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Maral Rasoolijaberi
Maral Rasoolijaberi


== Introduction ==  
== Introduction ==
This paper presents
 
This paper evaluated the performance of the state-of-the-art self-supervised methods on learning weights of convolutional neural networks (CNNs) and on a per-layer basis. They were motivated by the fact that low-level features in the first layers of networks may not require the high-level semantic information captured by manual labels. This paper also aims to figure out whether current self-supervision techniques can learn deep features from only one image.
 
The main goal of self-supervised learning is to take advantage of a vast amount of unlabeled data to train CNNs and find good generalized image representations. 
In self-supervised learning, unlabeled data is used to generate ground truth labels, such as the Jigsaw puzzle task[6], and the rotation estimation[3]. For example, in the rotation task, we have a picture of a bird without the label "bird". We rotate the bird image by 90 degrees clockwise and the CNN is trained in a way to find the rotation axis, as can be seen in the figure below. The intuition is that if a deep network can tell if a bird is upside down or not, perhaps it has learned a semantically relevant representation without the need for hand-labelling.
 
[[File:self-sup-rotation.png|700px|center]]
 
[[File:intro.png|500px|center]]


== Previous Work ==
== Previous Work ==


== Motivation ==
In recent literature, several papers addressed self-supervised learning methods.


The performance of deep neural networks can be improved by increasing the depth and the width of the networks. However, this suffers two major bottlenecks. One disadvantage is that the enlarged network tends to overfit the train data, especially if there is only limited labeled examples. The other drawback is the dramatic increase in computational resources when learning large number of parameters.
* Generative models: Generative Adversarial Networks (GANs), learn to generate images in an adversarial manner. They consist of a generator network which maps noise samples to image samples and a discriminator network whose task is to distinguish the fake images from the real ones. These two are trained together until the point where the fake images are indistinguishable. BiGAN [2], or Bidirectional GAN, is simply a generative adversarial network plus an encoder.  The generator maps latent samples to generated data and the encoder performs as the opposite of the generator. After training BiGAN, the encoder has learned to generate a rich image representation.  
* In RotNet method [3],  images are rotated and the CNN learns to figure out the direction. Therefore, this task is a 4-way classification task. Most images are taken upright which could be considered as labeled images with label 90 degrees. The authors of RotNet argue that the concept of 'upright' is hard to understand and requires high-level knowledge about the image, so this task encourages the network to discover more complex information about the images.
* DeepCluster [4] alternates between k-means clustering step, in which pseudo-labels are assigned to the data by k-means on the PCA-reduced features, and the learning step in which the model tries to learn to fit the representation to these labels(cluster IDs) under several image transformations. These transformations include random resized crops with <math> \beta = 0.08 </math> and <math> \gamma = \frac{3}{4}</math> and horizontal flips.


The fundamental way of handling both problems would be to use sparsely connected instead of fully connected networks and, at the same time, make numerical calculation on non-uniform sparse data structures efficient. Therefore, the inception architecture was motivated by Arora et al. [3] and Catalyurek et al. [4] and overcome these difficulties by clustering sparse matrices into relatively dense submatrices. It takes advantage of both extra sparsity and existing computational hardware.
* In Jigsaw task [6], the unlabelled images are divided into nine patches and then, the patches are permuted randomly to create a new image. Then, a deep neural network is trained to predict the permutation of patches in the perturbed image.


== Model Architecture ==
Following is the work done in the domain of learning from a single image:
The Inception architecture consists of stacking blocks called the inception modules. The idea is that to increase the depth and width of model by finding local optimal sparse structure and repeating it spatially. Traditionally, in each layer of convolutional network pooling operation and convolution and its size (1 by 1, 3 by 3 or 5 by 5) should be decided while all of them are beneficial for the modeling power of the network. Whereas, in Inception module instead of choosing, all these various options are computed simultaneously (Fig. 1a). Inspired by layer-by-layer construction of Arora et al. [3], in Inception module statistics correlation of the last layer is analyzed and clustered into groups of units with high correlation. These clusters form units of next layer and are connected to the units of previous layer. Each unit from the earlier layer corresponds to some region of the input image and the outputs of them are concatenated into a filter bank. Additionally, because of the beneficial effect of pooling in the convolutional networks, a parallel path of pooling has been added in each module. The Inception module in its naïve form (Fig. 1a) suffers from high computation and power cost. In addition, as the concatenated output from the various convolutions and the pooling layer will be an extremely deep channel of output volume, the claim that this architecture has an improved memory and computation power use looks like counterintuitive. However, this issue has been addressed by adding a 1 by 1 convolution before costly 3 by 3 and 5 by 5 convolutions. The idea of 1 by 1 convolution was first introduced by Lin et al. and called network in network [1]. This 1x1 convolution mathematically is equivalent to a multilayer perceptron which reduces the dimension of filter space (the depth of the output volume) and on top of that they also act as a non-linear rectifying activation layer ReLu to add to the non-linearity immediately after each 1 by 1 convolution (Fig. 1b). This enables less over-fitting due to smaller Kernel size (1 by 1). This distinctive dimensionality reduction feature of the 1 by 1 convolution allows shielding of the large number of input filters of the previous stage to the next stage (Footnote 2).


[[File:Inception module, naıve version.JPG | center]]
* Rodriguez et al. [7] used max-margin correlation filters to learn robust tracking templates from a single sample of the patch.
* Malisiewicz et al. [8] used a semi-parametric exemplar SVM model where the model uses one positive sample and separates it from thousands of negative samples mined from the background.


<div align="center">Figure 1(a): Inception module, naïve version</div>
== Method & Experiment ==


[[File:Inception module with dimension reductions.JPG | center]]
In this paper, BiGAN, RotNet, and DeepCluster are employed for training AlexNet in a self-supervised manner. The author uses the ResNet-50 to compute the image and the transpose of this image. The method is evaluated by multiple datasets, and the tasks majorly focus on object detection and image classification. Jigsaw ResNet-50, introduced by Priya Goyal, was utilized as a baseline of the experiment.  


<div align="center">Figure 1(b): Inception module with dimension reductions</div>
To evaluate the impact of the size of the training set, they have compared the results of a million images in the ImageNet dataset with a million augmented images generated from only one single image. Various data augmentation methods including cropping, rotation, scaling, contrast changes, and adding noise, have been used to generate the mentioned artificial dataset from one image. Augmentation can be seen as imposing a prior on how we expect the manifold of natural images to look like. When training with very few images, these priors become more important since the model cannot extract them directly from data.
   
   
The combination of various layers of convolution has some similarity with human eyes in interpreting the visual information in a sense that human eyes also process the visual information at various scale and combines to extract the features from different scale simultaneously. Similarly, in inception design network in network designs extract the fine grain details of input volume while medium- and large-sized filters cover a large receptive field of the inputs and extract their features and with pooling operations overfitting can be overcome by reducing the spatial sizes.
To measure the quality of deep features on a per-layer basis, a linear classifier is trained on top of each convolutional layer of AlexNet. Linear classifier probes are commonly used to monitor the features at every layer of a CNN and are trained entirely independently of the CNN itself [5]. Note that the main purpose of CNNs is to reach a linearly discriminable representation for images. Accordingly, the linear probing technique aims to evaluate the training of each layer of a CNN and inspect how much information each of the layers learned. The discrimination power at each layer under self-supervision is then compared to that of a fully supervised model classically trained.
The same experiment has been done using the CIFAR10/100 dataset.
 
=== Choice of augmentations ===
 
Here we describe how <math>N</math> surce images get expanded to an additional <math>d-N</math>images, where <math>d</math> is much larger and independent to <math>N</math>.
 
Given a source image of size <math>H \times W</math>, extract random patches of size <math>(w,h)</math>. Set <math>\beta , \gamma </math> such that <math>\beta \leq \frac{wh}{WH}</math> and <math>\gamma \leq \frac{h}{w} \leq \gamma^{-1}</math>. The smalles size of crops is at least <math>\beta WH</math>.  Changes in aspect ratio are limited by <math>\gamma</math>. In practice <math>\beta = 0.0001, \gamma = 0.75</math> are good choices.
 
Second, images are rotated by <math>\alpha</math> degrees, where <math>-35 \leq \alpha \leq 35</math>. Images are flipped with 50% probability.
 
Finally, colour and intensity of single pixels are linearly transformed to provide changes of illumination, as is common in natural images.
 
=== Quantitative Analysis ===
They compared the learned filters of all first-layer convolutions of an AlexNet trained with the different methods and a single image. Showed how the results of retraining a network with the first two convolutional filters, or the scattering transform from (Oyallon et al., 2017), left frozen. They also observed that their single image trained DeepCluster and BiGAN models achieve performances closes to the supervised benchmark. Lastly, they show how their features trained on only a single image can be used for other applications.
 
== Results ==
 


== ILSVRC 2014 Challenge Results ==
Figure 2 shows how well representations at each level are linearly separable using a single image, as compared to fully supervised performance using the entire dataset. Table 1 indicates the classification accuracy of the linear classifier trained on the top of each convolutional layer.
The proposed architecture was implemented through a deep network called GoogLeNet as a submission for ILSVRC14’s Classification Challenge and Detection Challenge.  
According to the results, training the CNN with self-supervision methods can match the performance of fully supervised learning in the first two convolutional layers. It must be pointed out that only one single image with massive augmentation is utilized in this experiment.
[[File:histo.png|500px|center]]
[[File:table_results_imageNet_SSL_2.png|500px|center]]
[[File:Capture123.PNG|500px|center]]
<div align="center">'''Table1 :''' ImageNet LSVRC-12 linear probing evaluation. Activations of pretrained layers are used to train a linear classifier. </div>


The classification challenge is to classify images into one of 1000 categories in the Imagenet hierarchy. The top-5 error rate -  the percentage of test examples for which the correct class is not in the top 5 predicted classes - is used for measuring accuracy. The results of the classification challenge is shown in Table 1. The final submission of GoogLeNet obtains a top-5 error of 6.67% on both the validation and testing data, ranking first among all participants, significantly outperforming top teams in previous years, and not utilizing external data.


[[File:Classification performance.JPG | center]]
[[File:critical_analysis.png|500px|center]]


<div align="center">Table 1: Classification performance</div>
The above table (Table 3) corresponds to the Accuracy of linear classifiers on different network layers on CIFAR-10 and CIFAR-100 datasets.


The ILSVRC detection challenge asks to produce bounding boxes around objects in images among 200 classes. Detected objects count as correct if they match the class of the groundtruth and their bounding boxes overlap by at least 50%. Each image may contain multiple objects (with different scales) or none. The mean average precision (mAP) is used to report performance. The results of the detection challenge is listed in Table 2. Using the Inception model as a region classifier, combining Selective Search and using an ensemble of 6 CNNs, GoogLeNet gave top detection results, almost doubling accuracy of the the 2013 top model.
[[File:pretrain.png|500px|center]]


[[File:Detection performance.JPG | center]]
In table 4, the authors fine-tuned a convolution neural network with the first two filters left frozen. They achieved almost benchmark results with just a single image. This tells us that a single image is sufficient for training the first two convolutional filter banks.


<div align="center">Table 2: Detection performance</div>
== Source Code ==
 
The source code for the paper can be found here: https://github.com/yukimasano/linear-probes


== Conclusion ==
== Conclusion ==
Googlenet outperformed the other previous deep learning networks, and it became a proof of concept that approximating the expected optimal sparse structure by readily available dense building blocks (or the inception modules) is a viable method for improving the neural networks in computer vision. The significant quality gain is at a modest increase for the computational requirement is the main advantage for this method. Even without performing any bounding box operations to detect objects, this architecture gained a significant amount of quality with a modest amount of computational resources.


== Critiques ==
In this paper, the authors conducted interesting experiments to show that the first few layers of CNNs contain only limited information for analyzing natural images. They saw this by examining the weights of the early layers in cases where they only trained using only a single image with much data augmentation. Specifically, sufficient data augmentation was enough to make up for a lack of data in early CNN layers. However, this technique was not able to elicit proper learning in deeper CNN layers. In fact, even millions of images were not enough to elicit proper learning without supervision. Thus, current unsupervised learning benefits from data augmentation more than a larger dataset. The results seem to indicate that we probably do not use the full semantic capacity of a million images yet.
By using nearly 5 million parameters, GoogLeNet represented nearly a 12 times reduction in terms of parameters compared it the previous architectures like VGGNet, AlexNet. This enabled Inception network to be used for many big data applications where a huge amount of data was needed to be processed at a reasonable cost while the computational capacity was limited. However, the inception network is still complex and susceptible to scaling. If the network is scaled up, large parts of the computational gains can be lost immediately. Also there was no clear description about the various factors that lead to the design decision of this inception architecture, making it harder to adapt to other applications while maintaining the same computational efficiency.
 
== Critique ==
This is a well-written paper. However, as the main contribution of the paper is experimental, I expected a more in-depth analysis. For example, it is interesting to see how these results change if we change AlexNet with a more powerful CNN like EfficientNet? Also, the authors could try other types of Self-Supervised tasks such as jigsaw task and state-of-the-art PIRL [8].
 
It would be interesting to consider and compare the effects of each augmentation strategy in terms of performance. Additionally, it may be worthwhile to try other augmentation techniques like Gaussian smoothing and see the impact on the learning performance.
 
It would be really beneficial to apply a more challenging dataset, with objects in clutter, occlusion, and wider pose variation, inter-image invariance can be more effective, as it is used in this paper [10]. It will help us to understand the author's methodology if it encourages intra image invariance, unlike the objective of contrastive learning like the proposed in [10] or not.


== References ==
== References ==
[1] Min Lin, Qiang Chen, and Shuicheng Yan. Network in network. CoRR, abs/1312.4400, 2013.


[2] Ross B. Girshick, Jeff Donahue, Trevor Darrell, and Jitendra Malik. Rich feature hierarchies for accurate object detection and semantic segmentation. In Computer Vision and Pattern Recognition, 2014. CVPR 2014. IEEE Conference on, 2014.


[3] Sanjeev Arora, Aditya Bhaskara, Rong Ge, and Tengyu Ma. Provable bounds for learning some deep representations. CoRR, abs/1310.6343, 2013.
[1]  Y.  Asano,  C.  Rupprecht,  and  A.  Vedaldi,  “A  critical  analysis  of  self-supervision,  or  what  we  can  learn  from  a  single  image,”  in International Conference on Learning Representations, 2019
 
[2] J. Donahue, P. Kr ̈ahenb ̈uhl, and T. Darrell, “Adversarial feature learning,”arXiv preprint arXiv:1605.09782, 2016.
 
[3] S.  Gidaris,  P.  Singh,  and  N.  Komodakis,  “Unsupervised  representation  learning  by  predicting  image  rotations,”arXiv preprintarXiv:1803.07728, 2018
 
[4] M.  Caron, P.  Bojanowski, A.  Joulin, and M. Douze,  “Deep  clustering  for unsupervised  learning of  visual  features,”  in Proceedings of the European Conference on Computer Vision (ECCV), 2018, pp. 132–149
 
[5] G. Alain and Y. Bengio, “Understanding intermediate layers using linear classifier probes,”arXiv preprint arXiv:1610.01644, 2016.
 
[6] Mehdi Noroozi and Paolo Favaro. Unsupervised learning of visual representations by solving jigsaw puzzles. In ECCV, 2016.
 
[7] T. Malisiewicz, A. Gupta, and A. A. Efros. Ensemble of exemplar-SVMs for object detection and beyond. In
Proc. ICCV, 2011.


[4] ¨Umit V. C¸ ataly¨urek, Cevdet Aykanat, and Bora Uc¸ar. On two-dimensional sparse matrix partitioning: Models, methods, and a recipe. SIAM J. Sci. Comput., 32(2):656–683, February 2010.
[8] A. Rodriguez, V. Naresh Boddeti, BVK V. Kumar, and A. Mahalanobis. Maximum margin correlation filter: A new approach for localization and classification. IEEE Transactions on Image Processing, 22(2):631–643, 2013


Footnote 1: Hebbian theory is a neuroscientific theory claiming that an increase in synaptic
[9] I. Misra and L. van der Maaten, "Self-Supervised Learning of Pretext-Invariant Representations," 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), 2020.
efficacy arises from a presynaptic cell's repeated and persistent stimulation of a postsynaptic
cell. It is an attempt to explain synaptic plasticity, the adaptation of brain neurons during the learning process.


Footnote 2: Fore more explanation on 1 by 1 convolution refer to: https://iamaaditya.github.io/2016/03/one-by-one-convolution/
[10] Cheng, Z., Su, J.-C., and Maji, S., “Unsupervised Discovery of Object Landmarks via Contrastive Learning”, <i>arXiv e-prints</i>, 2020.

Latest revision as of 23:08, 12 December 2020

Presented by

Maral Rasoolijaberi

Introduction

This paper evaluated the performance of the state-of-the-art self-supervised methods on learning weights of convolutional neural networks (CNNs) and on a per-layer basis. They were motivated by the fact that low-level features in the first layers of networks may not require the high-level semantic information captured by manual labels. This paper also aims to figure out whether current self-supervision techniques can learn deep features from only one image.

The main goal of self-supervised learning is to take advantage of a vast amount of unlabeled data to train CNNs and find good generalized image representations. In self-supervised learning, unlabeled data is used to generate ground truth labels, such as the Jigsaw puzzle task[6], and the rotation estimation[3]. For example, in the rotation task, we have a picture of a bird without the label "bird". We rotate the bird image by 90 degrees clockwise and the CNN is trained in a way to find the rotation axis, as can be seen in the figure below. The intuition is that if a deep network can tell if a bird is upside down or not, perhaps it has learned a semantically relevant representation without the need for hand-labelling.

Previous Work

In recent literature, several papers addressed self-supervised learning methods.

  • Generative models: Generative Adversarial Networks (GANs), learn to generate images in an adversarial manner. They consist of a generator network which maps noise samples to image samples and a discriminator network whose task is to distinguish the fake images from the real ones. These two are trained together until the point where the fake images are indistinguishable. BiGAN [2], or Bidirectional GAN, is simply a generative adversarial network plus an encoder. The generator maps latent samples to generated data and the encoder performs as the opposite of the generator. After training BiGAN, the encoder has learned to generate a rich image representation.
  • In RotNet method [3], images are rotated and the CNN learns to figure out the direction. Therefore, this task is a 4-way classification task. Most images are taken upright which could be considered as labeled images with label 90 degrees. The authors of RotNet argue that the concept of 'upright' is hard to understand and requires high-level knowledge about the image, so this task encourages the network to discover more complex information about the images.
  • DeepCluster [4] alternates between k-means clustering step, in which pseudo-labels are assigned to the data by k-means on the PCA-reduced features, and the learning step in which the model tries to learn to fit the representation to these labels(cluster IDs) under several image transformations. These transformations include random resized crops with [math]\displaystyle{ \beta = 0.08 }[/math] and [math]\displaystyle{ \gamma = \frac{3}{4} }[/math] and horizontal flips.
  • In Jigsaw task [6], the unlabelled images are divided into nine patches and then, the patches are permuted randomly to create a new image. Then, a deep neural network is trained to predict the permutation of patches in the perturbed image.

Following is the work done in the domain of learning from a single image:

  • Rodriguez et al. [7] used max-margin correlation filters to learn robust tracking templates from a single sample of the patch.
  • Malisiewicz et al. [8] used a semi-parametric exemplar SVM model where the model uses one positive sample and separates it from thousands of negative samples mined from the background.

Method & Experiment

In this paper, BiGAN, RotNet, and DeepCluster are employed for training AlexNet in a self-supervised manner. The author uses the ResNet-50 to compute the image and the transpose of this image. The method is evaluated by multiple datasets, and the tasks majorly focus on object detection and image classification. Jigsaw ResNet-50, introduced by Priya Goyal, was utilized as a baseline of the experiment.

To evaluate the impact of the size of the training set, they have compared the results of a million images in the ImageNet dataset with a million augmented images generated from only one single image. Various data augmentation methods including cropping, rotation, scaling, contrast changes, and adding noise, have been used to generate the mentioned artificial dataset from one image. Augmentation can be seen as imposing a prior on how we expect the manifold of natural images to look like. When training with very few images, these priors become more important since the model cannot extract them directly from data.

To measure the quality of deep features on a per-layer basis, a linear classifier is trained on top of each convolutional layer of AlexNet. Linear classifier probes are commonly used to monitor the features at every layer of a CNN and are trained entirely independently of the CNN itself [5]. Note that the main purpose of CNNs is to reach a linearly discriminable representation for images. Accordingly, the linear probing technique aims to evaluate the training of each layer of a CNN and inspect how much information each of the layers learned. The discrimination power at each layer under self-supervision is then compared to that of a fully supervised model classically trained. The same experiment has been done using the CIFAR10/100 dataset.

Choice of augmentations

Here we describe how [math]\displaystyle{ N }[/math] surce images get expanded to an additional [math]\displaystyle{ d-N }[/math]images, where [math]\displaystyle{ d }[/math] is much larger and independent to [math]\displaystyle{ N }[/math].

Given a source image of size [math]\displaystyle{ H \times W }[/math], extract random patches of size [math]\displaystyle{ (w,h) }[/math]. Set [math]\displaystyle{ \beta , \gamma }[/math] such that [math]\displaystyle{ \beta \leq \frac{wh}{WH} }[/math] and [math]\displaystyle{ \gamma \leq \frac{h}{w} \leq \gamma^{-1} }[/math]. The smalles size of crops is at least [math]\displaystyle{ \beta WH }[/math]. Changes in aspect ratio are limited by [math]\displaystyle{ \gamma }[/math]. In practice [math]\displaystyle{ \beta = 0.0001, \gamma = 0.75 }[/math] are good choices.

Second, images are rotated by [math]\displaystyle{ \alpha }[/math] degrees, where [math]\displaystyle{ -35 \leq \alpha \leq 35 }[/math]. Images are flipped with 50% probability.

Finally, colour and intensity of single pixels are linearly transformed to provide changes of illumination, as is common in natural images.

Quantitative Analysis

They compared the learned filters of all first-layer convolutions of an AlexNet trained with the different methods and a single image. Showed how the results of retraining a network with the first two convolutional filters, or the scattering transform from (Oyallon et al., 2017), left frozen. They also observed that their single image trained DeepCluster and BiGAN models achieve performances closes to the supervised benchmark. Lastly, they show how their features trained on only a single image can be used for other applications.

Results

Figure 2 shows how well representations at each level are linearly separable using a single image, as compared to fully supervised performance using the entire dataset. Table 1 indicates the classification accuracy of the linear classifier trained on the top of each convolutional layer. According to the results, training the CNN with self-supervision methods can match the performance of fully supervised learning in the first two convolutional layers. It must be pointed out that only one single image with massive augmentation is utilized in this experiment.

Table1 : ImageNet LSVRC-12 linear probing evaluation. Activations of pretrained layers are used to train a linear classifier.


The above table (Table 3) corresponds to the Accuracy of linear classifiers on different network layers on CIFAR-10 and CIFAR-100 datasets.

In table 4, the authors fine-tuned a convolution neural network with the first two filters left frozen. They achieved almost benchmark results with just a single image. This tells us that a single image is sufficient for training the first two convolutional filter banks.

Source Code

The source code for the paper can be found here: https://github.com/yukimasano/linear-probes

Conclusion

In this paper, the authors conducted interesting experiments to show that the first few layers of CNNs contain only limited information for analyzing natural images. They saw this by examining the weights of the early layers in cases where they only trained using only a single image with much data augmentation. Specifically, sufficient data augmentation was enough to make up for a lack of data in early CNN layers. However, this technique was not able to elicit proper learning in deeper CNN layers. In fact, even millions of images were not enough to elicit proper learning without supervision. Thus, current unsupervised learning benefits from data augmentation more than a larger dataset. The results seem to indicate that we probably do not use the full semantic capacity of a million images yet.

Critique

This is a well-written paper. However, as the main contribution of the paper is experimental, I expected a more in-depth analysis. For example, it is interesting to see how these results change if we change AlexNet with a more powerful CNN like EfficientNet? Also, the authors could try other types of Self-Supervised tasks such as jigsaw task and state-of-the-art PIRL [8].

It would be interesting to consider and compare the effects of each augmentation strategy in terms of performance. Additionally, it may be worthwhile to try other augmentation techniques like Gaussian smoothing and see the impact on the learning performance.

It would be really beneficial to apply a more challenging dataset, with objects in clutter, occlusion, and wider pose variation, inter-image invariance can be more effective, as it is used in this paper [10]. It will help us to understand the author's methodology if it encourages intra image invariance, unlike the objective of contrastive learning like the proposed in [10] or not.

References

[1] Y. Asano, C. Rupprecht, and A. Vedaldi, “A critical analysis of self-supervision, or what we can learn from a single image,” in International Conference on Learning Representations, 2019

[2] J. Donahue, P. Kr ̈ahenb ̈uhl, and T. Darrell, “Adversarial feature learning,”arXiv preprint arXiv:1605.09782, 2016.

[3] S. Gidaris, P. Singh, and N. Komodakis, “Unsupervised representation learning by predicting image rotations,”arXiv preprintarXiv:1803.07728, 2018

[4] M. Caron, P. Bojanowski, A. Joulin, and M. Douze, “Deep clustering for unsupervised learning of visual features,” in Proceedings of the European Conference on Computer Vision (ECCV), 2018, pp. 132–149

[5] G. Alain and Y. Bengio, “Understanding intermediate layers using linear classifier probes,”arXiv preprint arXiv:1610.01644, 2016.

[6] Mehdi Noroozi and Paolo Favaro. Unsupervised learning of visual representations by solving jigsaw puzzles. In ECCV, 2016.

[7] T. Malisiewicz, A. Gupta, and A. A. Efros. Ensemble of exemplar-SVMs for object detection and beyond. In Proc. ICCV, 2011.

[8] A. Rodriguez, V. Naresh Boddeti, BVK V. Kumar, and A. Mahalanobis. Maximum margin correlation filter: A new approach for localization and classification. IEEE Transactions on Image Processing, 22(2):631–643, 2013

[9] I. Misra and L. van der Maaten, "Self-Supervised Learning of Pretext-Invariant Representations," 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), 2020.

[10] Cheng, Z., Su, J.-C., and Maji, S., “Unsupervised Discovery of Object Landmarks via Contrastive Learning”, arXiv e-prints, 2020.