DreamPrinting: Volumetric Printing Primitives for High-Fidelity 3D Printing

1ShanghaiTech University, 2LumiAni Technology, 3Kyoto University
DreamPrinting Teaser

We present DreamPrinting, a novel 3D volumetric printing pipeline that precisely assigns pigment labels at the voxel level, enabling the reproduction of complex visual effects with remarkable realism.

Abstract

Translating the rich visual fidelity of volumetric rendering techniques into physically realizable 3D prints remains an open challenge. We introduce DreamPrinting, a novel pipeline that transforms radiance-based volumetric representations into explicit, material-centric Volumetric Printing Primitives (VPPs).

While volumetric rendering primitives (e.g., NeRF) excel at capturing intricate geometry and appearance, they lack the physical constraints necessary for real-world fabrication, such as pigment compatibility and material density. DreamPrinting addresses these challenges by integrating the Kubelka-Munk model with a spectrophotometric calibration process to characterize and mix pigments for accurate reproduction of color and translucency. The result is a continuous-to-discrete mapping that determines optimal pigment concentrations for each voxel, ensuring fidelity to both geometry and optical properties. A 3D stochastic halftoning procedure then converts these concentrations into printable labels, enabling fine-grained control over opacity, texture, and color gradients.

Our evaluations show that DreamPrinting achieves exceptional detail in reproducing semi-transparent structures—such as fur, leaves, and clouds—while outperforming traditional surface-based methods in managing translucency and internal consistency. Furthermore, by seamlessly integrating VPPs with cutting-edge 3D generation techniques, DreamPrinting expands the potential for complex, high-quality volumetric prints, providing a robust framework for printing objects that closely mirror their digital origins.

DreamPrinting Pipeline

Results

3D printing objects from InstantNGP radiance reconstruction

From left to right: the original images, the 2D images rendering from the radiance reconstruction, and the corresponding 3D printing results.

Artist-made OpenVDB assets

From left to right: the original volumetric representation, and the corresponding 3D printing results.

Printings of radiance models generated by TRELLIS

From left to right: the prompt image, the generated radiance fields (RF), and the corresponding 3D-printed results.

BibTeX

@inproceedings{10.1145/3721257.3734025,
      author = {Wang, Youjia and Cao, Ruixiang and Xu, Teng and Liu, Yifei and Zhang, Dong and Wu, Yiwen and Yu, Jingyi},
      title = {DreamPrinting: Volumetric Printing Primitives for High-Fidelity 3D Printing},
      year = {2025},
      isbn = {9798400715518},
      publisher = {Association for Computing Machinery},
      address = {New York, NY, USA},
      url = {https://doi.org/10.1145/3721257.3734025},
      doi = {10.1145/3721257.3734025},
      series = {SIGGRAPH '25}
      }