This paper presents a variational approach to the maximisation of mutual information in the context of a reinforcement learning agent. Mutual information in this context can provide a learning signal to the agent that is "intrinsically motivated", because it relies solely on the agent's state/beliefs and does not require from the ("outside") user an explicit definition of rewards.

Specifically, the learning objective, for a current state s, is the mutual information between the sequence of K actions a proposed by an exploration distribution $w(a|s)$ and the final state s' of the agent after performing these actions. To understand what the properties of this objective, it is useful to consider the form of this mutual information as a difference of conditional entropies:

$$I(a,s'|s) = H(a|s) - H(a|s',s)$$

Where $I(.|.)$ is the (conditional) mutual information and $H(.|.)$ is the (conditional) entropy. This objective thus asks that the agent find an exploration distribution that explores as much as possible (i.e. has high $H(a|s)$ entropy) but is such that these actions have predictable consequences (i.e. lead to predictable state s' so that $H(a|s',s)$ is low). So one could think of the agent as trying to learn to have control of as much of the environment as possible, thus this objective has also been coined as "empowerment".

The main contribution of this work is to show how to train, on a large scale (i.e. larger state space and action space) with this objective, using neural networks. They build on a variational lower bound on the mutual information and then derive from it a stochastic variational training algorithm for it. The procedure has 3 components: the exploration distribution $w(a|s)$, the environment $p(s'|s,a)$ (can be thought as an encoder, but which isn't modeled and is only interacted with/sampled from) and the planning model $p(a|s',s)$ (which is modeled and can be thought of as a decoder). The main technical contribution is in how to update the exploration distribution (see section 4.2.2 for the technical details).

This approach exploits neural networks of various forms. Neural autoregressive generative models are also used as models for the exploration distribution as well as the decoder or planning distribution. Interestingly, the framework allows to also learn the state representation s as a function of some "raw" representation x of states. For raw states corresponding to images (e.g. the pixels of the screen image in a game), CNNs are used.

#### Introduction

* The paper explores the domain of conditional image generation by adopting and improving PixelCNN architecture.
* [Link to the paper](https://arxiv.org/abs/1606.05328)

#### Based on PixelRNN and PixelCNN

* Models image pixel by pixel by decomposing the joint image distribution as a product of conditionals.
* PixelRNN uses two-dimensional LSTM while PixelCNN uses convolutional networks.
* PixelRNN gives better results but PixelCNN is faster to train.

#### Gated PixelCNN

* PixelRNN outperforms PixelCNN due to the larger receptive field and because they contain multiplicative units, LSTM gates, which allow modelling more complex interactions.
* To account for these, deeper models and gated activation units (equation 2 in the [paper](https://arxiv.org/abs/1606.05328)) can be used respectively.
* Masked convolutions can lead to blind spots in the receptive fields.
* These can be removed by combining 2 convolutional network stacks:
    * Horizontal stack - conditions on the current row.
    * Vertical stack - conditions on all rows above the current row.
* Every layer in the horizontal stack takes as input the output of the previous layer as well as that of the vertical stack.
* Residual connections are used in the horizontal stack and not in the vertical stack (as they did not seem to improve results in the initial settings).

#### Conditional PixelCNN

* Model conditional distribution of image, given the high-level description of the image, represented using the latent vector h (equation 4 in the [paper](https://arxiv.org/abs/1606.05328))
* This conditioning does not depend on the location of the pixel in the image.
* To consider the location as well, map h to spatial representation $s = m(h)$ (equation 5 in the the [paper](https://arxiv.org/abs/1606.05328))

#### PixelCNN Auto-Encoders

* Start with a traditional auto-encoder architecture and replace the deconvolutional decoder with PixelCNN and train the network end-to-end.

#### Experiments

* For unconditional modelling, Gated PixelCNN either outperforms PixelRNN or performs almost as good and takes much less time to train.
* In the case of conditioning on ImageNet classes, the log likelihood measure did not improve a lot but the visual quality of the generated sampled was significantly improved.
* Paper also included sample images generated by conditioning on human portraits and by training a PixelCNN auto-encoder on ImageNet patches.

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 about Convolutional Neural Networks for Computer Vision. It was the first break-through in the ImageNet classification challenge (LSVRC-2010, 1000 classes).

ReLU was a key aspect which was not so often used before. The paper also used Dropout in the last two layers.

## Training details

* Momentum of 0.9
* Learning rate of $\varepsilon$ (initialized at 0.01)
* Weight decay of $0.0005 \cdot \varepsilon$.
* Batch size of 128
* The training took 5 to 6 days on two NVIDIA GTX 580 3GB GPUs.

## See also

* [Stanford presentation](http://vision.stanford.edu/teaching/cs231b_spring1415/slides/alexnet_tugce_kyunghee.pdf)

SSD aims to solve the major problem with most of the current state of the art object detectors namely Faster RCNN and like. All the object detection algortihms have same  methodology 

- Train 2 different nets - Region Proposal Net (RPN) and advanced classifier to detect class of an object and bounding box separately.
- During inference, run the test image at different scales to detect object at multiple scales to account for invariance

This makes the nets extremely slow. Faster RCNN could operate at **7 FPS with 73.2% mAP** while SSD could achieve **59 FPS with 74.3% mAP ** on VOC 2007 dataset.

#### Methodology

SSD uses a single net for predict object class and bounding box. However it doesn't do that directly. It uses a mechanism for choosing ROIs, training end-to-end for predicting class and boundary shift for that ROI.

##### ROI selection

Borrowing from FasterRCNNs SSD uses the  concept of anchor boxes for generating ROIs from the feature maps of last layer of shared conv layer. For each pixel in layer of feature maps, k default boxes with different aspect ratios are chosen around every pixel in the map. So if there are feature maps each of m x n resolutions - that's *mnk* ROIs for a single feature layer. Now SSD uses multiple feature layers (with differing resolutions) for generating such ROIs primarily to capture size invariance of objects. But because earlier layers in deep conv net tends to capture low level features, it uses features after certain levels and layers henceforth.

##### ROI labelling
Any ROI that matches to Ground Truth for a class after applying appropriate transforms and having Jaccard overlap greater than 0.5 is positive. Now, given all feature maps are at different resolutions and each boxes are at different aspect ratios, doing that's not simple. SDD uses simple scaling and aspect ratios to get to the appropriate  ground truth dimensions for calculating Jaccard overlap for default boxes for each pixel at the given resolution

##### ROI classification

SSD uses single convolution kernel of 3*3 receptive fields to predict for each ROI the 4 offsets (centre-x offset, centre-y offset, height offset , width offset) from the Ground Truth box for each RoI, along with class confidence scores for each class. So that is if there are c classes (including background), there are (c+4) filters for each convolution kernels that looks at a ROI. 

So summarily we have convolution kernels  that look at ROIs (which are default boxes around each pixel in feature map layer) to generate (c+4) scores for each RoI. Multiple feature map layers with different resolutions are used for generating such ROIs. Some ROIs are positive and some negative depending on jaccard overlap after ground box has scaled appropriately taking resolution differences in input image and feature map into consideration.

Here's how it looks :
![](https://i.imgur.com/HOhsPZh.png)

##### Training

For each ROI a combined loss is calculated as a combination of localisation error and classification error. The details are best explained in the figure. 
![](https://i.imgur.com/zEDuSgi.png)

##### Inference
For each ROI predictions a small threshold is used to first filter out irrelevant predictions, Non Maximum Suppression (nms) with jaccard overlap of 0.45 per class is applied then on the remaining candidate ROIs and the top 200 detections per image are kept.

For further understanding of the intuitions regarding the paper and the results obtained please consider giving the full paper a read. 

The open sourced code is available at this [Github repo](https://github.com/weiliu89/caffe/tree/ssd)
 

TLDR; The authors use an attention mechanism in image caption generation, allowing the decoder RNN focus on specific parts of the image. In order find the correspondence between words and image patches, the RNN uses a lower convolutional layer as its input (before pooling). The authors propose both a "hard" attention (trained using sampling methods) and "soft" attention (trained end-to-end) mechanism, and show qualitatively that the decoder focuses on sensible regions while generating text, adding an additional layer of interpretability to the model. The attention-based models achieve state-of-the art on Flickr8k, Flickr30 and MS Coco.

#### Key Points

- To find image correspondence use lower convolutional layers to attend to.
- Two attention mechanisms: Soft and hard. Depending on evaluation metric (BLEU vs. METERO) one or the other performs better.
- Largest data set (MS COCO) takes 3 days to train on Titan Black GPU. Oxford VGG.
- Soft attention is same as for seq2seq models.
- Attention weights are visualized by upsampling and applying a Gaussian

#### Notes/Questions

- Would've liked to see an explanation of when/how soft vs. hard attention does better.
- What is the computational overhead of using the attention mechanism? Is it significant?

Here the authors present a model which projects queries and documents into a low dimensional space, where you can fetch relevant documents by computing distance, *here cosine is used*, between the query vector and the document vectors.

### Model Description

#### Word Hashing Layer
They have used bag of tri-grams for representing words(office -> #office# -> {#of, off, ffi, fic, ice, ce#}). This is able to generalize unseen words and maps morphological variation of same words to points which are close in n-gram space.

#### Context Window Vector
Then for representing a sentence they are taking a `Window Size` around a word and appending them to form a context window vector. If we take `Window Size` = 3: 

(He is going to Office -> { [vec of 'he', vec of 'is', vec of 'going'], [vec of 'is', vec of 'going', vec of 'to'], [vec of 'going', vec of 'to', vec of 'Office'] }

#### Convolutional Layer and Max-Pool layer

Run a convolutional layer over each of the context window vector (for an intuition these are local features). Max pool over the resulting features to get global features. The output dimension is taken here to be 300.

#### Semantic Layer

Use a fully connected layer and project the 300-D vector to a 128-D vector.


They have used two different networks, one for queries and other for documents. Now for each query and document (we are given labeled documents, one of them is positive and rest are negative) they compute the cosine similarity of the 128-D output vector. And then they learn the weights of convolutional filters and the fully connected layer by maximizing conditional likelihood of positive documents. 

My thinking is that they have used two different networks as their is significant difference between Query length and Document Length.
 

## Introduction

* [Link to Paper](http://arxiv.org/pdf/1412.6071v4.pdf)
* Spatial pooling layers are building blocks for Convolutional Neural Networks (CNNs).
* Input to pooling operation is a $N_{in}$ x $N_{in}$ matrix and output is a smaller matrix $N_{out}$ x $N_{out}$.
* Pooling operation divides $N_{in}$ x $N_{in}$ square into $N^2_{out}$ pooling regions $P_{i, j}$.
* $P_{i, j}$ ⊂ $\{1, 2, . . . , N_{in}\}$ $\forall$ $(i, j) \in \{1, . . . , N_{out} \}^2$

## MP2

* Refers to 2x2 max-pooling layer.
* Popular choice for max-pooling operation.

### Advantages of MP2
* Fast.
* Quickly reduces the size of the hidden layer.
* Encodes a degree of invariance with respect to translations and elastic distortions.

### Issues with MP2
* Disjoint nature of pooling regions.
* Since size decreases rapidly, stacks of back-to-back CNNs are needed to build deep networks.

## FMP

* Reduces the spatial size of the image by a factor of *α*, where *α ∈ (1, 2)*.
* Introduces randomness in terms of choice of pooling region.
* Pooling regions can be chosen in a *random* or *pseudorandom* manner.
* Pooling regions can be *disjoint* or *overlapping*.

## Generating Pooling Regions

* Let $a_i$ and $b_i$ be 2 increasing sequences of integers, starting at 1 and ending at $N_{in}$.
* Increments are either 1 or 2.
* For *disjoint regions, $P = [a_{i−1}, a_{i − 1}] × [b_{j−1}, b_{j − 1}]$
* For *overlapping regions, $P = [a_{i−1}, a_i] × [b_{j−1}, b_j 1]$
* Pooling regions can be generated *randomly* by choosing the increment randomly at each step.
* To generate pooling regions in a *peusdorandom* manner, choose $a_i$ = ceil($\alpha | (i+u))$, where $\alpha \in (1, 2)$ with some $u \in (0, 1)$.
* Each FMP layer uses a different pair of sequence.
* An FMP network can be thought of as an ensemble of similar networks, with each different pooling-region configuration defining a different member of the ensemble.

## Observations  

* *Random* FMP is good on its own but may underfit when combined with dropout or training data augmentation.  
* *Pseudorandom* approach generates more stable pooling regions.   
* *Overlapping* FMP performs better than *disjoint* FMP.    

## Weakness

* No justification is provided for the observations mentioned above.
* It needs to be seen how performance is affected if the pooling layer in architectures like GoogLeNet.

If you were to survey researchers, and ask them to name the 5 most broadly influential ideas in Machine Learning from the last 5 years, I’d bet good money that Batch Normalization would be somewhere on everyone’s lists. Before Batch Norm, training meaningfully deep neural networks was an unstable process, and one that often took a long time to converge to success. When we added Batch Norm to models, it allowed us to increase our learning rates substantially (leading to quicker training) without the risk of activations either collapsing or blowing up in values. It had this effect because it addressed one of the key difficulties of deep networks: internal covariate shift. 

To understand this, imagine the smaller problem, of a one-layer model that’s trying to classify based on a set of input features. Now, imagine that, over the course of training, the input distribution of features moved around, so that, perhaps, a value that was at the 70th percentile of the data distribution initially is now at the 30th. We have an obvious intuition that this would make the model quite hard to train, because it would learn some mapping between feature values and class at the beginning of training, but that would become invalid by the end. This is, fundamentally, the problem faced by higher layers of deep networks, since, if the distribution of activations in a lower layer changed even by a small amount, that can cause a “butterfly effect” style outcome, where the activation distributions of higher layers change more dramatically. Batch Normalization - which takes each feature “channel” a network learns, and normalizes [normalize = subtract mean, divide by variance] it by the mean and variance of that feature over spatial locations and over all the observations in a given batch - helps solve this problem because it ensures that, throughout the course of training, the distribution of inputs that a given layer sees stays roughly constant, no matter what the lower layers get up to. 

On the whole, Batch Norm has been wildly successful at stabilizing training, and is now canonized - along with the likes of ReLU and Dropout - as one of the default sensible training procedures for any given network. However, it does have its difficulties and downsides. One salient one of these comes about when you train using very small batch sizes - in the range of 2-16 examples per batch. Under these circumstance, the mean and variance calculated off of that batch are noisy and high variance (for the general reason that statistics calculated off of small sample sizes are noisy and high variance), which takes away from the stability that Batch Norm is trying to provide. 

One proposed alternative to Batch Norm, that didn’t run into this problem of small sample sizes, is Layer Normalization. This operates under the assumption that the activations of all feature “channels” within a given layer hopefully have roughly similar distributions, and, so, you an normalize all of them by taking the aggregate mean over all channels, *for a given observation*, and use that as the mean and variance you normalize by. Because there are typically many channels in a given layer, this means that you have many “samples” that go into the mean and variance. However, this assumption - that the distributions for each feature channel are roughly the same - can be an incorrect one. 

A useful model I have for thinking about the distinction between these two approaches is the idea that both are calculating approximations of an underlying abstract notion: the in-the-limit mean and variance of a single feature channel, at a given point in time. Batch Normalization is an approximation of that insofar as it only has a small sample of points to work with, and so its estimate will tend to be high variance. Layer Normalization is an approximation insofar as it makes the assumption that feature distributions are aligned across channels: if this turns out not to be the case, individual channels will have normalizations that are biased, due to being pulled towards the mean and variance calculated over an aggregate of channels that are different than them. 

Group Norm tries to find a balance point between these two approaches, one that uses multiple channels, and normalizes within a given instance (to avoid the problems of small batch size), but, instead of calculating the mean and variance over all channels, calculates them over a group of channels that represents a subset. The inspiration for this idea comes from the fact that, in old school computer vision, it was typical to have parts of your feature vector that - for example - represented a histogram of some value (say: localized contrast) over the image. Since these multiple values all corresponded to a larger shared “group” feature. If a group of features all represent a similar idea, then their distributions will be more likely to be aligned, and therefore you have less of the bias issue. 

One confusing element of this paper for me was that the motivation part of the paper strongly implied that the reason group norm is sensible is that you are able to combine statistically dependent channels into a group together. However, as far as I an tell, there’s no actually clustering or similarity analysis of channels that is done to place certain channels into certain groups; it’s just done so semi-randomly based on the index location within the feature channel vector. So, under this implementation, it seems like the benefits of group norm are less because of any explicit seeking out of dependant channels, and more that just having fewer channels in each group means that each individual channel makes up more of the weight in its group, which does something to reduce the bias effect anyway.

The upshot of the Group Norm paper, results-wise, is that Group Norm performs better than both Batch Norm and Layer Norm at very low batch sizes. This is useful if you’re training on very dense data (e.g. high res video), where it might be difficult to store more than a few observations in memory at a time. However, once you get to batch sizes of ~24, Batch Norm starts to do better, presumably since that’s a large enough sample size to reduce variance, and you get to the point where the variance of BN is preferable to the bias of GN.  

Cheney et al. study the robustness of deep neural networks, especially AlexNet, with regard to randomly dropping or perturbing weights. In particular, the authors consider three types of perturbations: synapse knockouts set random weights to zero, node knockouts set all weights corresponding to a set of neurons to zero, and weight perturbations add random Gaussian noise to the weights of a specific layer. These perturbations are studied on AlexNet, considering the top-5 accuracy on ImageNet; perturbations are considered per layer. For example, Figure 1 (left) shows the influence on accuracy when knocking out synapses. As can be seen, the lower layers, especially the first convolutional layer, are impacted significantly by these perturbations. Similar observations, Figure 1 (right) are made for random perturbations of weights; although the impact is less significant. Especially high-level features, i.e., the corresponding layers, seem to be robust to these kind of perturbations. The authors also provide evidence that these results extend to the top-1 accuracy, as well as other architectures. For VGG, however, the impact is significantly less pronounced which may also be due to the employed dropout layers.

https://i.imgur.com/78T6Gg2.png
Figure 1: Left: Influence of setting weights in the corresponding layers to zero. Right: Influence of randomly perturbing weights of specific layers. Experiments are on ImageNet using AlexNet.

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