|Table of Contents|

Reconstruction and Application of Paleo-Stratigraphy ofArchaeological Site Based on Multi-Source Data Fusion(PDF)

《南京师大学报(自然科学版)》[ISSN:1001-4616/CN:32-1239/N]

Issue:
2020年02期
Page:
49-55
Research Field:
·地理学·
Publishing date:

Info

Title:
Reconstruction and Application of Paleo-Stratigraphy ofArchaeological Site Based on Multi-Source Data Fusion
Author(s):
Shen Jiangwei12Yang Lin13Zheng Fangzihao1Wu Weihong4
(1.Key Laboratory of Virtual Geographic Environment of Ministry of Education,Nanjing Normal University,Nanjing 210023,China)(2.Suzhou Industrial Park Surveying,Mapping and Geoinformation Company,Suzhou 215027,China)(3.Jiangsu Center for Collaborative Innovation in Geographical Information Resource Development and Application,Nanjing 210023,China)(4.Department of History,Anhui University,Hefei 230039,China)
Keywords:
multi-source datapaleo-stratigraphic reconstructiondata fusionapplication analysisLingjiatan Site
PACS:
P234.1 K854.3
DOI:
10.3969/j.issn.1001-4616.2020.02.009
Abstract:
A multi-source data fusion method and a 3D modeling method for paleostratigraphy(by focusing on solving the difference of the multi-source data in the space criterion,scale,data structure and so on.)based on fusion results were proposed in this paper. By taking Lingjiatan Site as a study case,the 3D model of the ancient surface was constructed based on UAV aerial data,extensive drilling data,basic geographic data,field archaeological maps,text data and so on. What’s more,the application research method of spatial statistics,spatial relationship and optimal path analysis based on the constructed model were also discussed preliminarily in the paper,and the experimental results were in line with the expectations of archaeologists. It had proved that the method proposed in this paper provided an intuitive and scientific visualization platform for archaeological research,and was helpful for further analysis of spatio-temporal relationship of various relics in large-scale sites. Besides,it could help archaeologists understand the living environment,customs and productivity development level of the ancients,and provide a basis for the study of historical development and environmental change. More importantly,this study deepens the cross-application of geography and archaeology,not only solves the practical problems in digital archaeology and promotes the process of archaeological digitization and standardization,but also brings new vitality into the geography subject,and expands the new direction of historical and geographical research.

References:

[1] 杨林,裴安平. 田野考古地层空间数据模型构建[J]. 应用基础与工程科学学报,2011,19(1):85-94.
[2]KONNIE L,BRANDON R. Practical application of GIS for archaeologists:a predictive modeling toolkit[M]. London; New York:Taylor & Francis,2005:144-159.
[3]FORD M,GRIFFITHS R,WATSON L. The sandford inventory of earth buildings constructed using a GIS[J]. Building and environment,2005,40(7):964-972.
[4]DAY W,COSMAS J,RYAN N,et al. Linking 2D harris matrix with 3D stratigraphic visualizations:an integrated approach to archaeological visualizations[EB/OL]. [2019-05-12]. https://publikationen.uni-tuebingen.de/xmlui/handle/10900/60970.
[5]阚瑷珂. 考古地层的三维可视化及应用研究[D]. 成都:成都理工大学,2006.
[6]林冰仙,周良辰,盛业华,等. 基于手绘图件的考古遗址三维建模方法[J]. 地球信息科学学报,2014,16(3):349-357.
[7]张立莹. 考古地层的三维建模方法在秦始皇帝陵考古勘探中应用尝试[J]. 文物保护与考古科学,2017,29(2):63-66.
[8]ARIF R,ESSA K. Evolving techniques of ation of a world heritage site in Lahore[J]. The international archives of photogrammetry,remote sensing and spatial information sciences,2017,42(2):33-40.
[9]BENJAMIN D,DAVID S,JOSEPH R. Multiview 3D reconstruction of the archaeological site at Weymouth from image series[J]. Computers & graphics,2011,35(2):375-382.
[10]JEFFREY L,CHRISTOPHER C,NICHOLAS P,et al. Employing airborne lidar and archaeological testing to determine the role of small depressions in water management at the ancient Maya site of Yaxnohcah,Campeche,Mexico[J]. Journal of archaeological science:reports,2017,13:291-302.
[11]JAMES M,NORMAN S,ANGELINA D,et al. A geoinformatic approach to the collection of archaeological survey data[J]. Cartography and geographic information science,2013,40(1):3-17.
[12]ROSA L,ROSA C,FABRIZIO T,et al. On the LiDAR contribution for the archaeological and geomorphological study of a deserted medi village in Southern Italy[J]. Journal of geophysics and engineering,2010,7(2):155-163.
[13]DEODATO T,VANESSA B,LEE J,et al. Contextualising archaeological models with geological,airborne and terrestrial LiDAR data:the ice age landscape in farndon fields,Nottinghamshire,UK[J]. Journal of archaeological science,2017,81:31-48.
[14]ROVERATO M,CAPRA L,SULPIZIO R,et al. Stratigraphic reconstruction of two debris avalanche deposits at Colima Volcano(Mexico):insights into pre-failure conditions and climate influence[J]. Journal of volcanology and geothermal research,2011,207(1):33-46.
[15]赵明. Pix4D mapper软件在无人机航空摄影与工程地质调查中的数据处理[J]. 水电站设计,2017,33(2):47-48,62.
[16]吴立新,史文中. 地理信息系统原理与算法[M]. 北京:科学出版社,2003.
[17]党海燕. 考古探方三维数据组织与可视化研究[D]. 石家庄:河北师范大学,2018.
[18]张渭军,王文科. 基于钻孔数据的地层三维建模与可视化研究[J]. 大地构造与成矿学,2006(1):108-113.
[19]刘林贵,刘高扬. 基于ArcGIS的三维地层建模方法[J]. 山西建筑,2015,41(12):55-56.
[20]胡杨. 面向田野考古发掘场景3D重建的点云数据处理方法[D]. 南京:南京师范大学,2016.
[21]王心源,吴立,吴学泽,等. 巢湖凌家滩遗址古人类活动的地理环境特征[J]. 地理研究,2009,28(5):1208-1216.
[22]邵英,张敬国. 凌家滩上的远古文明[J]. 文物鉴定与鉴赏,2018,127(4):80-82.
[23]刘松林. 凌家滩遗址防御体系及其社会意义之蠡测[J]. 巢湖学院学报,2014,16(5):5-8.
[24]高伟,张剑波. 基于栅格数据模型的最优路径分析算法及实现[J]. 黑龙江工程学院学报,2004,18(1):22-24.

Memo

Memo:
-
Last Update: 2020-05-15