基本信息出版社：浙江大学出版社
页码：219 页
出版日期：2009年10月
ISBN：9783642048616
条形码：9783642048616
版本：第1版
装帧：精装
开本：16
正文语种：英语
外文书名：Digital Preservation For Heritages:Technologies and Applications

内容简介 《文化遗产的数字化保护:技术与应用(英文版)》内容简介：Digital Preservation for Heritages Technologies and Applications provides a comprehensive and up-to-date coverage of digitaltechnologies in the area of cultural heritage preservation, includingdigitalization, research aiding, conservation aiding, digital exhibi-tion, and digital utilization. Processes, technical frameworks, keytechnologies, as well as typical systems and applications are discussedin the book. It is intended for researchers and students in the fields ofcomputer science and technology, museology, and archaeology.
作者简介 Dr. Dongming Lu is a professor at College of Computer Science andTechnology, Zhejiang University, China. His research area includesdigital preservation for cultural heritages and digital media networks.
Prof. Yunhe Pan is a member of Chinese Academy of Engineering,and also a professor at College of Computer Science and Technology,Zhejiang University, China. His research area includes digitalpreservation for cultural heritages, digital library, and intelligenthuman animation.
编辑推荐 《文化遗产的数字化保护:技术与应用(英文版)》由浙江大学出版社出版。
目录
1 Introduction
1.1 Cultural Heritage, the Crystallization of History
1.2 Cultural Heritage Preservation and Its Objectives
1.3 New Requirements of Digital Technologies for Heritage Preservation
References

2 The Basis of Digital Technologies for Cultural Heritage Preservation
2.1 Basis of Information Acquisition and Perception
2.1.1 Digital Photography and Processing
2.1.2 3D Scanning and Processing
2.1.3 3S Technology
2.1.4 Sensing and Wireless Transmission
2.2 Basis of Information Analysis and Recognition
2.2.1 Image Processing
2.2.2 Intelligent Information Processing
2.3 Basis of Digital Exhibition and Interaction
2.3.1 Animation
2.3.2 Real-time Rendering
2.3.3 Stereo Display
2.3.4 Natural Interaction
2.4 Summary
References

3 Digitalization of Cultural Heritage
3.1 Information Acquisition from Archaeological Excavation Sites
3.1.1 Preventing Loss of Information from Archaeological Sites
3.1.2 Process and Technical Framework of Information Acquisition from Archaeological Excavation Sites
3.1.3 Key Technologies for Information Acquisition from Archaeological Excavation Sites
3.1.4 Typical System for Information Acquisition from Archaeological Excavation Sites and Applications
3.2 Information Acquisition of Museum Preserved Sculptures and Artifacts
3.2.1 Digital Technology Makes Sculptures and Artifacts Remain "Young Forever"
3.2.2 Information Acquisition Process and Technical Framework for Museum Preserved Sculptures and Artifacts
3.2.3 Key Technologies for Information Acquisition of Museum Preserved Sculptures and Artifacts
3.2.4 Devices and Applications
3.3 Information Acquisition from Large Scenes
3.3.1 Process and Technical Framework of Large Scene Information Acquisition
3.3.2 Key Technologies of Large Scene Information Acquisition
3.3.3 Typical Applications
3.4 Information Acquisition of Large Paintings and Murals
3.4.1 Process and Technical Framework of Acquisition of Large Paintings and Murals
3.4.2 Key Technologies for Information Acquisition of Large Paintings and Murals
3.4.3 Typical Devices and Applications
3.5 Summary and Prospects
References

4 Archaeological Research Aiding Technologies
4.1 Digital Technology and Archaeological Research
4.2 Process and Technical Framework of Archaeological Research Aiding
4.2.1 Process of Archaeological Research Aiding Technologie
4.2.2 Technical Framework of Archaeological Research Aiding Technologies
4.3 Typical Applications
4.3.1 Utilization of RS
4.3.2 Digital Measurement of Large-size Archaeological Sites
4.3.3 Computer Aided Bronze Ware Identification Expert System
4.3.4 Reconstruction Simulation of Stilt Style Buildings of the Hemudu Site
4.4 Summary and Prospects
References

5 Digitally Aided Conservation and Restoration of Cultural Heritages
5.1 Digitally Aided Investigation
5.1.1 Current Situation Investigation by Digitally Aided Technologies
5.1.2 Process and Technical Framework of Digitally Aided Current Situation Investigation
5.1.3 Key Technologies of Digitally Aided Investigation
5.1.4 Typical Digitally Aided Current Situation Investigation System
5.2 Dynamic Environmental Monitoring of Cultural Heritages
5.2.1 Process and Technical Framework of Dynamic Environmental Monitoring
5.2.2 Key Technologies of Dynamic Environmental Monitoring
5.2.3 Typical Dynamic Environmental Monitoring System
5.3 Digitally Aided Restoration of Cultural Heritages
5.3.1 Process and Technical Framework of Digitally Aided Restoration
5.3.2 Key Technologies in Digitally Aided Restoration
5.3.3 An Introduction to Typical Application of Digitally Aided Conservation and Virtual Restoration
5.4 Summary and Prospects
References

6 The Impact of Digital Technologies on the Exhibition of Cultural Heritages
6.1 Online Heritage Exhibition
6.1.1 Online Exhibitions Breaking Constraints of Time and Space
6.1.2 Process and Technical Framework of Online Heritage Exhibitions
6.1.3 Key Technologies for Online Heritage Browsing
6.1.4 Typical Online Heritage Exhibition Applications
6.2 Digital Exhibitions of Reconstructed Archaeological Sites
6.2.1 Archaeological Sites Exhibition of Reconstructed Original Appearance
6.2.2 Process and Technical Framework of a Digital Reconstruction Exhibition
6.2.3 Key Technologies of Digital Reconstruction Exhibition
6.2.4 Typical Applications for Digitized Reconstruction and Exhibition of Sites
6.3 Interactive Experience in the Exhibition Hall
6.3.1 Interactive Experience that Enhances a Sense of Participation
6.3.2 Process and Technical Framework of the Interactive Experience in the Exhibition Hall
6.3.3 Key Technologies of Interactive Experience in Exhibition Hall
6.3.4 Typical Application of Interactive Experience System
6.4 Summary and Prospects
References

7 Digital Development and Utilization of Cultural Heritages' Information
7.1 Culture Heritages' Value
7.2 Process and Technical Framework of Digital Development and Utilization
7.3 Key Technologies for Development and Utilization
7.3.1 Source Material Extraction
7.3.2 Expression and Extraction of Ancient Murals'Artistic Style
7.3.3 Artistic Style Learning Based Re-creation
7.3.4 Computer-aided Imitation of Murals
7.4 Introduction of Typical System for the Development and Utilization
7.4.1 Computer Aided Art Design and Creating System
7.4.2 Semantic Modeling for Chinese Ancient Buildings
7.5 Summary and Prospects
References

8 Applications of Digital Preservation Technologies for Cultural Heritages
8.1 Digital Preservation Project for the Mogao Grottoes
8.1.1 Digital Acquisition of the Dunhuang Grottoes
8.1.2 Microclimate Monitoring in the Mogao Grottoes
8.1.3 Digitally-Aided Imitation of the Dunhuang Murals
8.1.4 Color Simulation of the Dunhuang Murals
8.1.5 Dunhuang-style Pattern Creation and Product Development
8.2 Digital Preservation Project for the Jinsha Site
8.2.1 Information Management and Sharing for Archaeological Sites
8.2.2 Acquisition and Exhibition of the Excavation Field
8.3 Digital Reconstruction Project of the Hemudu Site
8.4 Digital Exhibition of the Liangzhu Relics
8.5 Summary
References
9 Summary and Prospect
Index
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序言 Cultural heritages include rich information related to social, historical andcultural values. Affected by climate, environmental and other factors, somevaluable heritage information is threatened through destruction or disappear-ance, and some is still not utilized sufficiently. How to investigate and utilizesuch information effectively is a significant scientific and technological issue.Archaeologists, museologists and conservators are working on issues such asthe excavation of precious heritage items, the exhibiting of this valuable in-formation and the strengthening of their outline structure, which aims toconserve and utilize the heritage items as well as their values.
The development of information technology has shown its significant rolein large and fast digitalization, personalization and so on. Information tech-nology is more and more important in heritage preservation, including, butnot limited to, digitalization, digitally-aided research, conservation, exhibi-tion and utilization. First introduced in the 1980s, information technologywas initially used to store information about relics, and then some digital-ization and exhibition applications were implemented. Currently, informationtechnology is applied in many different aspects in heritage information preser-vation.
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Developed in 1960s, RS has its broad sense and narrow sense. In a broadsense, it is a detection technology that remotely senses objects and naturalphenomena using electromagnetic waves, gravitational fields, electric fields,mechanical waves （sound waves, seismic waves）, and so on, without directcontact. In a narrow sense, it is a technology that is used to study the shapes,sizes, locations, and properties of objects on the earth and their correlationswith the environment. The radiation features of electromagnetic waves, fromultraviolet to microwave, of various objects on the earth are obtained usingvarious sensors placed on aerospace carriers （including near-earth carriers）at different heights. Those features are then formed into images, which arethen transmitted and processed. Through such procedures, the attributes ofobjects on the earth are identified, and their temporal and spatial changingrules are explored.
Multi-sensors, high-resolution, and multi-temporal data are the distinctivefeatures of contemporary development of RS technology. The application andanalysis of RS information is currently undergoing a number of changes fromthe analysis of single remote sensing data to the analysis of fused informationfrom multiple data sources, from static analysis to dynamic monitoring anal-ysis, from qualitative investigation to computer-aided automatic quantitativeinvestigation. Aerial RS has become an important aspect of RS developmentfor the reason of its mobility and high-resolution.
RS archaeology, as its name suggests, is the nondestructive detection ofobjects on the ground, underground, or underwater using RS technology. Tobe specific, we detect, record, and analyze archaeological sites and their re-gional environments from four levels, namely aerospace, aviation, ground andunderground, using geophysical means such a
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