Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing
Digital light processing (DLP) is a widely used additive manufacturing technique for functional applications due to its high accuracy and print speeds. However, a variety of factors such as pixel size, motion stage resolution, optical focus, and chemical properties of the resin limit DLP's mini...
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sg-ntu-dr.10356-1706592023-09-25T05:14:56Z Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing Montgomery, S. Macrae Demoly, Frederic Zhou, Kun Qi, H. Jerry School of Mechanical and Aerospace Engineering Singapore Centre for 3D Printing Engineering::Mechanical engineering Additive Manufacturing Digital Light Processing Digital light processing (DLP) is a widely used additive manufacturing technique for functional applications due to its high accuracy and print speeds. However, a variety of factors such as pixel size, motion stage resolution, optical focus, and chemical properties of the resin limit DLP's minimum resolution. Recently, research into locally varying light intensities has led to the emergence of grayscale DLP printing, which offers new capabilities including sub-pixel manipulation of the printed shape. Here, a methodology is developed to enhance accuracy beyond what is typically capable for a given projector resolution by using pixel-level grayscale control to create round features from sharp pixels. A numerical representation of the DLP pixel shape is developed to account for the effects of the incident light patterns. A reaction-diffusion model is then used to predict the printed shapes before and after grayscale enhancement. This model is used to determine the optimal pixel intensities to match a target shape. Finally, the minimum feature size allowed by the proposed method is explored. The promising results represent an important step forward in raising DLP printing to higher accuracy, which will allow the fabrication of functional and structural components with smaller features or smoother faces. The support of Air Force Office of Scientific Research (AFOSR) grant (A9550-20-1-0306; Dr. B.-L. "Les" Lee, Program Manager) is gratefully acknowledged. Gift funds from HP, Inc and Northrop Grumman Corporation are also greatly appreciated. 2023-09-25T05:14:56Z 2023-09-25T05:14:56Z 2023 Journal Article Montgomery, S. M., Demoly, F., Zhou, K. & Qi, H. J. (2023). Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing. Advanced Functional Materials, 33(17), 2213252-. https://dx.doi.org/10.1002/adfm.202213252 1616-301X https://hdl.handle.net/10356/170659 10.1002/adfm.202213252 2-s2.0-85148038780 17 33 2213252 en Advanced Functional Materials © 2023 Wiley-VCH GmbH. All rights reserved. |
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Engineering::Mechanical engineering Additive Manufacturing Digital Light Processing Montgomery, S. Macrae Demoly, Frederic Zhou, Kun Qi, H. Jerry Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing |
| description |
Digital light processing (DLP) is a widely used additive manufacturing technique for functional applications due to its high accuracy and print speeds. However, a variety of factors such as pixel size, motion stage resolution, optical focus, and chemical properties of the resin limit DLP's minimum resolution. Recently, research into locally varying light intensities has led to the emergence of grayscale DLP printing, which offers new capabilities including sub-pixel manipulation of the printed shape. Here, a methodology is developed to enhance accuracy beyond what is typically capable for a given projector resolution by using pixel-level grayscale control to create round features from sharp pixels. A numerical representation of the DLP pixel shape is developed to account for the effects of the incident light patterns. A reaction-diffusion model is then used to predict the printed shapes before and after grayscale enhancement. This model is used to determine the optimal pixel intensities to match a target shape. Finally, the minimum feature size allowed by the proposed method is explored. The promising results represent an important step forward in raising DLP printing to higher accuracy, which will allow the fabrication of functional and structural components with smaller features or smoother faces. |
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School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Montgomery, S. Macrae Demoly, Frederic Zhou, Kun Qi, H. Jerry |
| format |
Article |
| author |
Montgomery, S. Macrae Demoly, Frederic Zhou, Kun Qi, H. Jerry |
| author_sort |
Montgomery, S. Macrae |
| title |
Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing |
| title_short |
Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing |
| title_full |
Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing |
| title_fullStr |
Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing |
| title_full_unstemmed |
Pixel-level grayscale manipulation to improve accuracy in digital light processing 3D printing |
| title_sort |
pixel-level grayscale manipulation to improve accuracy in digital light processing 3d printing |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/170659 |
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1779156684267061248 |