Litcius/Paper detail

Framework for optimizing AR waveguide in-coupler architectures

Jeremy Goodsell, Daniel K. Nikolov, A. Nick Vamivakas, Jannick P. Rolland

2024Optics Express10 citationsDOIOpen Access PDF

Abstract

Waveguide displays have been shown to exhibit multiple interactions of light at the in-coupler diffractive surface, leading to light loss. Any losses at the in-coupler set a fundamental upper limit on the full-system efficiency. Furthermore, these losses vary spatially across the beam for each field, significantly decreasing the displayed image quality. We present a framework for alleviating the losses based on irradiance, efficiency, and MTF maps. We then derive and quantify the innate tradeoff between the in-coupling efficiency and the achievable modulation transfer function (MTF) characterizing image quality. Applying the framework, we show a new in-coupler architecture that mitigates the efficiency vs image quality tradeoff. In the example architecture, we demonstrate a computation speed that is 2,000 times faster than that of a commercial non-sequential ray tracer, enabling faster optimization and more thorough exploration of the parameter space. Results show that with this architecture, the in-coupling efficiency still meets the fundamental limit, while the MTF achieves the diffraction limit up to and including 30 cycles/deg, equivalent to 20/20 vision.

Topics & Concepts

Optical transfer functionOpticsImage qualityLimit (mathematics)WaveguideComputer scienceDiffraction efficiencyDiffractionPhysicsComputationCoupling (piping)Modulation (music)Image (mathematics)AlgorithmMaterials scienceArtificial intelligenceAcousticsMathematicsMathematical analysisMetallurgyAdvanced Optical Imaging TechnologiesPhotonic and Optical DevicesSemiconductor Lasers and Optical Devices