Optimization of laser scanner positioning networks for architectural surveys through the design of genetic algorithms

Identificadores
ISSN: 2632241
DOI: 10.1016/j.measurement.2020.108898
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Autor
Cabrera Revuelta, Elena; Chávez de Diego, María José; Barrera Vera, José Antonio; Fernández Rodríguez, Yago; Caballero Sánchez, Manuel [et al.]
Fecha
2021
Materia/s

Algoritmos

Topografía

Levantamiento geométrico tridimensional

Escáner Láser 3D

Banco de datos

Gestión de la información

Materia/s Unesco

3305.34 Topografía de la Edificación

1203.09 Diseño Con Ayuda del Ordenador

1203.12 Bancos de Datos

Resumen

In recent decades, the use of terrestrial laser scanners has become the principal method for metric data collection in architecture. However, there are no systematic procedures in place to plan the data capture process. This means that the obtaining tasks of the clouds of points are based either on operator experience, or on the overlap register that grants a complete acquisition. In both cases, data redundancy represents a significant percentage, which forces subsequent filtration or point removal. This work describes the design and development of an automated methodology, based on genetic algorithms, for the selection of a set of positions from which to execute the data capture process. The algorithm designed herein is applied to a variety of cases, thereby attaining the best station-positioning network for data collection, which maximizes coverage and minimizes overlap between clouds of points. © 2021 Elsevier Ltd

In recent decades, the use of terrestrial laser scanners has become the principal method for metric data collection in architecture. However, there are no systematic procedures in place to plan the data capture process. This means that the obtaining tasks of the clouds of points are based either on operator experience, or on the overlap register that grants a complete acquisition. In both cases, data redundancy represents a significant percentage, which forces subsequent filtration or point removal. This work describes the design and development of an automated methodology, based on genetic algorithms, for the selection of a set of positions from which to execute the data capture process. The algorithm designed herein is applied to a variety of cases, thereby attaining the best station-positioning network for data collection, which maximizes coverage and minimizes overlap between clouds of points. © 2021 Elsevier Ltd

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