Resolution and Precision of Fast Long-Range Terrestrial Photogrammetric Surveying Aimed at Detecting Slope Changes
Author(s)
Language
English
Obiettivo Specifico
2T. Deformazione crostale attiva
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
4/146 (2020)
Pages (printed)
4020017
Date Issued
November 2020
Subjects
Resolution and Precision of Fast Long-Range Terrestrial Photogrammetric Surveying Aimed at Detecting Slope Changes
Abstract
Structure-from-motion (SfM) is currently used for geological-geomorphological purposes under the condition that the modeling is based either on several ground control points (GCPs) well distributed in the scene or on direct georeferencing (DG). In emergency conditions and in presence of active morphodynamic processes, it could be unfeasible to use GCPs or DG. A study aimed at evaluating the quality of the results achievable by means of completely free SfM modeling of images taken from a distance of some hundred meters is shown in this paper.
It is based on an experiment with an artificial target and some surveys of a bedrock scarp, where resolution and precision are evaluated as empirical functions of distance and focal length, taking into account the issues related to the scale factor. The problems related to the recognition of localized surface changes by means of multitemporal surveys are also studied. The primary result is that the free approach can really be used in geomorphological and seismotectonical surveying carried out in emergency conditions.
It is based on an experiment with an artificial target and some surveys of a bedrock scarp, where resolution and precision are evaluated as empirical functions of distance and focal length, taking into account the issues related to the scale factor. The problems related to the recognition of localized surface changes by means of multitemporal surveys are also studied. The primary result is that the free approach can really be used in geomorphological and seismotectonical surveying carried out in emergency conditions.
References
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Baroň, I., L. Plan, B. Grasemann, I. Mitroviċ, W. Lenhardt, H. Hausmann,
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deformations be activated by regional tectonic strain: First insights from
displacement measurements in caves from the Eastern Alps.” Geomor-
phology 259 (Apr): 81–89. https://doi.org/10.1016/j.geomorph.2016.02
.007.
Beshr, A. A. A., and I. M. A. Elnaga. 2011. “Investigating the accuracy of
digital levels and reflectorless total stations for purposes of geodetic
engineering.” Alexandria Eng. J. 50 (4): 399–405. https://doi.org/10
.1016/j.aej.2011.12.004.
Brunier, G., J. Fleury, J. E. Anthony, V. Pothin, C. Vella, P. Dussouillez, A.
Gardel, and E. Michaud. 2016. “Structure-from-motion photogram-
metry for high-resolution coastal and fluvial geomorphic surveys.” Géo-
morphologie 22 (2): 147–161. https://doi.org/10.4000/geomorphologie
.11358.
Carbonneau, P. E., and J. T. Dietrich. 2017. “Cost-effective non-metric
photogrammetry from consumer-grade sUAS: Implications for direct
georeferencing of structure from motion photogrammetry.” Earth Surf.
Process Landforms 42 (3): 473–486. https://doi.org/10.1002/esp.4012.
Caroti, G., I. Martínez-Espejo Zaragoza, and A. Piemonte. 2015. “Accuracy
assessment in structure from motion 3D reconstruction from UAV-born
images: The influence of the data processing methods.” Int. Arch. Pho-
togramm. Remote Sens. Spatial Inf. Sci. 40 (1/W4): 103–109. https://doi
.org/10.5194/isprsarchives-XL-1-W4-103-2015.
Di Naccio, D., V. Kastelic, M. M. C. Carafa, C. Esposito, P. Millilo, and C.
Di Lorenzo. 2019. “Gravity versus tectonics: The case of 2016
Amatrice and Norcia (central Italy) earthquakes surface coseismic frac-
tures.” J. Geophys. Res. Earth Surf. 124 (4): 994–1017. https://doi.org
/10.1029/2018JF004762.
Ferrigno, F., G. Gigli, R. Fanti, E. Intrieri, and N. Casagli. 2020.
“GB-InSAR monitoring and observational method for landslide emer-
gency management: The Montaguto earthflow (AV, Italy).” Nat. Haz-
ards Earth Syst. Sci. 17 (6): 845–860. https://doi.org/10.5194/nhess-17
-845-2017.
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seamless SRTM data V4, international centre for tropical agriculture
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Jaud, M., S. Passot, R. Le Bivic, C. Delacourt, P. Grandjean, and N. Le
Dantec. 2016. “Assessing the accuracy of high resolution digital
surface models computed by PhotoScan and MicMac in sub-optimal
survey conditions.” Remote Sens. 8 (6): 465. https://doi.org/10.3390
/rs8060465.
Kastelic, V., P. Burrato, M. M. C. Carafa, and R. Basili. 2017. “Repeated
surveys reveal nontectonic exposure of supposedly active normal faults
in the central Apennines, Italy.” J. Geophys. Res. Earth Surf. 122 (1):
114–129. https://doi.org/10.1002/2016JF003953.
Lichti, D. D., and S. Jamtsho. 2006. “Angular resolution of terrestrial laser
scanners.” Photogramm. Rec. 21 (114): 141–160. https://doi.org/10
.1111/j.1477-9730.2006.00367.x.
Murtiyoso, A., P. Grussenmeyer, N. Börlin, J. Vandermeerschen, and T.
Freville. 2018. “Open source and independent methods for bundle
adjustment assessment in close-range UAV photogrammetry.” Drones
2 (1): 3. https://doi.org/10.3390/drones2010003.
Nouwakpo, S. K., M. A. Weltz, and K. McGwire. 2016. “Assessing the
performance of structure-from-motion photogrammetry and terrestrial
LiDAR for reconstructing soil surface microtopography of naturally
vegetated plots.” Earth Surf. Processes Landforms 41 (3): 308–322.
https://doi.org/10.1002/esp.3787.
Paredes-Hernandez, C. U., W. E. Salinas-Castillo, F. Guevara-Cortina, and
X. Martinez-Becerra. 2013. “Horizontal positional accuracy of Google
Earth’s imagery over rural areas: A study case in Tamaulipas, Mexico.”
Boletim de Ciências Geodésicas 19 (4): 588–601. https://doi.org/10
.1590/S1982-21702013000400005.
Pesci, A., et al. 2016. “A fast method for monitoring the coast through
independent photogrammetric measurements: Application and case
study.” J. Geosci. Geomatics 4 (4): 73–81. https://doi.org/10.12691/jgg
-4-4-1.
Pesci, A., S. Amoroso, G. Teza, and L. Minarelli. 2018. “Characterisation
of soil deformation due to blast-induced liquefaction by UAV-based
photogrammetry and terrestrial laser scanning.” Int. J. Remote Sens.
39 (22): 8317–8336. https://doi.org/10.1080/01431161.2018.1484960.
Pesci, A., G. Teza, and E. Bonali. 2011. “Terrestrial laser scanner resolu-
tion: Numerical simulations and experiments on spatial sampling opti-
mization.” Remote Sens. 3 (1): 167–184. https://doi.org/10.3390
/rs3010167.
Pesci, A., G. Teza, and F. Loddo. 2019. “Low cost structure-from-motion-
based fast surveying of a rock cliff: Precision and reliability assess-
ment.” Quaderni di Geofisica 2019 (156): 1–22.
Pulighe, G., V. Baiocchi, and F. Lupia. 2016. “Horizontal accuracy assess-
ment of very high resolution Google Earth images in the city of Rome,
Italy.” Int. J. Dig. Earth 9 (4): 342–362. https://doi.org/10.1080
/17538947.2015.1031716.
Schlagenhauf, A. 2009. “Identication des forts séismes passés sur les failles
normales actives de la région Lazio-Abruzzo (Italie Centrale) par ‘data-
tions cosmogéniques’ (36Cl) de leurs escarpements.” Ph.D. thesis,
Laboratoire de Géophysique Interne et Tectonophysique, Université Jo-
seph Fourier.
Smith, M. W., J. L. Carrivick, and D. J. Quincey. 2016. “Structure from
motion photogrammetry in physical geography.” Prog. Phys. Geogr.
40 (2): 247–275. https://doi.org/10.1177/0309133315615805.
Teza, G., A. Galgaro, N. Zaltron, and R. Genevois. 2007. “Terrestrial laser
scanner to detect landslide displacement fields: A new approach.”
Int. J. Remote Sens. 28 (16): 3425–3446. https://doi.org/10.1080
/01431160601024234.
Teza, G., A. Pesci, and A. Ninfo. 2016. “Morphological analysis for archi-
tectural applications: Comparison between laser scanning and structure-
from-motion photogrammetry.” J. Sur. Eng. 142 (3): 04016004. https://
doi.org/10.1061/(ASCE)SU.1943-5428.0000172.
Tonkin, N. T., and G. N. Midgley. 2016. “Ground-control networks for
image based surface reconstruction: An investigation of optimum sur-
vey designs using UAV derived imagery and structure-from-motion
photogrammetry.” Remote Sens. 8 (9): 786. https://doi.org/10.3390
/rs8090786.
Travelletti, J., C. Delacourt, J. P. Malet, P. Allemand, J. Schmittbuhl, and
R. Toussaint. 2013. “Performance of image correlation techniques for
landslide displacement monitoring.” In Landslide science and practice,
edited by C. Margottini, P. Canuti, and K. Sassa, 217–226. Berlin:
Springer.
Triggs, B., P. Mclauchlan, P. Hartley, and A. Fitzgibbon. 2000. “Bundle
adjustment—A modern synthesis.” In Proc., Int. Workshop on Vision Al-
gorithms IWVA 1999, edited by B. Triggs, A. Zisserman and R. Szeliski,
298–372. Berlin: Springer. https://doi.org/10.1007/3-540-44480-7_21.
Turner, D., A. Lucieer, and L. Wallace. 2014. “Direct georeferencing of
ultrahigh-resolution UAV imagery.” IEEE T. Geosci. Remote Sens.
52 (5): 2738–2745. https://doi.org/10.1109/TGRS.2013.2265295.
Vajsová, B., A. Walczynska, P. Aastrand, S. Barisch, and S. Hain. 2015.
“New sensors benchmark report on WorldView-3.” Accessed February
14, 2020. https://publications.jrc.ec.europa.eu/repository/bitstream
/JRC99433/reqno_jrc99433_lb-na-27673-en-n.pdf.
www.agisoft.com.
Agrafiotis, P., and A. Georgopoulos. 2015. “Comparative assessment of
very high resolution satellite and aerial orthoimagery.” Int. Arch. Photo-
gramm. Remote Sens. Spatial Inf. Sci. 40 (3/W2): 1–7. https://doi.org
/10.5194/isprsarchives-XL-3-W2-1-2015.
Al-Halbouni, D., E. Holohan, L. Saberi, H. Alrshdan, A. Sawarieh, D.
Closson, T. R. Walter, and T. Dahm. 2017. “Sinkholes, subsidence
and subrosion on the eastern shore of the Dead Sea as revealed by a
close-range photogrammetric survey.” Geomorphology 285 (May):
305–324. https://doi.org/10.1016/j.geomorph.2017.02.006.
Baroň, I., L. Plan, B. Grasemann, I. Mitroviċ, W. Lenhardt, H. Hausmann,
and J. Stemberk. 2016. “Can deep seated gravitational slope
deformations be activated by regional tectonic strain: First insights from
displacement measurements in caves from the Eastern Alps.” Geomor-
phology 259 (Apr): 81–89. https://doi.org/10.1016/j.geomorph.2016.02
.007.
Beshr, A. A. A., and I. M. A. Elnaga. 2011. “Investigating the accuracy of
digital levels and reflectorless total stations for purposes of geodetic
engineering.” Alexandria Eng. J. 50 (4): 399–405. https://doi.org/10
.1016/j.aej.2011.12.004.
Brunier, G., J. Fleury, J. E. Anthony, V. Pothin, C. Vella, P. Dussouillez, A.
Gardel, and E. Michaud. 2016. “Structure-from-motion photogram-
metry for high-resolution coastal and fluvial geomorphic surveys.” Géo-
morphologie 22 (2): 147–161. https://doi.org/10.4000/geomorphologie
.11358.
Carbonneau, P. E., and J. T. Dietrich. 2017. “Cost-effective non-metric
photogrammetry from consumer-grade sUAS: Implications for direct
georeferencing of structure from motion photogrammetry.” Earth Surf.
Process Landforms 42 (3): 473–486. https://doi.org/10.1002/esp.4012.
Caroti, G., I. Martínez-Espejo Zaragoza, and A. Piemonte. 2015. “Accuracy
assessment in structure from motion 3D reconstruction from UAV-born
images: The influence of the data processing methods.” Int. Arch. Pho-
togramm. Remote Sens. Spatial Inf. Sci. 40 (1/W4): 103–109. https://doi
.org/10.5194/isprsarchives-XL-1-W4-103-2015.
Di Naccio, D., V. Kastelic, M. M. C. Carafa, C. Esposito, P. Millilo, and C.
Di Lorenzo. 2019. “Gravity versus tectonics: The case of 2016
Amatrice and Norcia (central Italy) earthquakes surface coseismic frac-
tures.” J. Geophys. Res. Earth Surf. 124 (4): 994–1017. https://doi.org
/10.1029/2018JF004762.
Ferrigno, F., G. Gigli, R. Fanti, E. Intrieri, and N. Casagli. 2020.
“GB-InSAR monitoring and observational method for landslide emer-
gency management: The Montaguto earthflow (AV, Italy).” Nat. Haz-
ards Earth Syst. Sci. 17 (6): 845–860. https://doi.org/10.5194/nhess-17
-845-2017.
Innovmetric. 2020. “PolyWorks web page.” Accessed January 28, 2020.
http://www.innovmetric.com/en.
Jarvis, A., H. I. Reuter, A. Nelson, and E. Guevara. 2008. “Hole-filled
seamless SRTM data V4, international centre for tropical agriculture
(CIAT).” Accessed June 10, 2020. http://srtm.csi.cgiar.org.
Jaud, M., S. Passot, R. Le Bivic, C. Delacourt, P. Grandjean, and N. Le
Dantec. 2016. “Assessing the accuracy of high resolution digital
surface models computed by PhotoScan and MicMac in sub-optimal
survey conditions.” Remote Sens. 8 (6): 465. https://doi.org/10.3390
/rs8060465.
Kastelic, V., P. Burrato, M. M. C. Carafa, and R. Basili. 2017. “Repeated
surveys reveal nontectonic exposure of supposedly active normal faults
in the central Apennines, Italy.” J. Geophys. Res. Earth Surf. 122 (1):
114–129. https://doi.org/10.1002/2016JF003953.
Lichti, D. D., and S. Jamtsho. 2006. “Angular resolution of terrestrial laser
scanners.” Photogramm. Rec. 21 (114): 141–160. https://doi.org/10
.1111/j.1477-9730.2006.00367.x.
Murtiyoso, A., P. Grussenmeyer, N. Börlin, J. Vandermeerschen, and T.
Freville. 2018. “Open source and independent methods for bundle
adjustment assessment in close-range UAV photogrammetry.” Drones
2 (1): 3. https://doi.org/10.3390/drones2010003.
Nouwakpo, S. K., M. A. Weltz, and K. McGwire. 2016. “Assessing the
performance of structure-from-motion photogrammetry and terrestrial
LiDAR for reconstructing soil surface microtopography of naturally
vegetated plots.” Earth Surf. Processes Landforms 41 (3): 308–322.
https://doi.org/10.1002/esp.3787.
Paredes-Hernandez, C. U., W. E. Salinas-Castillo, F. Guevara-Cortina, and
X. Martinez-Becerra. 2013. “Horizontal positional accuracy of Google
Earth’s imagery over rural areas: A study case in Tamaulipas, Mexico.”
Boletim de Ciências Geodésicas 19 (4): 588–601. https://doi.org/10
.1590/S1982-21702013000400005.
Pesci, A., et al. 2016. “A fast method for monitoring the coast through
independent photogrammetric measurements: Application and case
study.” J. Geosci. Geomatics 4 (4): 73–81. https://doi.org/10.12691/jgg
-4-4-1.
Pesci, A., S. Amoroso, G. Teza, and L. Minarelli. 2018. “Characterisation
of soil deformation due to blast-induced liquefaction by UAV-based
photogrammetry and terrestrial laser scanning.” Int. J. Remote Sens.
39 (22): 8317–8336. https://doi.org/10.1080/01431161.2018.1484960.
Pesci, A., G. Teza, and E. Bonali. 2011. “Terrestrial laser scanner resolu-
tion: Numerical simulations and experiments on spatial sampling opti-
mization.” Remote Sens. 3 (1): 167–184. https://doi.org/10.3390
/rs3010167.
Pesci, A., G. Teza, and F. Loddo. 2019. “Low cost structure-from-motion-
based fast surveying of a rock cliff: Precision and reliability assess-
ment.” Quaderni di Geofisica 2019 (156): 1–22.
Pulighe, G., V. Baiocchi, and F. Lupia. 2016. “Horizontal accuracy assess-
ment of very high resolution Google Earth images in the city of Rome,
Italy.” Int. J. Dig. Earth 9 (4): 342–362. https://doi.org/10.1080
/17538947.2015.1031716.
Schlagenhauf, A. 2009. “Identication des forts séismes passés sur les failles
normales actives de la région Lazio-Abruzzo (Italie Centrale) par ‘data-
tions cosmogéniques’ (36Cl) de leurs escarpements.” Ph.D. thesis,
Laboratoire de Géophysique Interne et Tectonophysique, Université Jo-
seph Fourier.
Smith, M. W., J. L. Carrivick, and D. J. Quincey. 2016. “Structure from
motion photogrammetry in physical geography.” Prog. Phys. Geogr.
40 (2): 247–275. https://doi.org/10.1177/0309133315615805.
Teza, G., A. Galgaro, N. Zaltron, and R. Genevois. 2007. “Terrestrial laser
scanner to detect landslide displacement fields: A new approach.”
Int. J. Remote Sens. 28 (16): 3425–3446. https://doi.org/10.1080
/01431160601024234.
Teza, G., A. Pesci, and A. Ninfo. 2016. “Morphological analysis for archi-
tectural applications: Comparison between laser scanning and structure-
from-motion photogrammetry.” J. Sur. Eng. 142 (3): 04016004. https://
doi.org/10.1061/(ASCE)SU.1943-5428.0000172.
Tonkin, N. T., and G. N. Midgley. 2016. “Ground-control networks for
image based surface reconstruction: An investigation of optimum sur-
vey designs using UAV derived imagery and structure-from-motion
photogrammetry.” Remote Sens. 8 (9): 786. https://doi.org/10.3390
/rs8090786.
Travelletti, J., C. Delacourt, J. P. Malet, P. Allemand, J. Schmittbuhl, and
R. Toussaint. 2013. “Performance of image correlation techniques for
landslide displacement monitoring.” In Landslide science and practice,
edited by C. Margottini, P. Canuti, and K. Sassa, 217–226. Berlin:
Springer.
Triggs, B., P. Mclauchlan, P. Hartley, and A. Fitzgibbon. 2000. “Bundle
adjustment—A modern synthesis.” In Proc., Int. Workshop on Vision Al-
gorithms IWVA 1999, edited by B. Triggs, A. Zisserman and R. Szeliski,
298–372. Berlin: Springer. https://doi.org/10.1007/3-540-44480-7_21.
Turner, D., A. Lucieer, and L. Wallace. 2014. “Direct georeferencing of
ultrahigh-resolution UAV imagery.” IEEE T. Geosci. Remote Sens.
52 (5): 2738–2745. https://doi.org/10.1109/TGRS.2013.2265295.
Vajsová, B., A. Walczynska, P. Aastrand, S. Barisch, and S. Hain. 2015.
“New sensors benchmark report on WorldView-3.” Accessed February
14, 2020. https://publications.jrc.ec.europa.eu/repository/bitstream
/JRC99433/reqno_jrc99433_lb-na-27673-en-n.pdf.
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