2015
Testing photogrammetry-based techniques for three-dimensional surface documentation in forensic pathology
URBANOVÁ, Petra; Petr HEJNA a Mikoláš JURDAZákladní údaje
Originální název
Testing photogrammetry-based techniques for three-dimensional surface documentation in forensic pathology
Autoři
URBANOVÁ, Petra (203 Česká republika, garant, domácí); Petr HEJNA (203 Česká republika) a Mikoláš JURDA (203 Česká republika, domácí)
Vydání
Forensic Science International, Irsko, Elsevier Sequoia, 2015, 0379-0738
Další údaje
Jazyk
angličtina
Typ výsledku
Článek v odborném periodiku
Obor
30000 3. Medical and Health Sciences
Stát vydavatele
Irsko
Utajení
není předmětem státního či obchodního tajemství
Impakt faktor
Impact factor: 1.950
Kód RIV
RIV/00216224:14310/15:00082599
Organizační jednotka
Přírodovědecká fakulta
UT WoS
000352441700012
EID Scopus
2-s2.0-84925448475
Klíčová slova česky
Postmortem dokumentace; optické skenování; fotogrammetrie; srovnání 3D sítí
Klíčová slova anglicky
Postmortem documentation; Optical surface scanning; Photogrammetry; Point cloud comparison
Změněno: 8. 3. 2018 10:00, prof. RNDr. Petra Urbanová, Ph.D.
Anotace
V originále
Three-dimensional surface technologies particularly close range photogrammetry and optical surface scanning have recently advanced into affordable, flexible and accurate techniques. Forensic postmortem investigation as performed on a daily basis, however, has not yet fully benefited from their potentials. In the present paper, we tested two approaches to 3D external body documentation – digital camera-based photogrammetry combined with commercial Agisoft PhotoScan1 software and stereophotogrammetry- based Vectra H11, a portable handheld surface scanner. In order to conduct the study three human subjects were selected, a living person, a 25-year-old female, and two forensic cases admitted for postmortem examination at the Department of Forensic Medicine, Hradec Kra´ love´ , Czech Republic (both 63-year-old males), one dead to traumatic, self-inflicted, injuries (suicide by hanging), the other diagnosed with the heart failure. All three cases were photographed in 3608 manner with a Nikon 7000 digital camera and simultaneously documented with the handheld scanner. In addition to having recorded the pre-autopsy phase of the forensic cases, both techniques were employed in various stages of autopsy. The sets of collected digital images (approximately 100 per case) were further processed to generate point clouds and 3D meshes. Final 3D models (a pair per individual) were counted for numbers of points and polygons, then assessed visually and compared quantitatively using ICP alignment algorithm and a cloud point comparison technique based on closest point to point distances. Both techniques were proven to be easy to handle and equally laborious. While collecting the images at autopsy took around 20 min, the post-processing was much more time-demanding and required up to 10 h of computation time. Moreover, for the full-body scanning the post-processing of the handheld scanner required rather time-consuming manual image alignment. In all instances the applied approaches produced high-resolution photorealistic, real sized or easy to calibrate 3D surface models. Both methods equally failed when the scanned body surface was covered with body hair or reflective moist areas. Still, it can be concluded that single camera close range photogrammetry and optical surface scanning using Vectra H1 scanner represent relatively low-cost solutions which were shown to be beneficial for postmortem body documentation in forensic pathology.