Exit pupil-forming display with reconvergent sheet

What is claimed is: 1. A display comprising: a source that establishes an exit pupil of far field content; a reconvergent sheet disposed along an optical axis to receive light of the far field content, the reconvergent sheet being configured to implement a phase-corrected Fourier transform to reconverge the far field content in position space; a reflective surface disposed along the optical axis for reflection of light of the position space back through the reconvergent sheet after reflection off of the reflective surface to re-form the exit pupil of the far field content; and a splitter disposed along the optical axis between the source and the reconvergent sheet and configured to redirect light exhibiting the re-formed exit pupil in a direction offset from the optical axis. 2. The display of claim 1 , wherein: the reconvergent sheet comprises first and second in-tandem microlens arrays sequentially disposed along an optical axis to receive the light of the far field content; each of the first and second microlens arrays comprises a respective set of constituent lenslets; each constituent lenslet has a common focal length; and the first and second in-tandem microlens arrays are separated from one another along the optical axis by the common focal length such that the first and second in-tandem microlens arrays form a plurality of Fourier transform cells. 3. The display of claim 1 , wherein the optical axis is free of lens elements between the source and the reconvergent sheet. 4. The display of claim 1 , further comprising a reflective layer that provides the reflective surface, the reflective layer being disposed past the reconvergent sheet along the optical axis. 5. The display of claim 1 , wherein the reflective surface is a surface on a side of the reconvergent sheet. 6. The display of claim 1 , wherein the reconvergent sheet and the reflective surface are foldable. 7. A display comprising: a source that establishes an exit pupil of far field content; a reconvergent sheet disposed along an optical axis to receive light of the far field content, the reconvergent sheet being configured to reconverge the far field content in position space; a reflective surface disposed along the optical axis for reflection of light of the position space back through the reconvergent sheet after reflection off of the reflective surface to re-form the exit pupil of the far field content; and a splitter disposed along the optical axis between the source and the reconvergent sheet and configured to redirect light exhibiting the re-formed exit pupil in a direction offset from the optical axis, wherein the splitter is disposed as a combiner to allow ambient light to reach a plane at which the re-formed exit pupil is exhibited. 8. A display comprising: a source that establishes an exit pupil of far field content; a reconvergent sheet disposed along an optical axis to receive light of the far field content, the reconvergent sheet being configured to reconverge the far field content in position space; a reflective surface disposed along the optical axis for reflection of light of the position space back through the reconvergent sheet after reflection off of the reflective surface to re-form the exit pupil of the far field content; and a splitter disposed along the optical axis between the source and the reconvergent sheet and configured to redirect light exhibiting the re-formed exit pupil in a direction offset from the optical axis, wherein the splitter comprises a polarizing splitter. 9. A display comprising: a source that establishes an exit pupil of far field content; a reconvergent sheet disposed along an optical axis to receive light of the far field content, the reconvergent sheet being configured to reconverge the far field content in position space; a reflective surface disposed along the optical axis for reflection of light of the position space back through the reconvergent sheet after reflection off of the reflective surface to re-form the exit pupil of the far field content; and a splitter disposed along the optical axis between the source and the reconvergent sheet and configured to redirect light exhibiting the re-formed exit pupil in a direction offset from the optical axis, wherein the source comprises a scanned beam system. 10. A display comprising: a source that establishes an exit pupil of angle space light; first and second in-tandem microlens arrays sequentially disposed along an optical axis to receive the angle space light, each of the first and second microlens arrays comprising a respective set of constituent lenslets, each constituent lenslet having a common focal length such that the first and second in-tandem microlens arrays form a plurality of Fourier transform cells to transform the angle space light into position space light; a reflective layer disposed past the second microlens array such that the position space light passes back through the first and second in-tandem microlens arrays after reflection off of the reflective layer to re-form the exit pupil in angle space; and a splitter disposed along the optical axis between the source and the first and second in-tandem microlens arrays to redirect light exhibiting the re-formed exit pupil in a direction offset from the optical axis. 11. The display of claim 10 , wherein the optical axis is free of lens elements between the source and the first and second in-tandem microlens arrays. 12. The display of claim 10 , wherein the reconvergent sheet and the reflective layer are foldable. 13. The display of claim 10 , wherein the splitter is disposed as a combiner to allow ambient light to reach a plane at which the re-formed exit pupil is exhibited. 14. The display of claim 10 , wherein the splitter comprises a polarizing splitter. 15. The display of claim 10 , wherein the source comprises a scanned beam system. 16. A display comprising: a source that establishes an exit pupil of angle space light; and first and second pairs of in-tandem microlens arrays spaced from the source along an optical axis, each array of the first and second pairs of in-tandem microlens arrays comprising a respective set of constituent lenslets, each constituent lenslet having a common focal length such that each array of the first and second pairs of in-tandem microlens arrays forms a plurality of Fourier transform cells; wherein the first pair of in-tandem microlens arrays is disposed along the optical axis to receive the angle space light from the source, the arrays of the first pair being sequentially disposed along the optical axis relative to one another to transform the angle space light into position space light, and wherein the second pair of in-tandem microlens arrays is disposed along the axis past the first pair of in-tandem microlens arrays to receive the position space light, the arrays of the second pair being sequentially disposed along the optical axis relative to one another to re-form the exit pupil in angle space. 17. The display of claim 16 , wherein the first and second pairs of in-tandem microlens arrays are not spaced from one another. 18. The display of claim 16 , wherein the first and second pairs of in-tandem microlens arrays are in contact with one another. 19. The display of claim 16 , wherein the optical axis is free of lens elements between the source and the first and second pairs of in-tandem microlens arrays. 20. The display of claim 16 , wherein the source comprises a scanned beam system.