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| Hiệu chỉnh mô hình× | Dự đoán Hợp thức× | Định lượng Bất định× | |
|---|---|---|---|
| Lĩnh vực≠ | Học máy | Học máy | Mô phỏng |
| Họ≠ | Machine learning | Machine learning | Process / pipeline |
| Năm ra đời≠ | 2017 | 2005 | Seminal modern form: 2002 |
| Người khởi xướng≠ | Platt; Guo et al. | Vovk, Gammerman & Shafer | Norbert Wiener (polynomial chaos, 1938); extended to Wiener–Askey scheme by Xiu & Karniadakis (2002) |
| Loại≠ | Post-hoc probability correction technique | Distribution-free uncertainty quantification framework | Computational uncertainty analysis framework |
| Công trình gốc≠ | Guo, C., Pleiss, G., Sun, Y., & Weinberger, K. Q. (2017). On calibration of modern neural networks. International Conference on Machine Learning, 1321–1330. link ↗ | Vovk, V., Gammerman, A., & Shafer, G. (2005). Algorithmic Learning in a Random World. Springer. ISBN: 978-0-387-00152-4 | Xiu, D. & Karniadakis, G.E. (2002). The Wiener-Askey Polynomial Chaos for Stochastic Differential Equations. SIAM Journal on Scientific Computing, 24(2), 619–644. DOI ↗ |
| Tên gọi khác≠ | Classifier Calibration, Probability Calibration, Score Calibration, Model Kalibrasyonu | Conformal Inference, Conformal Risk Control, Inductive Conformal Prediction, Uyumsal Tahmin | UQ, polynomial chaos expansion, PCE, Kriging surrogate |
| Liên quan≠ | 3 | 2 | 9 |
| Tóm tắt≠ | Model calibration is a post-hoc technique that adjusts the probability outputs of a trained classifier so that predicted confidence scores match empirical outcome frequencies. A classifier is said to be perfectly calibrated if, among all predictions made with confidence p, exactly a fraction p of them are correct. Systematic miscalibration of modern deep neural networks was rigorously documented by Guo et al. (2017), who showed that networks trained with standard cross-entropy loss tend to be overconfident, and proposed temperature scaling as a simple, effective remedy. | Conformal Prediction is a distribution-free framework for constructing statistically valid prediction sets (for classification) or prediction intervals (for regression) around the output of any pre-trained machine learning model. Introduced by Vovk, Gammerman, and Shafer in their 2005 monograph, it provides a finite-sample marginal coverage guarantee — the true label falls inside the prediction set with at least 1-alpha probability — without requiring parametric assumptions about the data distribution. | Uncertainty Quantification (UQ) is a computational framework for systematically measuring how uncertainty in the inputs of a model propagates into uncertainty in its outputs. Building on Wiener's polynomial chaos theory (1938) and formalised for general stochastic problems by Xiu and Karniadakis (2002), UQ uses two primary strategies: Polynomial Chaos Expansion (PCE), which represents the model output as a series of orthogonal polynomials matched to the input distributions, and Kriging (Gaussian process) surrogates, which replace an expensive simulation with a fast statistical approximation fitted to a small set of carefully chosen runs. |
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