3D imaging technology for improvement of and application in architecturalmonitoring

Miao Zhu; Giulio Ventura; Miao Zhu; Giulio Ventura

doi:10.3934/Math.2018.3.426

AIMS Mathematics

2018, Volume 3, Issue 3: 426-438. doi: 10.3934/Math.2018.3.426

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Research article Special Issues

3D imaging technology for improvement of and application in architecturalmonitoring

Miao Zhu ^{1,3
,
,},
Giulio Ventura ²

1.
Politecnico di Torino Collegio di Ingegneria Elettronica, delle Telecomunicazioni e Fisica (ETF), Torino, Italy
2.
Politecnico di Torino Dept. of Structural, Building and Geotechnical Engineering, Torino, Italy
3.
National Tsing Hua University the Institute of Communications Engineering, Hsinchu, Republic of China

Received: 29 July 2018 Accepted: 24 September 2018 Published: 12 October 2018
MSC : 93

We consider the problem of laser scanners are increasingly being employed as surveying instruments for numerous applications. In this paper we have constructed a system for monitoring dangerous parts of archaeological sites or buildings. In order to the fragile parts of an archaeological site or building are protected without human intervention, the system will perform a 3D scan of the building in real time and collect the data. The system will restore the collected data and monitor the building by comparing and analyzing the data at di erent times. At the same time, in order to reduce the error generated in the coordinate system transformation process, we have established a "flattened" model to optimize 3D imaging to ensure that the final image does not exhibit distortion. By simulating di erent data, we can determine that our "flattened" model produces good results in 3D imaging.
- three-dimensional scanning,
- archaeological,
- monitoring,
- big data
Citation: Miao Zhu, Giulio Ventura. 3D imaging technology for improvement of and application in architecturalmonitoring[J]. AIMS Mathematics, 2018, 3(3): 426-438. doi: 10.3934/Math.2018.3.426

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Abstract

We consider the problem of laser scanners are increasingly being employed as surveying instruments for numerous applications. In this paper we have constructed a system for monitoring dangerous parts of archaeological sites or buildings. In order to the fragile parts of an archaeological site or building are protected without human intervention, the system will perform a 3D scan of the building in real time and collect the data. The system will restore the collected data and monitor the building by comparing and analyzing the data at di erent times. At the same time, in order to reduce the error generated in the coordinate system transformation process, we have established a "flattened" model to optimize 3D imaging to ensure that the final image does not exhibit distortion. By simulating di erent data, we can determine that our "flattened" model produces good results in 3D imaging.

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