https://www.scipedia.com/wd/index.php?action=history&feed=atom&title=Porcel_et_al_2021aPorcel et al 2021a - Revision history2026-04-21T15:36:25ZRevision history for this page on the wikiMediaWiki 1.27.0-wmf.10https://www.scipedia.com/wd/index.php?title=Porcel_et_al_2021a&diff=232735&oldid=prevScipediacontent: Scipediacontent moved page Draft Content 432320474 to Porcel et al 2021a2021-11-30T13:15:57Z<p>Scipediacontent moved page <a href="/public/Draft_Content_432320474" class="mw-redirect" title="Draft Content 432320474">Draft Content 432320474</a> to <a href="/public/Porcel_et_al_2021a" title="Porcel et al 2021a">Porcel et al 2021a</a></p>
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</td></tr></table>Scipediacontenthttps://www.scipedia.com/wd/index.php?title=Porcel_et_al_2021a&diff=232734&oldid=prevScipediacontent: Created page with "== Abstract == Cracks are structural pathologies that affect the structural integrity of historical buildings. The methodologies commonly used to detect cracks are..."2021-11-30T13:15:54Z<p>Created page with "== Abstract == Cracks are structural pathologies that affect the structural integrity of historical buildings. The methodologies commonly used to detect cracks are..."</p>
<p><b>New page</b></p><div>== Abstract ==<br />
<br />
Cracks are structural pathologies that affect the structural integrity of historical <br />
buildings. The methodologies commonly used to detect cracks are based on visual inspections <br />
or in intrusive techniques that involve removing external wall layers. The main objective of this <br />
study is to develop and validate a semi-automatic and non-destructive tool that helps the user <br />
to analyze the position and growth of the cracks in masonry constructions based on a <br />
photogrammetry analysis. The developed tool uses image processing to plot a curve of the crack <br />
area, and, in case needed, its evolution over time. The tool was validated in laboratory using <br />
earthen samples that were subjected to uniaxial compression tests. The research also provides <br />
the results of the tool used in a case study of a 16th Century stone masonry church located in <br />
the main square of Cusco; Southern Peru. This case study validates the qualitative metrics of <br />
the present work, and indicates that the tool provided accurate results when compared to the <br />
ground truth, which could be helpful in future research studies in order to automatize crack <br />
monitoring.<br />
<br />
== Full document ==<br />
<pdf>Media:Draft_Content_432320474p861.pdf</pdf><br />
== References ==<br />
<br />
[1] R. Segre, America Latina en su arquitectura, Ciudad de Mexico, (1983). <br />
<br />
[2] M. Blondet, M. Serrano, A. Rubiños y E. Mattson, La Experiencia de Capacitación de una Comunidad Andina en Construcción Sismorresistente con Adobe» de Seminario Iberoamericano de Arquitectura y Construccion con Tierra, Cuenca, 2015. <br />
<br />
[3] D. Inaudi, A. Rufenacht, B. von Arx, H. P. Noher, S. Vurpillot y B. Glisic, «Monitoring of a concrete arch bridge during construction,» Smart Structures and Materials, 2002 <br />
<br />
[4] X. W. Ye, C. Z. Dong y T. Liu, «A review of Machine Vision-Based Structural Health Monitoring: Methogologies and Applications,» Journal of Sensors, 2016. <br />
<br />
[5] T. Yamaguchi y S. Hashimoto, «Fast crack detection method for large-size concrete surface images using percolation-based image processing,» Machine Vision and Applications, pp. 797-809, 2010. <br />
<br />
[6] Z. Chen y T. C. Hutchinson, «Image-Based Framework for Concrete Surface Crack Monitoring and Quantification,» de Advances in Civil Engineering, Hindawi Publishing Corporation, 2010. <br />
<br />
[7] J. Valenca, D. Dias-da-Costa, E. Julio, H. Araujo y H. Costa, «Automatic crack monitoring using photogrammetry and image processing,» de Measurement, 2013, pp. 433-441. <br />
<br />
[8] W. Benning, J. Lange, R. Schwermann, C. Effkemann y S. Gortz, «MONITORING CRACK ORIGIN AND EVOLUTION AT CONCRETE ELEMENTS USING PHOTOGRAMMETRY,» de TS COMM V: Metrology and Industrial Applications, 2004. <br />
<br />
[9] U. Hampel y H.-G. Maas, «Cascaded image analysis for dynamic crack detection in material testing,» ISPRS Journal of Photogrammetry and Remote Sensing, vol. 64, pp. 345- 350, 2009. <br />
<br />
[10] S. Nishiyama, N. Minakata, T. Kikuchi y T. Yano, «Improved digital photogrammetry technique for crack monitoring,» de Advanced Engineering Informatics, 2015. <br />
<br />
[11] G. Medioni, C.-K. Tang y M.-S. Lee, «Tensor Voting: Theory and Applications». <br />
<br />
[12] The Mathworks, «MATLAB, Image Processing Toolbox and Vision Computer Toolbox,» Natick, 2019. <br />
<br />
[13] A. International, Standard Test Method for Compressive Strength of Hydraulic Cement Mortars (Using 2-in. or <br />
<br />
[14] S. Y. Alvarez Ordoñez, «COMPARACIÓN DE LAS PROPIEDADES MECÁNICAS DE UNIDADES Y PRISMAS DE BLOQUES DE TIERRA COMPRIMIDA ESTABILIZADA CON CEMENTO Y GEOPOLÍMERO DE PUZOLANA,» PUCP, Lima, 2018. <br />
<br />
[15] L. E. Yamin Lacouture, C. Philips Bernal, J. C. Reyes Ortiz y D. Ruiz Valencia, «Estudios de vulnerabilidad sismica, rehabilitacion y refuerzo de casas en adobe y tapia pisada,» de APUNTES, 2007, pp. 286-303. <br />
<br />
[16] G. K. Velarde Abugattas, «ANÁLISIS DE VULNERABILIDAD SÍSMICA DE VIVIENDAS DE DOS PISOS DE ADOBE EXISTENTE EN LIMA,» Lima, 2014.</div>Scipediacontent