Abstract: A diffractive beam expander for use in an augmented-reality display is disclosed. The device can include a optical substrate with a first diffractive optical element having a first diffractive grating disposed on one surface and a second diffractive grating disposed on the opposing surface. Portions of the first and second diffractive gratings overlap to define an in-coupling area configured to receive a beam of incoming light. The first diffractive optical element expands at least part of the received light beam by odd-order diffraction expansion in a first region and a second region and expands at least part of the received light beam by even-order diffraction expansion in a third region. The light components by the first diffractive optical element are then coupled into a second diffractive optical element, which is configured to out-couple at least part of the expanded diffracted light components to exit the substrate by diffraction.

Abstract: Lightweight, compact, and cost-efficient solutions for increasing the exit pupil size for use in laser-scanner and waveguide based augmented-reality displays are disclosed. Light from a laser-scanner is focused onto intermediate image plane; a diffuser is positioned at the intermediate image plane to steer light efficiently in a desired direction; the pupil is then expanded with a lens assembly; the lens assembly can contain one or more aspherical and/or free-form optics; the output of the lens assembly can then act as the input to a waveguide plate or stack; and the result is a large field-of-view image with sufficiently large exit pupil to overcome/reduce the pupil-replication problem.

Abstract: A diffractive beam expander for use in an augmented-reality display is disclosed. The device can include a optical substrate with a first diffractive optical element having a first diffractive grating disposed on one surface and a second diffractive grating disposed on the opposing surface. Portions of the first and second diffractive gratings overlap to define an in-coupling area configured to receive a beam of incoming light. The first diffractive optical element expands at least part of the received light beam by odd-order diffraction expansion in a first region and a second region and expands at least part of the received light beam by even-order diffraction expansion in a third region. The light components by the first diffractive optical element are then coupled into a second diffractive optical element, which is configured to out-couple at least part of the expanded diffracted light components to exit the substrate by diffraction.