tag:blogger.com,1999:blog-5822805028291837738.post361091675022796246..comments2023-12-09T03:51:33.158-05:00Comments on Various Consequences: ProFORMA: Probabilistic Feature-based On-line Rapid Model AcquisitionJoshua Stultshttp://www.blogger.com/profile/03506970399027046387noreply@blogger.comBlogger1125tag:blogger.com,1999:blog-5822805028291837738.post-92157653214983257562010-03-14T10:04:55.176-04:002010-03-14T10:04:55.176-04:00Performance and Use of 3D Imaging Systems
Summary:...<a href="http://www.nist.gov/bfrl/construction_productivity/3di-systems-project.cfm" rel="nofollow">Performance and Use of 3D Imaging Systems</a><br /><i><b>Summary:</b><br />The use of 3D imaging systems[1] in numerous industry sectors continues to grow. These sectors include widely varying fields such as construction, manufacturing, forensics, and archeology. Of all these sectors, 3D imaging systems have been used primarily in the construction sector; they have used to improve construction productivity by enabling reduced errors and rework, schedule reduction, improved responsiveness to project changes, increased worker safety, and better quality control. Greater use of 3D imaging systems in construction processes is limited by a lack of standards for understanding system performance and delivered information quality. Standards can only be developed when the underlying measurement science is provided which will allow comparable and repeatable evaluation of 3D imaging system performance. Such measurement science would allow for wider acceptance of and increased confidence in the use of 3D imaging systems, and would advance the delivery, whether new or repair, of the nation's physical infrastructure.<br /><br />[1] a non-contact measurement instrument used to produce a 3D representation (for example, a point cloud) of an object or a site.<br /></i>Joshua Stultshttps://www.blogger.com/profile/03506970399027046387noreply@blogger.com