English

Training-Free Stimulus Encoding for Retinal Implants via Sparse Projected Gradient Descent

Image and Video Processing 2026-02-12 v1

Abstract

Retinal implants aim to restore functional vision despite photoreceptor degeneration, yet are fundamentally constrained by low resolution electrode arrays and patient-specific perceptual distortions. Most deployed encoders rely on task-agnostic downsampling and linear brightness-to-amplitude mappings, which are suboptimal under realistic perceptual models. While global inverse problems have been formulated as neural networks, such approaches can be fast at inference, and can achieve high reconstruction fidelity, but require training and have limited generalizability to arbitrary inputs. We cast stimulus encoding as a constrained sparse least-squares problem under a linearized perceptual forward model. Our key observation is that the resulting perception matrix can be highly sparse, depending on patient and implant configuration. Building on this, we apply an efficient projected residual norm steepest descent solver that exploits sparsity and supports stimulus bounds via projection. In silico experiments across four simulated patients and implant resolutions from 15×1515\times15 to 100×100100\times100 electrodes demonstrate improved reconstruction fidelity, with up to +0.265+0.265 SSIM increase, +12.4dB+12.4\,\mathrm{dB} PSNR, and 81.4%81.4\% MAE reduction on Fashion-MNIST compared to Lanczos downsampling.

Keywords

Cite

@article{arxiv.2602.10906,
  title  = {Training-Free Stimulus Encoding for Retinal Implants via Sparse Projected Gradient Descent},
  author = {Henning Konermann and Yuli Wu and Emil Mededovic and Volkmar Schulz and Peter Walter and Johannes Stegmaier},
  journal= {arXiv preprint arXiv:2602.10906},
  year   = {2026}
}

Comments

This work has been submitted to the IEEE for possible publication

R2 v1 2026-07-01T10:31:58.502Z