收稿日期: 2020-07-15
修回日期: 2020-08-24
网络出版日期: 2020-11-06
基金资助
中国科学院战略性先导科技专项(XDB26000000);虚拟现实技术与系统国家重点实验室北京航空航天大学开放课题基金(VRLAB2019A02)
The three-dimensional facial reconstruction of a male Upper Cave 101 skull
Received date: 2020-07-15
Revised date: 2020-08-24
Online published: 2020-11-06
山顶洞101号头骨化石是东亚地区保存最为完整的化石之一,是探讨东亚地区现代人起源的重要研究材料。本文依据数据集中现生人的面部软组织平均分布,提出了计算机三维颅面复原方法,实现了101号头骨生前面貌的预测复原。主要包括三个步骤:首先使用CT完成了101号男性头骨和下颌骨仿制模型的三维重建。然后,利用计算机技术将现生人的面部软组织分布作为101号头骨的面部软组织分布,实现了颅面虚拟复原,并采用手工绘画技巧再现了复原面貌的形态特征。最后,提出了一种基于面部软组织分布和面貌统计形状模型的形态分析方法,实现了颅面复原结果的评估。山顶洞101号头骨的复原面貌具有头部较长、额头前倾、眉弓粗壮等特征,与101号头骨的几何形态基本一致。该技术再现了更新世晚期人类的脑颅及面部的形态特征,为古人类颅面复原的研究提供了技术支持和参考资料。
税午阳 , 张亚盟 , 吴秀杰 , 周明全 . 山顶洞101号男性头骨的三维颅面复原[J]. 人类学学报, 2020 , 39(04) : 659 -670 . DOI: 10.16359/j.cnki.cn11-1963/q.2020.0055
The Upper Cave (UC) 101 skull is one of the most complete human fossils in the Eastern Asia, which has been the most important material to investigate the origins of modern Eastern Asian humans. In this study, we proposed a computerized craniofacial reconstruction approach to produce a possible 3D facial appearance of UC 101 skull based on the average facial soft-tissue thickness measurements (FSTMs) distribution of modern living humans within the skull and face datasets. It contains three steps: first, we used computerized tomography (CT) scan to acquire the digital model of a high-quality replica of UC 101 skull, which consists of the cranium and mandible. Second, based on the assumption that the average FSTMs distribution of the living humans is the similar to that of the UC 101, we used computer technique to virtually attach this FSTMs distribution to the UC 101 so as to produce the facial appearance. We also employed the handmade drawing technique to produce the facial morphological characteristics and subtle details of the reconstructed face. Finally, we proposed a geometric shape analysis approach to assess the reliability of the reconstructed face by means of the comparison of FSTMs distributions and the face statistical shape model. Our results illustrate that the reconstructed face is consistent with the geometric shape of UC 101, which exhibits an elongated face, a sloped forehead, stronger and wider eyebrows, etc. Our method exhibits a possible likeness of geometric shape of the neurocranium and facial morphological characters, which may further be applicable for other anthropological fossils.
Key words: Upper cave; Craniofacial reconstruction; Soft-tissue
| [1] | 刘武, 何嘉宁, 吴秀杰, 等. 山顶洞人与现代华北人头骨非测量性特征比较及中国更新世晚期人类演化的一些问题[J]. 人类学学报, 2006,25(1):26-41 |
| [2] | Li F, Bae CJ, Ramsey CB, et al. Re-dating Zhoukoudian Upper Cave, northern China and its regional significance[J]. Journal of Human Evolution, 2018,121:170-177 |
| [3] | Wilkinson C. Forensic Facial Reconstruction[M]. Cambridge University Press, Cambridge, 2004. |
| [4] | Lee WJ, Yoon AY, Mi KS, et al. The archaeological contribution of forensic craniofacial reconstruction to a portrait drawing of a Korean historical figure[J]. Journal of Archaeological Science, 2014,49:228-236. |
| [5] | Stephan CN, Caple JM, Guyomarc’h P, et al. An overview of the latest developments in facial imaging[J]. Forensic sciences research, 2019,4(1):10-28 |
| [6] | 周明全, 耿国华, 李康, 等. 颅面形态信息学[M]. 北京: 科学出版社, 2016 |
| [7] | Claes P, Vandermeulen D, De Greef S, et al. Computerized craniofacial reconstruction: conceptual framework and review[J]. Forensic Science International, 2010,201(1-3):138-145 |
| [8] | Vanezis P, Vanezis M, McCombe G, et al. Facial reconstruction using 3-D computer graphics[J]. Forensic Science International, 2000,108(2):81-95 |
| [9] | 税午阳, 周明全, 纪元, 等. 面部软组织厚度测量及其在面貌复原中的应用[J]. 人类学学报, 2013,32(3):345-353 |
| [10] | Quatrehomme G, Cotin S, Subsol G, et al. A fully three-dimensional method for facial reconstruction based on deformable models[J]. Journal of Forensic Sciences, 1997,42(4):649-652 |
| [11] | Turner WD, Brown RE, Kelliher TP, et al. A novel method of automated skull registration for forensic facial approximation. Forensic Science International, 2005,154(2-3):149-158 |
| [12] | Deng QQ, Zhou MQ, Shui W, et al. A novel skull registration based on global and local deformations for craniofacial reconstruction[J]. Forensic Science International, 2011,208(1-3):95-102 |
| [13] | Shui WY, Zhou MQ, Deng QQ, et al. Densely Calculated Facial Soft Tissue Thickness for Craniofacial Reconstruction in Chinese Adults[J]. Forensic Science International, 2016, 266:573.e1-573.e12 |
| [14] | Gietzen T, Brylka R, Achenbach J, et al. A method for automatic forensic facial reconstruction based on dense statistics of soft tissue thickness[J]. PloS one, 2019. 14(1):e0210257 |
| [15] | K?hler K, Haber J, Seidel H. Reanimating the dead: reconstruction of expressive faces from skull data[J]. ACM Transactions on Graphics, 2003,22(3):554-561 |
| [16] | Lee WJ, Wilkinson C, Hwang HS, et al. Correlation Between Average Tissue Depth Data and Quantitative Accuracy of Forensic Craniofacial Reconstructions Measured by Geometric Surface Comparison Method[J]. Journal of Forensic Sciences, 60(3):572-580 |
| [17] | Wilkinson C, Rynn C, Peters H, et al. A blind accuracy assessment of computer-modeled forensic facial reconstruction using computed tomography data from live subjects[J]. Forensic Science, Medicine and Pathology, 2006,2(3):179-187 |
| [18] | Deng QQ, Zhou MQ, Wu ZK, et al. A regional method for craniofacial reconstruction based on coordinate adjustments and a new fusion strategy[J]. Forensic Science International, 2016,259:19-31 |
| [19] | Paysan P, Lüthi M, Albrecht T, et al. Face Reconstruction from Skull Shapes and Physical Attributes[C]. Lecture Notes in Computer Science, Pattern Recognition, Springer, 2009: 232-241 |
| [20] | Berar M, Tilotta F M, Glaunès J A, et al. Craniofacial reconstruction as a prediction problem using a Latent Root Regression model[J]. Forensic Science International, 2011,210(1-3):228-236 |
| [21] | 税午阳, 吴秀杰. 奇和洞古人类头骨面貌的三维虚拟复原[J]. 科学通报, 2018,63(8):745-754 |
| [22] | Sero D, Zaidi A, Li J, et al. Facial recognition from DNA using face-to-DNA classifiers[J]. Nature Communications. 2019,10:2557 |
| [23] | 吴新智. 周口店山顶洞人化石的研究[J]. 古脊椎动物与古人类, 1961,3(3):181-211 |
| [24] | Shui WY, Zhou MQ, Maddock S, et al. A computerized craniofacial reconstruction method for an unidentified skull based on statistical shape models[J]. Multimedia Tools and Applications, 2020,79:25589-25611 |
| [25] | Martin R. Lehrbuch der Anthropologie in systematischer Darstellung[M]. G. Fischer, Stuttgart, 1928 |
| [26] | Wiley DF, Amenta N, Alcantara DA, et al. Evolutionary morphing[C]. IEEE Visualization (VIS’05), 2005: 431-438 |
| [27] | Shui WY, Zhou MQ, Maddock S, et al. A PCA-Based method for determining craniofacial relationship and sexual dimorphism of facial shapes[J]. Computers in Biology and Medicine. 2017,90:33-49 |
| [28] | Shui W, Zhou M, Wu Z, et al. An improved algorithm for craniofacial reconstruction based on landmarks registration[C]. IEEE International Conference on Computer Application and System Modeling (ICCASM), 2010: 498-502 |
| [29] | 税午阳, 周明全, 武仲科, 等. 数据配准的颅骨面貌复原方法[J]. 计算机辅助设计与图形学学报, 2011,23(4):607-614 |
| [30] | Amberg B, Romdhani S, Vetter T. Optimal step nonrigid ICP algorithms for surface registration[C]. IEEE Conference on Computer Vision and Pattern Recognition, 2007: 1-8 |
| [31] | Wilkinson C. Facial reconstruction—anatomical art or artistic anatomy?[J]. Journal of Anatomy, 2010,216:235-250 |
| [32] | Short LJ, Khambay B, Ayoub A, et al. Validation of a computer modelled forensic facial reconstruction technique using CT data from live subjects: a pilot study[J]. Forensic Science International, 2014, 237: 147.e1-147.e8 |
| [33] | Miranda GE, Wilkinson C, Roughley M, et al. Assessment of accuracy and recognition of three-dimensional computerized forensic craniofacial reconstruction[J]. Plos One, 2018,13(5):e0196770 |
| [34] | Cunningham DL and Jantz RL. The morphometric relationship of Upper Cave 101 and 103 to modern Homo sapiens[J]. Journal of Human Evolution, 2003,45(1):1-18 |
| [35] | Kustar A. The facial restoration of Antal Simon, a Hungarian priest-teacher of the 19th c[J]. HOMO-Journal of Comparative Human Biology, 2004,55(1-2):77-90 |
| [36] | Benazzi S, Fantini M, Crescenzio FD, et al. The face of the poet Dante Alighieri reconstructed by virtual modelling and forensic anthropology techniques[J]. Journal of Archaeological Science, 2009,36(2):278-283 |
| [37] | Benazzi S, Bertelli P, Lippi B, et al. Virtual anthropology and forensic arts: the facial reconstruction of Ferrante Gonzaga[J]. Journal of Archaeological Science, 2010,37(7):1572-1578 |
| [38] | 张建军. 谈谈我国古人类化石面貌复原像[J]. 大自然, 2011,3:24-26 |
| [39] | 张建军. 从北京猿人到南京猿人的面貌复原[J]. 化石, 2015,2:66-69 |
| [40] | Vanezis P, Blowes RW, Linney AD, et al. Application of 3-D computer graphics for facial reconstruction and comparison with sculpting techniques[J]. Forensic Science International, 1989,42(1-2):69-84 |
| [41] | Pei Y, Zha H, Yuan Z. The Craniofacial Reconstruction from the Local Structural Diversity of Skulls[J]. Computer Graphics Forum, 2008,27(7):1711-1718 |
| [42] | Stephan CN and Preisler R. In vivo facial soft tissue thicknesses of adult Australians[J]. Forensic Science International, 2018, 282: 220.e1-e12 |
| [43] | Cavanagh D and Steyn M. Facial reconstruction: soft tissue thickness values for South African black females[J]. Forensic Science International, 2011,206(1-3):215 e1-e7 |
| [44] | Shrimpton S, Daniels K, De Greef S, et al. A spatially-dense regression study of facial form and tissue depth: towards an interactive tool for craniofacial reconstruction[J]. Forensic Science International, 2014,234:103-110 |
| [45] | Vandermeulen D, Claes P, Loeckx D, et al. Computerized craniofacial reconstruction using CT-derived implicit surface representations[J]. Forensic Science International, 2006,159(S):S164-S174 |
| [46] | Bulut O, Jessica L C Y, Koca F, et al. Comparison of three-dimensional facial morphology between upright and supine positions employing three-dimensional scanner from live subjects[J]. Legal Medicine, 2017,27:32-37 |
/
| 〈 |
|
〉 |
京ICP证05002819号-3