Don't Just Blame Over-parametrization

From statwiki
Jump to navigation Jump to search
The printable version is no longer supported and may have rendering errors. Please update your browser bookmarks and please use the default browser print function instead.

Presented by

Jared Feng, Xipeng Huang, Mingwei Xu, Tingzhou Yu

Introduction

Don't Just Blame Over-parametrization for Over-confidence: Theoretical Analysis of Calibration in Binary Classification is a paper from ICML 2021 written by Yu Bai, Song Mei, Huan Wang, Caiming Xiong.

Machine learning models such as deep neural networks have high accuracy. However, the predicted top probability (confidence) does not reflect the actual accuracy of the model, which tends to be over-confident. For example, a WideResNet 32 on CIFAR100 has on average a predicted top probability of 87%, while the actual test accuracy is only 72% in (Guo et al., 17'). To address this issue, more and more researchers work on improving the calibration of models, which can reduce the over-confidence and preserve (or even improve) the accuracy in (Ovadia et al., 19').

Previous Work

1. Algorithms for model calibration.

Practitioners have observed and dealt with the over-confidence of logistic regression long ago. Recalibration algorithms fix this by adjusting the output of a well-trained model and dates back to the classical methods of Platt scaling (Platt et al., 1999), histogram binning (Zadrozny & Elkan), and isotonic regression (Zadrozny & Elkan, 2002). Platt et al. (1999) also use a particular kind of label smoothing as a way of mitigating the over-confidence in logistic regression. Guo et al. (2017)show that temperature scaling, a simple method that learns a rescaling factor for the logits, is a competitive method for calibrating neural networks. A number of recent recalibration methods further improve the performances over these approaches (Kull et al., 2017; 2019; Ding et al., 2020;Rahimi et al., 2020; Zhang et al., 2020)

Another line of work improves calibration by aggregating the probabilistic predictions over multiple models, using either an ensemble of models (Lakshminarayanan et al.,2016; Malinin et al., 2019; Wen et al., 2020; Tran et al.,2020), or randomized predictions such as Bayesian neural networks (Gal & Ghahramani, 2016; Gal et al., 2017; Mad-dox et al., 2019; Dusenberry et al., 2020). Finally, there are techniques for improving the calibration of a single neural network during training (Thulasidasan et al., 2019; Mukhotiet al., 2020; Liu et al., 2020).

2.Theoretical analysis of calibration.

Kumar et al. (2019) show that continuous rescaling methods such as temperature scaling is less calibrated than reported, and proposed a method that combines temperature scaling and histogram binning. Gupta et al. (2020) study the relationship between calibration and other notions of uncertainty such as confidence intervals. Shabat et al. (2020); Jung et al. (2020) study the sample complexity of estimating the multicalibration error (group calibration). A related theoretical result to ours is (Liu et al., 2019) which shows that the calibration error of any classifier is upper bounded by its square root excess logistic loss over the Bayes classifier. This result can be translated to aO(√d/n)upper bound for well-specified logistic regression, whereas our main result implies Θ(d/n)calibration error in our high-dimensional limiting regime(with input distribution assumptions).

Motivation

There is a typical question is that why does such over-confidence happen for vanilla trained models. One common understanding is that over-confidence is a result of over-parametrization, such as deep neural networks in (Mukhoti et al., 20'). However, so far it is unclear whether over-parametrization is the only reason, or whether there are other intrinsic reasons leading to over-confidence. In this paper, the conclusion is that over-confidence is not just a result of over-parametrization and is more inherent.

Model Architecture

Experiments

The authors conducted two experiments to test the theories: the first was based on simulation, and the second used the data CIFAR10.

There are two activations used in the simulation: well-specified under-parametrized logistic regression as well as general convex ERM with the under-confident activation [math]\displaystyle{ \sigma_{underconf} }[/math]. The “calibration curves” were plotted for both activations: the x-axis is p, the y-axis is the average probability given the prediction.

The figure above shows four main results: First, the logistic regression is over-confident at all [math]\displaystyle{ \kappa }[/math]. Second, over-confidence is more severe when [math]\displaystyle{ \kappa }[/math] increases, suggests the conclusion of the theory holds more broadly than its assumptions. Third, [math]\displaystyle{ \sigma_{underconf} }[/math] leads to under-confidence for [math]\displaystyle{ p \in (0.5, 0.51) }[/math], which verifies Theorem 2 and Corollary 3. Finally, theoretical prediction closely matches the simulation, further confirms the theory.

The generality of the theory beyond the Gaussian input assumption and the binary classification setting was further tested using dataset CIFAR10 by running multi-class logistic regression on the first five classes on it. The author performed logistic regression on two kinds of labels: true label and pseudo-label generated from the multi-class logistic (softmax) model.

The figure above indicates that the logistic regression is over-confident on both labels, where the over-confidence is more severe on the pseudo-labels than the true labels. This suggests the result that logistic regression is inherently over-confident may hold more broadly for other under-parametrized problems without strong assumptions on the input distribution, or even when the labels are not necessarily realizable by the model.


Conclusion

Critiques

References