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Creators/Authors contains: "Attal, Benjamin"

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  1. ; ; ; ; ; (, ECCV)
    Accepted Manuscript Full Text Available
  2. ; ; ; ; ; (, European Conference on Computer Vision)
    Accepted Manuscript Full Text Available
  3. ; ; ; ; ; ; (, ECCV)
    Accepted Manuscript Full Text Available
  4. ; ; ; ; (, IEEE)
  5. ; (, IEEE Transactions on Pattern Analysis and Machine Intelligence)
    Full Text Available 
  6. ; ; ; ; ; ; (, IEEE Conference on Computer Vision and Pattern Recognition)
    Accepted Manuscript Full Text Available
  7. ; ; ; ; ; ; (, Advances in neural information processing systems)
    Neural networks can represent and accurately reconstruct radiance fields for static 3D scenes (e.g., NeRF). Several works extend these to dynamic scenes captured with monocular video, with promising performance. However, the monocular setting is known to be an under-constrained problem, and so methods rely on data-driven priors for reconstructing dynamic content. We replace these priors with measurements from a time-of-flight (ToF) camera, and introduce a neural representation based on an image formation model for continuous-wave ToF cameras. Instead of working with processed depth maps, we model the raw ToF sensor measurements to improve reconstruction quality and avoid issues with low reflectance regions, multi-path interference, and a sensor's limited unambiguous depth range. We show that this approach improves robustness of dynamic scene reconstruction to erroneous calibration and large motions, and discuss the benefits and limitations of integrating RGB+ToF sensors that are now available on modern smartphones. 
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    Accepted Manuscript Full Text Available
  8. ; ; ; ; ; ; (, Advances in neural information processing systems)
    Neural networks can represent and accurately reconstruct radiance fields for static 3D scenes (e.g., NeRF). Several works extend these to dynamic scenes captured with monocular video, with promising performance. However, the monocular setting is known to be an under-constrained problem, and so methods rely on data-driven priors for reconstructing dynamic content. We replace these priors with measurements from a time-of-flight (ToF) camera, and introduce a neural representation based on an image formation model for continuous-wave ToF cameras. Instead of working with processed depth maps, we model the raw ToF sensor measurements to improve reconstruction quality and avoid issues with low reflectance regions, multi-path interference, and a sensor's limited unambiguous depth range. We show that this approach improves robustness of dynamic scene reconstruction to erroneous calibration and large motions, and discuss the benefits and limitations of integrating RGB+ToF sensors now available on modern smartphones. 
    more » « less
    Accepted Manuscript Full Text Available