RRoocchheesstteerr IInnssttiittuuttee ooff TTeecchhnnoollooggyy RRIITT SScchhoollaarr WWoorrkkss Theses 5-9-2006 MMuullttiissppeeccttrraall iimmaaggiinngg aanndd aannaallyyssiiss ooff tthhee AArrcchhiimmeeddeess PPaalliimmppsseesstt D. Michael Hansen Follow this and additional works at: https://scholarworks.rit.edu/theses RReeccoommmmeennddeedd CCiittaattiioonn Hansen, D. Michael, "Multispectral imaging and analysis of the Archimedes Palimpsest" (2006). Thesis. Rochester Institute of Technology. Accessed from This Thesis is brought to you for free and open access by RIT Scholar Works. It has been accepted for inclusion in Theses by an authorized administrator of RIT Scholar Works. For more information, please contact [email protected]. School of Print Media Rochester Institute of Technology Rochester, New York Certificate of Approval Master's Thesis This is to certify that the Master's Thesis of D. Michael Hansen has been approved by the Thesis Committee as satisfactory for the thesis requirement for the Master of Science degree at the convocation of May 2006 Thesis Committee: Franziska Frey Primary Thesis Advisor Roger L. Easton, Jr. Secondary Thesis Advisor Twyla J. Cummings Graduate Program Coordinator Twyla J. Cummings Graduate Thesis Coordinator Name Illegible Chair, SPM Multispectral Imaging andAnalysis ofthe Archimedes Palimpsest By D. Michael Hansen Athesis submitted inpartial fulfillmentofthe requirements forthe degree ofMasterofScience inthe School ofPrint Media inthe College ofImagingArts and Sciences ofthe Rochester Institute ofTechnology May 9, 2006 Advisors: Dr. Franziska Frey Dr. RogerEaston, Jr. Copyright Notice Rochester Institute of Technology School of Print Media Title of Thesis: Multispectral Imaging and Analysis of the Archimedes Palimpsest All images of the Archimedes Palimpsest, unless otherwise noted, including those produced for this research project, are copyrighted intellectual property of the owner of the Archimedes Palimpsest. Images were produced by the Rochester Institute of Technology and lohns Hopkins University and are used with permission. All images may not be reproduced for any purpose in whole or in part without written permission. All other images used in conjunction with this thesis research are used with permission. D. Michael Hansen Signature of Author 11 Acknowledgements IwishtothankRogerEastonforgivingmeauniqueopportunitytoconductresearch ontheArchimedesPalimpsest. I amespeciallygratefulforhisvaluable suggestions and technical expertise. His multispectral imaging experiences and insight have had a significant impact onmy research interests. Rolando Raqueno has also been very helpful in explaining the algorithms used in the software. Ialso expressappreciationtotheWaltersArtMuseum,theowneroftheArchimedes Palimpsest, and especially Keith Knox for creating the datacubes. IwishtothankFranziskaFreyforherexcellentguidanceandadvice,includingallthe hours spentreviewingmyresearch andplanningmytimeline. She is knowledgable inthis fieldandhas showngreat support formywork. Her experience with various museums, including the Hermitage in St. Petersburg, has been influential in my careerpursuits. I thank Twyla Cummings forher support and approval for my research, especially with regards to this project. Her endorsementhas been very appreciated. I also thankNatalie Russo forher extensive photographic experience and interests inmuseumimagingandfine-artreproduction. Herfamiliaritywithimagingdevices, workflows, and otherprojects has been a valuable resource. I am especially grateful forMr. Iwao Numakura, who providedthe funding forthis research. His generous support forthe School ofPrint Media has allowed students to more fullyrealize theireducation through meaningful research projects. Finally, I give a heartfelt thanks to my wife, Vanessa, for her enthusiasm, interest, and encouragement, especially on certain research days that didn't seem to end. Her support and strength ofcharacter keeps me wanting to do my best. Ithas been aprivilege to workwith suchremarkable andbrilliant individuals. in Table ofContents List ofFigures vi Abstract viii Chapter 1 - Introduction 1.1 The need to preserve ancient writings 1 1.2 TheArchimedes Palimpsest 2 1.3 Identifying theArchimedes text 3 1.4 Aneed formultispectral imaging 3 Chapter 2 - TheoreticalBackground 2.1 Introduction 6 2.2 Charge-coupleddevice (CCD) 6 2.3 Multispectral datacube 9 2.4 X-ray fluorescence 9 2.5 ENVI software 12 2.6 Principal component analysis (PCA) 12 2.7 Minimumnoise fraction (MNF) 13 2.8 Spectral classification 14 2.9 Spectral classification supervised 15 2.10 EDAX datacube limitation 16 Chapter3 - AReview ofLiterature in the Field 3.1 Introduction 17 3.2 Developing MSI forancient manuscripts 17 3.3 Other ancientmanuscriptprojects involving MSI 19 3.4 Different methods ofMSI used in ancient studies 21 3.5 Characterrecognition and facsimile reproduction 23 3.6 Atale oftwo inks 23 3.7 Parchment preparation 25 3.8 Imaging the palimpsest 26 3.9 X-ray fluorescence and theArchimedes Palimpsest 30 3.10 Conclusion 32 iv Chapter 4 Hypothesis - 4.1 Hypothesis 33 4.2 Otherquestions forresearch 33 4.3 Research limitations 34 Chapter 5 - Methodology 5.1 Objectives 35 5.2 XRF data evaluation 35 5.3 RGB composite image 36 5.4 Literature review preparation 36 Chapter 6 Results - 6.1 Scanonedatacube 37 6.2 Classification 39 6.3 Scanonedatacube analysis PCA 41 6.4 Scanonedatacube analysis MNF 43 6.5 Creating subsets 43 6.6 Subset analysis PCA 44 6.7 Subset analysis MNF 46 6.8 Pseudocoloring 48 Chapter 7 - Summary and Conclusions 7.1 Summary 51 7.2 Conclusions 51 7.3 Recommendations for further investigation 52 List ofreferences 53 AppendixA: Glossary ofterms 61 Appendix B: Datacube histogram & subsets 67 Appendix C: Composite RGB images 69 List ofFigures Figure 1: TheArchimedes Palimpsest 2 Figure 2: Manuscriptpages: 1906 vs. present condition 4 Figure 3: Electromagnetic spectrum 8 Figure 4: Formation ofa datacube 8 Figure 5: Stages ofX-ray fluorescence 10 Figure 6: X-ray fluorescence spectrum 11 Figure 7: Preparing parchment forwriting 25 Figure 8: Scribe writing onparchment 25 Figure 9: Tungsten vs. ultraviolet illumination 28 Figure 10: Spectral signatures ofthe ink layers 28 Figure 11: Monochromatic images used to create aRGB composite image 29 Figure 12: Pseudocolored palimpsest image 29 Figure 13: Iron andpotassiumX-ray fluorescence images 31 Figure 14: Using X rays to illuminate an illumination 31 Figure 15: Scanonedatacube spectrum 38 Figure 16: Parchment and inkwithinthe datacube 38 Figure 17: Four layers oftextvisible 39 Figure 18: Unsupervised classificationresults 39 Figure 19: Regions ofinterest 40 Figure 20: Supervised classificationresults 41 Figure 21: Principal component analysis results 42 Figure 22: PCAeigenvalues 42 Figure 23: Location ofsubsets 43 Figure 24: PCAresults for Subset 13 44 vi Figure 25: PCAresults for subsets 45 Figure 26: MNF results for Subset 13 46 Figure 27: Unique MNF images 47 Figure 28: Creating composite RGB images inAdobe Photoshop 48 Figure 29: PseudocoloredXRF images 49 Figure 30: 3D palimpsestimages 50 vn ABSTRACT The Archimedes Palimpsest is a manuscript that has been preserved for approximately 1,000years.Amongitspages aresomeofthefewknownsourcesoftreatises from the Greek mathematicianArchimedes. The writing has been overwritten with prayer text, called the Euchologion, and portions of the faded Archimedes text are difficult to read. This research investigates methods to detect the presence ofink in the Archimedes Palimpsest using state-of-the-art image processing techniques applied to data from X-ray fluorescence (XRF) scans. In an effort to extract more legible text, various methods of imaging have been appliedtotheArchimedesmanuscript. RecentX-rayfluorescence images ofthepalimpsest suggest the possibility of detecting individual text layers and isolating them from each other. This is encouraging, since many ofthe pages have also been partially masked by gold-leafed, Byzantine-style artwork, making theArchimedes writing difficult to see with the human eye. The scans measure the X radiation emitted by atoms on the pages that have been excited by other higher energy X rays incident to the parchment. This caused certain elements within the manuscript, such as the iron in the ink, tofluoresce at energies that are specific to the particular material. Atotal of2,000 different energy levels, or bands, were recorded. To evaluate the data contained in this large number ofbands, a single data set was createdthat included allbands, referredto as a"datacube," which shows thetransition ofeach pixel through the spectrum. Special image processing tools, developed for use in the field ofremote sensing to process aerial and satellite data, canbe usedto detect certain vm