Immersive VR applications demand high resolutions and refresh rates, posing significant challenges for real-time rendering. Foveated rendering mitigates this cost by exploiting properties of the Human Visual System (HVS), but conventional approaches often rely on oversimplified heuristic models that neglect high-level attentional cues, resulting in artifacts in peripheral regions. To this end, we present a neural saliency-driven foveated ray tracing framework that overcomes these limitations. Our method introduces a motion-aware foveation model to capture temporal dynamics and employs a lightweight convolutional neural network to predict saliency maps that reflect complex attentional patterns derived from eye-gaze data. The combination of these guides adaptive path tracing and filtering, enabling perceptually optimized rendering with minimal artifacts. Experimental results show that our approach improves perceptual quality over prior methods while sustaining real-time performance.
Gao et al. (Thu,) studied this question.
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