3D Research Challenges in Cultural Heritage III : : Complexity and Quality in Digitisation.
Saved in:
| Superior document: | Lecture Notes in Computer Science Series ; v.13125 |
|---|---|
| : | |
| TeilnehmendeR: | |
| Place / Publishing House: | Cham : : Springer International Publishing AG,, 2023. ©2023. |
| Year of Publication: | 2023 |
| Edition: | 1st ed. |
| Language: | English |
| Series: | Lecture Notes in Computer Science Series
|
| Online Access: | |
| Physical Description: | 1 online resource (165 pages) |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
Table of Contents:
- Intro
- Preface
- Contents
- The Complexity and Quality in 3D Digitisation of the Past: Challenges and Risks
- 1 Introduction
- 2 The Process of Digitising Movable and Immovable Tangible Cultural Heritage
- 3 Defining Complexity
- 4 Exemplification of Complexity
- 5 Parameters that Determine Quality
- 6 Standards and Benchmarks
- 7 Identification of Gaps, Additional Formats, Standards, Benchmarks, Methodologies, and Guidelines
- 8 Uncertainty
- 9 Forecast Impact of Future Technological Advances
- 10 3D Digitisation Process Complexity
- 11 Conclusion
- References
- Towards Sustainable Digitization
- 1 Introduction
- 2 What Makes Heritage Documentation so Complex? Key Limiting Factors in Surveys with TLS
- 2.1 Technological Aspects
- 2.2 Challenging Object Properties
- 2.3 Challenging Circumstances and Environment
- 3 Technological Strategies for Managing Complexity and Data Quality in High Profile Projects
- 3.1 Software and Workflow Strategies
- 3.2 Hardware Approaches
- 4 Conclusions and Outlook
- References
- Evolving Standards in Digital Cultural Heritage - Developing a IIIF 3D Technical Specification
- 1 Overview
- 2 Key Use Cases and Prototypes
- 3 Combining Content in 3D Environments
- 4 Requirements for Annotation in a 3D Environment
- 5 Authentication and Search APIs for 3D Content
- 6 IIIF 3D Technical Specification Group Charter
- References
- The Quality in 3D Acquisition of Cultural Heritage Assets: Challenges and Risks
- 1 Introduction
- 2 Technologies for 3D Acquisition
- 2.1 Photogrammetry Methods
- 2.2 Laser Scanners
- 2.3 Handheld for Close-Range Acquisition
- 2.4 Supplementary Instruments
- 3 Factors Affecting the Quality of 3D Acquisition
- 3.1 Instrumental
- 3.2 Object Materials and Geometry
- 3.3 Environmental Conditions
- 3.4 Human Factor
- 4 Conclusions
- References.
- How to Measure Quality Models? Digitization into Informative Models Re-use
- 1 Introduction
- 2 Complexity and Quality: #Parameters into a Multiple Variable Radar Chart
- 2.1 A Success Story into the Radar Chart: The Basilica di Santa Maria di Collemaggio (L'Aquila, Earthquake 2009) Reopened to the Public in 2018, Awarded by Europa Nostra 2020
- 3 How to Define the User Needs? #Scale as a Parameter
- 3.1 How to Measure Quality Model? Surveying to Digitization: Scale as a Parameter to Check Quality Control and to Re-use Models
- 3.2 3D Quality Content Models: #scale as a Parameter to Select the Proper Instruments and to Process Reliable Data (Precision and Accuracy): Specifications, Scales of Representation, Minimum Detail, and Tolerance Parameters
- 4 Beyond Geometry Through Geometry: # Parameters to Manage Informative Enriched 3D Quality Models Contents Transferring
- 4.1 Not Just a Matter of Measuring: Geometries Embodying Materials and Construction Techniques Through HBIM
- 4.2 Structural Health Monitoring: #Finite Element Analysis Complex Models as a Parameter of Quality (BIM-to-FEA)
- 4.3 3D Quality Models Enriched by Building Archeology: HBIM 3D Volume Stratigraphic Units and Levels of Uncertainties
- 5 Toward Quality Model Specification: BIM to HBIM LOGs-LODs, Reversing the Logic Simplex-to-Complex BIM Model (Building Construction) in Favor of Complex Modeling Knowledge-Creation Since the Design Starting Phases
- 5.1 # Level of Development Phases Inherited by the BIM Logic and Adapted to the HBIM
- 5.2 Levels of Geometry Proposal in the Heritage Domain: HBIM LOG100-200-300-400-500-600
- 5.3 Sharing 3D Quality Models, Re-use and Circulation: Common Data Environment Toward XR Platforms and Interoperability
- 6 Conclusions and Remarks
- References.
- The Holistic Documentation of Movable Cultural Heritage Objects - The Case of the Antikythera Mechanism
- 1 Introduction
- 2 Identifying Necessary Data for the Holistic Documentation of Movable Archaeological Findings
- 3 The Existing Data for the Holistic Documentation of the Antikythera Mechanism
- 3.1 The Antikythera Shipwreck and the Discovery of the Mechanism
- 3.2 The Investigation of the Antikythera Mechanism
- References
- Digital Documentation of Reflective Objects: A Cross-Polarised Photogrammetry Workflow for Complex Materials
- 1 Introduction
- 1.1 Background
- 1.2 Our Approach
- 2 Methodology
- 2.1 Data Capture
- 2.2 Data Processing
- 3 Results and Discussion
- 3.1 Ceramic
- 3.2 Metal
- 3.3 Wood
- 4 Conclusion
- Appendix
- References
- Author Index.