Array-based floating display

What is claimed is: 1. A lens system comprising: a first lens array assembly comprising a first plurality of cells, wherein the first plurality of cells defines a first plane, each cell of the first plurality of cells configured to exhibit a pair of first Fourier transform lenses positioned in normal direction to the first plane, wherein the pair of first Fourier transform lenses of the first lens array are separated in the first plane by a focal length of the first Fourier transform lenses to perform a phase correction; and a second lens array assembly comprising a second plurality of cells, wherein the second plurality of cells defines a second plane, each cell of the second plurality of cells configured to exhibit a pair of second Fourier transform lenses positioned in normal direction to the second plane, wherein the pair of second Fourier transform lenses of the second lens array are separated in the second plane by a focal length of the second Fourier transform lenses to perform a phase correction; wherein: the first and second lens array assemblies are positioned relative to one another along an optical axis of the lens system such that light diverging from an object at a plane disposed at an object conjugate distance from the first lens array assembly reconverges at an image plane after passing through the first and second lens array assemblies; and the image plane is disposed at an image conjugate distance from the second lens array assembly in accordance with the object conjugate distance. 2. The lens system of claim 1 , wherein: the image conjugate distance is established via a function of the object conjugate distance, a distance between the first and second lens array assemblies, a first focal length of the first plurality of cells, a second focal length of the second plurality of cells, a first pitch of the first plurality of cells, and a second pitch of the second plurality of cells; and the function establishes that the light diverging from the object reconverges at the image conjugate distance. 3. The lens system of claim 1 , wherein the first and second lens array assemblies are spaced apart from one another by a gap of optical media. 4. The lens system of claim 1 , wherein the image plane is a floating image plane. 5. The lens system of claim 1 , wherein the image conjugate distance substantially equals the object conjugate distance. 6. The lens system of claim 1 , wherein the plane of the object and the image plane are oriented in parallel. 7. The lens system of claim 6 , wherein the plane of the object and the image plane are oriented orthogonally to the optical axis of the lens system. 8. The lens system of claim 6 , wherein the plane of the object and the image plane are oriented orthogonally to a line oriented at an angle to the optical axis of the lens system. 9. The lens system of claim 1 , wherein the pairs of first and second Fourier transform lenses have a common focal length. 10. The lens system of claim 1 , further comprising a display disposed at the object conjugate distance. 11. The lens system of claim 1 , wherein: further object content is disposed at a second object conjugate distance shorter than the object conjugate distance of the plane; and the first and second lens array assemblies are configured such that an image of the further object content reconverges at a further image plane that appears to be disposed in a background of the image plane. 12. The lens system of claim 1 , wherein: the first lens array assembly comprises a first pair of in-tandem microlens arrays, each microlens array of the first pair comprising a respective set of constituent lenslets such that each cell of the first plurality of cells comprises a respective one of the constituent lenslets from each respective set of constituent lenslets, each constituent lenslet having a first common focal length; the second lens array assembly comprises a second pair of in-tandem microlens arrays, each microlens array of the second pair comprising a respective set of constituent lenslets such that each cell of the second plurality of cells comprises a respective one of the constituent lenslets from each respective set of constituent lenslets, each constituent lenslet having a second common focal length; the in-tandem microlens arrays of the first pair are separated from one another along the optical axis of the lens system by the first common focal length; the in-tandem microlens arrays of the second pair are separated from one another along the optical axis of the lens system by the second common focal length; and the first and second pairs of in-tandem microlens arrays are positioned relative to one another along the optical axis such that the image is provided at the image conjugate distance. 13. The lens system of claim 12 , wherein the first and second common focal lengths are equal to one another. 14. The lens system of claim 1 , wherein: the first lens array assembly comprises a first array of graded-index microlensing structures; each graded-index microlensing structure of the first array corresponds with a respective one of the first plurality of cells; the second lens array assembly comprises a second array of graded-index microlensing structures; and each graded-index microlensing structure of the second array corresponds with a respective one of the second plurality of cells. 15. A lens system comprising: a lens array assembly comprising a plurality of cells, wherein the plurality of cells defines a plane, each cell of the plurality of cells configured to exhibit a pair of Fourier transform lenses positioned in normal direction to the plane, wherein the pair of Fourier transform lenses of the lens array are separated in the plane by a focal length of the Fourier transform lenses to perform a phase correction, the lens array assembly disposed along an optical axis to receive light diverging from an object at a plane disposed at an object conjugate distance from the lens array assembly; and a reflective surface disposed along the optical axis for reflection of the light back through the lens array assembly after reflection off of the reflective surface; wherein: the lens array assembly is configured such that the light reconverges at an image plane after passing back through the lens array assembly; and the image plane is disposed at an image conjugate distance from the lens array assembly in accordance with the object conjugate distance. 16. The lens system of claim 15 , further comprising a reflective layer that provides the reflective surface, the reflective layer spaced from the lens array assembly along the optical axis. 17. The lens system of claim 15 , wherein the lens array assembly comprises a pair of in-tandem microlens arrays, each microlens array of the pair comprising a respective set of constituent lenslets such that each cell of the plurality of cells comprises a respective one of the constituent lenslets from each respective set of constituent lenslets. 18. The lens system of claim 17 , wherein: the pair of in-tandem microlens arrays comprises a first microlens array and a second microlens array; the reflective surface is disposed on the second microlens array; and a focal length of the constituent lenslets of the second microlens array is equal to half of a focal length of the constituent lenslets of the first microlens array to compensate for a change in optical power from the reflective surface. 19. The lens system of claim 17 , wherein the respective sets of constituent lenslet