Saved in:
Bibliographic Details
Main Author: Yang, Chengcheng
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.15915
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866929693324738560
author Yang, Chengcheng
author_facet Yang, Chengcheng
contents This paper generalizes the Michell Truss problem and Gangbo's paper from 1-dimension to higher dimensions using geometric measure theory. Given an elastic surface $S$ made of $(k-1)$-beams under an equilibriated system $F$ of external forces, then we ask the following two questions: 1. What are the necessary and sufficient conditions for the existence of an elastic body made of $k$-beams whose forces on the surface balance $F$ and whose surfaces consist of $S$. 2. What is an optimal design so that the total cost is a minimum? We've solved the existence question completely; and research is still in progress for the minimal question. In particular when $k=1$, it involves a system of beams joining a given finite collection of pointed forces. It was first introduced by A. Michell in 1904, then used in mechanical engineering, and recently popularized in many pure mathematics works by W. Gangbo, Prager, and others. Here we are going to generalize them to higher dimensional cases. We have already found the minimal solutions in terms of the flat chain complex and vector-valued currents. Right now we are studying the Calibration theory for future directions. I appreciate the discussion with Prof. Robert Hardt!
format Preprint
id arxiv_https___arxiv_org_abs_2403_15915
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Michell Truss and From 1-beam to k-beam
Yang, Chengcheng
Optimization and Control
Differential Geometry
This paper generalizes the Michell Truss problem and Gangbo's paper from 1-dimension to higher dimensions using geometric measure theory. Given an elastic surface $S$ made of $(k-1)$-beams under an equilibriated system $F$ of external forces, then we ask the following two questions: 1. What are the necessary and sufficient conditions for the existence of an elastic body made of $k$-beams whose forces on the surface balance $F$ and whose surfaces consist of $S$. 2. What is an optimal design so that the total cost is a minimum? We've solved the existence question completely; and research is still in progress for the minimal question. In particular when $k=1$, it involves a system of beams joining a given finite collection of pointed forces. It was first introduced by A. Michell in 1904, then used in mechanical engineering, and recently popularized in many pure mathematics works by W. Gangbo, Prager, and others. Here we are going to generalize them to higher dimensional cases. We have already found the minimal solutions in terms of the flat chain complex and vector-valued currents. Right now we are studying the Calibration theory for future directions. I appreciate the discussion with Prof. Robert Hardt!
title Michell Truss and From 1-beam to k-beam
topic Optimization and Control
Differential Geometry
url https://arxiv.org/abs/2403.15915