Knowledge-based FEA Modeling Method for Highly Coupled Variable Topology Multi-body Problems

Zeng, Sai

18 August 2004

The increasingly competitive market is forcing the industry to develop higher-quality products more quickly and less expensively. Engineering analysis, at the same time, plays an important role in helping designers evaluate the performance of the designed product against design requirements. In the context of automated CAD/FEA integration, the domain-dependent engineers different usage views toward product models cause an information gap between CAD and FEA models, which impedes the interoperability among these engineering tools and the automatic transformation from an idealized design model into a solvable FEA model. Especially in highly coupled variable topology multi-body (HCVTMB) problems, this transformation process is usually very labor-intensive and time-consuming. In this dissertation, a knowledge-based FEA modeling method, which consists of three information models and the transformation processes between these models, is presented. An Analysis Building Block (ABB) model represents the idealized analytical concepts in a FEA modeling process. Solution Method Models (SMMs) represent these analytical concepts in a solution technique-specific format. When FEA is used as the solution technique, an SMM consists of a Ready to Mesh Model (RMM) and a Control Information Model (CIM). An RMM is obtained from an ABB through geometry manipulation so that the quality mesh can be automatically generated using FEA tools. CIMs contain information that controls the FEA modeling and solving activities. A Solution Tool Model (STM) represents an analytical model at the tool-specific level to guide the entire FEA modeling process. Two information transformation processes are presented between these information models. A solution method mapping transforms an ABB into an RMM through a complex cell decomposition process and an attribute association process. A solution tool mapping transforms an SMM into an STM by mimicking an engineers selection of FEA modeling operations. Four HCVTMB industrial FEA modeling cases are presented for demonstration and validation. These involve thermo-mechanical analysis scenarios: a simple chip package, a Plastic Ball Grid Array (PBGA), and an Enhanced Ball Grid Array (EBGA), as well as a thermal analysis scenario: another PBGA. Compared to traditional methods, results indicate that this method provides better knowledge capture and decreases the modeling time from days/hours to hours/minutes.

Finite element analysis

Design analysis integration

Highly coupled variable topology

Knowledge-based FEA modeling

Multi-representation architecture

Engineering design Data processing

Topology

Finite element method

Computer-aided design

Annotation sémantique 2D/3D d'images spatialisées pour la documentation et l'analyse d'objets patrimoniaux / 2D/3D semantic annotation of spatialized images for the documentation and analysis of cultural heritage

Manuel, Adeline

22 March 2016

Dans le domaine de l’architecture et de la conservation du patrimoine historique, les technologies de l’information et de la communication permettent l’acquisition de grandes quantités de données introduisant des supports d’analyses pour différentes finalités et à différents niveaux de détails (photographies, nuages de points, imagerie scientifique, …). L’organisation et la structuration de ces ressources est aujourd’hui un problème majeur pour la description, l’analyse et la compréhension d’objets patrimoniaux. Cependant les solutions existantes d’annotations sémantiques d’images ou de modèle 3D se révèlent insuffisantes notamment sur l’aspect de mise en relation des différents supports d’analyse.Cette thèse propose une approche permettant de conduire des annotations sur les différents supports bidimensionnels tout en permettant la propagation de ces annotations entre les différentes représentations (2D ou 3D) de l’objet. L’objectif est d’identifier des solutions pour corréler (d’un point de vue spatial, temporel et sémantique) des jeux d’annotations au sein d’un jeu d’images. Ainsi le système repose sur le principe de spatialisation des données permettant d’établir une relation entre les représentations 3D, intégrant toute la complexité géométrique de l’objet et par conséquent permettant l’extraction d’informations métriques, et les représentations 2D de l’objet. L’approche cherche donc à la mise en place d’une continuité informationnelle depuis l’acquisition d’images jusqu’à la construction de représentations 3D sémantiquement enrichies en intégrant des aspects multi-supports et multi-temporels. Ce travail a abouti à la définition et le développement d’un ensemble de modules informatiques pouvant être utilisés par des spécialistes de la conservation d’un patrimoine architectural comme par le grand public. / In the field of architecture and historic preservation , the information and communication technologies enable the acquisition of large amounts of data introducing analysis media for different purposes and at different levels of details ( photographs, point cloud, scientific imaging, ...). The organization and the structure of these resources is now a major problem for the description, the analysis and the understanding of cultural heritage objects. However the existing solutions in semantic annotations on images or on 3D model are insufficient, especially in the linking of different analysis media.This thesis proposes an approach for conducting annotations on different two-dimensional media while allowing the propagation of these annotations between different representations (2D or 3D) of the object. The objective is to identify solutions to correlate (from a spatial, temporal and semantic point of view) sets of annotations within sets of images. Thus, the system is based on the principle of data spatialization for establishing a relationship between the 3D representations, incorporating all the geometric complexity of the object and therefore to the metric information extraction, and 2D representations of object. The approach seeks to the establishment of an information continuity from the image acquisition to the construction of 3D representations semantically enhanced by incorporating multi-media and multi-temporal aspects. This work resulted in the definition and the development of a set of software modules that can be used by specialists of conservation of architectural heritage as by the general public.

Patrimoine culturel

Description sémantique

Annotation d'images

Spatialisation d'informations

Multi-Représentation

Multi-Temporel

Cultural heritage

Semantic description

Image annotations

Information spatialization

Multi-Representation

Multi-Temporal