The main contribution of [Understanding the difficulty of training deep feedforward neural networks](http://jmlr.org/proceedings/papers/v9/glorot10a/glorot10a.pdf) by Glorot et al. is a **normalized weight initialization**

$$W \sim U \left [  - \frac{\sqrt{6}}{\sqrt{n_j + n_{j+1}}}, \frac{\sqrt{6}}{\sqrt{n_j + n_{j+1}}} \right ]$$

where $n_j \in \mathbb{N}^+$ is the number of neurons in the layer $j$.

Showing some ways **how to debug neural networks** might be another reason to read the paper.

The paper analyzed standard multilayer perceptrons (MLPs) on a artificial dataset of $32 \text{px} \times 32 \text{px}$ images with either one or two of the 3 shapes: triangle, parallelogram and ellipse. The MLPs varied in the activation function which was used (either sigmoid, tanh or softsign).

However, no regularization was used and many mini-batch epochs were learned. It might be that batch normalization / dropout might change the influence of initialization very much.

Questions that remain open for me:

* [How is weight initialization done today?](https://www.reddit.com/r/MLQuestions/comments/4jsge9)
* Figure 4: Why is this plot not simply completely dependent on the data?
* Is softsign still used? Why not?
* If the only advantage of softsign is that is has the plateau later, why doesn't anybody use $\frac{1}{1+e^{-0.1 \cdot x}}$ or something similar instead of the standard sigmoid activation function?

The main contribution of [Asynchronous Methods for Deep Reinforcement Learning](https://arxiv.org/pdf/1602.01783v1.pdf) by Mnih et al. is a ligthweight framework for reinforcement learning agents. 

They propose a training procedure which utilizes asynchronous gradient decent updates from multiple agents at once. Instead of training one single agent who interacts with its environment, multiple agents are interacting with their own version of the environment simultaneously.

After a certain amount of timesteps, accumulated gradient updates from an agent are applied to a global model, e.g. a Deep Q-Network. These updates are asynchronous and lock free. 

Effects of training speed and quality are analyzed for various reinforcement learning methods. No replay memory is need to decorrelate successive game states, since all agents are already exploring different game states in real time. Also, on-policy algorithms like actor-critic can be applied.

They show that asynchronous updates have a stabilizing effect on policy and value updates. Also, their best method, an asynchronous variant of actor-critic, surpasses the current state-of-the-art on the Atari domain while training for half the time on a single multi-core CPU instead of a GPU.

#### Introduction

* Introduces a new global log-bilinear regression model which combines the benefits of both global matrix factorization and local context window methods.


#### Global Matrix Factorization Methods

* Decompose large matrices into low-rank approximations.
* eg - Latent Semantic Analysis (LSA)

##### Limitations

* Poor performance on word analogy task
* Frequent words contribute disproportionately high to the similarity measure.

#### Shallow, Local Context-Based Window Methods

* Learn word representations using adjacent words.
* eg - Continous bag-of-words (CBOW) model and skip-gram model.

##### Limitations

* Since they do not operate directly on the global co-occurrence counts, they can not utilise the statistics of the corpus effectively.


#### GloVe Model

* To capture the relationship between words $i$ and $j$, word vector models should use ratios of co-occurene probabilites (with other words $k$) instead of using raw probabilites themselves.
* In most general form:
     * $F(w_{i}, w_{j}, w_{k}^{~} ) = P_{ik}/P_{jk}$
* We want $F$ to encode information in the vector space (which have a linear structure), so we can restrict to the difference of $w_{i}$ and $w_{j}$
    * $F(w_{i} - w_{j}, w_{k}^{~} ) = P_{ik}/P_{jk}$
* Since right hand side is a scalar and left hand side is a vector, we take dot product of the arguments.
    * $F( (w_{i} - w_{j})^{T}, w_{k}^{~} ) = P_{ik}/P_{jk}$
* *F* should be invariant to order of the word pair $i$ and $j$.
    * $F(w_{i}^{T}w_{k}^{~}) = P_{ik}$
* Doing further simplifications and optimisations (refer paper), we get cost function, 
    * $J = \sum_{\text{over all i, j pairs in the vocabulary}}[w_{i}^{T}w_{k}^{~} + b_{i} + b_{k}^{~} - log(X_{ik})]^{2}$
    * $f$ is a weighing function.
    * $f(x) = min((x/x_{max})^{\alpha}, 1)$
    * Typical values, $x_{\max} = 100$ and $\alpha = 3/4$
    * *b* are the bias terms.

##### Complexity

* Depends on a number of non-zero elements in the input matrix.
* Upper bound by the square of vocabulary size
* Since for shallow window-based approaches, complexity depends on $|C|$ (size of the corpus), tighter bounds are needed.
* By modelling number of co-occurrences of words as power law function of frequency rank, the complexity can be shown to be proportional to $|C|^{0.8}$

#### Evaluation

##### Tasks

* Word Analogies
    * a is to b as c is to ___?
    * Both semantic and syntactic pairs
    * Find closest d to $w_{b} - w_{c} + w_{a}$ (using cosine similarity)

* Word Similarity
* Named Entity Recognition

##### Datasets

* Wikipedia Dumps - 2010 and 2014
* Gigaword5
* Combination of Gigaword5 and Wikipedia2014
* CommonCrawl
* 400,000 most frequent words considered from the corpus.

##### Hyperparameters

* Size of context window.
* Whether to distinguish left context from right context.
* $f$ - Word pairs that are $d$ words apart contribute $1/d$ to the total count.
* $xmax = 100$
* $\alpha = 3/4$
* AdaGrad update

##### Models Compared With

* Singular Value Decomposition
* Continous Bag-Of-Words
* Skip-Gram

##### Results

* Glove outperforms all other models significantly.
* Diminishing returns for vectors larger than 200 dimensions.
* Small and asymmetric context windows (context window only to the left) works better for syntactic tasks.
* Long and symmetric context windows (context window to both the sides) works better for semantic tasks.
* Syntactic task benefited from larger corpus though semantic task performed better with Wikipedia instead of Gigaword5 probably due to the comprehensiveness of Wikipedia and slightly outdated nature of Gigaword5.
* Word2vec’s performance decreases if the number of negative samples increases beyond about 10.
* For the same corpus, vocabulary, and window size GloVe consistently achieves better results, faster.

**Problem Setting:**

Sequence to Sequence learning (seq2seq) is one of the most successful techniques in machine learning nowadays. The basic idea is to encode a sequence into a vector (or a sequence of vectors if using attention based encoder) and then use a recurrent decoder to decode the target sequence conditioned on the encoder output. While researchers have explored various architectural changes to this basic encoder-decoder model, the standard way of training such seq2seq models is to maximize the likelihood of each successive target word conditioned on the input sequence and the *gold* history of target words. This is also known as *teacher-forcing* in RNN literature. Such an approach has three major issues:

1. **Exposure Bias:** Since we teacher-force the model with *gold* history during training, the model is never exposed to its errors during training. At test time, we will not have access to *gold* history and we feed the history generated by the model. If it is erroneous, the model does not have any clue about how to rectify it.

2. **Loss-Evaluation Mismatch:** While we evaluate the model using sequence level metrics (such as BLEU for Machine Translation), we are training the model with word level cross entropy loss.

3. **Label bias:** Since the word probabilities are normalized at each time step (by using softmax over the final layer of the decoder), this can result in label bias if we vary the number of possible candidates in each step. More about this later. 

**Solution:**

This paper proposes an alternative training procedure for seq2seq models which attempt to solve all the 3 major issues listed above. The idea is to pose seq2seq learning as beam-search optimization problem. Authors begin by removing the final softmax activation function from the decoder. Now instead of probability distributions, we will get score for next possible word. Then the training procedure is changed as follows: At every time step $t$, they maintain a set $S_t$ of $K$ candidate sequences of length $t$. Now the loss function is defined with the following characteristics:

1. If the *gold* sub-sequence of length $t$ is in set $S_t$ and the score for *gold* sub-sequence exceeds the score of the $K$-th ranked candidate by a margin, the model incurs no loss. Now the candidates for next time-step are chosen in a way similar to regular beam-search with beam-size $K$.

2. If the *gold* sub-sequence of length $t$ is in set $S_t$ and it is the $K$-th ranked candidate, then the loss will push the *gold* sequence up by increasing its score. The candidates for next time-step are chosen in a way similar as first case.

3. If the *gold* sub-sequence of length $t$ is NOT in set $S_t$, then the score of the *gold* sequence is increased to be higher than $K$-th ranked candidate by a margin. In this case, candidates for next step or chosen by only considering *gold* word at time $t$ and getting its top-$K$ successors.

4. Further, since we want the full *gold* sequence to be at top of the beam at the end of the search, when $t=T$, the loss is modified to require the score of *gold* sequence to exceed the score of the *highest* ranked incorrect prediction by a margin. 

This non-probabilistic training method has several advantages:

* The model is trained in a similar way it would be tested, since we use beam-search during training as well as testing. Hence this helps to eliminate exposure bias.

* The score based loss can be easily scaled by a mistake-specific cost function. For example, in MT, one could use a cost function which is inversely proportional to BLEU score. So there is no loss-evaluation mismatch.

* Each time step can have different set of successor words based on any hard constraints in the problem. Note that the model is non-probabilistic and hence this varying successor function will not introduce any label bias. Refer [this set of slides][1] for an excellent illustration of label bias.

Cost of forward-prop grows linearly with respect to beam size $K$. However, GPU implementation should help to reduce this cost. Authors propose a clever way of doing BPTT which makes the back-prop almost same cost as ordinary seq2seq training.

**Additional Tricks**

1. Authors pre-train the seq2seq model with regular word level cross-entropy loss and this is crucial since random initialization did not work.

2. Authors use "curriculum beam" strategy in training where they start with beam size of 2 and increase the beam size by 1 for every 2 epochs until it reaches the required beam size. You have to train your model with training beam size of at least test beam size + 1. (i.e $K_{tr} >= K_{te} + 1$).

3. When you use drop-out, you need to be careful to use the same dropout value during back-prop. Authors do this by sharing a single dropout across all sequences in a time step.

**Experiments**

Authors compare the proposed model against basic seq2seq in word ordering, dependency parsing and MT tasks. The proposed model achieves significant improvement over the strong baseline.

**Related Work:**

The whole idea of the paper is based on [learning as search optimization (LaSO) framework][2] of Daume III and Marcu (2005). Other notable related work are training seq2seq models using mix of cross-entropy and REINFORCE called [MIXER][3] and [an actor-critic based seq2seq training][4]. Authors compare with MIXER and they do significantly better than MIXER. 

**My two cents:**

This is one of the important research directions in my opinion. While other recent methods attempt to use reinforcement learning to avoid the issues in word-level cross-entropy training, this paper proposes a really simple score based solution which works very well. While most of the language generation research is stuck with probabilistic framework (I am saying this w.r.t Deep NLP research), this paper highlights the benefits on non-probabilistic generation models. I see this as one potential way of avoiding the nasty scalability issues that come with softmax based generative models.

[1]: http://www.cs.stanford.edu/~nmramesh/crf
[2]: https://www.isi.edu/~marcu/papers/daume05laso.pdf
[3]: http://arxiv.org/pdf/1511.06732v7.pdf
[4]: https://arxiv.org/pdf/1607.07086v2.pdf

### Main Idea:
It basically tunes the hyper-parameters of the neural network architecture using reinforcement learning. The reward signal is taken as evaluation on the validation set. The method is policy gradient as the cost function is non-differentiable. 

### Method:
 #### i.   Actions:
1. There is controller RNN which predicts some hyper-parameters of the layer conditioned on the previous predictions. This prediction is just a one-hot vector based on the previous hyper-parameter chosen. At the start for the first prediction - this vector is just all zeros.
2. Once the network is generated completely, it is trained for a fixed number of epochs, the reward signal is calculated based on the evaluation on the validation set.

#### ii.  Training:
1. Nothing fancy in the reinforcement learning approach simple policy gradients.
2. Baseline is added to reduce the variance.
3.  It takes 2-3 weeks to train it over 800 GPUs!!

#### iii. Results:
1. Use it to generate CNNs and LSTM cells. Close to state-of-art results with generated architectures.

### Possible new directions:
1. Use better techniques RL techniques like TRPO, PPO etc.
2. Right now, they generate fixed length architecture. Their reason is for variable length architectures, it is difficult to determine how much time each architecture is trained. Smaller networks are easier to train. Thus, somehow determine training time as function of the learning capacity of the network.


Code:
They haven't released the code yet. I tried to simulate it in torch.(https://github.com/abhigenie92/nn_search)