. 16. The optical stop unit of claim 15 , wherein the variable transparency stack includes at least ten LCD layers. 17. The optical stop unit of claim 9 , wherein an optically clear bonding layer is used to bind each pair of the multiple LCD layers. 18. The optical stop unit of claim 17 , wherein the optically clear bonding layer comprises an acrylic-based adhesive. 19. The optical stop unit of claim 17 , wherein the optically clear bonding layer comprises a silicon-based adhesive. 20. The optical stop unit of claim 9 , wherein the variable transparency stack further includes a substrate on which at least one of the multiple LCD layers is mounted with an optically clear binding layer, and wherein the substrate comprises glass, indium tin oxide (ITO), polyethylene (PET), polycarbonate (PC), or polymethyl methacrylate (PMMA). 21. An optical stop unit for a retinal camera to which an eye is presented for imaging of a retina, the optical stop unit comprising: a variable transparency layer that includes sublayers or regions for which opacity is separately controllable and that is arranged parallel to a capturing medium of the retinal camera; and a power component that is configured to: generate a voltage, the controlled application of which to the sublayers or the regions defines a transparent region that is representative of an optical stop through which light returning from the eye passes along an axis toward the capturing medium of the retinal camera, receive input that indicates a position of the eye has changed, and adjust the sublayers or the regions to which the voltage is controllably applied, so as to reposition the optical stop along a plane that is substantially orthogonal to the axis in an automated manner.