Layer-Stack Temperature Scaling
This work addresses calibration and accuracy issues in neural networks for practitioners, but it is incremental as it builds on existing temperature scaling methods.
The paper tackles the problem of improving neural network calibration and accuracy by extending temperature scaling across all layers, resulting in consistent improvements in accuracy, calibration, and AUC across multiple architectures and datasets.
Recent works demonstrate that early layers in a neural network contain useful information for prediction. Inspired by this, we show that extending temperature scaling across all layers improves both calibration and accuracy. We call this procedure "layer-stack temperature scaling" (LATES). Informally, LATES grants each layer a weighted vote during inference. We evaluate it on five popular convolutional neural network architectures both in- and out-of-distribution and observe a consistent improvement over temperature scaling in terms of accuracy, calibration, and AUC. All conclusions are supported by comprehensive statistical analyses. Since LATES neither retrains the architecture nor introduces many more parameters, its advantages can be reaped without requiring additional data beyond what is used in temperature scaling. Finally, we show that combining LATES with Monte Carlo Dropout matches state-of-the-art results on CIFAR10/100.