Submitted:
14 July 2026
Posted:
15 July 2026
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Abstract
Keywords:
1. Introduction
- to develop and implement a VRTI workflow through a dedicated virtual workspace in Blender, providing a reproducible environment for virtual relighting and image generation;
- to validate the scientific reliability of the proposed VRTI methodology by assessing whether it provides an operationally simpler yet perceptually equivalent alternative to conventional RTI for dinosaur footprint interpretation through a controlled comparative protocol;
- to evaluate the usability of the validated workspace through a pilot System Usability Scale (SUS) study, assessing its suitability for adoption by Cultural Heritage and ichnological practitioners.
2. Related Works
2.1 Introduction to the Study of Footprints and Documentation Problems
2.2 RTI and Virtual RTI: Limitations, Extensions, and Methodological Challenges
3. Materials and Methods
3.1. The Context

3.2. RTI Acquisition

3.3. 3D Scanning and Virtual Dome: a Standardised Workspace for VRTI Workflow
3.3.1. 3D Acquisition Campaign
3.3.2. Virtual Dome Creation and Parameters Configuration
3.4. Relighting: RTI and VRTI
3.5. User-Based Evaluation on Footprint Readability
3.5.1. Materials

3.5.2. Participants and Procedure
3.5.3. Evaluation Framework
- Unidirectional distance (primary metric)
- Bidirectional Chamfer distance (complementary analysis)
- Root Mean Square Error (RMSE): used as the primary metric, as it preserves the original measurement units (pixels) while penalizing larger deviations, providing a robust measure of overall geometric accuracy.
- 90th percentile (P90): Calculated to identify the error threshold for 90% of the tracing, offering a reliable representation of typical performance by reducing the influence of extreme outliers.
- Standard Deviation (StdDev): Used to assess the consistency and variability of the tracing stroke across each participant’s dataset.
3.6. Validation and Standardisation of the Workspace
- approximately 15 minutes to set up the workspace and launch the VRTI rendering process;
- approximately 1 hour for rendering, depending on hardware specifications and selected output resolution. This phase did not require active user intervention and could be executed in the background;
- no more than 15 minutes to complete a final anonymous questionnaire.
4. Results
4.1. Quantitative Results: Unidirectional Point Clouds Analysis

4.2. Qualitative Results: Expert Evaluation
4.3. Lighting Perspective And Spatial Behavior
4.4. SUS Results Of VRTI Workspace
5. Discussion
6. Conclusion
7. Patents
Author Contributions
Funding
Data Availability Statement
Acknowledgments
References
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| Scanner: Artec Spider II | Source scans | Maximum error (Resolution) | Tracking mode | FPS | Triangular mesh | 3D model size |
| CS1 (CNA1943) | 10 | 0.2mm | Geometry + texture | 8 | 2,900,000 | 65MB |
| CS2 (CNA1944) | 8 | 0.2mm | Geometry + texture | 8 | 2,570,807 | 56MB |
| CS3 (CNA1946) | 3 | 0.2mm | Geometry + texture | 8 | 2,997,132 | 65MB |
| Task | Group | RMSE | P90 | StdDev | p-value |
|---|---|---|---|---|---|
| A (Footprint) | RTI | 57.30 | 96.86 | 42.42 | 0.361 |
| VRTI | 59.70 | 104.98 | 43.36 | ||
| B (Detail) | RTI | 67.04 | 123.85 | 47.41 | 0.255 |
| VRTI | 59.46 | 105.54 | 37.96 |
| Axis | RTI Mean | VRTI Mean | RTI Median | VRTI Median | p-value |
|---|---|---|---|---|---|
| X | 0.10 | -0.06 | 0.25 | -0.30 | 0.366 |
| Y | -0.05 | -0.20 | -0.15 | -0.30 | 0.344 |
| SUS question | Normalized average values (0-10) |
|---|---|
|
6.36 |
|
7.73 |
|
6.82 |
|
7.27 |
|
7.73 |
|
7.73 |
|
6.36 |
|
6.14 |
|
5.45 |
|
6.14 |
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