Abstract
Prosthetic vision is being applied to partially recover the retinal stimulation of visually impaired people. However, the phosphenic images produced by the implants have very limited information bandwidth due to the poor resolution and lack of color or contrast. The ability of object recognition and scene understanding in real environments is severely restricted for prosthetic users. Computer vision can play a key role to overcome the limitations and to optimize the visual information in the prosthetic vision, improving the amount of information that is presented. We present a new approach to build a schematic representation of indoor environments for simulated phosphene images. The proposed method combines a variety of convolutional neural networks for extracting and conveying relevant information about the scene such as structural informative edges of the environment and silhouettes of segmented objects. Experiments were conducted with normal sighted subjects with a Simulated Prosthetic Vision system. The results show good accuracy for object recognition and room identification tasks for indoor scenes using the proposed approach, compared to other image processing methods.
Highlights
Retinal degenerative diseases such as retinitis pigmentosa and age-related macular degeneration cause loss of vision due to the gradual degeneration of the sensory cells in the retina [1, 2]
We evaluate and compare the proposed semantic and structural image segmentation with baseline methods through a Simulated Prosthetic Vision (SPV) experiment, which is a standard procedure for non-invasive evaluation using normal vision subjects [19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36]
We compared structural informative edges (SIE)-object masks and silhouettes (OMS) with two baseline methods used in retinal prothesis: a) a direct method that converts the input image directly to the phosphene map by averaging the brightness on the region covered by each phosphene, and b) a standard edge detector to extract brightness contours
Summary
Retinal degenerative diseases such as retinitis pigmentosa and age-related macular degeneration cause loss of vision due to the gradual degeneration of the sensory cells in the retina [1, 2]. Retinal prostheses are currently the most promising technology to improve vision in patients with such advanced degenerative diseases [3,4,5,6]. These devices elicit visual perception by electrically stimulating retina cells. Current retinal prosthetic devices are limited to hundreds of electrical receptors, which produce a very limited visual elicitation [10,11,12].
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