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Computational Intelligence Dating of the Iron Age Glass

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Title: Computational Intelligence Dating of the Iron Age Glass


1
Computational Intelligence Dating of the Iron
Age Glass
  • Karol Grudzinski
  • Bydgoszcz Academy, Poland
  • Maciej Karwowski
  • University of Rzeszów, Poland
  • Wlodzislaw Duch
  • Nanyang Institute of Technology, Singapore
  • Nicolaus Copernicus University, Poland

2
Donors of the Data
  • Interdisciplinary Project Celtic Glass
    Characterization Prof. G. Trnka (Institute of
    Prehistory, University of Vienna) Prof. P.
    Wobrauschek (Atomic Institute of the Austrian
    Universities in Vienna)

3
Celtic Glass samples
4
Data Description (Original Database)
  • Measurements of chemical compound concentrations
    using Energy Dispersive X-ray Fluorescence
    Spectroscopy (26 compounds)
  • Class chronological period of manufacturement
  • LT C1 (La Tene C1, 260 170 B.C.)
  • LT C2 (La Tene C2, 170 110 B.C.)
  • LT D1 (La Tene D1, 110 50 B.C.)
  • 555 glass measurements, usually in 4 points of a
    single glass object.

5
Questions to be answered using CI analysis
  • System capable of automatic dating of glass
    artifacts given chemical compound concentrations
    is needed, because there are few experts that can
    do it.
  • Exploration of the hidden patterns in the data,
    with possible implication in archeology through
    rule extraction analysis (expert archeologist are
    unable to formalize the knowledge required to
    predict date).
  • Corrosion layer is on the surface, broken parts
    are less corroded. Influence of corrosion on
    measurements and prediction of the class unknown.

6
Data Preprocessing
  • Challenge to classification methods several
    vectors for one object, small data. In this case
    for one glass artifact usually two measurements
    on each side on the surface and two on the broken
    parts are included.
  • Database contains cases with missing class,
    belonging to other chronological periods,
    measurements on decorations were excluded.

7
Numerical Experiments
  • Three different experiments
  • 1st Both Surface and Broken Side Data
  • 2nd Surface Data
  • 3rd Broken Side Data
  • Many algorithms implemented in WEKA, NETLAB, SBL
    and the GhostMiner packages were used for
    calculations.

8
Surface and Broken Side Data
  • Experiment on the whole preprocessed dataset
    divided into training and test sets.
  • Class Distribution (whole set)
  • 1) LT C1, 29.68 (84 cases)
  • 2) LT C2, 33.57 (95 cases)
  • 3) LT D1, 36.75 (104 cases)
  • 283 cases total, 143 training, 140 test 1
    surface and 1 side measurement (on average)
    belonging to the same glass object in both
    training and test sets !

9
Results of the First Experiment
10
Summary of the Results of the First Experiment
  • LT C1 well separated.
  • Naive Bayes works very well.
  • SBM methods may be very misleading for such data
    measurements on the same artifact both in train
    and test uncontrolled bootstrap learning.

11
MDS visualization
12
Logical Rules Attribute Selection
  • 1R Tree Rules predict correctly 100/143 training
    and 93/140 test samples
  • 1. IF MnO lt 2185.205 THEN C1
  • 2. IF MnO ? 2185.205,9317.315) THEN C2
  • 3. IF MnO ?9317.315 THEN D1
  • Important attributes MnO
  • TiO2, Fe2O3, NiO, Sb2O3, ZnO (LT C1),
  • Fe2O3, TiO2, NiO, PbO (LT C2)
  • TiO2, Sb2O3, Fe2O3, PbO, ZnO (LT D1)

13
Surface data experiment
  • Experiment on a surface measurement dataset
    divided into training and test sets.
  • Class Distribution (whole set)
  • 1) LT C1, 26.36 (34 cases)
  • 2) LT C2, 37.98 (49 cases)
  • 3) LT D1, 35.66 (46 cases)
  • 129 cases total, 61 training, 68 test, cases
    belonging to the same artifact distributed into
    training and test partition.

14
Results - Second Experiment
15
Logical rules from 1R
  • 1R rules predict correctly 42/61 (68.9) training
    and 43/68 (63.2) test samples.
  • 1. IF MnO lt 187.34 THEN C1
  • 2. IF MnO lt 3821.99,9489.09) THEN C2
  • 3. IF MnO ? 187.34, 3821.99) or MnO ?
    9489.09 THEN D1

16
Logical Rules from C45
  • C45 rules predict correctly 54/68 (79.4) test
    samples
  • 1. IF ZrO2 gt 296.1 THEN C1
  • 2. IF Na2O ? 36472.22 THEN C1
  • 3. IF Sb2O3 gt2078.76 THEN C2
  • 4. IF CdO 0 Na2O ? 27414.98 THEN C2
  • 5. IF Na2O gt 27414.98 NiO ? 58.42 THEN D1
  • 6. IF NiO gt 48.45 CdO 0 BaO 0 Br2O7 lt
    53.6 Fe2O3 ? 12003.35 ZnO ? 149.31 THEN D1
  • 7. Default D1

17
Logical rules from SSV
  • 1. IF MnO lt 1668.47 ZrO2 gt 303.34 THEN C1
  • 2. IF MnO lt 1668.47 ZrO2 lt 303.34 TiO2 lt
    76.235, or MnO gt 1668.47 Sb2O3 gt 986.19, or
    MnO gt 1668.47 Sb2O3 lt 986.19 CaO lt 79370 THEN
    C2
  • 3. IF MnO gt 1668.47 Sb2O3 lt 986.19 CaO gt
    79370, or MnO lt 1668.47 ZrO2 lt 303.34 TiO2 gt
    76.235 THEN D1

18
Broken Side Data
  • Experiment on a broken side data divided into
    training and test partition
  • Class Distribution (whole set)
  • 1) LT C1, 32.47 (50 cases)
  • 2) LT C2, 29.87 (46 cases)
  • 3) LT D1, 37.66 (58 cases)
  • 154 cases total, 78 training, 76 test, cases
    separated

19
Results of the third experiment
20
Logical rules from 1R
  • 1R Rules predict correctly 58/78 (74.4) training
    and 57/76 (75.0) test samples.
  • 1. IF MnO lt 2134.61 THEN C1
  • 2. IF MnO ? 2134.61 9078.525) THEN C2
  • 3. IF MnO ? 9078.525 THEN D1
  • Similar Rules were found by the SSV tree with
    strong pruning.

21
Rules from C45
  • 1. IF ZrO2 gt 199.38 CdO 0 THEN C1
  • 2. IF NiO ? 62.23 CaO ? 114121.35 THEN C1
  • 3. IF CuO ? 5105.37 MnO gt 2546.77 ZnO ?
    126.29 THEN C2
  • 4. IF SnO2 gt 61.98 Br2O7 ? 64.08 THEN D1
  • 5. IF Sb2O3 ? 8246.11 CuO ? 2042.19 Al2O3 gt
    11525.69 THEN D1
  • 6. Default C2

22
Conclusions
  • CI methods may help to assign samples of
    uncertain chronology to one of the chronological
    periods, providing rough logical rules to
    archeologists.
  • Important chemical compounds useful for dating
    have been identified.
  • Separate tests on the surface and broken side
    data lead to similar classification accuracies,
    confirming the hypothesis that corrosion on the
    surface has minor or no influence on results of
    the analysis.

23
Further Work
  • Larger database is needed.
  • Detailed predictions by the CI methods should be
    confronted with archeologists.
  • There is a significant proportion of unlabeled
    samples in the original database, unsupervised
    methods should be applied using reduced feature
    space.

24
Acknowledgments
  • The research on chemical analysis of the
    archeological glass was funded by the Austrian
    Science Foundation, project No. P12526-SPR.
  • We are very grateful to our colleagues from the
    Atomic Institute in Vienna for making this data
    available to us.
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