Compact display engine with MEMS scanners

What is claimed: 1. A near-eye optical display system configured to show images within a field of view (FOV) described by a first direction and a second direction, comprising: a waveguide display comprising one or more diffractive optical elements (DOEs) including an in-coupling DOE configured for in-coupling image light to the waveguide display; a polarizing beam splitter located proximate to the in-coupling DOE, the polarizing beam splitter configured to reflect image light having a first polarization state and transmit image light having a second polarization state; a first MEMS (micro electro mechanical system) scanner and configured to scan in the first direction of the FOV; a first quarter wave plate having an optical axis that is parallel to front and rear faces of the first quarter wave plate, the first MEMS scanner being disposed proximate to the front face and the polarizing beam splitter being disposed proximate to the rear face; a second MEMS scanner configured to scan in the second direction of the FOV; and a second quarter wave plate having an optical axis that is parallel to front and rear faces of the second quarter wave plate, the second MEMS scanner being disposed proximate to the front face and the polarizing beam splitter being disposed proximate to the rear face, wherein image light from an imager incident on the polarizing beam splitter propagates to each of the first and second MEMS scanners in succession so that the image light exits the polarizing beam splitter and is in-coupled into the waveguide display over the extent of the FOV as the first and second MEMS scanners are operated. 2. The near-eye optical display system of claim 1 in which the FOV is rectangular and each of the first and second MEMS scanners have a single scanning axis, and wherein the single scanning axis of the first MEMS scanner is orthogonal to the single scanning axis of the second MEMS scanner, and the first and second MEMS scanners are operated to perform raster scanning. 3. The near-eye optical display system of claim 1 in which the waveguide display further includes at least one intermediate DOE and an out-coupling DOE, wherein the one intermediate DOE provides exit pupil expansion in a first direction of the FOV and the out-coupling DOE provides exit pupil expansion in the second direction of the FOV. 4. The near-eye optical display system of claim 1 in which a propagation path of the image light in the near-eye optical display system includes two passes through each of the first and second quarter wave plates and wherein the image light changes its state of polarization after completion of each of the two passes. 5. The near-eye optical display system of claim 4 in which the image light is polarized in the first polarization state when incident on the polarizing beam splitter. 6. The near-eye optical display system of claim 1 in which one or more of the first and second MEMS scanners are operated resonantly. 7. A head mounted display (HMD) device configured to display images within a field of view (FOV) having first and second directions, comprising: a polarization beam splitter (PBS) cube having twelve edges and six faces including an entrance face and an exit face, the entrance and exit faces sharing a common edge, the PBS cube configured to reflect propagating image light having a first polarization state orthogonally to a direction of propagation and further configured to transmit image light having a second polarization state parallel to the direction of propagation; an in-coupling diffractive optical element (DOE) in a waveguide display that provides exit pupil expansion in the first and second directions of the FOV, the in-coupling DOE located adjacent to the exit face of the PBS cube; a first quarter wave plate located adjacent to a face of the PBS cube that is opposite the entrance face; a second quarter wave plate located adjacent to a face of the PBS cube that is opposite the exit face; a first MEMS (micro electro mechanical system) scanner having a reflective scanning plate and configured to scan in the first direction of the FOV, the first MEMS scanner located adjacent to the first quarter wave plate; and a second MEMS scanner having a reflective scanning plate and configured to scan in the second direction of the FOV, the second MEMS scanner located adjacent to the second quarter wave plate. 8. The HMD device of claim 7 wherein image light entering the entrance face passes through the PBS cube, makes a first pass through the first quarter wave plate, is reflected by the first MEMS scanner, makes a second pass through the first quarter wave plate, is reflected by the PBS cube towards the face opposite the exit face, makes a first pass through the second quarter wave plate, is reflected by the second MEMS scanner towards the exit face, makes a second pass through the second quarter wave plate, is passed through the PBS cube, exits the exit face to be in-coupled by the in-coupling DOE to the waveguide display. 9. The HMD device of claim 8 wherein the image light is generated by an imager comprising one or more lasers and the image light is in the second state of polarization when incident upon the entrance face of the PBS cube. 10. The HMD device of claim 7 wherein the first and second MEMS scanners are operated in combination to provide raster scanning through a fast axis and a slow axis. 11. The HMD device of claim 7 wherein the waveguide display includes at least one intermediate DOE configured to provide exit pupil expansion in the first direction and at least one out-coupling DOE configured to provide exit pupil expansion in the second direction and out-couple the image light from the waveguide display to an eye of an HMD device user. 12. The HMD device of claim 7 in which the image light enters the entrance face of the PBS cube in a direction that is parallel to a plane of the in-coupling DOE. 13. A device configured to control image light associated with virtual images within a field of view (FOV), comprising: an imager configured to produce the image light; a waveguide display including a polarization-sensitive in-coupling diffractive optical element (DOE) configured to in-couple image light into the waveguide display or transmit image light according to a state of polarization of the image light, at least one intermediate DOE configured to expand an exit pupil of the image light in a first direction of the FOV, and an out-coupling DOE configured to expand the exit pupil of the image light in a second direction of the FOV and further configured to out-couple image light out of the waveguide display to an eye of a user of the device; a pair of MEMS (micro electro mechanical system) scanners operatively coupled to perform raster scanning of the virtual images in the FOV using the image light from the imager, the MEMS scanners further providing the image light to the in-coupling DOE in the waveguide display; and a polarizing beam splitter device configured to direct image light to either a first MEMS scanner in the pair or a second MEMS scanner in the pair according to a state of polarization of the image light. 14. The device of claim 13 in which the polarizing beam splitter device includes a polarizing beam splitting cube comprising two right angle prisms joined along a plane defined by each prism's hypotenuse, the plane including a polarization-sensitive material configured to reflect or transmit image light based on the state of polarization, in which the reflected image light and transmitted image light have an orthogonal separation and the pair of MEMS scanners are respectively located with respe