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MULTIPLE-SCALE PATTERN RECOGNITION: Application to Drought Prediction in Africa

MULTIPLE-SCALE PATTERN RECOGNITION: Application to Drought Prediction in Africa. R Gil Pontius Jr ( rpontius@clarku.edu ) Hao Chen, and Olufunmilayo E Thontteh. Lessons. We present methods to compare two maps of a common real variable at multiple spatial-resolutions.

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MULTIPLE-SCALE PATTERN RECOGNITION: Application to Drought Prediction in Africa

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  1. MULTIPLE-SCALE PATTERN RECOGNITION:Application to Drought Prediction in Africa R Gil Pontius Jr (rpontius@clarku.edu) Hao Chen, and Olufunmilayo E Thontteh

  2. Lessons • We present methods to compare two maps of a common real variable at multiple spatial-resolutions. • We examine various components of two measures of accuracy: • Root Mean Square Error (RMSE) • Mean Absolute Error (MAE) • The proposed methods are better than regression at giving useful information to evaluate prediction of drought in Africa.

  3. How do these two maps compare? Map Y Map X

  4. -2 -1 7 8 -4 -3 5 6 -6 -5 3 4 -8 -7 1 2 Map X at 16 fine resolution pixels

  5. 2 0 8 8 -2 0 6 6 -4 -4 2 6 -4 -2 -4 -2 Map Y at 16 fine resolution pixels

  6. Y versus X with west & east strata

  7. Perfect QuantityPerfect Global Location

  8. Posterior QuantityPerfect Global Location

  9. Posterior QuantityPerfect In-Stratum Location

  10. Posterior QuantityPosterior Location

  11. Posterior QuantityUniform In-Stratum Location

  12. Posterior QuantityUniform Global Location

  13. Prior QuantityUniform Global Location

  14. Components of Information for plots Perfect Perfect Posterior Uniform Uniform Global In-Stratum Pixel In-Stratum Global INFORMATION OF LOCATION Perfect Posterior Prior INFORMATION OF QUANTITY

  15. Xj 1 e 1 Xj 1 e 2 Xj 1 e 5 Xj 1 e 6 Xj 1 e 3 Xj 1 e 4 Xj 1 e 7 Xj 1 e 8 Xj 1 e 9 Xj 1 e 10 Xj 1 e 13 Xj 1 e 14 Xj 1 e 11 Xj 1 e 12 Xj 1 e 15 Xj 1 e 16 16 fine resolution pixels

  16. 4 medium resolution pixels

  17. 1 coarse pixel

  18. Components of Information for plots Perfect Perfect Posterior Uniform Uniform Global In-Stratum Pixel In-Stratum Global INFORMATION OF LOCATION Perfect Posterior Prior INFORMATION OF QUANTITY

  19. Components of Information for plots Perfect Perfect Posterior Uniform Uniform Global In-Stratum Pixel In-Stratum Global INFORMATION OF LOCATION Perfect Posterior Prior INFORMATION OF QUANTITY

  20. Components of Information for RMSE Perfect Perfect Posterior Uniform Uniform Global In-Stratum Pixel In-Stratum Global INFORMATION OF LOCATION Perfect Posterior Prior INFORMATION OF QUANTITY

  21. Components of Information for MAE Perfect Perfect Posterior Uniform Uniform Global In-Stratum Pixel In-Stratum Global INFORMATION OF LOCATION Perfect Posterior Prior INFORMATION OF QUANTITY

  22. Component Budgets forRMSE and MAE

  23. NDVI deviation at 8X8 km Truth versus Predicted Null model predicts zero everywhere.

  24. NDVI deviation at 32X32 km Truth versus Predicted Null model predicts zero everywhere.

  25. NDVI deviation at 128X128 km Truth versus Predicted Null model predicts zero everywhere.

  26. NDVI deviation Regression at 8X8 kmRed Line is Y=X, Black Line is Least Squares (-0.7,0.0) (-0.5,-0.7) (0.0,-0.7) -1.6 -0.7 +0.2

  27. Regression at resolution multiples:1, 2, 4, & 8

  28. Regression at resolution multiples:16, 32, 64, & 128

  29. Confidence Intervals for Slope

  30. Prediction versus Null • Disagreement of quantity shows the model predicted accurately that it would be a low year, and predicted that it would be lower than it actually was.

  31. Interpretation of RMSE • At all resolutions, the model prediction would be more accurate if it were to assign the average of -0.7 to each pixel. • At resolutions at or finer than 4, the Null model is better than the prediction. • At resolutions coarser than 4, the prediction is better than the Null model.

  32. Interpretation of MAE • At all resolutions, the model prediction would be more accurate if it were to assign the average of -0.7 to each pixel. • At all resolutions, the prediction is better than a Null model, because the prediction’s quantity better than a Null model.

  33. RMSE versus MAE • Only perfect spatial arrangement minimizes RMSE, whereas many spatial arrangements can minimize MAE. • RMSE gives larger penalty than MAE for outliers, thus RMSE is more sensitive to changes in resolution. • MAE is consistent with the categorical variable case.

  34. Lessons • We present methods to compare two maps of a common real variable at multiple spatial-resolutions. • We examine various components of two measures of accuracy: • Root Mean Square Error (RMSE) • Mean Absolute Error (MAE) • The proposed methods are better than regression at giving useful information to evaluate prediction of drought in Africa.

  35. Plugs & Acknowledgements Method is based on: Pontius. 2002. Statistical methods to partition effects of quantity and location during comparison of categorical maps at multiple resolutions. Photogrammetric Engineering & Remote Sensing 68(10). pp. 1041-1049. PDF file is available at www.clarku.edu/~rpontius or rpontius@clarku.edu National Science Foundation funded this via: Center for Integrated Study of the Human Dimensions of Global Change Human Environment Regional Observatory (HERO) We extent special thanks to: Clarklabs (www.clarklabs.org) who is incorporating this into the GIS software Idrisi Ron Eastman who supplied data George Kariuki who helped with analysis

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