3D design terrain models for construction plans and GPS control of highway construction equipment
File(s)
Date
2010-03Author
Hanna, Awad
Hintz, Cassie
Vonderohe, Alan
Publisher
National Center for Freight and Infrastructure Research and Education
Metadata
Show full item recordAbstract
Use of Global Positioning System (GPS) technology to guide earth-moving equipment is quickly becoming common place in transportation facilities construction because it speeds project delivery and cuts costs. A requirement of this technology is a 3D representation of the design surface. Current design products for highways and other transportation facilities are 2D plans, profiles, and cross sections. To employ GPS machine guidance, these design products must be converted to 3D models prior to construction. Ironically, the technology used for producing 2D plans is often capable of 3D outputs. This research is intended to aid transportation organizations in developing strategies to overcome institutional, cultural, and legal impediments to adoption of 3D design and creation of more seamless data and work flows from design through construction. The full potential of new, spatial technologies to increase efficiencies in transportation facilities delivery cannot be realized without addressing these issues. The objectives of this project are to: 1) Describe the state of the art in adoption of 3D transportation design and construction technologies; 2) describe potential benefits and productivity gains of utility of 3D technologies in transportation design and construction; 3) identify and characterize technological, institutional, cultural, and legal impediments to adoption of 3D design/construct technologies; 4) suggest strategies to overcome identified impediments; 5) incorporate aspects of this research in the educational program of the Department of Civil and Environmental Engineering at UW-Madison.
Subject
Cost effectiveness
State of the art
Three dimensional displays
Construction equipment
Road construction
Global Positioning System
Permanent Link
http://digital.library.wisc.edu/1793/55940Description
109 p.