An automated CAD-to-XR framework based on generative AI and Shrinkwrap modelling for a User-Centred design approach

•Automated CAD to XR workflow for interactive Photorealistic Virtual Prototype (iPVP)•Unique texture generation module using a tailored approach based on GANs.•Shrinkwrap modelling for efficient 3D model simplification and texture UV mapping.•Significant time savings in virtual prototyping process.•...

Full description

Saved in:
Bibliographic Details
Published in:Advanced engineering informatics 2024-10, Vol.62, p.102848, Article 102848
Main Authors: Rosati, Riccardo, Senesi, Paolo, Lonzi, Barbara, Mancini, Adriano, Mandolini, Marco
Format: Article
Language:English
Subjects:
Artificial Intelligence
CAD-to-XR
Extended Reality
Generative Adversarial Networks
User-Centered Design
Virtual Prototyping
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Automated CAD to XR workflow for interactive Photorealistic Virtual Prototype (iPVP)•Unique texture generation module using a tailored approach based on GANs.•Shrinkwrap modelling for efficient 3D model simplification and texture UV mapping.•Significant time savings in virtual prototyping process.•Framework validated with a case study on sporting rifles, showing high-quality iPVP. CAD-to-XR is the workflow to generate interactive Photorealistic Virtual Prototypes (iPVPs) for Extended Reality (XR) apps from Computer-Aided Design (CAD) models. This process entails modelling, texturing, and XR programming. In the literature, no automatic CAD-to-XR frameworks simultaneously manage CAD simplification and texturing. There are no examples of their adoption for User-Centered Design (UCD). Moreover, such CAD-to-XR workflows do not seize the potentialities of generative algorithms to produce synthetic images (textures). The paper presents a framework for implementing the CAD-to-XR workflow. The solution consists of a module for texture generation based on Generative Adversarial Networks (GANs). The generated texture is then managed by another module (based on Shrinkwrap modelling) to develop the iPVP by simplifying the 3D model and UV mapping the generated texture. The geometric and material data is integrated into a graphic engine, which allows for programming an interactive experience with the iPVP in XR. The CAD-to-XR framework was validated on two components (rifle stock and forend) of a sporting rifle. The solution can automate the texturing process of different product versions in shorter times (compared to a manual procedure). After each product revision, it avoids tedious and manual activities required to generate a new iPVP. The image quality metrics highlight that images are generated in a “realistic” manner (the perceived quality of generated textures is highly comparable to real images). The quality of the iPVPs, generated through the proposed framework and visualised by users through a mixed reality head-mounted display, is equivalent to traditionally designed prototypes.
ISSN:1474-0346
DOI:10.1016/j.aei.2024.102848