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On the Versatile Uses of Partial Distance Correlation in Deep Learning - Official PyTorch Implementation

On the Versatile Uses of Partial Distance Correlation in Deep Learning
Xingjian Zhen, Zihang Meng, Rudrasis Chakraborty, Vikas Singh European Conference on Computer Vision (ECCV), 2022.

Update:

  • Fixed typo in Partial_Distance_Correlation.ipynb from Peasor_Correlation() to Pearson_Correlation()
  • Reimplementation in TensorFlow in TF_Partial_Distance_Correlation.ipynb
  • Reimplementation in TF_Diverge_Training module

Abstract: Comparing the functional behavior of neural network models, whether it is a single network over time or two (or more networks) during or post-training, is an essential step in understanding what they are learning (and what they are not), and for identifying strategies for regularization or efficiency improvements. Despite recent progress, e.g., comparing vision transformers to CNNs, systematic comparison of function, especially across different networks, remains difficult and is often carried out layer by layer. Approaches such as canonical correlation analysis (CCA) are applicable in principle, but have been sparingly used so far. In this paper, we revisit a (less widely known) from statistics, called distance correlation (and its partial variant), designed to evaluate correlation between feature spaces of different dimensions. We describe the steps necessary to carry out its deployment for large scale models -- this opens the door to a surprising array of applications ranging from conditioning one deep model w.r.t. another, learning disentangled representations as well as optimizing diverse models that would directly be more robust to adversarial attacks. Our experiments suggest a versatile regularizer (or constraint) with many advantages, which avoids some of the common difficulties one faces in such analyses.

YouTube Introduction

Please also go check the project webpage

Results

Independent Features Help Robustness (Diverge Training)

Table 1: The test accuracy (%) of a model $f_2$ on the adversarial examples generated using $f_1$ with the same architecture. "Baseline": train without constraint. "Ours": $f_2$ is independent to $f_1$. "Clean": test accuracy without adversarial examples.

Dataset Network Method Clean FGM $\epsilon=0.03$ PGD $\epsilon=0.03$ FGM $\epsilon=0.05$ PGD $\epsilon=0.05$ FGM $\epsilon=0.10$ PGD $\epsilon=0.10$
CIFAR10 Resnet 18 Baseline 89.14 72.10 66.34 62.00 49.42 48.23 27.41
CIFAR10 Resnet 18 Ours 87.61 74.76 72.85 65.56 59.33 50.24 36.11
ImageNet Mobilenet-v3-small Baseline 47.16 29.64 30.00 23.52 24.81 13.90 17.15
ImageNet Mobilenet-v3-small Ours 42.34 34.47 36.98 29.53 33.77 19.53 28.04
ImageNet Efficientnet-B0 Baseline 57.85 26.72 28.22 18.96 19.45 12.04 11.17
ImageNet Efficientnet-B0 Ours 55.82 30.42 35.99 22.05 27.56 14.16 17.62
ImageNet Resnet 34 Baseline 64.01 52.62 56.61 45.45 51.11 33.75 41.70
ImageNet Resnet 34 Ours 63.77 53.19 57.18 46.50 52.28 35.00 43.35
ImageNet Resnet 152 Baseline 66.88 56.56 59.19 50.61 53.49 40.50 44.49
ImageNet Resnet 152 Ours 68.04 58.34 61.33 52.59 56.05 42.61 47.17

Diverge Training

Informative Comparisons between Networks (Partial Distance Correlation)

Table 2: Partial DC between the network $\Theta_X$ conditioned on the network $\Theta_Y$ , and the ImageNet class name embedding. The higher value indicates the more information.

Network $\Theta_X$ Network $\Theta_Y$ $\mathcal{R}^2(X, GT)$ $\mathcal{R}^2(Y, GT)$ $\mathcal{R}^2(X|Y, GT)$ $\mathcal{R}^2((Y|X), GT)$
ViT$^1$ Resnet 18$^2$ 0.042 0.025 0.035 0.007
ViT Resnet 50$^3$ 0.043 0.036 0.028 0.017
ViT Resnet 152$^4$ 0.044 0.020 0.040 0.009
ViT VGG 19 BN$^5$ 0.042 0.037 0.026 0.015
ViT Densenet121$^6$ 0.043 0.026 0.035 0.007
ViT large$^7$ Resnet 18 0.046 0.027 0.038 0.007
ViT large Resnet 50 0.046 0.037 0.031 0.016
ViT large Resnet 152 0.046 0.021 0.042 0.010
ViT large ViT 0.045 0.043 0.019 0.013
ViT+Resnet 50$^8$ Resnet 18 0.044 0.024 0.037 0.005
Resnet 152 Resnet 18 0.019 0.025 0.013 0.020
Resnet 152 Resnet 50 0.021 0.037 0.003 0.030
Resnet 50 Resnet 18 0.036 0.025 0.027 0.008
Resnet 50 VGG 19 BN 0.036 0.036 0.020 0.019

Note Accuracy: 1. 84.40%; 2. 69.76%; 3. 79.02%; 4. 82.54%; 5. 74.22%; 6. 75.57%; 7. 85.68%; 8. 84.13%

Grad Cam Heat Map

Disentanglement

Visualization Distance Correlation in Disentanglement

Quantitive measurement (distance correlation between residual and attribute of interest)

Table 3: DC between residual attributes (R) and attributes of interest, if we use the ground truth CLIP labeled data to measure the attribute of interest. Range from 0 to 1, and smaller is better.

age vs R. gender vs R. ethnicity vs R. hair color vs R. beard vs R. glasses vs R
0.0329 0.0180 0.0222 0.0242 0.0219 0.0255

Table 4: DC between residual attributes (R) and attributes of interest, if we use in-model classifier to classify the attribute of interest. Range from 0 to 1, and smaller is better.

age vs R. gender vs R. ethnicity vs R. hair color vs R. beard vs R. glasses vs R
0.0430 0.0124 0.0376 0.0259 0.0490 0.0188

Requirements

python 3.8 pytorch 1.8 cuda 10.2

Training

Please refer to each different directory for detailed training steps for each experiment.

Citation

@inproceedings{zhen2022versatile,
  author    = {Zhen, Xingjian and Meng, Zihang and Chakraborty, Rudrasis and Singh, Vikas},
  title     = {On the Versatile Uses of Partial Distance Correlation in Deep Learning},
  booktitle = {Proceedings of the European conference on computer vision (ECCV)},
  year      = {2022}
}

If you use distance correlation for disentanglement, please give credit to the following paper: Measuring the Biases and Effectiveness of Content-Style Disentanglement which discusses a nice demonstration of distance correlation helps content style disentanglement. We were not aware of this paper when we wrote the paper last year and thank Sotirios Tsaftaris for communicating his findings with us.

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