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MAAYA: Multimedia Analysis and Access for Documentation and
Decipherment of Maya Epigraphy
April Morton
Gulcan Can
Rui Hu
February 27th, 2013
The MAAYA Project
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Main goal: Advance the state of the art in image description and visualization techniques, while providing support to epigraphers
Dr. Daniel Gatica-Perez
Gulcan Can
Dr. Jean-Marc Odobez
Dr Rui Hu
Prof. Stéphane Marchand-Maillet
Dr. Edgar Roman-Rangel
April Morton
Oscar Dabrowski
Prof. Nikolai Grube
Carlos Pallan
Guido Krempel
Outline
• Mayan Overview
• Project Overview
• Data Preparation/Storage
• Computer Vision Algorithms
• Using Context to Improve Glyph Recognition
• Visualization
• Conclusion
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Mayan Overview
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Ancient Mayan Culture
Flourished from BC 2000 - 1500 AD
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Mayan Writing System
Mayan Overview
Logographs
Syllabographs
Iconography
Take Photographs
Obtain Digital Line Drawings
Identify Glyphs Annotate Glyphs
Documentation Process
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Mayan Overview
Need better digital preservation and automatic analysis techniques
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The CODICES Project
Project Overview
Statistical Shape Descriptors
CBIR System
Main goal: Develop statistical shape descriptors and a CBIR system
The MAAYA Project
Project Overview
Data Preparation/Storage
Content-Based Data Processing/Computer
Vision Algorithms High Level Analysis Visualization
Main Goal: Advance the state of the art in image description and visualization techniques, while providing support to epigraphers
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Data Preparation/Storage Process
Segment glyphs and blocks
Upload segmented page into database
Annotate and store glyphs
Computer Vision Algorithms
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Glyph Representation
Identification
(Classification
- Retrieval)
Attribute Learning
Where is the
data?
How to recognize the data?
Localization
Segmentation
Decomposition
Sparse Representation
Shape Descriptors
Part-based Representation
Computer Vision Algorithms
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Localization
Computer Vision Algorithms
Localization
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Computer Vision Algorithms
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Segmentation
Hierarchical Decomposition
Codices → Page → T'ol → Row of Blocks → Block → Glyph
Computer Vision Algorithms
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• Glyph representation + Identification • Can we utilize/capture diagnostic features?
Computer Vision Algorithms
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Recognition
Computer Vision Algorithms
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Diagnostic Features
Computer Vision Algorithms
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Histogram-of-Orientations Shape Context
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Learning Features with Autoencoders
Computer Vision Algorithms
Computer Vision Algorithms
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Compute pivots and HOOSC descriptors
k-means clustering & bag-of-visual-words
representation
Ranking of “bov”s of each glyph
Identification – Glyph Retrieval
Computer Vision Algorithms
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Compute pivots and HOOSC descriptors
Classify each pivot
Apply voting for glyph-level prediction
Identification - Classification
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Using context to improve glyph recognition
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Using context to improve glyph recognition
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Using context to improve glyph recognition
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Category:T668.T102 Cha-ki Meaning: Rain god
Category:T227:T561.T23 xib?-ka’an-na Meaning: man, sky, ?
Using context to improve glyph recognition
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Data preparation
Using context to improve glyph recognition
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Glyph matching
Using context to improve glyph recognition
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Glyph matching
Using context to improve glyph recognition
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● Statistic language model
● Icon
● Translation
Category:T668.T102 Cha-ki Meaning: Rain god
Category:T227:T561.T23 xib?-ka’an-na Meaning: man, sky, ?
Using context to improve glyph recognition
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Context Information
Using context to improve glyph recognition
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● Improve recognition accuracy
● Help with noisy and partially missing examples
● High-level translation
Using context to improve glyph recognition
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A final goal is to advance state-of-the art in effective interactive visualization tools
Visualization
Input Data
Apply Data Mining
Technique
Display Visualization
Accept User Input
Update Parameters
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MDS projection based on weighted Euclidean distance function
Interactive Clustering
Visualization
Data from UCI wine data set
Eli T. Brown, Jingjing Liu, Carla E. Brodley, Remco Chang: Dis-function: Learning distance functions interactively. IEEE VAST 2012: 83-92
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Interactive Clustering
Visualization
Re-projection
Eli T. Brown, Jingjing Liu, Carla E. Brodley, Remco Chang: Dis-function: Learning distance functions interactively. IEEE VAST 2012: 83-92
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Interactive Clustering
Visualization
Updated Weights
Re-projection Could think of data points as glyphs
Eli T. Brown, Jingjing Liu, Carla E. Brodley, Remco Chang: Dis-function: Learning distance functions interactively. IEEE VAST 2012: 83-92
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Distribution of values among attributes
Visualization
Can filter and sort words based on probability of co-occurrence
Area encodes probabilities
Topic Model Visualization
Jason Chuang, Christopher D. Manning, Jeffrey Heer: Termite: visualization techniques for assessing textual topic models. AVI 2012: 74-77
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Topic Model Visualization
Visualization
Area encodes probabilities
Can filter and sort words based on probability of co-occurrence
Can think of terms as glyphs
Can think of documents as codices (add) Jason Chuang, Christopher D. Manning, Jeffrey Heer: Termite: visualization techniques for assessing textual topic models. AVI 2012: 74-77
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Conclusion
The MAAYA project aims to improve the entire process of digital glyph analysis
Data Preparation/Storage
Content-Based Data Processing/Computer
Vision Algorithms High Level Analysis Visualization
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Main Goal: Advance the state of the art in image description and visualization techniques, while providing support to epigraphers
And a special thanks to the Swiss National Science Foundation: Project CR21I2L_144238
Acknowledgements
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Questions
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Backup Slides
The webpage includes a user friendly upload wizard for segmented files
The Online Wizard
As well as a standardized data annotation page
The Data Annotation Page
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Mayan Overview
Mayan Writing System
Mayan Writing System
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Mayan Overview
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