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Calculation of exact Shapley values for explaining support vector machine models using the radial basis function

Andrea Mastropietro1, Christian Feldmann2, Jürgen Bajorath3

  • 1Department of Computer, Control and Management Engineering "Antonio Ruberti", Sapienza University of Rome, 00185, Rome, Italy.

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Summary
This summary is machine-generated.

Explainable AI (XAI) methods like SHAP have limitations in interpreting machine learning (ML) models. A new method, SVERAD, efficiently calculates exact Shapley values for Support Vector Machine (SVM) models, improving prediction explanations.

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Area of Science:

  • Computational chemistry
  • Artificial intelligence
  • Drug discovery

Background:

  • Machine learning (ML) models are crucial in pharmaceutical research but often act as black boxes, hindering interpretation.
  • Explainable AI (XAI) methods, particularly Shapley values, aim to rationalize ML predictions for experimental design.
  • Existing approximations like SHAP show limited correlation with exact Shapley values for Support Vector Machine (SVM) models, especially with Tanimoto kernels.

Purpose of the Study:

  • To develop a computationally efficient method for calculating exact Shapley values for SVM models.
  • To address the limitations of SHAP in explaining SVM predictions accurately.
  • To enable more reliable interpretation of ML models in pharmaceutical research.

Main Methods:

  • Developed the Shapley value-expressed radial basis function (SVERAD) approach.
  • Applied SVERAD to calculate exact Shapley values for SVM models using radial basis function kernels.
  • Evaluated SVERAD's efficiency and accuracy compared to existing methods.

Main Results:

  • SVERAD enables efficient computation of exact Shapley values for SVM models.
  • The new method provides meaningful explanations for SVM predictions.
  • Demonstrated improved correlation between SVERAD and exact Shapley values compared to SHAP for SVMs.

Conclusions:

  • SVERAD offers a computationally efficient and accurate solution for explaining SVM models in pharmaceutical research.
  • This advancement facilitates better understanding and trust in ML-driven predictions.
  • The method supports the rational design of experiments in drug discovery.