This paper tackles the challenge of action recognition by representing a video as space-time graphs: **similarity graph** captures the relationship between correlated objects in the video while the **spatial-temporal graph** captures the interaction between objects.

The algorithm is composed of several modules:

https://i.imgur.com/DGacPVo.png

1. **Inflated 3D (I3D) network**. In essence, it is usual 2D CNN (e.g. ResNet-50) converted to 3D CNN by copying 2D weights along an additional dimension and subsequent renormalization. The network takes *batch x 3 x 32 x 224 x 224* tensor input and outputs *batch x 16 x 14 x 14*.

2. **Region Proposal Network (RPN)**. This is the same RPN used to predict initial bounding boxes in two-stage detectors like Faster R-CNN. Specifically, it predicts a predefined number of bounding boxes on every other frame of the input (initially input is 32 frames, thus 16 frames are used) to match the temporal dimension of I3D network's output. Then, I3D network output features and projected on them bounding boxes are passed to ROIAlign to obtain temporal features for each object proposal. Fortunately, PyTorch comes with a [pretrained Faster R-CNN on MSCOCO](https://pytorch.org/tutorials/intermediate/torchvision_tutorial.html) which can be easily cut to have only RPN functionality.

3. **Similarity Graph**. This graph represents a feature similarity between different objects in a video. Having features $x_i$ extracted by RPN+ROIAlign for every bounding box predictions in a video, the similarity between any pair of objects is computed as $F(x_i, x_j) = (wx_i)^T * (w'x_j)$, where $w$ and $w'$ are learnable transformation weights. Softmax normalization is performed on each edge on the graph connected to a current node $i$. Graph convolutional network is represented as several graph convolutional layers with ReLU activation in between. Graph construction and convolutions can be conveniently implemented using [PyTorch Geometric](https://github.com/rusty1s/pytorch_geometric).

4. **Spatial-Temporal Graph**. This graph captures a spatial and temporal relationship between objects in neighboring frames. To construct a graph $G_{i,j}^{front}$, we need to iterate through every bounding box in frame $t$ and compute Intersection over Union (IoU) with every object in frame $t+1$. The IoU value serves as the weight of the edge connecting nodes (ROI aligned features from RPN) $i$ and $j$. The edge values are normalized so that the sum of edge values connected to proposal $i$ will be 1. In a similar manner, the backward graph $G_{i,j}^{back}$ is defined by analyzing frames $t$ and $t-1$. 

5. **Classification Head**. The classification head takes two inputs. One is coming from average pooled features from I3D model resulting in *1 x 512* tensor. The other one is from pooled sum of features (i.e. *1 x 512* tensor) from the graph convolutional networks defined above. Both inputs are concatenated and fed to Fully-Connected (FC) layer to perform final multi-label (or multi-class) classification.

**Dataset**. The authors have tested the proposed algorithm on [Something-Something](https://20bn.com/datasets/something-something) and [Charades](https://allenai.org/plato/charades/) datasets. For the first dataset, a softmax loss function is used, while the second one utilizes binary sigmoid loss to handle a multi-label property. The input data is sampled at 6fps, covering about 5 seconds of a video input.

**My take**. I think this paper is a great engineering effort. While the paper is easy to understand at the high-level, implementing it is much harder partially due to unclear/misleading writing/description. I have challenged myself with [reproducing this paper](https://github.com/BAILOOL/Videos-as-Space-Time-Region-Graphs). It is work in progress, so be careful not to damage your PC and eyes :-)

This recent paper, a collaboration involving some of the authors of MAML, proposes an intriguing application of techniques developed in the field of meta learning to the problem of unsupervised learning - specifically, the problem of developing representations without labeled data, which can then be used to learn quickly from a small amount of labeled data. As a reminder, the idea behind meta learning is that you train models on multiple different tasks, using only a small amount of data from each task, and update the model based on the test set performance of the model. 

The conceptual advance proposed by this paper is to adopt the broad strokes of the meta learning framework, but apply it to unsupervised data, i.e. data with no pre-defined supervised tasks. The goal of such a project is, as so often is the case with unsupervised learning, to learn representations, specifically, representations we believe might be useful over a whole distribution of supervised tasks. However, to apply traditional meta learning techniques, we need that aforementioned distribution of tasks, and we’ve defined our problem as being over unsupervised data.  How exactly are we supposed to construct the former out of the latter? This may seem a little circular, or strange, or definitionally impossible: how can we generate supervised tasks without supervised labels? 

https://i.imgur.com/YaU1y1k.png

The artificial tasks created by this paper are rooted in mechanically straightforward operations, but conceptually interesting ones all the same: it uses an off the shelf unsupervised learning algorithm to generate a fixed-width vector embedding of your input data (say, images), and then generates multiple different clusterings of the embedded data, and then uses those cluster IDs as labels in a faux-supervised task. It manages to get multiple different tasks, rather than just one - remember, the premise of meta learning is in models learned over multiple tasks - by randomly up and down-scaling dimensions of the embedding before clustering is applied. Different scalings of dimensions means different points close to one another, which means the partition of the dataset into different clusters. 

With this distribution of “supervised” tasks in hand, the paper simply applies previously proposed meta learning techniques - like MAML, which learns a model which can be quickly fine tuned on a new task, or prototypical networks, which learn an embedding space in which observations from the same class, across many possible class definitions are close to one another.

https://i.imgur.com/BRcg6n7.png

An interesting note from the evaluation is that this method - which is somewhat amusingly dubbed “CACTUs” - performs best relative to alternative baselines in cases where the true underlying class distribution on which the model is meta-trained is the most different from the underlying class distribution on which the model is tested. Intuitively, this makes reasonable sense: meta learning is designed to trade off knowledge of any given specific task against the flexibility to be performant on a new class division, and so it gets the most value from trade off where a genuinely dissimilar class split is seen during testing. 

One other quick thing I’d like to note is the set of implicit assumptions this model builds on, in the way it creates its unsupervised tasks. First, it leverages the smoothness assumptions of classes - that is, it assumes that the kinds of classes we might want our model to eventually perform on are close together, in some idealized conceptual space. While not a perfect assumption (there’s a reason we don’t use KNN over embeddings for all of our ML tasks) it does have a general reasonableness behind it, since rarely are the kinds of classes very conceptually heterogenous. Second, it assumes that a truly unsupervised learning method can learn a representation that, despite being itself sub-optimal as a basis for supervised tasks, is a well-enough designed feature space for the general heuristic of “nearby things are likely of the same class” to at least approximately hold. I find this set of assumptions interesting because they are so simplifying that it’s a bit of a surprise that they actually work: even if the “classes” we meta-train our model on are defined with simple Euclidean rules, optimizing to be able to perform that separation using little data does indeed seem to transfer to the general problem of “separating real world, messier-in-embedding-space classes using little data”.  

# Summary

This paper presents state-of-the-art methods for both caption generation of images and visual question answering (VQA). The authors build on previous methods by adding what they call a "bottom-up" approach to previous "top-down" attention mechanisms. They show that using their approach they obtain SOTA on both Image captioning (MSCOCO) and the Visual Question and Answering (2017 VQA challenge). They propose a specific network configurations for each. Their biggest contribution is using Faster-R-CNN to retrieve the "important" parts of an image to focus on in both models.

## Top Down

Up until this paper, the traditional approach was to use a "top-down" approach, in which the last feature map layer of a CNN is used to obtain a latent representation of the given input image. These features, along with the context of the caption being generated, were used to generate attention weights that were used to predict the next sequence in the context of caption generation. The network would learn to focus its attention on regions of the feature map that matters most. This is the approach used in previous SOTA methods like [Show, Attend and Tell: Neural Image Caption Generation with Visual Attention](https://arxiv.org/abs/1502.03044).

## Bottom-up

The authors argue that the feature map of a CNN is too generic and can be thought of operating on a uniform, grid-like feature map. In other words, there is no particular reason to think that the feature map of generated by a CNN would give optimal regions to attend to. Also, carefully choosing the dimensions of the feature map can be very arbitrary.

In order to fix this, the authors propose combining object detection methods in a *bottom-up* approach. To do so, the authors propose using Faster-R-CNN to identify regions of interest in an image. Given an input image, Faster-R-CNN will identify bounding boxes of the image that likely correspond to objects of a given category and simultaneously compute a feature vector of that bounding box. Figure 1 shows the difference between the Bottom-up and Top-Down approach.

![image](https://user-images.githubusercontent.com/18450628/61817263-2683cd00-ae1c-11e9-971a-d3b531dbbd98.png)

## Combining the two

In this paper, the authors suggest using the bottom-up approach to compute the salient regions of the image the network should focus on using Faster-R-CNN. FRCNN is carefully pretrained on both imagenet and the Visual Genome dataset. It is then frozen and only used to generate bounding boxes of regions with high confidence of being of interest. The top-down approach is then used on the features obtained from the bottom-up approach. In order to "enhance" the FRCNN performance, they initialize their FRCNN with a ResNet-101 pre-trained on imagenet. They train their FRCNN on the Visual Genome dataset, adding attributes to the loss function that are available from the Visual Genome dataset, attributes such as color (black, white, gold etc.),  state (open, close, dark, bright, etc.). A sample of FRCNN outputs are shown in figure 2. It is important to stress that only the feature representations and not the actual outputs (i.e. not the labels) are used in their model.

![image](https://user-images.githubusercontent.com/18450628/61817487-aca01380-ae1c-11e9-90fa-134033b95bb0.png)

## Caption Generation

Figure 3 provides a high-level overview of the model being used for caption generation for images. The image is first passed through FRCNN which produces a set of image features *V*. In their specific implementation, *V* consists of *k* vectors of size 1x2048. Their model consists of two LSTM blocks, one for attention and the other for language generation.

![image](https://user-images.githubusercontent.com/18450628/61818488-effb8180-ae1e-11e9-8ae4-14355115429a.png)

The first block of their model is a Top-Down Attention LSTM layer. It takes as input the mean-pooled features *V* , i.e. 1/k*sum(v_i), concatenated with the previous timestep's hidden representation of the language LSTM as well as the word embedding of the previously generated word. The word embedding is learned and not pretrained. 

The output of the first LSTM is used to compute the attention for each vector using an MLP and softmax:

![image](https://user-images.githubusercontent.com/18450628/61819982-21298100-ae22-11e9-80a9-99640896413d.png)

The attention weighted image feature is then used as an input to the language LSTM model, concatenated with the output from the top-down Attention LSTM and a softmax is used to predict the next word in the sequence. The loss function seeks to minimize the cross-entropy of the generated sentence. 

## VQA Model

The VQA task differs to the image generation in that a text-based question accompanies an input image and the network must produce an answer. The VQA model proposed is different to that of the caption generation model previously described, however they both use the same bottom-up approach to generate the feature vectors of the image based on the FRCNN architecture. A high-level overview of the architecture for the VQA model is presented in Figure 4.

![image](https://user-images.githubusercontent.com/18450628/61821988-8da67f00-ae26-11e9-8456-3c9e5ec60787.png)

Each word from the question is converted to a learned word embedding which is used as input to a GRU. The number of words for each question is limited to 14 for computational efficiency. The output from the GRU is concatenated with each of the *k* image features, and attention weights are computed for each *k*th feature using an MLP and softmax, similar to what is done in the attention for caption generation. The weighted sum of the feature vectors is then passed through an linear layer such that its shape is compatible with the gru output, and the Hadamard product (element-wise product) is computed over the GRU output and attention-weighted image feature representation. Finally, a tanh non-linear activation is used. This results in a "gated tanh", which have been shown empirically to outperform both ReLU and tanh. Finally, a softmax probability distribution is generated at the output which selects a candidate answer among all possible candidate answers.

## Results and experiments

### Resnet Baseline

To demonstrate that their contribution of bottom-up mechanism actually improves on results, the authors use a ResNet trained on imagenet as a baseline for generating the image feature vectors (they resize the final CNN layers using bilinear interpolation when needed). They consistently obtain better results when using the bottom-up approach over the ResNet approach in both caption generation and VQA.

## MSCOCO

The authors demonstrate that they outperform all results on all metrics on the MSCOCO test server.

![image](https://user-images.githubusercontent.com/18450628/61824157-4f5f8e80-ae2b-11e9-8d90-657db453e26e.png)

They also show how using the bottom-up approach over ResNet consistently scores them higher on detecting instances of objects, attributes, relations, etc:

![image](https://user-images.githubusercontent.com/18450628/61824238-7fa72d00-ae2b-11e9-81b3-b5a7f80153f3.png)

The authors, like their predecessors, insist on demonstrating their network's frisbee ability:

![image](https://user-images.githubusercontent.com/18450628/61824344-bed57e00-ae2b-11e9-87cd-597568587e1d.png)

## VQA Results

They also demonstrate that the addition of bottom-up attention improves results over a ResNet baseline. 

![image](https://user-images.githubusercontent.com/18450628/61824500-28ee2300-ae2c-11e9-9016-2120a91917e4.png)

They also show that their model outperformed all other submissions on the VQA submission. They mention using an ensemble of 30 models for their submission. 

![image](https://user-images.githubusercontent.com/18450628/61824634-83877f00-ae2c-11e9-8d84-9589e0ea2be2.png)


A sample image of what is attended in an image given a proper answer is shown in figure 6.

![image](https://user-images.githubusercontent.com/18450628/61824608-736f9f80-ae2c-11e9-9d4e-8cb6bd0a1a92.png)


# Comments

The authors introduce a new way to select portions of the image on which to focus attention. The idea is very original and came at a time when object detection was making significant progress (i.e. FRCNN).

A few comments:

* This method might not generalize well to other types of data. It requires pre-training on larger datasets (visual genome, imagenet, etc.) which consist of categories that overlap with both the MSCOCO and VQA datasets (i.e. cars, people, etc.). It would be interesting to see an end-to-end model that does not rely on pre-training on other similar datasets.

* No insight is given to the computational complexity nor to the inference time or training time. I imagine that FRCNN is resource intensive, and having to do a forward pass of FRCNN for every pass of the network must be a computational bottleneck. Not to mention that they ensembled 30 of them!

This method is based on improving the speed of R-CNN \cite{conf/cvpr/GirshickDDM14}

1. Where R-CNN would have two different objective functions, Fast R-CNN combines localization and classification losses into a "multi-task loss" in order to speed up training.
2. It also uses a pooling method based on \cite{journals/pami/HeZR015} called the RoI pooling layer that scales the input so the images don't have to be scaled before being set an an input image to the CNN. "RoI max pooling works by dividing the $h \times w$ RoI window into an $H \times W$ grid of sub-windows of approximate size $h/H \times w/W$ and then max-pooling the values in each sub-window into the corresponding output grid cell."
3. Backprop is performed for the RoI pooling layer by taking the argmax of the incoming gradients that overlap the incoming values.

This method is further improved by the paper "Faster R-CNN" \cite{conf/nips/RenHGS15}

Brendel and Bethge show empirically that state-of-the-art deep neural networks on ImageNet rely to a large extent on local features, without any notion of interaction between them. To this end, they propose a bag-of-local-features model by applying a ResNet-like architecture on small patches of ImageNet images. The predictions of these local features are then averaged and a linear classifier is trained on top. Due to the locality, this model allows to inspect which areas in an image contribute to the model’s decision, as shown in Figure 1. Furthermore, these local features are sufficient for good performance on ImageNet. Finally, they show, on scrambled ImageNet images, that regular deep neural networks also rely heavily on local features, without any notion of spatial interaction between them.

https://i.imgur.com/8NO1w0d.png
Figure 1: Illustration of the heap maps obtained using BagNets, the bag-of-local-features model proposed in the paper. Here, different sizes for the local patches are used.

Also find this summary at [davidstutz.de](https://davidstutz.de/category/reading/).

This paper is a top-down (i.e. requires person detection separately) pose estimation method with a focus on improving high-resolution representations (features) to make keypoint detection easier. 

During the training stage, this method utilizes annotated bounding boxes of person class to extract ground truth images and keypoints. The data augmentations include random rotation, random scale, flipping, and [half body augmentations](http://presentations.cocodataset.org/ECCV18/COCO18-Keypoints-Megvii.pdf) (feeding upper or lower part of the body separately). Heatmap learning is performed in a typical for this task approach of applying L2 loss between predicted keypoint locations and ground truth locations (generated by applying 2D Gaussian with std = 1).

During the inference stage, pre-trained object detector is used to provide bounding boxes. The final heatmap is obtained by averaging heatmaps obtained from the original and flipped images. The pixel location of the keypoint is determined by $argmax$ heatmap value with a quarter offset in the direction to the second-highest heatmap value.

While the pipeline described in this paper is a common practice for pose estimation methods, this method can achieve better results by proposing a network design to extract better representations. This is done through having several parallel sub-networks of different resolutions (next one is half the size of the previous one) while repeatedly fusing branches between each other:
https://raw.githubusercontent.com/leoxiaobin/deep-high-resolution-net.pytorch/master/figures/hrnet.png

The fusion process varies depending on the scale of the sub-network and its location in relation to others:
https://i.imgur.com/mGDn7pT.png

Ilyas et al. present a follow-up work to their paper on the trade-off between accuracy and robustness. Specifically, given a feature $f(x)$ computed from input $x$, the feature is considered predictive if

$\mathbb{E}_{(x,y) \sim \mathcal{D}}[y f(x)] \geq \rho$;

similarly, a predictive feature is robust if

$\mathbb{E}_{(x,y) \sim \mathcal{D}}\left[\inf_{\delta \in \Delta(x)} yf(x + \delta)\right] \geq \gamma$.

This means, a feature is considered robust if the worst-case correlation with the label exceeds some threshold $\gamma$; here the worst-case is considered within a pre-defined set of allowed perturbations $\Delta(x)$ relative to the input $x$. Obviously, there also exist predictive features, which are however not robust according to the above definition. In the paper, Ilyas et al. present two simple algorithms for obtaining adapted datasets which contain only robust or only non-robust features. The main idea of these algorithms is that an adversarially trained model only utilizes robust features, while a standard model utilizes both robust and non-robust features. Based on these datasets, they show that non-robust, predictive features are sufficient to obtain high accuracy; similarly training a normal model on a robust dataset also leads to reasonable accuracy but also increases robustness. Experiments were done on Cifar10. These observations are supported by a theoretical toy dataset consisting of two overlapping Gaussians; I refer to the paper for details.

Also find this summary at [davidstutz.de](https://davidstutz.de/category/reading/).

Sarkar et al. propose two “learned” adversarial example attacks, UPSET and ANGRI. The former, UPSET, learns to predict universal, targeted adversarial examples. The latter, ANGRI, learns to predict (non-universal) targeted adversarial attacks. For UPSET, a network takes the target label as input and learns to predict a perturbation, which added to the original image results in mis-classification; for ANGRI, a network takes both the target label and the original image as input to predict a perturbation. These networks are then trained using a mis-classification loss while also minimizing the norm of the perturbation. To this end, the target classifier needs to be differentiable – i.e., UPSET and ANGRI require white-box access.

Also find this summary at [davidstutz.de](https://davidstutz.de/category/reading/).

Lee et al. propose a variant of adversarial training where a generator is trained simultaneously to generated adversarial perturbations. This approach follows the idea that it is possible to “learn” how to generate adversarial perturbations (as in [1]). In this case, the authors use the gradient of the classifier with respect to the input as hint for the generator. Both generator and classifier are then trained in an adversarial setting (analogously to generative adversarial networks), see the paper for details.

[1] Omid Poursaeed, Isay Katsman, Bicheng Gao, Serge Belongie. Generative Adversarial Perturbations. ArXiv, abs/1712.02328, 2017.

FaceNet directly maps face images to $\mathbb{R}^{128}$ where distances directly correspond to a measure of face similarity. They use a triplet loss function. The triplet is (face of person A, other face of person A, face of person which is not A). Later, this is called (anchor, positive, negative).

The loss function is learned and inspired by LMNN. The idea is to minimize the distance between the two images of the same person and maximize the distance to the other persons image.

## LMNN

Large Margin Nearest Neighbor (LMNN) is learning a pseudo-metric

$$d(x, y) = (x -y) M  (x -y)^T$$

where $M$ is a positive-definite matrix. The only difference between a pseudo-metric and a metric is that $d(x, y) = 0 \Leftrightarrow x = y$ does not hold.

## Curriculum Learning: Triplet selection

Show simple examples first, then increase the difficulty. This is done by selecting the triplets.

They use the triplets which are *hard*. For the positive example, this means the distance between the anchor and the positive example is high. For the negative example this means the distance between the anchor and the negative example is low.

They want to have

$$||f(x_i^a) - f(x_i^p)||_2^2 + \alpha < ||f(x_i^a) - f(x_i^n)||_2^2$$

where $\alpha$ is a margin and $x_i^a$ is the anchor, $x_i^p$ is the positive face example and $x_i^n$ is the negative example. They increase $\alpha$ over time. It is crucial that $f$ maps the images not in the complete $\mathbb{R}^{128}$, but on the unit sphere. Otherwise one could double $\alpha$ by simply making $f' = 2 \cdot f$.

## Tasks

* **Face verification**: Is this the same person?
* **Face recognition**: Who is this person?

## Datasets

* 99.63% accuracy on Labeled FAces in the Wild (LFW)
* 95.12% accuracy on YouTube Faces DB

## Network

Two models are evaluated: The [Zeiler & Fergus model](http://www.shortscience.org/paper?bibtexKey=journals/corr/ZeilerF13)  and an architecture based on the [Inception model](http://www.shortscience.org/paper?bibtexKey=journals/corr/SzegedyLJSRAEVR14).

## See also

* [DeepFace](http://www.shortscience.org/paper?bibtexKey=conf/cvpr/TaigmanYRW14#martinthoma)