Guo et al. study calibration of deep neural networks as post-processing step. Here, calibration means a correction of the predicted confidence scores as these are commonlz too overconfident in recent deep networks. They consider several state-of-the-art post-processing steps for calibration, but surprisingly, they show that a simple linear mapping, or even scaling, works surprisingly well. So if $z_i$ are the logits of the network, then (the network being fixed) a parameter $T$ is found such that

$\sigma(\frac{z_i}{T})$

is calibrated and minimized the NLL loss on a held-out validation set. Here, the temeratur $T$ either softens or roughens the probability distribution over classes. Interestingly, finding $T$ by optimizing the same training loss helps to reduce over-confidence.

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

**TL;DR**: Rearranging the terms in Maximum Mean Discrepancy yields a much better loss function for the discriminator of Generative Adversarial Nets.

**Keywords**: Generative adversarial nets, Maximum Mean Discrepancy, spectral normalization, convolutional neural networks, Gaussian kernel, local stability.

**Summary**

Generative adversarial nets (GANs) are widely used to learn the data sampling process and are notoriously difficult to train. The training of GANs may be improved from three aspects: loss function, network architecture, and training process.

This study focuses on a loss function called the Maximum Mean Discrepancy (MMD), defined as:
$$
MMD^2(P_X,P_G)=\mathbb{E}_{P_X}k_{D}(x,x')+\mathbb{E}_{P_G}k_{D}(y,y')-2\mathbb{E}_{P_X,P_G}k_{D}(x,y)
$$
where $G,D$ are the generator and discriminator networks, $x,x'$ are real samples, $y,y'$ are generated samples, $k_D=k\circ D$ is a learned kernel that calculates the similariy between two samples. Overall, MMD calculates the distance between the real and the generated sample distributions. Thus, traditionally, the generator is trained to minimize $L_G=MMD^2(P_X,P_G)$, while the discriminator minimizes $L_D=-MMD^2(P_X,P_G)$.

This study makes three contributions:
-  It argues that $L_D$ encourages the discriminator to ignores the fine details in real data. By minimizing $L_D$, $D$ attempts to maximize $\mathbb{E}_{P_X}k_{D}(x,x')$, the similarity between real samples scores. Thus, $D$ has to focus on common features shared by real samples rather than fine details that separate them. This may slow down training. Instead, a repulsive loss is proposed, with no additional computational cost to MMD:
$$
L_D^{rep}=\mathbb{E}_{P_X}k_{D}(x,x')-\mathbb{E}_{P_G}k_{D}(y,y')
$$
- Inspired by the hinge loss, this study proposes a bounded Gaussian kernel for the discriminator to facilitate stable training of MMD-GAN.
- The spectral normalization method divides the weight matrix at each layer by its spectral norm to enforce that each layer is Lipschitz continuous. This study proposes a simple method to calculate the spectral norm of a convolutional kernel.

The results show the efficiency of proposed methods on CIFAR-10, STL-10, CelebA and LSUN-bedroom datasets. In Appendix, we prove that MMD-GAN training using gradient method is locally exponentially stable (a property that the Wasserstein loss does not have), and show that the repulsive loss works well with gradient penalty. 

The paper has been accepted at ICLR 2019 ([OpenReview link](https://openreview.net/forum?id=HygjqjR9Km)). The code is available at [GitHub link](https://github.com/richardwth/MMD-GAN). 

TLDR; The authors propose Neural Turing Machines (NTMs). A NTM consists of a memory bank and a controller network. The controller network (LSTM or MLP in this paper) controls read/write heads by focusing their attention softly, using a distribution over all memory addresses. It can learn the parameters for two addressing mechanisms: Content-based addressing ("find similar items") and location-based addressing. NTMs can be trained end-to-end using gradient descent. The authors evaluate NTMs on program generations tasks and compare their performance against that of LSTMs. Tasks include copying, recall, prediction, and sorting binary vectors. While both LSTMs and NTMs seems to perform well on training data, only NTMs are able to generalize to longer sequences.


#### Key Observations

- Controller network tried with LSTM or MLP. Which one works better is task-dependent, but LSTM "cache" can be a bottleneck.
- Controller size, number  of read/write heads, and memory size are hyperparameters. 
- Monitoring the memory addressing shows that the NTM actually learns meaningful programs.
- Number LSTM parameters grow quadratically with hidden unit size due to recurrent connection, not so for NTMs, leading to models with fewer parameters.
- Example problems are very small, typically using sequences 8 bit vectors.


#### Notes/Questions

- At what length to NTMs stop to work? Would've liked to see where results get significantly worse.
- Can we automatically transform fuzzy NTM programs into deterministic ones?

TLDR; The authors propose a Contextual LSTM (CLSTM) model that appends a context vector to input words when making predictions. The authors evaluate the model and Language Modeling, next sentence selection and next topic prediction tasks, beating standard LSTM baselines.


#### Key Points

- The topic vector comes from an internal classifier system and is supervised data. Topics can also be estimated using unsupervised techniques.
- Topic can be calculated either based on the previous words of the current sentence (SentSegTopic), all words of the previous sentence (PrevSegTopic), and current paragraph (ParaSegTopic). Best CLSTM uses all of them. 
- English Wikipedia Dataset: 1400M words train, 177M validation, 178M words test. 129k vocab.
- When current segment topic is present, the topic of the previous sentence doesn't matter.
- Authors couldn't compare to other models that incorporate topics because they don't scale to large-scale datasets.
- LSTMs are a long chain and authors don't reset the hidden state between sentence boundaries. So, a sentence has implicit access to the prev. sentence information, but explicitly modeling the topic still makes a difference.

#### Notes/Thoughts

- Increasing number of hidden units seems to have a *much* larger impact on performance than increasing model perplexity. The simple word-based LSTM model with more hidden units significantly outperforms the complex CLSTM model. This makes me question the practical usefulness of this model.
- IMO the comparisons are somewhat unfair because by using an external classifier to obtain topic labels you are bringing in external data that the baseline models didn't have access to.
- What about using other unsupervised sentence embeddings as context vectors, e.g. seq2seq autoencoders or PV?
- If the LSTM was perfect in modeling long-range dependencies then we wouldn't need to feed extra topic vectors. What about residual connections?

This paper is about a recommendation system approach using collaborative filtering (CF) on implicit feedback datasets.

The core of it is the minimization problem

$$\min_{x_*, y_*} \sum_{u,i} c_{ui} (p_{ui} - x_u^T y_i)^2 + \underbrace{\lambda \left ( \sum_u || x_u ||^2 + \sum_i || y_i ||^2\right )}_{\text{Regularization}}$$

with

* $\lambda \in [0, \infty[$ is a hyper parameter which defines how strong the model is regularized
* $u$ denoting a user, $u_*$ are all user factors $x_u$ combined
* $i$ denoting an item, $y_*$ are all item factors $y_i$ combined
* $x_u \in \mathbb{R}^n$ is the latent user factor (embedding); $n$ is another hyper parameter. $n=50$ seems to be a reasonable choice.
* $y_i \in \mathbb{R}^n$ is the latent item factor (embedding)
* $r_{ui}$ defines the "intensity"; higher values mean user $u$ interacted more with item $i$
* $p_{ui} = \begin{cases}1 & \text{if } r_{ui} >0\\0 &\text{otherwise}\end{cases}$
* $c_{ui} := 1 + \alpha r_{ui}$ where $\alpha \in [0, \infty[$ is a hyper parameter; $\alpha =40$ seems to be reasonable

In contrast, the standard matrix factoriation optimization function looks like this ([example](https://www.cs.cmu.edu/~mgormley/courses/10601-s17/slides/lecture25-mf.pdf)):

$$\min_{x_*, y_*} \sum_{(u, i, r_{ui}) \in \mathcal{R}} {(r_{ui} - x_u^T y_i)}^2  + \underbrace{\lambda \left ( \sum_u || x_u ||^2 + \sum_i || y_i ||^2\right )}_{\text{Regularization}}$$

where

* $\mathcal{R}$ is the set of all ratings $(u, i, r_{ui})$ - user $u$ has rated item $i$ with value $r_{ui} \in \mathbb{R}$

They use alternating least squares (ALS) to train this model.

The prediction then is the dot product between the user factor and all item factors ([source](https://github.com/benfred/implicit/blob/master/implicit/recommender_base.pyx#L157-L176))