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}

In this note, I'll implement the [Stochastically Unbiased Marginalization Objective (SUMO)](https://openreview.net/forum?id=SylkYeHtwr) to estimate the log-partition function of an energy funtion. 

Estimation of log-partition function has many important applications in machine learning. Take latent variable models or Bayeisian inference. The log-partition function of the posterior distribution $$p(z|x)=\frac{1}{Z}p(x|z)p(z)$$ is the log-marginal likelihood of the data $$\log Z = \log \int p(x|z)p(z)dz = \log p(x)$$. 

More generally, let $U(x)$ be some energy function which induces some density function $p(x)=\frac{e^{-U(x)}}{\int e^{-U(x)} dx}$. The common practice is to look at a variational form of the log-partition function, 
$$
\log Z = \log \int e^{-U(x)}dx = \max_{q(x)}\mathbb{E}[-U(x)-\log q(x)] \nonumber
$$
Plugging in an arbitrary $q$ would normally yield a strict lower bound, which means 
$$
\frac{1}{n}\sum_{i=1}^n \left(-U(x_i) - \log q(x_i)\right) \nonumber
$$
for $x_i$ sampled *i.i.d.* from $q$, would be a biased estimate for $\log Z$. In particular, it would be an underestimation. 



To see this, lets define the energy function $U$ as follows:
$$
U(x_1,x_2)= - \log \left(\frac{1}{2}\cdot e^{-\frac{(x_1+2)^2 + x_2^2}{2}} + \frac{1}{2}\cdot\frac{1}{4}e^{-\frac{(x_1-2)^2 + x_2^2}{8}}\right) \nonumber
$$
It is not hard to see that $U$ is the energy function of a mixture of Gaussian distribution $\frac{1}{2}\mathcal{N}([-2,0], I) + \frac{1}{2}\mathcal{N}([2,0], 4I)$ with a normalizing constant $Z=2\pi\approx6.28$ and $\log Z\approx1.8379$.

```python
def U(x):
  x1 = x[:,0]
  x2 = x[:,1]
  d2 = x2 ** 2
  return - np.log(np.exp(-((x1+2) ** 2 + d2)/2)/2 + np.exp(-((x1-2) ** 2 + d2)/8)/4/2)
```



To visualize the density corresponding to the energy $p(x)\propto e^{-U(x)}$

```python
xx = np.linspace(-5,5,200)
yy = np.linspace(-5,5,200)
X = np.meshgrid(xx,yy)
X = np.concatenate([X[0][:,:,None], X[1][:,:,None]], 2).reshape(-1,2)
unnormalized_density = np.exp(-U(X)).reshape(200,200)
plt.imshow(unnormalized_density)
plt.axis('off')
```

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



As a sanity check, lets also visualize the density of the mixture of Gaussians. 

```python
N1, N2 = mvn([-2,0], 1), mvn([2,0], 4)
density = (np.exp(N1.logpdf(X))/2 + np.exp(N2.logpdf(X))/2).reshape(200,200)
plt.imshow(density)
plt.axis('off')
print(np.allclose(unnormalized_density / density - 2*np.pi, 0))
```

`True`

https://i.imgur.com/g4inQxB.png



Now if we estimate the log-partition function by estimating the variational lower bound, we get

```python
q = mvn([0,0],5)

xs = q.rvs(10000*5)
elbo = - U(xs) - q.logpdf(xs)
plt.hist(elbo, range(-5,10))
print("Estimate:  %.4f  / Ground true:  %.4f" % (elbo.mean(), np.log(2*np.pi)))
print("Empirical variance: %.4f" % elbo.var())
```

`Estimate:  1.4595  / Ground true:  1.8379`

`Empirical variance: 0.9921`

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



The lower bound can be tightened via [importance sampling):
$$
\log \int e^{-U(x)} dx \geq \mathbb{E}_{q^K}\left[\log\left(\frac{1}{K}\sum_{j=1}^K \frac{e^{-U(x_j)}}{q(x_j)}\right)\right] \nonumber
$$

> This bound is tighter for larger $K$ partly due to the [concentration of the average](https://arxiv.org/pdf/1906.03708.pdf) inside of the $\log$ function: when the random variable is more deterministic, using a local linear approximation near its mean is more accurate as there's less "mass" outside of some neighborhood of the mean.  



Now if we use this new estimator with $K=5$

```python
k = 5
xs = q.rvs(10000*k)
elbo = - U(xs) - q.logpdf(xs)
iwlb = elbo.reshape(10000,k)
iwlb = np.log(np.exp(iwlb).mean(1))
plt.hist(iwlb, range(-5,10))
print("Estimate:  %.4f  / Ground true:  %.4f" % (iwlb.mean(), np.log(2*np.pi)))
print("Empirical variance: %.4f" % iwlb.var())
```

`Estimate:  1.7616  / Ground true:  1.8379`

`Empirical variance: 0.1544`

https://i.imgur.com/sCcsQd4.png

We see that both the bias and variance decrease. 



Finally, we use the [Stochastically Unbiased Marginalization Objective](https://openreview.net/pdf?id=SylkYeHtwr) (SUMO), which uses the *Russian Roulette* estimator to randomly truncate a telescoping series that converges in expectation to the log partition function. Let $\text{IWAE}_K = \log\left(\frac{1}{K}\sum_{j=1}^K \frac{e^{-U(x_j)}}{q(x_j)}\right)$ be the importance-weighted estimator, and $\Delta_K = \text{IWAE}_{K+1} - \text{IWAE}_K$ be the difference (which can be thought of as some form of correction). The SUMO estimator is defined as 
$$
\text{SUMO} = \text{IWAE}_1 + \sum_{k=1}^K \frac{\Delta_K}{\mathbb{P}(\mathcal{K}\geq k)} \nonumber
$$
where $K\sim p(K)=\mathbb{P}(\mathcal{K}=K)$. To see why this is an unbiased estimator,
$$
\begin{align*}
\mathbb{E}[\text{SUMO}] &= \mathbb{E}\left[\text{IWAE}_1 + \sum_{k=1}^K \frac{\Delta_K}{\mathbb{P}(\mathcal{K}\geq k)} \right] \nonumber\\
&= \mathbb{E}_{x's}\left[\text{IWAE}_1 + \mathbb{E}_{K}\left[\sum_{k=1}^K \frac{\Delta_K}{\mathbb{P}(\mathcal{K}\geq k)} \right]\right] \nonumber
\end{align*}
$$
The inner expectation can be further expanded
$$
\begin{align*}
\mathbb{E}_{K}\left[\sum_{k=1}^K \frac{\Delta_K}{\mathbb{P}(\mathcal{K}\geq k)} \right]
&= \sum_{K=1}^\infty P(K)\sum_{k=1}^K \frac{\Delta_K}{\mathbb{P}(\mathcal{K}\geq k)} \\
&= \sum_{k=1}^\infty \frac{\Delta_K}{\mathbb{P}(\mathcal{K}\geq k)} \sum_{K=k}^\infty P(K) \\
&= \sum_{k=1}^\infty \frac{\Delta_K}{\mathbb{P}(\mathcal{K}\geq k)} \mathbb{P}(\mathcal{K}\geq k) \\
&= \sum_{k=1}^\infty\Delta_K \\
&= \text{IWAE}_{2} - \text{IWAE}_1 + \text{IWAE}_{3} - \text{IWAE}_2 + ... = \lim_{k\rightarrow\infty}\text{IWAE}_{k}-\text{IWAE}_1
\end{align*}
$$
which shows $\mathbb{E}[\text{SUMO}] = \mathbb{E}[\text{IWAE}_\infty] = \log Z$. 

>  (N.B.) Some care needs to be taken care of for taking the limit. See the paper for more formal derivation.



A choice of $P(K)$ proposed in the paper satisfy $\mathbb{P}(\mathcal{K}\geq K)=\frac{1}{K}$. We can sample such a $K$ easily using the [inverse CDF](https://en.wikipedia.org/wiki/Inverse_transform_sampling),  $K=\lfloor\frac{u}{1-u}\rfloor$ where $u$ is sampled uniformly from the interval $[0,1]$. 



Now putting things all together, we can estimate the log-partition using SUMO. 

```python
count = 0
bs = 10
iwlb = list()
while count <= 1000000:
  u = np.random.rand(1)
  k = np.ceil(u/(1-u)).astype(int)[0]
  xs = q.rvs(bs*(k+1))
  elbo = - U(xs) - q.logpdf(xs)
  iwlb_ = elbo.reshape(bs, k+1)
  iwlb_ = np.log(np.cumsum(np.exp(iwlb_), 1) / np.arange(1,k+2))
  iwlb_ = iwlb_[:,0] + ((iwlb_[:,1:k+1] - iwlb_[:,0:k]) * np.arange(1,k+1)).sum(1)
  count += bs * (k+1)
  iwlb.append(iwlb_)

iwlb = np.concatenate(iwlb)
plt.hist(iwlb, range(-5,10))
print("Estimate:  %.4f  / Ground true:  %.4f" % (iwlb.mean(), np.log(2*np.pi)))
print("Empirical variance: %.4f" % iwlb.var())
```

`Estimate:  1.8359  / Ground true:  1.8379`

`Empirical variance: 4.1794`

https://i.imgur.com/04kPKo5.png

Indeed the empirical average is quite close to the true log-partition of the energy function. However we can also see that the distribution of the estimator is much more spread-out. In fact, it is very heavy-tailed. Note that I did not tune the proposal distribution $q$ based on the ELBO, or IWAE or SUMO. In the paper, the authors propose to tune $q$ to minimize the variance of the $\text{SUMO}$ estimator, which might be an interesting trick to look at next. 

(Reposted, see more details and code from https://www.chinweihuang.com/pages/sumo)

Modelling a distributed system as a replicated state machine provides the illusion that the distributed system is really just a single machine. At the core of the replicated state machine approach is a replicated log that is kept consistent by a consensus algorithm. Traditionally, consensus has been synonymous with Paxos. Paxos is taught in schools, and most consensus algorithm implementations are based on Paxos. However, Paxos has two main disadvantages:

1. It is hard to understand. Single-decree Paxos is nuanced, and composing single-decree Paxos into multi-Paxos is confusing.
2. It is hard to implement efficiently. Multi-Paxos is not very well described in the literature, and the algorithm is difficult to implement efficiently without modification.

This paper presents the Raft consensus algorithm. Raft provides the same performance and safety as multi-Paxos but it is designed to be much easier to understand.

Basics. Every node in a raft cluster is in one of three states: leader, follower, or candidate. The leader receives requests from users and forwards them to followers. Followers are completely passive and receive messages from leaders. Candidates perform leader elections in an attempt to become a leader. In normal operation, there is a single leader, and every other node is a follower.

Raft proceeds in a series of increasingly numbered terms. Each term consists of a leader election followed by (potentially) normal operation. There is exactly one leader elected per term. Moreover, each node participates in monotonically increasing terms. When a node sends a message in Raft, it annotates it with its term. If a leader receives a message from a later term, it immediately becomes a follower. Nodes ignore messages annotated with older terms.

Raft uses two RPCs: RequestVote (for leader election) and AppendEntries (for replication and heartbeats).

Leader Election. Leaders periodically send heartbeats (AppendEntries RPCs without any entries) to followers. As long as a follower continues to receive heartbeats, it continues to be a follower. If a follower does not receive a heartbeat after a certain amount of time, it begins leader election: it increments its term, enters the candidate state, votes for itself, and sends RequestVote RPCs in parallel to all other nodes. Either,

1. It wins. Nodes issue a single vote per term on a first come first serve basis. If a candidate receives a vote from a majority of the nodes, then it becomes leader.
2. It hears from another leader. If a candidate receives a message from another leader in a term at least as large as it, it becomes a follower.
3. It times out. It's possible that a split vote occurs and nobody becomes leader in a particular term. If this happens, the candidate times out after a certain amount of time and begins another election in the next term.

Log Replication. During normal operation, a leader receives a request from a client, appends it to its log annotated with the current term, and issues AppendEntries to all nodes in parallel. An entry is considered committed after it is replicated to a majority of the nodes. Once a log entry is committed, all previous log entries are also committed. Once a log entry is committed, the leader can apply it and respond to the user. Moreover, once an entry is committed, it is guaranteed to eventually execute at all available nodes. The leader keeps track of the index of the largest committed entry and sends it to all other nodes so that they can also apply log entries.

Raft satisfies a powerful log matching invariant:

1. "If two entries in different logs have the same index and term, then they store the same command."
2. "If two entries in different logs have the same index and term, then the logs are identical in all preceding entries."

1 is ensured by the fact that a single leader is elected for any given term, the fact that a leader only creates a single log entry per index, and the fact that once a log entry is created, it never changes index. 2 is ensured by a runtime check. When a leader sends an AppendEntries RPC for a particular index, it also sends its log entry for the previous index. The follower only applies the AppendEntries RPC if it agrees on the previous index. Inductively, this guarantees 2.

Followers may have missing or extraneous log entries. When this happens, the leader identifies the longest prefix on which the two agree. It then sends the rest of its log. The follower overwrites its log to match the leader.

Safety. The protocol described so far is unsafe. If a new leader is elected, it can accidentally force followers to overwrite committed values with uncommitted values. Thus, we must ensure that leaders contain all committed entries. Other consensus algorithms ensure this by shipping committed values to newly elected leaders. Raft takes an alternative approach and guarantees that if a leader is elected, it has every committed entry. To ensure this, Raft must restrict which nodes can be elected.

A follower rejects a RequestVote RPC if the requesting candidate's log is not as up-to-date as its log. One log is as up-to-date as another if its last entry has a higher term or has the same term but is longer.

Since a candidate must receive a majority of votes and committed values have been replicated to a majority of nodes, a candidate must contact a node with all committed values during its election which will prevent it from being elected if it doesn't have all the committed log entries.

To prevent another subtle bug, leaders also do not directly commit values from previous terms. They only commit values from their own term which indirectly commits previous log entries from previous terms.

Cluster Membership Changes. A Raft cluster cannot be instantaneously switched from one configuration to another. For example consider a cluster moving from 3 to 5 nodes. It's possible that two nodes are elected master for the same term which can lead to a safety violation. Instead, the cluster transitions to a joint consensus phase where decisions require a majority from both the old and new configuration. Once a majority of nodes accept the new configuration, the cluster can transition to it.

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?

This paper performs a comparitive study of recent advances in deep learning with human-like learning from a cognitive science point of view. Since natural intelligence is still the best form of intelligence, the authors list a core set of ingredients required to build machines that reason like humans.

- Cognitive capabilities present from childhood in humans.  
    - Intuitive physics; for example, a sense of plausibility of object trajectories, affordances.
    - Intuitive psychology; for example, goals and beliefs.
- Learning as rapid model-building (and not just pattern recognition).
    - Based on compositionality and learning-to-learn.
    - Humans learn by inferring a general schema to describe goals, object types and interactions. This enables learning from few examples. 
    - Humans also learn richer conceptual models.
        - Indicator: variety of functions supported by these models: classification, prediction, explanation, communication, action, imagination and composition.
        - Models should hence have strong inductive biases and domain knowledge built into them; structural sharing of concepts by compositional reuse of primitives.
- Use of both model-free and model-based learning.
    - Model-free, fast selection of actions in simple associative learning and discriminative tasks.
    - Model-based learning when a causal model has been built to plan future actions or maximize rewards.
- Selective attention, augmented working memory, and experience replay are low-level promising trends in deep learning inspired from cognitive psychology.
    - Need for higher-level aforementioned ingredients.