Multispectral and hyperspectral image analysis has experienced much
development in the last decade. The application of these methods to palimpsests
has produced significant results, enabling researchers to recover texts that
would be otherwise lost under the visible overtext, by improving the contrast
between the undertext and the overtext. In this paper we explore an extended
number of multispectral and hyperspectral image analysis methods, consisting of
supervised and unsupervised dimensionality reduction techniques, on a part of
the Syriac Galen Palimpsest dataset (www.digitalgalen.net). Of this extended
set of methods, eight methods gave good results: three were supervised methods
Generalized Discriminant Analysis (GDA), Linear Discriminant Analysis (LDA),
and Neighborhood Component Analysis (NCA); and the other five methods were
unsupervised methods (but still used in a supervised way) Gaussian Process
Latent Variable Model (GPLVM), Isomap, Landmark Isomap, Principal Component
Analysis (PCA), and Probabilistic Principal Component Analysis (PPCA). The
relative success of these methods was determined visually, using color
pictures, on the basis of whether the undertext was distinguishable from the
overtext, resulting in the following ranking of the methods: LDA, NCA, GDA,
Isomap, Landmark Isomap, PPCA, PCA, and GPLVM. These results were compared with
those obtained using the Canonical Variates Analysis (CVA) method on the same
dataset, which showed remarkably accuracy (LDA is a particular case of CVA
where the objects are classified to two classes).Comment: 29 February - 2 March 2016, Second International Conference on
  Natural Sciences and Technology in Manuscript Analysis, Centre for the study
  of Manuscript Cultures, Hamburg, German

Arsene, Corneliu

Bhayro, Siam

Pormann, Peter

Sellers, W I

English

arXiv

Multispectral/hyperspectral image analysis has experienced much development in the last decade
(Kwon et al. 2013; Wang and Chunhui 2015; Shanmugam and Srinivasa Perumal 2014; Chang 2013;
Zhang and Du 2012). The application of these methods to palimpsests (Bhayro 2013; Pormann 2015;
Hollaus et al. 2012) has produced significant results, enabling researchers to recover texts that would
be otherwise lost under the visible overtext, by improving the contrast between the undertext and
the overtext. In this paper we explore an extended number of multispectral/hyperspectral image
analysis methods, consisting of supervised and unsupervised dimensionality reduction techniques
(van der Maaten and Hinton 2008), on a part of the Syriac Galen Palimpsest dataset
(http://www.digitalgalen.net). Of this extended set of methods, eight methods gave good results:
three were supervised methods – Generalized Discriminant Analysis (GDA), Linear Discriminant
Analysis (LDA), and Neighborhood Component Analysis (NCA); and the other five methods were
unsupervised methods – Gaussian Process Latent Variable Model (GPLVM), Isomap, Landmark
Isomap, Principal Component Analysis (PCA), and Probabilistic Principal Component Analysis (PPCA).
The relative success of these methods was determined visually, using color pictures, on the basis of
whether the undertext was distinguishable from the overtext, resulting in the following ranking of
the methods: LDA, NCA, GDA, Isomap, Landmark Isomap, PPCA, PCA, and GPLVM. These results were
compared with those obtained using the Canonical Variates Analysis (CVA) method [6,7] on the same
dataset, which showed remarkably accuracy (LDA is a particular case of CVA where the objects are
classified to two classes). A comparison was also made with a double thresholding and processing
technique, developed as part of this project, which consists of the following: the darker overtext is
carefully identified by the human operator and colored in white (threshold 1), and then the
remaining undertext, which is black but not as black as the overtext was, is made even darker
(threshold 2). This last technique showed some initial encouraging results, but its success depends on
the human operator selecting suitable cutting values. Figure 1 shows the results and a comparison of
the different computational techniques applied to page 102v‐107r_B of the Syriac Galen Palimpsest
data (http://www.digitalgalen.net) and for the page obtained with the ultraviolet (365 nm)
illumination with green color filter (i.e. called CFUG).
Ultimately the choice of technique is based on the preferences of the person trying to read the
manuscript and the precise makeup of the original document but easy access to an appropriate
toolset is clearly highly desirable. Further work will consist of applying other reducing dimensionality
techniques that enable the recovery of the undertext in palimpsests, as well as applying the above
techniques to the rest of the Syriac Galen Palimpsest

Sellers, William

NEUROSURGERY ENTHUSIASTIC WOMEN SOCIETY

Computational Techniques in Multispectral Image Processing: Application to the Syriac Galen Palimpsest

Multispectral/hyperspectral image analysis has experienced much development in the last decade (Kwon et al. 2013; Wang and Chunhui 2015; Shanmugam and Srinivasa Perumal 2014; Chang 2013; Zhang and Du 2012). The application of these methods to palimpsests (Bhayro 2013; Pormann 2015; Hollaus et al. 2012) has produced significant results, enabling researchers to recover texts that would be otherwise lost under the visible overtext, by improving the contrast between the undertext and the overtext. In this paper we explore an extended number of multispectral/hyperspectral image analysis methods, consisting of supervised and unsupervised dimensionality reduction techniques (van der Maaten and Hinton 2008), on a part of the Syriac Galen Palimpsest dataset (http://www.digitalgalen.net). Of this extended set of methods, eight methods gave good results: three were supervised methods – Generalized Discriminant Analysis (GDA), Linear Discriminant Analysis (LDA), and Neighborhood Component Analysis (NCA); and the other five methods were unsupervised methods – Gaussian Process Latent Variable Model (GPLVM), Isomap, Landmark Isomap, Principal Component Analysis (PCA), and Probabilistic Principal Component Analysis (PPCA). The relative success of these methods was determined visually, using color pictures, on the basis of whether the undertext was distinguishable from the overtext, resulting in the following ranking of the methods: LDA, NCA, GDA, Isomap, Landmark Isomap, PPCA, PCA, and GPLVM. These results were compared with those obtained using the Canonical Variates Analysis (CVA) method [6,7] on the same dataset, which showed remarkably accuracy (LDA is a particular case of CVA where the objects are classified to two classes). A comparison was also made with a double thresholding and processing technique, developed as part of this project, which consists of the following: the darker overtext is carefully identified by the human operator and colored in white (threshold 1), and then the remaining undertext, which is black but not as black as the overtext was, is made even darker (threshold 2). This last technique showed some initial encouraging results, but its success depends on the human operator selecting suitable cutting values. Figure 1 shows the results and a comparison of the different computational techniques applied to page 102v‐107r_B of the Syriac Galen Palimpsest data (http://www.digitalgalen.net) and for the page obtained with the ultraviolet (365 nm) illumination with green color filter (i.e. called CFUG). Ultimately the choice of technique is based on the preferences of the person trying to read the manuscript and the precise makeup of the original document but easy access to an appropriate toolset is clearly highly desirable. Further work will consist of applying other reducing dimensionality techniques that enable the recovery of the undertext in palimpsests, as well as applying the above techniques to the rest of the Syriac Galen Palimpsest

The University of Manchester - Institutional Repository

The University of Manchester ResearchComputational Techniques in Multispectral ImageProcessing : Application to the Syriac Galen PalimpsestDocument VersionProofLink to publication record in Manchester Research ExplorerCitation for published version (APA):Arsene, C., Pormann, P., Sellers, W. I., & Bhayro, S. (2016). Computational Techniques in Multispectral ImageProcessing : Application to the Syriac Galen Palimpsest. 29-30. Paper presented at Second InternationalConference on Natural Sciences and Technology in Manuscript Analysis, Centre for the Study of ManuscriptCultures, Hamburg, 29 February - 2 March 2016 , Hamburg, Germany.Citing this paperPlease note that where the full-text provided on Manchester Research Explorer is the Author Accepted Manuscriptor Proof version this may differ from the final Published version. If citing, it is advised that you check and use thepublisher's definitive version.General rightsCopyright and moral rights for the publications made accessible in the Research Explorer are retained by theauthors and/or other copyright owners and it is a condition of accessing publications that users recognise andabide by the legal requirements associated with these rights.Takedown policyIf you believe that this document breaches copyright please refer to the University of Manchester’s TakedownProcedures [http://man.ac.uk/04Y6Bo] or contact uml.scholarlycommunications@manchester.ac.uk providingrelevant details, so we can investigate your claim.Download date:21. Oct. 202229  Computational Techniques in Multispectral Image Processing:  Application to the Syriac Galen Palimpsest Corneliu T.C. Arsene1, Peter E. Pormann1, William I. Sellers1, and Siam Bhayro2 1School of Arts, Languages and Cultures, University of Manchester, United Kingdom 2Department of Theology and Religion, University of Exeter, United Kingdom  Multispectral/hyperspectral  image analysis has experienced much development  in  the  last decade (Kwon et al. 2013; Wang and Chunhui 2015; Shanmugam and Srinivasa Perumal 2014; Chang 2013; Zhang and Du 2012). The application of these methods to palimpsests (Bhayro 2013; Pormann 2015; Hollaus et al. 2012) has produced significant results, enabling researchers to recover texts that would be otherwise  lost under the visible overtext, by  improving the contrast between the undertext and the overtext.  In  this  paper we  explore  an  extended number of multispectral/hyperspectral  image analysis methods,  consisting  of  supervised  and  unsupervised  dimensionality  reduction  techniques (van  der  Maaten  and  Hinton  2008),  on  a  part  of  the  Syriac  Galen  Palimpsest  dataset (http://www.digitalgalen.net). Of  this  extended  set of methods,  eight methods  gave  good  results: three  were  supervised  methods  –  Generalized  Discriminant  Analysis  (GDA),  Linear  Discriminant Analysis  (LDA),  and  Neighborhood  Component  Analysis  (NCA);  and  the  other  five methods were unsupervised  methods  –  Gaussian  Process  Latent  Variable  Model  (GPLVM),  Isomap,  Landmark Isomap, Principal Component Analysis (PCA), and Probabilistic Principal Component Analysis (PPCA). The relative success of these methods was determined visually, using color pictures, on the basis of whether  the undertext was distinguishable  from  the overtext,  resulting  in  the  following  ranking of the methods: LDA, NCA, GDA, Isomap, Landmark Isomap, PPCA, PCA, and GPLVM. These results were compared with those obtained using the Canonical Variates Analysis (CVA) method [6,7] on the same dataset, which showed remarkably accuracy (LDA  is a particular case of CVA where the objects are classified  to  two classes). A comparison was also made with a double  thresholding and processing technique, developed as part of this project, which consists of the following: the darker overtext  is carefully  identified  by  the  human  operator  and  colored  in  white  (threshold  1),  and  then  the remaining  undertext, which  is  black  but  not  as  black  as  the  overtext was,  is made  even  darker (threshold 2). This last technique showed some initial encouraging results, but its success depends on the human operator selecting suitable cutting values. Figure 1 shows the results and a comparison of the different computational techniques applied to page 102v‐107r_B of the Syriac Galen Palimpsest data  (http://www.digitalgalen.net)  and  for  the  page  obtained  with  the  ultraviolet  (365  nm) illumination with green color filter (i.e. called CFUG). Ultimately  the  choice  of  technique  is  based  on  the  preferences  of  the  person  trying  to  read  the manuscript  and  the  precise makeup  of  the  original  document  but  easy  access  to  an  appropriate toolset is clearly highly desirable. Further work will consist of applying other reducing dimensionality techniques that enable the recovery of the undertext  in palimpsests, as well as applying the above techniques to the rest of the Syriac Galen Palimpsest.   30       a) Original picture                             b) Thresholding and processing     c) CVA      d) GDA  e) PCA  f) Probabilistic PCA Fig. 1: Comparison of different computational techniques applied to the Syriac Galen Palimpsest for multispec‐tral image processing and enhancement. Acknowledgment  The  authors would  like  to  thank  the  Arts  and Humanities  Research  Council, United  Kingdom,  for supporting  this work  (Research  Grant  AH/M005704/1  ‐  The  Syriac  Galen  Palimpsest:  Galen’s  On Simple Drugs and the Recovery of Lost Texts through Sophisticated Imaging Techniques).  References S. Bhayro, P.E. Pormann, W.J. Sellers, Imaging the Syriac Galen Palimpsest: preliminary analysis and future pro‐spects, Semitica et Classica, vol. 6 (2013) 297‐300. C. Chang, Hyperspectral data processing: algorithm design and analysis, Wiley (2013).  F. Hollaus, M. Gau, and R. Sablatnig, Multispectral Image Acquisition of Ancient Manuscripts, Progress in Cul‐tural Heritage Preservation, Lecture Notes in Computer Science, EuroMed, (2012), 30‐39. H. Kwon, X.Hu, J. Theiler, A. Zare, P. Gurram, Algorithms for Multispectral and Hyperspectral Image Analysis, Journal of Electrical and Computer Engineering (2013). S. Shanmugam, P. Srinivasa Perumal, Spectral matching approaches in hyperspectral image processing, Interna‐tional Journal of Remote Sensing, vol.35, 24 (2014). P.E. Pormann, Interdisciplinary: Inside Manchester’s ‘arts lab’, Nature, 525 (2015).  L.J.P. van der Maaten and G.E. Hinton. Visualizing High‐Dimensional Data Using t‐SNE, Journal of Machine Learning Research, 9, (2008), 2579‐2605. L. Wang, Z. Chunhui, Hyperspectral Image Processing, Springer (2015). L. Zhang, B. Du, Recent advances in hyperspectral image processing, Geo‐spatial Information Science, vol. 15‐3 (2012), 143‐156.   

Computational Techniques in Multispectral Image Processing : Application to the Syriac Galen Palimpsest

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