Related papers: An Artificial-intelligence/Statistics Solution to Quantify Material Distortion for Thermal Compensation in Additive Manufacturing

An Artificial-intelligence/Statistics Solution to Quantify Material Distortion for Thermal Compensation in Additive Manufacturing

URL: http://arxiv.org/abs/2005.09084v1
Date: Thu, 14 May 2020 20:02:47 GMT
Title: An Artificial-intelligence/Statistics Solution to Quantify Material Distortion for Thermal Compensation in Additive Manufacturing
Authors: Chao Wang, Shaofan Li, Danielle Zeng, and Xinhai Zhu
Abstract summary: We introduce a probabilistic statistics solution to identify and quantify permanent (non-zero strain) continuum/material deformation. We coined the method is an AI-based material deformation finding algorithm. This method has practical significance and important applications in finding and designing thermal compensation configuration of a 3D printed product.
Score: 4.124826613207753
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In this paper, we introduce a probabilistic statistics solution or artificial intelligence (AI) approach to identify and quantify permanent (non-zero strain) continuum/material deformation only based on the scanned material data in the spatial configuration and the shape of the initial design configuration or the material configuration. The challenge of this problem is that we only know the scanned material data in the spatial configuration and the shape of the design configuration of three-dimensional (3D) printed products, whereas for a specific scanned material point we do not know its corresponding material coordinates in the initial or designed referential configuration, provided that we do not know the detailed information on actual physical deformation process. Different from physics-based modeling, the method developed here is a data-driven artificial intelligence method, which solves the problem with incomplete deformation data or with missing information of actual physical deformation process. We coined the method is an AI-based material deformation finding algorithm. This method has practical significance and important applications in finding and designing thermal compensation configuration of a 3D printed product in additive manufacturing, which is at the heart of the cutting edge 3D printing technology. In this paper, we demonstrate that the proposed AI continuum/material deformation finding approach can accurately find permanent thermal deformation configuration for a complex 3D printed structure component, and hence to identify the thermal compensation design configuration in order to minimizing the impact of temperature fluctuations on 3D printed structure components that are sensitive to changes of temperature.

Related papers

OpenMaterial: A Comprehensive Dataset of Complex Materials for 3D Reconstruction [54.706361479680055]
We introduce the OpenMaterial dataset, comprising 1001 objects made of 295 distinct materials. OpenMaterial provides comprehensive annotations, including 3D shape, material type, camera pose, depth, and object mask. It stands as the first large-scale dataset enabling quantitative evaluations of existing algorithms on objects with diverse and challenging materials.
arXiv Detail & Related papers (2024-06-13T07:46:17Z)
Physically Compatible 3D Object Modeling from a Single Image [109.98124149566927]
We present a framework that transforms single images into 3D physical objects. Our framework embeds physical compatibility into the reconstruction process. It consistently enhances the physical realism of 3D models over existing methods.
arXiv Detail & Related papers (2024-05-30T21:59:29Z)
SphereDiffusion: Spherical Geometry-Aware Distortion Resilient Diffusion Model [63.685132323224124]
Controllable spherical panoramic image generation holds substantial applicative potential across a variety of domains. In this paper, we introduce a novel framework of SphereDiffusion to address these unique challenges. Experiments on Structured3D dataset show that SphereDiffusion significantly improves the quality of controllable spherical image generation and relatively reduces around 35% FID on average.
arXiv Detail & Related papers (2024-03-15T06:26:46Z)
S2P3: Self-Supervised Polarimetric Pose Prediction [55.43547228561919]
This paper proposes the first self-supervised 6D object pose prediction from multimodal RGB+polarimetric images. The novel training paradigm comprises 1) a physical model to extract geometric information of polarized light, 2) a teacher-student knowledge distillation scheme and 3) a self-supervised loss formulation through differentiable constraints.
arXiv Detail & Related papers (2023-12-02T10:46:40Z)
Differentiable graph-structured models for inverse design of lattice materials [0.0]
Architected materials possessing physico-chemical properties adaptable to disparate environmental conditions embody a disruptive new domain of materials science. We propose a new computational approach using graph-based representation for regular and irregular lattice materials.
arXiv Detail & Related papers (2023-04-11T18:00:21Z)
Combining Variational Autoencoders and Physical Bias for Improved Microscopy Data Analysis [0.0]
We present a physics augmented machine learning method which disentangles factors of variability within the data. Our method is applied to various materials, including NiO-LSMO, BiFeO3, and graphene. The results demonstrate the effectiveness of our approach in extracting meaningful information from large volumes of imaging data.
arXiv Detail & Related papers (2023-02-08T17:35:38Z)
Deep learning for the rare-event rational design of 3D printed multi-material mechanical metamaterials [0.0]
Multi-material 3D printing techniques have paved the way for the rational design of metamaterials. We study the resulting anisotropic mechanical properties of the network in general and the rare designs in particular. Deep learning-based algorithms can accurately predict the mechanical properties of the different designs.
arXiv Detail & Related papers (2022-04-04T18:04:23Z)
{\phi}-SfT: Shape-from-Template with a Physics-Based Deformation Model [69.27632025495512]
Shape-from-Template (SfT) methods estimate 3D surface deformations from a single monocular RGB camera. This paper proposes a new SfT approach explaining 2D observations through physical simulations.
arXiv Detail & Related papers (2022-03-22T17:59:57Z)
gradSim: Differentiable simulation for system identification and visuomotor control [66.37288629125996]
We present gradSim, a framework that overcomes the dependence on 3D supervision by leveraging differentiable multiphysics simulation and differentiable rendering. Our unified graph enables learning in challenging visuomotor control tasks, without relying on state-based (3D) supervision.
arXiv Detail & Related papers (2021-04-06T16:32:01Z)
A Compact Spectral Descriptor for Shape Deformations [0.8268443804509721]
We propose a novel methodology to obtain a parameterization of a component's plastic deformation behavior under stress. Existing parameterizations limit computational analysis to relatively simple deformations. We propose a way to derive a compact descriptor of deformation behavior based on spectral mesh processing.
arXiv Detail & Related papers (2020-03-10T10:34:30Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.