arxiv_cv 88% Match Research Paper CAD Engineers,Product Designers,Machine Learning Researchers,Generative AI Developers 1 week ago

Target-Guided Bayesian Flow Networks for Quantitatively Constrained CAD Generation

generative-ai › diffusion

📄 Abstract

Abstract: Deep generative models, such as diffusion models, have shown promising progress in image generation and audio generation via simplified continuity assumptions. However, the development of generative modeling techniques for generating multi-modal data, such as parametric CAD sequences, still lags behind due to the challenges in addressing long-range constraints and parameter sensitivity. In this work, we propose a novel framework for quantitatively constrained CAD generation, termed Target-Guided Bayesian Flow Network (TGBFN). For the first time, TGBFN handles the multi-modality of CAD sequences (i.e., discrete commands and continuous parameters) in a unified continuous and differentiable parameter space rather than in the discrete data space. In addition, TGBFN penetrates the parameter update kernel and introduces a guided Bayesian flow to control the CAD properties. To evaluate TGBFN, we construct a new dataset for quantitatively constrained CAD generation. Extensive comparisons across single-condition and multi-condition constrained generation tasks demonstrate that TGBFN achieves state-of-the-art performance in generating high-fidelity, condition-aware CAD sequences. The code is available at https://github.com/scu-zwh/TGBFN.

Authors (5)

Wenhao Zheng

Chenwei Sun

Wenbo Zhang

Jiancheng Lv

Xianggen Liu

Submitted

October 29, 2025

arXiv Category

cs.CV

Proceedings of the 33rd ACM International Conference on Multimedia (2025) 3330-3339

arXiv PDF

Key Contributions

TGBFN is a novel framework for quantitatively constrained CAD generation that unifies discrete commands and continuous parameters in a differentiable space. It introduces a guided Bayesian flow to control CAD properties, addressing challenges in multi-modal data generation and long-range constraints, unlike diffusion models which have simplified continuity assumptions.

Business Value

Accelerates the product design and engineering process by automating the generation of complex CAD models with precise quantitative constraints, reducing design time and errors.

Paper Metadata

Innovation Type

Novel Generative Framework / Unified Parameter Space

Deployment Feasibility

Moderate. Requires specialized data and integration into CAD workflows. The novelty of the approach may require further validation.

Limitations Addressed

Existing generative models struggle with multi-modal CAD data, long-range constraints, and parameter sensitivity. TGBFN provides a unified approach to handle these issues.

Technical Tags

CAD GenerationQuantitatively ConstrainedBayesian Flow NetworksDiffusion ModelsMulti-modal DataParametric SequencesLong-range ConstraintsParameter SensitivityGenerative ModelingConditional Generation

Research Topics

Generative AIComputer-Aided Design (CAD)Machine LearningConditional GenerationDeep Generative Models

Methods & Architectures

Target-Guided Bayesian Flow Network (TGBFN)Unified Continuous Parameter SpaceGuided Bayesian FlowParameter Update Kernel Penetration Bayesian Flow NetworksDiffusion Models (mentioned as related)

Applications & Tasks

Product Design Engineering Manufacturing 3D Modeling Generating multi-modal data (discrete commands, continuous parameters)Addressing long-range constraints in CAD sequencesHandling parameter sensitivityLagging generative modeling for parametric CAD Quantitatively constrained CAD generationGenerating parametric CAD sequences

Datasets & Benchmarks

Datasets

New dataset for quantitatively constrained CAD generation (constructed)

Generation QualityConstraint SatisfactionParameter Accuracy

Related Fields

Computer GraphicsEngineering DesignMachine LearningGenerative Models

Keywords

CAD GenerationGenerative ModelsBayesian Flow NetworksDiffusion ModelsConditional GenerationParametric DesignEngineeringProduct DesignMulti-modalConstraintsDeep Learning

Academic Context

#Generative AI#Computer-Aided Design (CAD)#Machine Learning#Conditional Generation#Deep Generative Models

Commercial Potential

Potential Products

Automated CAD design softwareGenerative design tools for engineersParametric modeling assistants

Target Industries

ManufacturingAutomotiveAerospaceProduct DesignArchitecture

Use Case Examples

Generating complex mechanical parts with specific performance requirementsAutomating the creation of variations for product design explorationDesigning customized components based on user-defined parameters

Competitive Edge

Offers a more sophisticated approach to constrained generation for multi-modal CAD data compared to standard diffusion models, by directly manipulating parameters and incorporating Bayesian principles.

Resource Requirements

Compute Needs

Requires significant compute resources for training the Bayesian Flow Network, potentially comparable to diffusion models.

Data Requirements

Requires a custom dataset of parametric CAD sequences with associated constraints.

Deployment Constraints

Integration into existing CAD software pipelines. The complexity of the model might pose challenges for real-time interactive design.

Scalability

The framework's ability to handle long-range constraints and parameter updates suggests potential for generating complex and large-scale CAD models.

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