Neural Slicer for Multi-Axis 3D Printing

Tao Liu; Tianyu Zhang; Yongxue Chen; Yuming Huang; Charlie C.L. Wang

doi:10.1145/3658212

Neural Slicer for Multi-Axis 3D Printing

Tao Liu, Tianyu Zhang, Yongxue Chen, Yuming Huang, Charlie C.L. Wang^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

We introduce a novel neural network-based computational pipeline as a representation-agnostic slicer for multi-axis 3D printing. This advanced slicer can work on models with diverse representations and intricate topology. The approach involves employing neural networks to establish a deformation mapping, defining a scalar field in the space surrounding an input model. Isosurfaces are subsequently extracted from this field to generate curved layers for 3D printing. Creating a differentiable pipeline enables us to optimize the mapping through loss functions directly defined on the field gradients as the local printing directions. New loss functions have been introduced to meet the manufacturing objectives of support-free and strength reinforcement. Our new computation pipeline relies less on the initial values of the field and can generate slicing results with significantly improved performance.

Original language	English
Article number	85
Journal	ACM Transactions on Graphics
Volume	43
Issue number	4
DOIs	https://doi.org/10.1145/3658212
Publication status	Published - 19 Jul 2024

Keywords

3D printing
curved slicing
field optimization
multi-axis motion
neural network

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abstract = "We introduce a novel neural network-based computational pipeline as a representation-agnostic slicer for multi-axis 3D printing. This advanced slicer can work on models with diverse representations and intricate topology. The approach involves employing neural networks to establish a deformation mapping, defining a scalar field in the space surrounding an input model. Isosurfaces are subsequently extracted from this field to generate curved layers for 3D printing. Creating a differentiable pipeline enables us to optimize the mapping through loss functions directly defined on the field gradients as the local printing directions. New loss functions have been introduced to meet the manufacturing objectives of support-free and strength reinforcement. Our new computation pipeline relies less on the initial values of the field and can generate slicing results with significantly improved performance.",

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AB - We introduce a novel neural network-based computational pipeline as a representation-agnostic slicer for multi-axis 3D printing. This advanced slicer can work on models with diverse representations and intricate topology. The approach involves employing neural networks to establish a deformation mapping, defining a scalar field in the space surrounding an input model. Isosurfaces are subsequently extracted from this field to generate curved layers for 3D printing. Creating a differentiable pipeline enables us to optimize the mapping through loss functions directly defined on the field gradients as the local printing directions. New loss functions have been introduced to meet the manufacturing objectives of support-free and strength reinforcement. Our new computation pipeline relies less on the initial values of the field and can generate slicing results with significantly improved performance.

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Neural Slicer for Multi-Axis 3D Printing

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