3 papers accepted at NeurIPS ‘23

21 September 2023

Our latest work achieves state-of-the-art predictions of primary visual cortex (V1) activity in mouse and monkey, and details a new way to optimize stimulation protocols for visual prostheses.

Towards a Smart Bionic Eye

4 October 2022

Prof. Beyeler receives $1.5 million NIH Director’s New Innovator award to enable an artificial intelligence (AI)-powered visual prosthesis.

A hybrid neural autoencoder to enhance sensory neuroprostheses

21 June 2022

Our approach to end-to-end optimization of bionic vision was featured in a news article by TechXplore.

Are we witnessing the dawn of post-theory science?

9 January 2022

Prof. Beyeler was mentioned in a recent article by The Guardian that discusses recent advances in machine learning and what data-driven discovery means for the classic methodology of hypothesizing, predicting, and testing.

Illustration: © PM Images/Getty

PCMag: Building the bionic eye… with car tech?

23 February 2021

Interview with Prof. Beyeler: Instead of focusing on one day restoring natural vision, we may be better off thinking about how to create useful artificial vision now.

Illustration: © Yuichiro Chino/Getty

All news articles

More media coverage can be found in our news archive.

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Who We Are

We are an interdisciplinary group interested in the computational modeling of human, animal, computer, and prosthetic vision to elucidate the science behind bionic technologies that may one day restore useful vision to people living with incurable blindness.

Our group combines expertise in computer science/engineering, neuroscience, and psychology. All our team members are computationally minded and have a keen interest in vision and medical applications. Our research projects range from predicting neurophysiological data with deep learning to building biophysical models of electrical brain stimulation, and from studying perception in people with visual impairment to developing prototypes of novel visual accessibility aids using virtual and augmented reality.

Importantly, our ongoing collaborations with several visual prosthesis manufacturers put our laboratory in a unique position to empirically validate our theoretical findings across multiple bionic eye technologies.

Brain Sciences

Vision Sciences

Brain-Computer Devices

Recent Publications

We systematically incorporated neuroscience-derived architectural components into CNNs to identify a set of mechanisms and architectures that comprehensively explain neural activity in V1.

We propose a personalized stimulus encoding strategy that combines state-of-the-art deep stimulus encoding with preferential Bayesian optimization.

We introduce a multimodal recurrent neural network that integrates gaze-contingent visual input with behavioral and temporal dynamics to explain V1 activity in freely moving mice.

We present a biophysically detailed in silico model of retinal degeneration that simulates the network-level response to both light and electrical stimulation as a function of disease progression.

We present a systematic literature review of 227 publications from 106 different venues assessing the potential of XR technology to further visual accessibility.

We present a SNN model that uses spike-latency coding and winner-take-all inhibition to efficiently represent visual objects with as little as 15 spikes per neuron.

We show that a neurologically-inspired decoding of CNN activations produces qualitatively accurate phosphenes, comparable to phosphenes reported by real patients.

We used a neurobiologically inspired model of simulated prosthetic vision in an immersive virtual reality environment to test the relative importance of semantic edges and relative depth cues to support the ability to avoid obstacles and identify objects.

We present VR-SPV, an open-source virtual reality toolbox for simulated prosthetic vision that uses a psychophysically validated computational model to allow sighted participants to ‘see through the eyes’ of a bionic eye user.

We combined deep learning-based scene simplification strategies with a psychophysically validated computational model of the retina to generate realistic predictions of simulated prosthetic vision.

Gallery

001 prof

001 prof

002 byron johnson presenting at vss

002 byron johnson presenting at vss

003 argus ii user drawing a perceived phosphene on a touchscreen in front of him

003 argus ii user drawing a perceived phosphene on a touchscreen in front of him

004 group picture of the bvl team at the eye and the chip 2023

004 group picture of the bvl team at the eye and the chip 2023

005 prof

005 prof

006 prof

006 prof

007 prof

007 prof

008 blind participant using a smartphone app to read the label on a jar of mayonnaise

008 blind participant using a smartphone app to read the label on a jar of mayonnaise

009 jacob granley in front of his poster at neur IP s 2022

009 jacob granley in front of his poster at neur IP s 2022

010 justin kasowski presenting his work on simple xr at vss 2023

010 justin kasowski presenting his work on simple xr at vss 2023

011 apurv varshney presenting his work on stressful navigation at vss 2023

011 apurv varshney presenting his work on stressful navigation at vss 2023

012 prof

012 prof

013 MAC and cheese trophy given to first place winner lily turkstra at the lab's first competitive MAC and cheese cookoff

013 MAC and cheese trophy given to first place winner lily turkstra at the lab's first competitive MAC and cheese cookoff

014 group picture of the bvl team at the MAC and cheese cookoff

014 group picture of the bvl team at the MAC and cheese cookoff

015 bvl team members enjoying a cake to celebrate their successful neur IP s submissions

015 bvl team members enjoying a cake to celebrate their successful neur IP s submissions

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