Prediction of progressive lens performance from neural network
simulations
- URL: http://arxiv.org/abs/2103.10842v1
- Date: Fri, 19 Mar 2021 14:51:02 GMT
- Title: Prediction of progressive lens performance from neural network
simulations
- Authors: Alexander Leube, Lukas Lang, Gerhard Kelch and Siegfried Wahl
- Abstract summary: The purpose of this study is to present a framework to predict visual acuity (VA) based on a convolutional neural network (CNN)
The proposed holistic simulation tool was shown to act as an accurate model for subjective visual performance.
- Score: 62.997667081978825
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Purpose: The purpose of this study is to present a framework to predict
visual acuity (VA) based on a convolutional neural network (CNN) and to further
to compare PAL designs.
Method: A simple two hidden layer CNN was trained to classify the gap
orientations of Landolt Cs by combining the feature extraction abilities of a
CNN with psychophysical staircase methods. The simulation was validated
regarding its predictability of clinical VA from induced spherical defocus
(between +/-1.5 D, step size: 0.5 D) from 39 subjectively measured eyes.
Afterwards, a simulation for a presbyopic eye corrected by either a generic
hard or a soft PAL design (addition power: 2.5 D) was performed including lower
and higher order aberrations.
Result: The validation revealed consistent offset of +0.20 logMAR +/-0.035
logMAR from simulated VA. Bland-Altman analysis from offset-corrected results
showed limits of agreement (+/-1.96 SD) of -0.08 logMAR and +0.07 logMAR, which
is comparable to clinical repeatability of VA assessment. The application of
the simulation for PALs confirmed a bigger far zone for generic hard design but
did not reveal zone width differences for the intermediate or near zone.
Furthermore, a horizontal area of better VA at the mid of the PAL was found,
which confirms the importance for realistic performance simulations using
object-based aberration and physiological performance measures as VA.
Conclusion: The proposed holistic simulation tool was shown to act as an
accurate model for subjective visual performance. Further, the simulations
application for PALs indicated its potential as an effective method to compare
visual performance of different optical designs. Moreover, the simulation
provides the basis to incorporate neural aspects of visual perception and thus
simulate the VA including neural processing in future.
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