Fraunhofer IGD - SIGGRAPH 2021: Rapid Prototyping in 3D Printing: New Pipeline Brings Increased Efficiency and Robustness

DARMSTADT, Germany, Aug. 11, 2021 /PRNewswire/ -- A new technique is increasing the efficiency of 3D printing at native device resolution, especially with multi-material jetting, aka Polyjet, printers. With the Cuttlefish^® 3D printer driver, even the finest textures can be reproduced with efficiency and robustness at reduced file size - a decisive factor in any large print job. The results will be presented at SIGGRAPH 2021.

The level of resolution and accuracy achieved by the hardware in the current generation of 3D printers allows for ever more realistic reproduction of surfaces. At the same time, factors such as file size, transmission and processing time add a further layer of complexity. This is due to the high number of polygons needed to approximate the desired surface, especially for large print sizes.

Researchers of the 3D Printing Technology team at Fraunhofer IGD recently published a paper - Displaced Signed Distance Fields for Additive Manufacturing - proposing a solution to this dilemma. The clever thing about the technique is the way it splits the surface representation into macroscopic and mesoscopic parts, and uses the latter to reproduce both fine-scale surface detail and smoothly curved surfaces. This results in an efficiency advantage that increases with scaling, especially for large print jobs, compared to refining the surface tessellation using flat primitives. The paper was accepted to SIGGRAPH 2021, the most prestigious event for computer graphics. The conference will be held virtually August 9-13, the paper will be presented August 13, 12 p.m. - 1 p.m. PDT. The solutions presented in the paper have already found an application in the Cuttlefish^® 3D printer driver.

The new method in detail

At the heart of the algorithms described are so-called "displaced signed distance fields", which augment the near ubiquitous signed distance field representation with a displacement field, specifying the offset from the input approximation to the true surface. This implicitly encodes smoothly curved or fine-detailed surfaces with respect to a coarse tessellation. For 3D printing, the models generated by human operators or by a scanning pipeline must be converted into polygon meshes. For a fixed print size, a fixed number of polygons suffices to print the object at the precision of the printer, but for larger print sizes, they must more finely tessellated, potentially with many more polygons.

The example of a plain sphere illustrates the problem: the printed sphere may appear round with a certain number of polygons, but if the object is printed larger with the same polygon mesh, the sphere no longer appears round. Displaced signed distance fields encode the difference between the piecewise flat input mesh and the true surface of the sphere, at the precision of the 3D printer.

Displaced signed distance fields represent the surface of the shape implicitly, allowing for volumetric regularization of the implicit function and robust computation from incomplete or self-overlapping surface data. This is especially relevant in 3D printing, as information processed in situ cannot be corrected. The new algorithms of the Cuttlefish^® 3D printer driver thus facilitate highly detailed and smooth surfaces from low-poly meshes, in a robust, streaming compatible approach.

The entire paper together with supplemental material can be found at: https://www.cuttlefish.de/publications

Fraunhofer IGD at SIGGRAPH 2021

August 13 / 12 p.m. - 1 p.m. PDT

The conference will be held virtually

About Fraunhofer IGD: Founded in 1987, the Fraunhofer Institute for Computer Graphics Research IGD is the world's leading institute for applied research in visual computing computer science based on images and 3D models. We turn information into images and images into information. Keywords are human-machine interaction, virtual and augmented reality, artificial intelligence, interactive simulation, modeling, 3D printing and 3D scanning. Around 180 researchers at three locations in Darmstadt, Rostock and Kiel in Germany develop new technology solutions and prototypes for industry 4.0, digital healthcare and the smart city. In cooperation with its sister institutes in Graz, Austria and in Singapore, they also take on international relevance. With an annual research volume of €21 million, we use applied research to help in the strategic development of industry and the economy.

Press Contact: 
Daniela Welling | Head of Corporate Communications
Fraunhofer Institute for Computer Graphics Research IGD
Fraunhoferstraße 5 | 64283 Darmstadt/Germany
Phone: +49 6151-155-146 | [email protected] | https://www.igd.fraunhofer.de

Related Images

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Fraunhofer IGD
A texture-mapped teapot with and without the use of a displacement map to add fine-scale geometry. The increased visual realism comes with a small increase in the total storage. ((c) Fraunhofer IGD)

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