We present an accommodation-invariant computational neareye display based on the extended depth of field imaging. The eyepiece of the display consists of a diffractive optical element (DOE) that is used in tandem with a conventional refractive lens. The DOE is co-designed with the pre-processing convolutional neural network, which is analogous to the post-processing deblurring networks in image capture. We demonstrate through simulations that such system achieves accommodation-invariant imaging within 2 Diopters depth range without significantly sacrificing spatial resolution.Peer reviewe
See-through near-eye displays with the form factor and field of view of eyeglasses are a natural cho...
Near-eye displays (NEDs) for augmented and virtual reality (AR/VR) are spotlighted because they have...
From consumer electronics to biomedical applications, device miniaturization has shown to be highly ...
We present a computational accommodation-invariant near-eye display, which relies on imaging with co...
We present a multifocal computational near-eye display that employs a static diffractive optical ele...
Although emerging virtual and augmented reality (VR/AR) systems can produce highly immersive experie...
We present a computational imaging approach, combining a phase-coded computational camera with a cor...
Computational accommodation-invariant (AI) display attempts to mitigate vergence-accommodation confl...
Diffractive optical elements (DOEs) have been studied extensively in optics for decades, but have re...
Near-eye displays (NEDs) are an excellent candidate for the future of augmented reality. Conventiona...
Unwanted camera obstruction can severely degrade captured images, including both scene occluders nea...
Depth of field is an important factor of imaging systems that highly affects the quality of the acqu...
High-resolution synthesis/projection of images over a large field-of-view (FOV) is hindered by the r...
Recent advances in camera technology, computing hardware, and optical fabrication have led to the em...
International audienceIn computational imaging by digital holography, lateral resolution of retinal ...
See-through near-eye displays with the form factor and field of view of eyeglasses are a natural cho...
Near-eye displays (NEDs) for augmented and virtual reality (AR/VR) are spotlighted because they have...
From consumer electronics to biomedical applications, device miniaturization has shown to be highly ...
We present a computational accommodation-invariant near-eye display, which relies on imaging with co...
We present a multifocal computational near-eye display that employs a static diffractive optical ele...
Although emerging virtual and augmented reality (VR/AR) systems can produce highly immersive experie...
We present a computational imaging approach, combining a phase-coded computational camera with a cor...
Computational accommodation-invariant (AI) display attempts to mitigate vergence-accommodation confl...
Diffractive optical elements (DOEs) have been studied extensively in optics for decades, but have re...
Near-eye displays (NEDs) are an excellent candidate for the future of augmented reality. Conventiona...
Unwanted camera obstruction can severely degrade captured images, including both scene occluders nea...
Depth of field is an important factor of imaging systems that highly affects the quality of the acqu...
High-resolution synthesis/projection of images over a large field-of-view (FOV) is hindered by the r...
Recent advances in camera technology, computing hardware, and optical fabrication have led to the em...
International audienceIn computational imaging by digital holography, lateral resolution of retinal ...
See-through near-eye displays with the form factor and field of view of eyeglasses are a natural cho...
Near-eye displays (NEDs) for augmented and virtual reality (AR/VR) are spotlighted because they have...
From consumer electronics to biomedical applications, device miniaturization has shown to be highly ...