Principal Component Analysis
Principal Component Analysis (PCA) is a widely used dimensionality reduction technique aiming to identify the principal components—the directions of greatest variance in a dataset—to simplify data representation while preserving essential information. Current research focuses on improving PCA's robustness to outliers and noise, developing distributed and efficient algorithms for large datasets (including adaptations for quantum computing and federated learning), and integrating PCA with other machine learning methods for tasks like classification, regression, and anomaly detection. PCA's impact spans diverse fields, enhancing data analysis in applications ranging from image processing and sensor data compression to biomedical signal analysis and industrial process monitoring.
Papers
Computationally and Memory-Efficient Robust Predictive Analytics Using Big Data
Daniel Menges, Adil Rasheed
Implementation of the Principal Component Analysis onto High-Performance Computer Facilities for Hyperspectral Dimensionality Reduction: Results and Comparisons
E. Martel, R. Lazcano, J. Lopez, D. Madroñal, R. Salvador, S. Lopez, E. Juarez, R. Guerra, C. Sanz, R. Sarmiento
Real-time EEG-based Emotion Recognition Model using Principal Component Analysis and Tree-based Models for Neurohumanities
Miguel A. Blanco-Rios, Milton O. Candela-Leal, Cecilia Orozco-Romo, Paulina Remis-Serna, Carol S. Velez-Saboya, Jorge De-J. Lozoya-Santos, Manuel Cebral-Loureda, Mauricio A. Ramirez-Moreno
GT-PCA: Effective and Interpretable Dimensionality Reduction with General Transform-Invariant Principal Component Analysis
Florian Heinrichs