Object Detection in Aerial Images is a challenging and interesting problem. By using Keras to train a RetinaNet model for object detection in aerial images, we can use it to extract valuable information.

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Tyler Cowen asks:

Why is there so much suspicion of big business?

Perhaps in part because we cannot do without business, so many people hate or resent business, and they love to criticize it, mock it, and lower its status. Business just bugs them. . . .

The short answer is, No, I don’t think there is so much suspicion of big business in this country. No, I don’t think people love to criticize, mock and lower the status of big business.

This came up a few years ago, and at the time I pulled out data from a 2007 survey showing that just about every big business you could think of was popular, with the only exception being oil companies. Microsoft, Walmart, Citibank, GM, Pfizer: you name it, the survey respondents were overwhelmingly positive.

Nearly two-thirds of respondents say corporate profits are too high, but, “more than seven in ten agree that ‘the strength of this country today is mostly based on the success of American business’ – an opinion that has changed very little over the past 20 years.”

Corporations are more popular with Republicans than with Democrats, but most of the corporations in the survey were popular with a clear majority in either party.

Big business does lots of things for us, and the United States is a proudly capitalist country, so it’s no shocker that most businesses in the survey were very popular.

So maybe the question is, Why did an economist such as Cowen think that people view big business so negatively?

My quick guess is that we notice negative statements more than positive statements. Cowen himself roots for big business, he’s generally on the side of big business, so when he sees any criticism of it, he bristles. He notices the criticism and is bothered by it. When he sees positive statements about big business, that all seems so sensible that perhaps he hardly notices. The negative attitudes are jarring to him so more noticeable. Perhaps in the same way that I notice bad presentations of data. An ugly table or graph is to me like fingernails on the blackboard.

Anyway, it’s perfectly reasonable for Cowen to be interested in those people who “hate or resent business, and they love to criticize it, mock it, and lower its status.” We should just remember that, at least from these survey data, it seems that this is a small minority of people.

Why did I write this post?

The bigger point here is that this is an example of something I see a lot, which is a social scientist or pundit coming up with theories to explain some empirical pattern in the world, but it turns out the pattern isn’t actually real. This came up years ago with Red State Blue State, when I noticed journalists coming up with explanations for voting patterns that were not happening (see for example here) and of course it comes up a lot with noise-mining research, whether it be a psychologist coming up with theories to explain ESP, or a sociologist coming up with theories to explain spurious patterns in sex ratios.

It’s fine to explain data; it’s just important to be aware of what’s being explained. In the context of the above-linked Cowen post, it’s fine to answer the question, “If business is so good, why is it so disliked?”—as long as this sentence is completed as follows: “If business is so good, why is it so disliked by a minority of Americans?” Explaining minority positions is important; we should just be clear it’s a minority.

Or of course it’s possible that Cowen has access to other data I haven’t looked at, perhaps more recent surveys that would modify my empirical understanding. That would be fine too.

P.S. The title of this post was originally “Most Americans like big business.” I changed the last word to “businesses” in response to comments who pointed out that most Americans express negative views about “big business” in general, but they like most individual big businesses that they’re asked about.

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This article contains an interview veteran data scientist, Dr Stylianos (Stelios) Kampakis, in which he discusses his career, and how he helps decision makers across a range of businesses understand how data science can benefit them.

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Everyone's relationship timeline is a little different. This animation plays out real-life paths to marriage. Read More

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Software Stack, Gig Economy, Simple Over Flexible, and Packet Radio

1. Thoughts on Conway's Law and the Software Stack (Jessie Frazelle) -- All these problems are not small by any means. They are miscommunications at various layers of the stack. They are people thinking an interface or feature is secure when it is merely a window dressing that can be bypassed with just a bit more knowledge about the stack. I really like the advice Lea Kissner gave: “take the long view, not just the broad view.” We should do this more often when building systems.
2. Troubles with the Open Source Gig Economy and Sustainability Tip Jar (Chris Aniszczyk) -- thoughtful long essay with a lot of links for background reading, on the challenges of sustainability via Patreon, etc., through to some signs of possibly-working models.
3. Choose Simple Solutions Over Flexible Ones -- flexibility does not come for free.
4. New Packet Radio (Hackaday) -- a custom radio protocol, designed to transport bidirectional IP traffic over 430MHz radio links (ham radio). This protocol is optimized for "point to multipoint" topology, with the help of managed-TDMA. Note that Hacker News commentors indicate some possible FCC violations; though, as the project comes from France, that's probably not a problem for the creators of the software.

Continue reading Four short links: 26 March 2019.

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Knowledge Graph Development for App Store Data Modeling

AttoNets: Compact and Efficient Deep Neural Networks for the Edge via Human-Machine Collaborative Design

Adaptive Strategies For Efficient Model Reduction In High-Dimensional Inverse Problems

QATM: Quality-Aware Template Matching For Deep Learning

Graph Convolutional Label Noise Cleaner: Train a Plug-and-play Action Classifier for Anomaly Detection

A novel quantum grid search algorithm and its application

In this paper we present a novel quantum algorithm, namely the quantum grid search algorithm, to solve a special search problem. Suppose non-empty buckets are given, such that each bucket contains some marked and some unmarked items. In one trial an item is selected from each of the buckets. If every selected item is a marked item, then the search is considered successful. This search problem can also be formulated as the problem of finding a ‘marked path’ associated with specified bounds on a discrete grid. Our algorithm essentially uses several Grover search operators in parallel to efficiently solve such problems. We also present an extension of our algorithm combined with a binary search algorithm in order to efficiently solve global trajectory optimization problems. Estimates of the expected run times of the algorithms are also presented, and it is proved that our proposed algorithms offer exponential improvement over pure classical search algorithms, while a traditional Grover’s search algorithm offers only a quadratic speedup. We note that this gain comes at the cost of increased complexity of the quantum circuitry. The implication of such exponential gains in performance is that many high dimensional optimization problems, which are intractable for classical computers, can be efficiently solved by our proposed quantum grid search algorithm.

Advanced Capsule Networks via Context Awareness

An Effective Label Noise Model for DNN Text Classification

A Comparison of Prediction Algorithms and Nexting for Short Term Weather Forecasts

Extrapolating paths with graph neural networks

LYRICS: a General Interface Layer to Integrate AI and Deep Learning

Short Datathon for the Interdisciplinary Development of Data Analysis and Visualization Skills

MediaRank: Computational Ranking of Online News Sources

Combining Model and Parameter Uncertainty in Bayesian Neural Networks

Multi-Differential Fairness Auditor for Black Box Classifiers

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Through Twitter, Danny H. submitted the following chart that shows a tiny 0.3 percent of Youtube creators generate almost 40 percent of all viewing on the platform. He asks for ideas about how to present lop-sided data that follow the "80/20" rule.

In the classic 80/20 rule, 20 percent of the units account for 80 percent of the data. The percentages vary, so long as the first number is small relative to the second. In the Youtube example, 0.3 percent is compared to 40 percent. The underlying reason for such lop-sidedness is the differential importance of the units. The top units are much more important than the bottom units, as measured by their contribution to the data.

I sense a bit of "loss aversion" on this chart (explained here). The designer color-coded the views data into blue, brown and gray but didn't have it in him/her to throw out the sub-categories, which slows down cognition and adds hardly to our understanding.

I like the chart title that explains what it is about.

Turning to the D corner of the Trifecta Checkup for a moment, I suspect that this chart only counts videos that have at least one play. (Zero-play videos do not show up in a play log.) For a site like Youtube, a large proportion of uploaded videos have no views and thus, many creators also have no views.

***

My initial reaction on Twitter is to use a mirrored bar chart, like this:

I ended up spending quite a bit of time exploring other concepts. In particular, I like to find an integrated way to present this information. Most charts, such as the mirrored bar chart, a Bumps chart (slopegraph), and Lorenz chart, keep the two series of percentages separate.

Also, the biggest bar (the gray bar showing 97% of all creators) highlights the least important Youtubers while the top creators ("super-creators") are cramped inside a slither of a bar, which is invisible in the original chart.

What I came up with is a bar-density plot, where I use density to encode the importance of creators, and bar lengths to encode the distribution of views.

Each bar is divided into pieces, with the number of pieces proportional to the number of creators in each segment. This has the happy result that the super-creators are represented by large (red) pieces while the least important creators by little (gray) pieces.

The embedded tessellation shows the structure of the data: the bottom third of the views are generated by a huge number of creators, producing a few views each - resulting in a high density. The top 38% of the views correspond to a small number of super-creators - appropriately shown by a bar of low density.

For those interested in technicalities, I embed a Voronoi diagram inside each bar, with randomly placed points. (There will be a companion post later this week with some more details, and R code.)

Here is what the bar-density plot looks like when the distribution is essentially uniform:

The density inside each bar is roughly the same, indicating that the creators are roughly equally important.

P.S. The next post on the bar-density plot, with some experimental R code, will be available here.

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In my last post, I described a bar-density chart to show paired data of proportions with an 80/20-type rule. The following example illustrates that a small proportion of Youtubers generate a large proportion of views.

Other examples of this type of data include:

• the top 10% of families own 75% of U.S. household wealth (link)
• the top 1% of artists earn 77% of recorded music income (link)
• Five percent of AT&T customers consume 46% of the bandwidth (link)

In all these examples, the message of the data is the importance of a small number of people (top earners, superstars, bandwidth hogs). A good visual should call out this message.

The bar-density plot consists of two components:

• the bar chart which shows the distribution of the data (views, wealth, income, bandwidth) among segments of people;
• The embedded Voronoi diagram within each bar that encodes the relative importance of each people segment, as measured by the (inverse) density of the population among these segments - a people segment is more important if each individual accounts for more of the data, or in other words, the density of people within the group is lower.

The bar chart can adopt a more conventional horizontal layout.

Voronoi tessellation

To understand the Voronoi diagram, think of a fixed number (say, 100) of randomly placed points inside a bar. Then, for any point inside the bar area, it has a nearest neighbor among those 100 fixed points. Assign every point on the surface to its nearest neighbor. From this, one can draw a boundary around each of the 100 points to include all its nearest neighbors. The resulting tessellation is the Voronoi diagram. (The following illustration comes from this AMS column.)

The density of points in the respective bars encodes the relative proportions of people within those groups. For my example, I placed 6 points in the red bar, 666 points in the yellow bar, and ~2000 points in the gray bar, which precisely represents the relative proportions of creators in the three segments.

Density is represented statistically

Notice that the density is represented statistically, not empirically. According to the annotation on the original chart, the red bar represents 14,000 super-creators. Correspondingly, there are 4.5 million creators in the gray bar. Any attempt to plot those as individual pieces will result in a much less impactful graphic. If the representation is interpreted statistically, as relative densities within each people segment, the message of relative importance of the units within each group is appropriately conveyed.

A more sophisticated way of deciding how many points to place in the red bar is to be developed. Here, I just used the convenient number of 6.

The color shades are randomly applied to the tessellation pieces, and used to facilitate reading of densities.

***

In this section, I provide R code for those who want to explore this some more. This is code used for prototyping, and you're welcome to improve them. The general strategy is as follows:

• Set the rectangular area (bar) in which the Voronoi diagram is to be embedded. The length of the bar is set to the proportion of views, appropriately scaled. The code utilizes the dirichlet function within the spatstat package to generate the fixed points; this requires setting up the owin parameter to represent a rectangle.
• Set the number of points (n) to be embedded in the bar, determined by the relative proportion of creators, appropriately scaled. Generate a data frame containing the x-y coordinates of n randomly placed points, within the rectangle defined above.
• Use the ppp function to generate the Voronoi data
• Set up a colormap for plotting the Voronoi diagram
• Plot the Voronoi diagram; assign shades at random to the pieces (in a production code, these random numbers should be set as marks in the ppp but it's easier to play around with the shades if placed here)

The code generates separate charts for each bar segment. A post-processing step is currently required to align the bars to attain equal height. I haven't figured out whether the multiplot option helps here.

library(spatstat)

# enter the scaled proportions of creators and views
# the Youtube example has three creator segments

# number of randomly generated points should be proportional to proportion of creators. Multiply nc by a scaling factor if desired

nc = c(3, 33, 965)*2

# bar widths should be proportional to proportion of views
# total width should be set based on the width of your page

wide = c(378, 276, 346)/2

# set bar height, to attain a particular aspect ratio
bar_h = 50

# define function to generate points
# defines rectangular window

makepoints = function (n, wide, height) {
    df <- data.frame(x = runif(n,0,wide),y = runif(n,0,height))
    W <- owin( c(0, wide), c(0,height) ) # rectangular window
    pp1 <- as.ppp( df, W )
    y <- dirichlet(pp1)
    # y$marks <- sample(0:wide, n, replace=T) # marks are for colors
    return (y)
}

y_red = makepoints(nc[1], wide[1], bar_h) # height of each bar fixed
y_yel = makepoints(nc[2], wide[2], bar_h)
y_gry = makepoints(nc[3], wide[3], bar_h)

# setting colors (4 shades per bar, one color per bar)

cr_red = colourmap(c("lightsalmon","lightsalmon2", "lightsalmon4", "brown"), breaks=round(seq(0, wide[1],length.out=5)))

cr_yel = colourmap(c("burlywood1", "burlywood2", "burlywood3", "burlywood4"), breaks=round(seq(0, wide[2],length.out=5)))

cr_gry = colourmap(c("gray80", "gray60", "gray40", "gray20"), breaks=round(seq(0, wide[3],length.out=5)))

# plotting

par(mar=c(0,0,0,0))

# add png to save image to png

# remove values= if colors set in ppp

plot.tess(y_red, main="", border="pink3", do.col=T, values = sample(0:wide[1], nc[1], replace=T), col=cr_red, xlim=c(0, wide[1]), ylim=c(0,bar_h), ribbon=F)

plot.tess(y_yel, main="", border="darkgoldenrod4", do.col=T, values=sample(0:wide[2], nc[2], replace=T), col=cr_yel, xlim=c(0, wide[2]), ylim=c(0,bar_h), ribbon=F)

plot.tess(y_gry, main="", border="darkgray", do.col=T, values=sample(0:wide[3], nc[3], replace=T), col=cr_gry, xlim=c(0, wide[3]), ylim=c(0,bar_h), ribbon=F)

# because of random points, the tessellation looks different each time
# post-processing: make each bar the same height when aligned side by side

***

A cousin of the bar-density plot is the pie-density plot. Since I'm using only three creator segments, which each account for about 30-40% of the total views, it is natural to use a pie chart. In this case, we embed the Voronoi diagrams into the pie sectors.

If the distribution were more even, that is to say, the creators are more or less equally important, the pie-density plot looks like this:

***

Something that is more like 80/20

The original chart shows the top 0.3 percent generating almost 40 percent of the views. A more typical insight is top X percent generates 80 percent of the data. For the YouTube data, X is 11 percent. What does the pie-density chart look like if  top 11 percent <-> 80 percent, middle 33 percent <-> 11 percent, bottom 56 percent <-> 8 percent?

Roughly speaking, the second segment includes 3 times the people as the largest, and the third has 5 times as the largest.

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Tabler’ API for ‘Shiny’ (tablerDash)
R’ interface to the ‘Tabler’ HTML template. See more here <https://tabler.io>. ‘tablerDash’ is …

Superfast Likelihood Inference for Stationary Gaussian Time Series (SuperGauss)
Likelihood evaluations for stationary Gaussian time series are typically obtained via the Durbin-Levinson algorithm, which scales as O(n^2) in the numb …

Design and Analyze Studies using the Sequential Parallel Comparison Design (SPCDAnalyze)
Programs to find the sample size or power of studies using the Sequential Parallel Comparison Design (SPCD) and programs to analyze such studies. This …

Tools for Acquiring and Analyzing Political Data (politicaldata)
Provides for useful functions to obtain commonly-used data in political analysis and political science, including from sources such as the Comparative …

Temporal Contributions on Trends using Mixed Models (TempCont)
Method to estimate the effect of the trend in predictor variables on the observed trend of the response variable using mixed models with temporal autoc …

Dynamic Functional Connectivity Analysis (dfConn)
An implementation of multivariate linear process bootstrap (MLPB) method and sliding window technique to assess the dynamic functional connectivity (dF …

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A fundamental aspect of the reproducible research framework is that (statistical) analysis can be reproduced; that is, given a set of instructions (or a script file) the exact results can be achieved by another analyst with the same raw data. This idea may seem intuitive, but in practice it can be difficult to achieve in an analytical environment that is always evolving and changing.

For example, Tidyverse users will have recently seen the following warning in R:

Warning message:
'data_frame()' is depreciated, use 'tibble()'.

data_frame(a = 1:3)

This is because dplyr has changed, hopefully for the better, and tibble() is now the preferred route. It is conceivable that in a future release the data_frame() function will no longer be a part of dplyr at all.

So, what does this have to do with reproducible research? Say you want to come back to your analysis in 5 years and re-run your old code. Your future installation of R with the latest Tidyverse installation may not be backwards compatible with your now ancient old code and the analysis will crash.

There are a couple of strategies that we could use to deal with updating dependencies. The first, and possibly the easiest, is to use devtools to install older package versions (see here for further details). But what if the version of the package you used is not archived on CRAN? For example, the analysis could have used a package from GitHub that has since changed and the maintainer hasn’t used systematic releases for you to pull from. Thus, this strategy is quite likely to fail.

Another solution is to put your entire project inside a static virtual environment that is isolated from the rest of your machine. The benefit of project isolation is that any dependencies that are installed within the environment can be made persistent, but are also separated from any dependency upgrades that might be applied to your host machine or to other projects.

Docker isn’t a new topic for regular R-Bloggers readers, but for those of you that are unfamiliar: Docker is a program that uses virtual containers, which isolate and bundle applications. The containers are defined by a set of instructions detailed in a docker-compose.yml or Dockerfile and can effectively be stacked to call upon the capabilities of base images. Furthermore, one of the fundamental tenets of Docker is portability – if a container will work on your local machine then it will work anywhere. And because base images are versioned, they will work for all time. This is also great for scalability onto servers and distribution to colleagues and collaborators who will see exactly what you have prepared regardless of their host operating system.

Our dockerised RStudio environment.

Our group at the Telethon Kids Institute has prepared source code to launch a dockerised RStudio Server instance via a NGINX reverse proxy enabled for HTTPS connections. Our GitHub repository provides everything you need to quickly establish a new project (just clone the repository) with the features of RStudio Web Server with the added benefit of SSL encryption (this will need some local configuration); even though RStudio Server is password protected, web encryption is still important for us as we routinely deal with individual level health data.

(Important note, even with data security measures in place, our policy is for patient data to be de-identified prior to analysis as per good clinical practice norms and, except for exceptional circumstances, we would use our intranet to further restrict access).

The defining docker-compose.yml that we use can be found at out our GitHub site via this link: https://github.com/TelethonKids/rstudio. We used an RStudio base image with Tidyverse pre-installed with R 3.5.3, which is maintained by rocker at https://hub.docker.com/r/rocker/tidyverse. As updates are made to the base-image, the repository will be updated with new releases that provide an opportunity to re-install a specific version of the virtual environment. It has also been set up with persistent volumes for the projects, rstudio, and lib/R directories to keep any changes made to the virtual environment for back-up and further version control.

By combining tools like Docker and Git we believe we can refine and make common place, within our institute and those we collaborate with, a culture of reproducible research as we conduct world class research to improve the lives of sick children.

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Manifold Adversarial Training (MAT)
The recently proposed adversarial training methods show the robustness to both adversarial and original examples and achieve state-of-the-art results in supervised and semi-supervised learning. All the existing adversarial training methods consider only how the worst perturbed examples (i.e., adversarial examples) could affect the model output. Despite their success, we argue that such setting may be in lack of generalization, since the output space (or label space) is apparently less informative. In this paper, we propose a novel method, called Manifold Adversarial Training (MAT). MAT manages to build an adversarial framework based on how the worst perturbation could affect the distributional manifold rather than the output space. Particularly, a latent data space with the Gaussian Mixture Model (GMM) will be first derived. On one hand, MAT tries to perturb the input samples in the way that would rough the distributional manifold the worst. On the other hand, the deep learning model is trained trying to promote in the latent space the manifold smoothness, measured by the variation of Gaussian mixtures (given the local perturbation around the data point). Importantly, since the latent space is more informative than the output space, the proposed MAT can learn better a robust and compact data representation, leading to further performance improvement. The proposed MAT is important in that it can be considered as a superset of one recently-proposed discriminative feature learning approach called center loss. We conducted a series of experiments in both supervised and semi-supervised learning on three benchmark data sets, showing that the proposed MAT can achieve remarkable performance, much better than those of the state-of-the-art adversarial approaches. …

RMSProp+AF
Source localization is of pivotal importance in several areas such as wireless sensor networks and Internet of Things (IoT), where the location information can be used for a variety of purposes, e.g. surveillance, monitoring, tracking, etc. Time Difference of Arrival (TDOA) is one of the well-known localization approaches where the source broadcasts a signal and a number of receivers record the arriving time of the transmitted signal. By means of computing the time difference from various receivers, the source location can be estimated. On the other hand, in the recent few years novel optimization algorithms have appeared in the literature for $(i)$ processing big data and for $(ii)$ training deep neural networks. Most of these techniques are enhanced variants of the classical stochastic gradient descent (SGD) but with additional features that promote faster convergence. In this paper, we compare the performance of the classical SGD with the novel techniques mentioned above. In addition, we propose an optimization procedure called RMSProp+AF, which is based on RMSProp algorithm but with the advantage of incorporating adaptation of the decaying factor. We show through simulations that all of these techniques—which are commonly used in the machine learning domain—can also be successfully applied to signal processing problems and are capable of attaining improved convergence and stability. Finally, it is also shown through simulations that the proposed method can outperform other competing approaches as both its convergence and stability are superior. …

Cross-Domain Latent Feature Mapping (CDLFM)
Collaborative Filtering (CF) is a widely adopted technique in recommender systems. Traditional CF models mainly focus on predicting a user’s preference to the items in a single domain such as the movie domain or the music domain. A major challenge for such models is the data sparsity problem, and especially, CF cannot make accurate predictions for the cold-start users who have no ratings at all. Although Cross-Domain Collaborative Filtering (CDCF) is proposed for effectively transferring users’ rating preference across different domains, it is still difficult for existing CDCF models to tackle the cold-start users in the target domain due to the extreme data sparsity. In this paper, we propose a Cross-Domain Latent Feature Mapping (CDLFM) model for cold-start users in the target domain. Firstly, in order to better characterize users in sparse domains, we take the users’ similarity relationship on rating behaviors into consideration and propose the Matrix Factorization by incorporating User Similarities (MFUS) in which three similarity measures are proposed. Next, to perform knowledge transfer across domains, we propose a neighborhood based gradient boosting trees method to learn the cross-domain user latent feature mapping function. For each cold-start user, we learn his/her feature mapping function based on the latent feature pairs of those linked users who have similar rating behaviors with the cold-start user in the auxiliary domain. And the preference of the cold-start user in the target domain can be predicted based on the mapping function and his/her latent features in the auxiliary domain. Experimental results on two real data sets extracted from Amazon transaction data demonstrate the superiority of our proposed model against other state-of-the-art methods. …

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“There are two kinds of people who violate the rules of statistical inference: people who don’t know them and people who don’t agree with them.” Allen Downey ( December 8, 2015 )

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Stationarity is a very general, qualitative assumption, that can be assessed on the basis of application specifics. It is thus a rather attractive assumption to base statistical analysis on, especially for problems for which less general qualitative assumptions, such as independence or finite memory, clearly fail. However, it has long been considered too general to be able to make statistical inference. One of the reasons for this is that rates of convergence, even of frequencies to the mean, are not available under this assumption alone. Recently, it has been shown that, while some natural and simple problems, such as homogeneity, are indeed provably impossible to solve if one only assumes that the data is stationary (or stationary ergodic), many others can be solved with rather simple and intuitive algorithms. The latter include clustering and change point estimation among others. In this volume I summarize these results. The emphasis is on asymptotic consistency, since this the strongest property one can obtain assuming stationarity alone. While for most of the problem for which a solution is found this solution is algorithmically realizable, the main objective in this area of research, the objective which is only partially attained, is to understand what is possible and what is not possible to do for stationary time series. The considered problems include homogeneity testing (the so-called two sample problem), clustering with respect to distribution, clustering with respect to independence, change point estimation, identity testing, and the general problem of composite hypotheses testing. For the latter problem, a topological criterion for the existence of a consistent test is presented. In addition, a number of open problems is presented.

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The 3 Best Optimization Methods in Neural Networks

Machine learning interpretability techniques

Statistical Tests for Comparing Machine Learning and Baseline Performance

Loss functions based on feature activation and style loss.

Advanced Keras – Accurately Resuming a Training Process

Automated Machine Learning: Myth Versus Realty

Regularization techniques for Neural Networks

Harnessing Organizational Knowledge for Machine Learning

Infographic: What’s the Future of the Data Catalog?

The Evolved Transformer – Enhancing Transformer with Neural Architecture Search

A Beginner’s Guide to Big Data and Blockchain

Text Preprocessing Techniques

Chatbot – A real game changer in the industry of technologically advanced practices

Factors Behind Data Storage Security: Is Your Business Vulnerable?

Building NLP Classifiers Cheaply With Transfer Learning and Weak Supervision

How to setup the PySpark environment for development, with good software engineering practices

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First some background, then the bad news, and finally the good news.

Spoiler alert: The bad news is that exploring the posterior is intractable; the good news is that we don’t need to explore all of it.

Sampling to characterize the posterior

There’s a misconception among Markov chain Monte Carlo (MCMC) practitioners that the purpose of sampling is to explore the posterior. For example, I’m writing up some reproducible notes on probability theory and statistics through sampling (in pseudocode with R implementations) and have just come to the point where I’ve introduced and implemented Metropolis and want to use it to exemplify convergence mmonitoring. So I did what any right-thinking student would do and borrowed one of my mentor’s diagrams (which is why this will look familiar if you’ve read the convergence monitoring section of Bayesian Data Analysis 3).

First M steps of of isotropic random-walk Metropolis with proposal scale normal(0, 0.2) targeting a bivariate normal with unit variance and 0.9 corelation. After 50 iterations, we haven’t found the typical set, but after 500 iterations we have. Then after 5000 iterations, everything seems to have mixed nicely through this two-dimensional example.

This two-dimensional traceplot gives the misleading impression that the goal is to make sure each chain has moved through the posterior. This low-dimensional thinking is nothing but a trap in higher dimensions. Don’t fall for it!

Bad news from higher dimensions

It’s simply intractable to “cover the posterior” in high dimensions. Consider a 20-dimensional standard normal distribution. There are 20 variables, each of which may be positive or negative, leading to a total of , or more than a million orthants (generalizations of quadrants). In 30 dimensions, that’s more than a billion. You get the picture—the number of orthant grows exponentially so we’ll never cover them all explicitly through sampling.

Good news in expectation

Bayesian inference is based on probability, which means integrating over the posterior density. This boils down to computing expectations of functions of parameters conditioned on data. This we can do.

For example, we can construct point estimates that minimize expected square error by using posterior means, which are just expectations conditioned on data, which are in turn integrals, which can be estimated via MCMC,

where are draws from the posterior

If we want to calculate predictions, we do so by using sampling to calculate the integral required for the expectation,

If we want to calculate event probabilities, it’s just the expectation of an indicator function, which we can calculate through sampling, e.g.,

The good news is that we don’t need to visit the entire posterior to compute these expectations to within a few decimal places of accuracy. Even so, MCMC isn’t magic—those two or three decimal places will be zeroes for tail probabilities.

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IBM’s Data Science Professional Certificate program on Coursera brings you everything you need to plunge into an exciting career in data science—no prior experience required! Start learning today.

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Data and AI are all about scale. Databricks is bringing the Spark + AI Summit to San Francisco Apr 23-25. Check out the full list of sessions at Summit to see more exciting talks. Use code KDNuggets200 and get $200 off registration.

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Machine learning techniques have deeply rooted in our everyday life. However, since it is knowledge- and labor-intensive to pursuit good learning performance, human experts are heavily engaged in every aspect of machine learning. In order to make machine learning techniques easier to apply and reduce the demand for experienced human experts, automatic machine learning~(AutoML) has emerged as a hot topic of both in industry and academy. In this paper, we provide a survey on existing AutoML works. First, we introduce and define the AutoML problem, with inspiration from both realms of automation and machine learning. Then, we propose a general AutoML framework that not only covers almost all existing approaches but also guides the design for new methods. Afterward, we categorize and review the existing works from two aspects, i.e., the problem setup and the employed techniques. Finally, we provide a detailed analysis of AutoML approaches and explain the reasons underneath their successful applications. We hope this survey can serve as not only an insightful guideline for AutoML beginners but also an inspiration for future researches. Taking Human out of Learning Applications: A Survey on Automated Machine Learning

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Last Friday, we discussed the use of ROC curves to describe the goodness of a classifier. I did say that I will post a brief paragraph on the interpretation of the diagonal. If you look around some say that it describes the “strategy of randomly guessing a class“, that it is obtained with “a diagnostic test that is no better than chance level“, even obtained by “making a prediction by tossing of an unbiased coin“.

Let us get back to ROC curves to illustrate those points. Consider a very simple dataset with 10 observations (that is not linearly separable)

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x1 = c(.4,.55,.65,.9,.1,.35,.5,.15,.2,.85)
x2 = c(.85,.95,.8,.87,.5,.55,.5,.2,.1,.3)
y = c(1,1,1,1,1,0,0,1,0,0)
df = data.frame(x1=x1,x2=x2,y=as.factor(y))

here we can check that, indeed, it is not separable

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plot(x1,x2,col=c("red","blue")[1+y],pch=19)

Consider a logistic regression (the course is on linear models)

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reg = glm(y~x1+x2,data=df,family=binomial(link = "logit"))

but any model here can be used… We can use our own function

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Y=df$y
S=predict(reg)
roc.curve=function(s,print=FALSE){
  Ps=(S>=s)*1
   
  FP=sum((Ps==1)*(Y==0))/sum(Y==0)
     
  TP=sum((Ps==1)*(Y==1))/sum(Y==1)
   
if(print==TRUE){
     
print(table(Observed=Y,Predicted=Ps))
     
}
   
vect=c(FP,TP)
   
names(vect)=c("FPR","TPR")
   
return(vect)
}

or any R package actually

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library(ROCR)

perf=performance(prediction(S,Y),"tpr","fpr")

We can plot the two simultaneously here

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plot(performance(prediction(S,Y),"tpr","fpr"))
V=Vectorize(roc.curve)(seq(-5,5,length=251))

points(V[1,],V[2,])

segments(0,0,1,1,col="light blue")

So our code works just fine, here. Let us consider various strategies that should lead us to the diagonal.

The first one is : everyone has the same probability (say 50%)

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S=rep(.5,10)

plot(performance(prediction(S,Y),"tpr","fpr"))

V=Vectorize(roc.curve)(seq(0,1,length=251))

points(V[1,],V[2,])

Indeed, we have the diagonal. But to be honest, we have only two points here : and . Claiming that we have a straight line is not very satisfying… Actually, note that we have this situation whatever the probability we choose

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S=rep(.2,10)

plot(performance(prediction(S,Y),"tpr","fpr"))

V=Vectorize(roc.curve)(seq(0,1,length=251))

points(V[1,],V[2,])

We can try another strategy, like “making a prediction by tossing of an unbiased coin“. This is what we obtain

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set.seed(1)

S=sample(0:1,size=10,replace=TRUE)

plot(performance(prediction(S,Y),"tpr","fpr"))

V=Vectorize(roc.curve)(seq(0,1,length=251))

points(V[1,],V[2,])

segments(0,0,1,1,col="light blue")

We can also try some sort of “random classifier”, where we choose the score randomly, say uniform on the unit interval

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set.seed(1)

S=runif(10)

plot(performance(prediction(S,Y),"tpr","fpr"))

V=Vectorize(roc.curve)(seq(0,1,length=251))

points(V[1,],V[2,])

segments(0,0,1,1,col="light blue")

Let us try to go further on that one. For convenience, let us consider another function to plot the ROC curve

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V=Vectorize(roc.curve)(seq(0,1,length=251))

roc_curve=Vectorize(function(x) max(V[2,which(V[1,]<=x)]))

We have the same line as previously

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x=seq(0,1,by=.025)

y=roc_curve(x) 

lines(x,y,type="s",col="red")

But now, consider many scoring strategies, all randomly chosen

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MY=matrix(NA,500,length(y))

for(i in 1:500){
  
S=runif(10)
  
V=Vectorize(roc.curve)(seq(0,1,length=251))
  
MY[i,]=roc_curve(x)

}

plot(performance(prediction(S,df$y),"tpr","fpr"),col="white")

for(i in 1:500){
  lines(x,MY[i,],col=rgb(0,0,1,.3),type="s")
}

lines(c(0,x),c(0,apply(MY,2,mean)),col="red",type="s",lwd=3)
segments(0,0,1,1,col="light blue")

The red line is the average of all random classifiers. It is not a straight line, be we observe oscillations around the diagonal.

Consider a dataset with more observations

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myocarde = read.table("http://freakonometrics.free.fr/myocarde.csv",head=TRUE, sep=";")

myocarde$PRONO = (myocarde$PRONO=="SURVIE")*1

reg = glm(PRONO~.,data=myocarde,family=binomial(link = "logit"))

Y=myocarde$PRONO

S=predict(reg)

plot(performance(prediction(S,Y),"tpr","fpr"))

V=Vectorize(roc.curve)(seq(-5,5,length=251))

points(V[1,],V[2,])

segments(0,0,1,1,col="light blue")

Here is a “random classifier” where we draw scores randomly on the unit interval

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S=runif(nrow(myocarde)

plot(performance(prediction(S,Y),"tpr","fpr"))

V=Vectorize(roc.curve)(seq(-5,5,length=251))

points(V[1,],V[2,])

segments(0,0,1,1,col="light blue")

And if we do that 500 times, we obtain, on average

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MY=matrix(NA,500,length(y))

for(i in 1:500){
  
S=runif(length(Y))
  
V=Vectorize(roc.curve)(seq(0,1,length=251))
  
MY[i,]=roc_curve(x)
}

plot(performance(prediction(S,Y),"tpr","fpr"),col="white")

for(i in 1:500){
  lines(x,MY[i,],col=rgb(0,0,1,.3),type="s")

}

lines(c(0,x),c(0,apply(MY,2,mean)),col="red",type="s",lwd=3)
segments(0,0,1,1,col="light blue")

So, it looks like me might say that the diagonal is what we have, on average, when drawing randomly scores on the unit interval…

I did mention that an interesting visual tool could be related to the use of the Kolmogorov Smirnov statistic on classifiers. We can plot the two empirical cumulative distribution functions of the scores, given the response

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score=data.frame(yobs=Y,
                 ypred=predict(reg,type="response"))

f0=c(0,sort(score$ypred[score$yobs==0]),1)

f1=c(0,sort(score$ypred[score$yobs==1]),1)

plot(f0,(0:(length(f0)-1))/(length(f0)-1),col="red",type="s",lwd=2,xlim=0:1)

lines(f1,(0:(length(f1)-1))/(length(f1)-1),col="blue",type="s",lwd=2)

we can also look at the distribution of the score, with the histogram (or density estimates)

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S=score$ypred

hist(S[Y==0],col=rgb(1,0,0,.2),
     probability=TRUE,breaks=(0:10)/10,border="white")

hist(S[Y==1],col=rgb(0,0,1,.2),
     probability=TRUE,breaks=(0:10)/10,border="white",add=TRUE)

lines(density(S[Y==0]),col="red",lwd=2,xlim=c(0,1))

lines(density(S[Y==1]),col="blue",lwd=2)

The underlying idea is the following : we do have a “perfect classifier” (top left corner)

is the supports of the scores do not overlap

otherwise, we should have errors. That the case below

we in 10% of the cases, we might have misclassification

or even more missclassification, with overlapping supports

Now, we have the diagonal

when the two conditional distributions of the scores are identical

Of course, that only valid when is very large, otherwise, it is only what we observe on average….

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As a Data Scientist, you will be responsible for shaping and delivering data-driven insights. We are looking for data scientists with a deep product sense, who have an innate curiosity, and are eager to dive into large, complex datasets and create actionable insights.

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A sampling of the many visuals created this month

The March #SWDchallenge took on a slightly different flavor. Rather than summoning you to try a certain graph type or approach, this month’s goal was effectiveness. We sought to see how people varied in answering specific questions about the same dataset. Data was sourced from AidData in partnership with Enrico Bertini, Associate Professor at NYU, who will be undertaking some data visualization research based on this challenge.

Sixty-nine people submitted a response to answer the primary question posed (“Who donates?”) and related sub-questions on the interesting patterns in the distribution across countries and recipients. With so many ways to visualize same dataset, you’ll see evidence that there isn’t a single “right” answer when it comes to how we show and communicate with data. Data can be visualized in countless different ways and by varying views of the same data, we enable our audience to see different things.

To everyone who submitted examples: THANK YOU for taking the time to create and share your work! We aren’t going to call out specific entries this month, so as not to introduce bias. By participating in this month’s challenge, you’ve helped Enrico push forward some important research. We’ll be sure to share more on that front once it’s available. The submissions below are posted below in alphabetical order and include the link to the original Tweet or interactive visual.

We encourage you to scroll through the entire post and be inspired by your peers’ approaches to this challenge! Spoiler alert: inspiration will be a central theme in the next challenge, which will be announced on April 1. Until then, check out the #SWDchallenge page for the archives of previous months' challenges and submissions. Happy browsing!

Alex

Link

Alexandre

Link

Ana

Link

Anna

Link

Anthony P

Link

Anthony S

Link

Arthur

Link

Ash

Link

Ben

Link

Bill

Link

Cameron

Link

Charles

Link

Dashibodi

Link

Declan

Link

Dennis

Link

Dmitry

Link

Edwin

Link

Equal Pay Act

Link

Fiona

Link

My approach to this challenge was to answer the question based on 2013 data, looking at who the top 10 donors are, who they have made donations to and for what causes. One thing that I have done differently was to group the purposes into broad categories to give us a rough idea on what efforts the top 10 donors are focused on contributing to. (I am looking to write a medium post about my approach soon.

Geoff

Link

Gianni

Link

Gordon

Link

Haley

Link

Impacsis

Link

Ioannis

Link

Jaclyn

Link

Jayleen

Link

Joakim

Link

Johanie

Link

Jonas

Link

Joost

For this month’s challenge I decided to use Power BI as an opportunity to get more familiar with DAX. I focused on all donations by The Netherlands to other countries. Because there are a lot of recipients and a lot of purposes in this dataset, I decided to show only the top 5 recipients and purposes. But because this shows only a part of the picture, I also wanted to visualize the part of this top 5 in the total amount. I did this with the stacked bar chart and the accompanying text. The interactive visual can be seen here.

Kate

Link

Kubasova

Link

Lora

Link

Lorenzo

Link

Michiel

Link

Mohit

Link

Narendran

Link

Natalia

Link

Pallavi

Link

I have visualized a simple line chart with a cumulative sum of $ metric, for the Top 5 Donor countries, to answer the 'Who Donates' question. The visual plot shows that since 1973, United States has been donating the highest $. However, it also shows that Japan is closing in on the Top spot, and likely already has. 

Patti

Link

Pragyansmita
*link

Pris

Link

Rebekah

Link

Rob

Link

Robert

Link

Rodrigo

Thanks for the challenge. Developed a little mobile first visualization that allows people to select their country and check the top donors, the total cumulative over time and also how they distribute geographically.
Link

Rolando

Link

Royce

Link

Ryan

Link

Sam

Link

Samo

Link

Sanaaya

Link

Seonaid

Link

Sohini

Link

Steve B

Link

Steve W

Link

Suzanne

Link

Taryn

Link

Tereza

Link

Tiffany

Link

Timea

Link

Vidya

Link

Visokio

Link

Vizu All

Link

Vizzy

Link

Wendy

Link

Xan

Link

Click ♥ if you've made it to the bottom—this helps us know that the time it takes to pull this together is worthwhile! Check out the #SWDchallenge page for more. Thanks for reading!

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As of cdata version 1.0.8 cdata implements an operator notation for data transform.

The idea is simple, yet powerful.

First let’s start with some data.

d <- wrapr::build_frame(
  "id", "measure", "value" |
    1   , "AUC"    , 0.7     |
    1   , "R2"     , 0.4     |
    2   , "AUC"    , 0.8     |
    2   , "R2"     , 0.5     )

knitr::kable(d)

In the above data we have two measurements each for two individuals (individuals identified by the "id" column). Using cdata‘s new_record_spec() method we can capture a description of this record structure.

library("cdata")

record_spec <- new_record_spec(
  wrapr::build_frame(
    "measure", "value" |
    "AUC"    , "AUC" |
    "R2"     , "R2"  ),
  recordKeys = "id")

print(record_spec)

## $controlTable
##   measure value
## 1     AUC   AUC
## 2      R2    R2
## 
## $recordKeys
## [1] "id"
## 
## $controlTableKeys
## [1] "measure"
## 
## attr(,"class")
## [1] "cdata_record_spec"

Once we have this specification we can transform the data using operator notation.

We can collect the record blocks into rows by a "factoring"/"division" (or aggregation/projection) step.

knitr::kable(d)

d2 <- d %//% record_spec

knitr::kable(d2)

We can expand record rows into blocks by a "multiplication" (or join) step.

knitr::kable(d2)

d3 <- d2 %**% record_spec

knitr::kable(d3)

And that is truly fluid data manipulation.

This article can be found in a vignette here.

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BigML, the leading Machine Learning platform, and GoHub from Global Omnium join forces with a strategic partnership to boost Machine Learning adoption throughout the startup and industry sectors. This partnership helps the tech and business sectors apply Machine Learning in their companies, provides them with Machine Learning education and helps them remain competitive in the […]

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Hugo Bowne-Anderson, the host of DataFramed, the DataCamp podcast, recently interviewed Debbie Berebichez, a physicist, TV host and data scientist and is currently the Chief Data Scientist at Metis in NY.

Introducing Debbie Berebichez

Hugo: Hi there, Debbie, and welcome to DataFramed.

Debbie: Hi, Hugo. It’s a pleasure of mine to be here.

Hugo: It is such a pleasure to have you on this show, and I’m really excited to be here today to talk in particular about critical thinking in data science, and what that actually means, and as we know, to get critical about critical thinking and to see what aspects of data science in the space, what ways we are being critical, where we can actually improve aspects of critical thinking, particularly with respect to data thinking in general. But before we get into that, I’d love to know a bit about you. So, could you start off by telling us what you’re known for in the data community?

Debbie: Sure. Thank you. Well, I’m not sure I’m that well known in the data science community, but if I am, I would say it’s because I’m a big promoter of both critical thinking and of getting minorities, such as women, and especially Hispanic women, to enter the fields of STEM, including data science, and I’ve promoted and have started a bunch of initiatives geared towards getting more women to get into science, technology, and engineering. The second reason could be because I cohost a TV show for the Discovery Channel called Outrageous Acts of Science, so I know that a lot of people know me from there.

Hugo: Right, and you also are at Metis, aren’t you, the data science bootcamp?

Debbie: Absolutely. I was gonna say that next. So, I’m the chief data scientist at Metis. Metis is a data science training company that is part of Kaplan, the large education company, and we basically have two modes of teaching data science. One is through bootcamps, which we host in person at four locations, in New York, Chicago, San Francisco, and Seattle, and the second mode of teaching is through corporate training and other products. So, we teach live online intro to data science as a pre-bootcamp course, but we also customize various courses for corporations that need either visualization courses or Python programming or big data techniques and whatnot, and we’ve had quite a bit of success with that.

Hugo: That’s great, and I look forward later on to talking about kind of the relationship to your work at Metis, bootcamps in general, how they can prepare people for a job market where … In the job market, in some respects, coding skills are at the forefront and not critical thinking skills, and how to deal with that trade-off in the education space, which is something we think a lot about.

Debbie: Absolutely.

Hugo: On top of that, though, you mentioned you’re a big promoter of women, in particular, Hispanic women in the space, and correct me if I’m wrong, I may have mess this up completely, but you were the first Mexican woman to get a PhD from Stanford in physics?

Debbie: Wow. You didn’t get it wrong.

Hugo: I got that right?

Debbie: Yes.

Hugo: Fantastic.

Debbie: That’s right, and I think it’s an important statistic not so much to brag about it, but to show that examples like mine, of persevering and working really hard and making your dream come true exist out there, and they’re so important to talk about because they really serve as inspiration for people who sometimes think that their particular minority group or so is not suited for a career in data science or STEM.

Hugo: So, is this how you got interested in data science and computation initially, through a physics PhD?

Debbie: Yeah, yeah. I have kind of a, I guess, not so atypical background for data science. I did my PhD in physics at Stanford, like you said, and I did theoretical physics. I did a lot of computational work the last two years, and so I learned about models and programming and working with data. Then I moved to New York to do two postdocs at Columbia University and at the Courant Institute, part of NYU, after which I decided, like a lot of physicists, to work in Wall Street for a few years as what is sometimes derogatorily called a quant. I was involved in creating risk models, and I did a lot of data analysis, and that’s when I realized that my skills in math and programming had other alternative ways of being applied, not just in physics.

Debbie: So then, after Wall Street, I thought that that was not the field for me because I didn’t really care about just making money, even though making money is nice, but I had bigger aspirations, and I wanted to do data and ethics and help the world and change the world in many ways, and so I’d heard about this new field, sort of new field for me at least, called data science about 10 years ago, and I took a course. It was kind of like a bootcamp. I had the skills, but I didn’t know how to translate them into the different techniques and algorithms that are typical of data science. So, after taking that course, I jumped ship and I started my career in data science.

Hugo: Awesome. That’s a really interesting trajectory, and I just want to step back a bit, and if you don’t want to talk about this, we don’t have to, but I’m just wondering, coming from where you were in Mexico, did you have kind of a social, cultural, and even familial or parental support to go down this path?

Debbie: No, I didn’t, and that is precisely why I care so much about inspiring and helping other young women who, like myself, feel attracted to a career in science or engineering, but who for some reason, whether it be financial or social, feel that they cannot achieve their dreams. From a very young age growing up in Mexico City, I was discouraged from pursuing a career in physics and math because I was a girl, and I was told by friends and parents and teachers in school that I better pick something more feminine, and that to do physics I had to practically be a genius, which I knew I wasn’t, and so they really discouraged me so much that I became insecure about my math skills and about my ability to conquer and study the field.

Debbie: So, years later when it came to go to university, I picked philosophy as an undergrad because I thought that that was something similar to physics. It had a lot of questions, and you could use your imagination to ask yourself why are we here, and all kinds of things that had to do with objects that surround us and their meaning and whatnot, but I realized, Hugo, that the more I tried to hide my love for physics and math, the more that this inner voice telling me to go for it and to study it was screaming at me, until two years into the bachelor’s program in Mexico, I decided behind everyone’s back to apply to schools in the US as a transfer student, and it was difficult because in Mexico we were paying an eighth of what universities cost in the US, and especially as a foreign student, it’s very hard to find scholarships and financial help, but I was extremely lucky that I got full scholarship offered to me by Brandeis University in Massachusetts, and so in the middle of my BA in philosophy, I transferred to Brandeis in the winter. I hadn’t seen the snow before, and I picked up philosophy courses, but right in my first semester I had the courage to take my first intro to physics class. It was a very large classroom with a hundred students, and the class was astronomy 101.

Debbie: In that class, I realized that my passion and my love for physics was not gonna go away, and I befriended the teaching assistant in the classroom who was a graduate student by the name of Rupesh, who came from India. He came from Darjeeling, town in the Himalayas, and Rupesh and I became friends, and we would meet all the time, and he was the first person who truly believed in me, and he told me that I wasn’t the typical student that just wanted to get an A in the homework, that my questions were just so curious, and I was so inquisitive, and that I really, really cared about knowing about the planets and quantum mechanics and statistical mechanics, and all kids of things, and so he really encouraged me to try to do physics, until one day, we were walking in Harvard Square in Cambridge, and we sat under a tree, and I looked at Rupesh with tears in my eyes, and I said, “Rupesh, I just don’t want to die without trying. I don’t want to die without trying to do physics.”

Debbie: He got up, and we didn’t have cellphones at the time, but he called his advisor who was the head of the physics department at Brandeis, Dr. Wardle, who was the professor in my astronomy class, and he said, “I have a student here who has a scholarship for only two years because she’s a transfer student, and I know that BA in physics takes normally four years to complete, but she’s really, really passionate. What can we do about it?” So, Dr. Wardle called me into his office, and we had a conversation, and he basically told me, me and Rupesh, who was there with me, he said, “Believe it or not, there’s somebody else who’s done this in the past at Brandeis. His name is Ed Witten. He is-”

Hugo: Wow …

Debbie: I know. For those people who know physics and know who he is, he’s basically the father of string theory, so he definitely qualifies as a genius, and so I thought he was pulling my leg, like okay, Ed Witten, there’s no way I could achieve this. But he said, "Ed switched at Brandeis from history to physics, and he did it in only two years," because I couldn’t ask my family to pay for another extra two years to stay there, and so what Dr. Wardle offered is he gave me a book called Div, Grad and Curl, which is vector calculus in three dimensions, and basically, he said to me, "If by the end of the summer you’re able to master this material," and Hugo, I didn’t even remember algebra at this point-

Hugo: And of course, there’s a whole bunch of linear algebra, which goes into this vector calculus. Right?

Debbie: Of course. There’s so much background you have to know to even get into studying this book. So, he said, "If in two months," because this was in the month of May, "you’re able to master this material, we’ll give you a test, and we’ll let you skip through the first two years of the physics major, so you can basically finish the whole BA in only two years." So, Rupesh looked at me, and he said, "We’re gonna do this," and he decided, incredibly, to devote his entire summer from mid June to end of August to teaching me and mentoring me, and basically covering all the subjects that I needed to master in order to enter the third year of physics in September.

Debbie: It was amazing because I was so incredibly hardworking and passionate that I didn’t move from my desk. Every day, Rupesh taught me from 9:00 in the morning till 9:00 p.m. We didn’t have much time, so it was just practical, knowing how to solve derivatives on Saturday. Sunday, we’ll do integrals. Monday, first three chapters of classical mechanics, and you get the idea. So, at the end of the summer I presented the test, and I passed. I tried to not burn too many capacitors in my first electronics lab at the time, and I remember how incredibly grateful I was to Rupesh, this person that absolutely changed the course of my life.

Debbie: I tell this story every time I have an opportunity because it’s incredible to me what Rupesh told me. I basically always wanted to pay him for all that he dedicated to me and all the effort he put into tutoring me, and he said to me that when he was growing up in India, in Darjeeling, there was an old man who used to climb up to his little town in this mountainous terrain, and used to teach him and his sisters the tabla, the musical instrument, math and English, and every time the family wanted to compensate this old man, he said, "No. The only way you could ever pay me back is if you do this with someone else in the world."

Debbie: That beautiful story is how my mission in life began, and Rupesh passed the torch of knowledge to me to inspire, help, and encourage other minorities who, like myself, dream of becoming scientists or engineers, but who for some reason lack the confidence or the skills at the time, and that has really informed my career. It has been the passion that connects everything that I’ve done, and I’m incredibly grateful to that pay-it-forward story. So, after graduating with highest honors from Brandeis is when I went to Stanford, and I reconnected with Rupesh only about seven years after that, because he had gone to the South Pole to be a submillimeter astronomer, and we connected, and he was incredibly proud that I managed to graduate and do my research with a Nobel Prize winner at Stanford, and it was a great story.

Critical Thinking and Data Science

Hugo: Firstly, Debbie, thank you so much for sharing that beautiful story. Secondly, I wish I had a box of tissues with me right now, and thirdly, I feel like I was sitting there under that tree with you and Rupesh solving all the vector calculus challenges, and I want to give Rupesh a big hug and a bunch of cash right now as well, but of course, I’ll do exactly what I’m trying to do and what we need to be doing, which is paying it forward, and I think that actually provides a great segue into talking about critical thinking and data science, how we think about critical thinking as educators, being critical of critical thinking, and maybe I want to frame this conversation by saying there’s just a lot of talk around the skills aspiring data scientists, data analysts, data-fluent, data-literate people need to know, and sometimes to me, anyway, the conversation around this seems to be a little bit superficial, and I was wondering, firstly, if that’s the case for you, and secondly, if it is, what seems superficial about it?

Debbie: Yes. I’m so glad you’re asking this question, Hugo. I can’t tell you how many times I have visited programs where I’ve been a mentor for high school students, and I’ll give you one example. One of these afternoon programs was receiving quite a bit of funding, and there were three groups of young girls from high school working in data science, and they had been taught SQL, so they were masters at it, much more than I was ever proficient at their age, so I was like, “Wow. These girls are really impressive.” There were three groups. They were working at a museum, and so one of them was working with a data set that was about birds in the museum, and they were trying to find patterns by looking at their demographics of the birds and their flying patterns and all this kind of information.

Debbie: Another group was looking at astronomical objects, and a third group was working with turtles because the museum had a whole bunch of turtles in an exhibit. So, I went to the third group that was working with turtles, and I looked at the data that they were working with, and one of the columns said weight, so the weight of the turtles, and so I said, “Oh, wow. So, just out of curiosity, how big are the turtles that you’re working with? Have you ever seen them?” They said, “Oh, yeah, we have. They’re about the size of the palm of my hand.” I said, “Oh, cute. I’d love to see those turtles.” I said, “Okay. So, is the weight here that you have in the column … You don’t have any units for it because you just have the number, and the numbers are around 150 and 200 and 300. So, is this weight in pounds? Is it in kilograms? What is this weight in? What are the units?”

Debbie: All of a sudden, these six girls in the group got all quiet, and none of them ventured to answer until one of them raised her hand and said, “Oh, I think it’s in pounds,” and I said, “Oh, wow. Let’s see. I’m about five-foot-three, and I weight probably about 120 pounds, so this is interesting because a turtle that’s the size of my hand, basically, you’re telling me it weighs double the amount of pounds that I do. Does that make sense?” Then they all laughed and said, “Oh, yeah. You’re right. It doesn’t make sense,” and we had this very nice conversation, and we went back and forth. It turns out, after an hour, we finally found a teacher who knew, and for certain, gave us the information that the weight was actually in grams.

Hugo: Wow.

Debbie: So, the girls were surprised, and that story really caught my attention because I had been visiting a lot of schools and programs that are trying to teach coding in a very kind of fast and superficial way, just to be able to say, "Our students know how to code," and I realized that in an effort to get more and more people to know the skills for data science and for data analysis in a world that’s going way too fast where we need to prepare our students for jobs in AI and machine learning and whatnot, we are forgetting what all of this is for. Coding and analyzing data has a purpose. It’s not an end in itself. The purpose is to be able to solve problems and to have insights about what the data is telling us.

Debbie: If we’re not taught to ask the right questions and to think critically about where the data comes from, why is it being used or collected in a certain way, what other data could help or hurt my dataset, what biases are being introduced by this dataset, if we’re not teaching our kids to think what’s behind these techniques, then we’re basically failing, because we’re just making them like robots who can only perform a simple task if, and only if, the next dataset they see is similar in scope and structure to the one that they’re learning to work with.

Debbie: It was a very moving, and in a way, also painful experience to see, because I realized how needed are those critical skills, and not only in the education at the high school level, but how many projects haven’t we seen at companies, at very large companies and advanced data science groups where there’s a significant bias being introduced because no one bothered to include a certain minority but important group in the statistical sample, or bias was introduced because people didn’t bother to check what some outliers in the dataset were describing et cetera. So, I’m very, very passionate about teaching the critical thinking skills that are behind our why for why we do data science.

Collecting Data

Hugo: You’ve spoken to so many essential points there. The overarching one is critical thinking, and what I like to think of, data thinking or data understanding before even … There’s a movement to put data into models and throw models at data before even looking at, as you say, units or important features, or really getting to know your data, getting to understand it, and performing that type of exploratory data analysis, and a related point that underlay a lot of what you were discussing there is thinking about the data collection process as well, and if you’re collecting data in a certain way, what are you leaving out? What are your instruments not picking up? Is your data censored for any of these reasons? Are you leaving out certain demographics because they don’t use a particular part of your service?

Debbie: Mm-hmm (affirmative). Exactly. Exactly, and I think I see a lot of companies that don’t really know what data science is about, because it has become this buzzword, and everyone wants to be in it, but nobody really knows exactly what you can get out of it, and what’s happening is a lot of companies are investing significant dollar amounts in big data and solving big problems because they have collected so much data, they just build a huge infrastructure and try to find insights, but without really know if, first of all, those insights are important for the company, second of all, if they find them, would they be able to use them for something and enact policies or something that’s actually gonna be helpful for the goals of the company? I always remind them with this kind of simple example. One of my heroes in physics is Tycho Brahe, who was a very famous Danish astronomer. Basically, he was locked up in a tower in an island in Denmark, which I actually had the opportunity to visit last summer.

Hugo: Oh, really?

Debbie: Yes.

Hugo: Wow.

Debbie: He lived in the 1500s, an amazing man, but he also had a … Apparently, he was a nobleman. He had an awful personality, and he lost his nose in a duel.

Hugo: They say he replaced it with a golden bridge, I think.

Debbie: With a bronze-

Hugo: Bronze. Yeah. Okay, great.

Debbie: I think that has been discredited a bit. That’s what they told me in the museum. But anyways, yeah, this very interesting character, but the amazing thing about him is that he looked at the sky without any telescope. He basically had created these sophisticated instruments, but in the 1500s, it took him years, and he created a catalog of only about a thousand stars. That’s it. So, that’s a very, very small dataset by today’s standards, but from only those thousand data points, I think it was like 1,800 or so, to be more accurate, but he helped the theories that were later created by Kepler and Copernicus, and where the laws of planetary motion were derived.

Debbie: Basically, Kepler used that, and then Isaac Newton used it as the basis for the law of gravity. So, from those thousand data points came universal theories that we’re still using today, that are incredibly powerful and deep, and that is a good example to say that sometimes we can put a lot of investment into huge datasets, but when we’re talking about data literacy, large datasets also have a lot of noise, and you have to start by teaching that the most important thing is the insight that you’re going to derive from that dataset and not its size.

Big Data

Hugo: I’d like to speak to this idea of the focus on big data and the fact that a lot of us are collecting as much data as possible, thinking that all the information we need will be contained in there, even before asking critical questions, which is very dangerous, but before that, I just want to say tangentially, Tycho Brahe and Kepler’s story is so wild. I haven’t looked into it in a while, but if I recall correctly, Kepler wanted to unlock the secrets of planetary motion and figure out what was happening, and he realized that Tycho had the data. So, this is a story of someone realizing someone else has this data, and he went to work with him in Tycho Brahe’s, I think, final years, and Tycho didn’t even give him all the data at that point. He was actually very secretive about the data he had, and even when Brahe died, Kepler had to struggle with Brahe’s family in order to get the data. So, there were all types of data secrecy and data privacy issues at that point as well.

Debbie: Also, data ownership, because what-

Hugo: Exactly. That’s what I meant. Yeah.

Debbie: Most people know who Kepler was, but if you ask people about Tycho Brahe, very few non-science people know, and that’s because a lot of the credit went to Kepler, and some people argue that the one that did all the meticulous observations and had theories about it was Tycho, and so he deserved more credit. So, it was kind of a crazy time, and lots of fights about data were happening.

Hugo: Of course, we’re talking about a decoupling or a separation of, let’s say, humans into the people who are fantastic at collecting data and the people who are fantastic at analyzing it as well. This is a division in a lot of ways.

Debbie: Yeah, absolutely.

Hugo: But this focus on big data, the fact that even a lot of companies’ valuations are based around the fact that they have so much data, and it must be useful in the future, right? This is incredibly dangerous for practitioners, but also for society.

Debbie: Absolutely. I mean, we did have a tipping point in that we had the hope in the ’70s of AI and changing the landscape of our society, and it didn’t quite deliver in its promise because we didn’t have the capacity to analyze very, very large datasets like we do now, and there was a tipping point where now we are able to analyze these much, much larger datasets. I mean, I think every day in the world, we produce 10 to the 18 bytes of data, like 3 exabytes of data, something like that, that we generate. So, obviously these are enormous scales, but what’s important is not that we now have this capacity to analyze it, but are we really getting a significant marginal insight, or are the insights that we’re getting commensurate with the ones that we were getting when we didn’t have such large datasets?

Debbie: I think that question’s still out there. We haven’t been able to answer it because, as you know, the real important applications of AI are still being created and worked on. A lot of the AI things that we see out there are still simplistic in that they don’t use all of the incredible and deep capacities that AI has to solve problems. So, dimensionality of the data matters. It matters a lot, and probably for certain problems, it’s going to be hugely important. But my point is more about when you’re educating people or when you’re a company investing in certain technology, you have to be able to walk before you run, so start analyzing the smaller datasets, come up with strategies that are based more on critical thinking, and the questions that you’re trying to solve rather than the size of your dataset, and the size of the infrastructure that you’ve built.

Top 3 Critical Thinking Skills to Learn

Hugo: Great. So, I’ve got a thought experiment for you, which may happen all the time. I have no idea. But a student, an aspiring data scientist data analyst comes to you and says, "I need to learn some data thinking skills, some critical thinking skills to work with data. What are the top three critical thinking skills that you think I should learn, Debbie?"

Debbie: Thanks for that question, Hugo. I think the first one is you have to be a skeptic about data. You have to always … Just like when you read a scientific paper, you have to know who paid for this research. Was it the drug company that is sponsoring a paper that says their drug is the only and best drug in the world? Clearly, I’m not gonna trust that paper. So, a healthy skepticism about the team that collected the data, what biases could have been introduced, where was this data taken, how was it collected, what things were left out, what variables would be important in the future, et cetera. All those questions I think are super important. So, if you don’t ask them before even doing exploratory data analysis, it means you’re thinking about the data, and your relationship with the data is gonna be limited.

Debbie: The second one, and this one, I came up with it from another famous physicist, Richard Feynman, who said, "The ability to not fool oneself is one of the hardest and most important skills one can acquire in life," because it’s very easy … Sometimes we think, oh, I wouldn’t be fooled by anyone, not any marketing campaign, not any government is gonna fool me, but we fool ourselves much more often than the people interpreting the data out there. So, the ability to not fall in love with what we think our data should be telling us, that is what I call fooling yourself, that is super important.

Debbie: The third skill is connecting the code and the algorithms to the real world, like my example with high school girls that were working with the data. To be working with a database for three months and forgetting that behind the data are actual turtles, in this example, that’s a big mistake, the same way when Facebook is incredible at doing face recognition and analyzing relationships between groups and people, but if they’re forgetting that behind those connections are real people with real lives and real consequences, then we’re failing. We need to really connect our analysis to the world out there.

Hugo: I agree, and I just want to go through those again, because I’m sure our listeners are scribbling away trying to remember all of this. So, the first one was a healthy skepticism about data, the second, the ability to not fool yourself, and the third, connecting the code and the real world and all the stakeholders that actually exist on the ground.

Debbie: Correct. Thank you, Hugo.

Bias

Hugo: So, I just want to build slightly on the ability not to fool yourself. I mean, all of these are incredibly important, but there’s a paper called, I hope I get this right, Many Analysts, One Dataset, that we’ve discussed once or twice on the podcast before, and it gives a whole bunch of statisticians and domain experts a dataset, separates them into teams, and gives them the same dataset and asks … It’s a dataset of, I think, either yellow or red cards given to football players in football or soccer matches, and the question is, are these decisions to give cards, is there some sort of ethnic bias or a racial bias in these decisions?

Hugo: The fact is, what happened was 70% of the teams said one thing, 30% said the other thing, either yes or no, and then when they got to see everyone else’s results, nearly all the teams were even more sure of their own techniques and their own results. There are a lot of reasons for this, but one of the points is that people go in with a certain bias already, and if you have a bias going into a dataset, you make all these micro-decisions as an analyst, which helps you get to the place that you already thought you were going, right?

Debbie: Yeah. You reminded me, funnily, of a paper that I discussed. I don’t even think you could consider it a scientific, sophisticated paper, but it was a paper done for the astrology, not astronomy, but Astrology Association in India years ago, and I talked about it at a conference because they first decided the hypothesis is that through some astrological charts that tell you certain characteristics about some kids, if these people that were the gurus and the chart readers and predictors were able to guess, I think that they gave themself a pretty low score. They said, "If we are able to guess 60% of the outcomes," and I think the question was whether these students were intellectually gifted or just going to be average students in school, based just on their astrological chart, "and if we’re able to get 60% of them right, then that means we are gurus, and astrology is true, and we are able to predict this with very high confidence." That was their confidence level.

Debbie: The funny thing is even though they did slightly worse than a coin toss, that is they got 49% of them right, and anybody in their right mind would be able to say, "Well, clearly they did even worse than chance, a toss of a coin would’ve done better," but they themselves patted themselves on the back saying, "You see? We got 49% right. We can do this." So, it’s a very funny paper, and I encourage people to read it because it’s so easy to fool ourselves.

Hugo: Absolutely, and the best thing about doing worse than a coin toss is you could actually just switch all your decisions and do better. So, we’ve been talking about critical thinking at an individual and societal level. I’m wondering how you think about the needs for all these skills, critical thinking skills, how they should be spread through organizations, and what I mean is, what type of critical thinking and data thinking skills will be needed and are needed for people who don’t even work directly with data themselves, but in jobs impacted by data?

Debbie: Yes. That’s an excellent question because I think the more that our field of data science grows, the more that we get different dependencies in companies, different groups needing insights or even having contact with the data, and not everybody’s going to be a data scientist. We’re gonna have people just interpret visualizations that come from the data, others using APIs and having to interpret what the algorithms come up with and whatnot. So, I think it’s essential that we spread the critical thinking message across organizations, and it has to start early in school because the ability to ask the right questions in an industry setting in incredibly important, and I don’t think we’re putting enough emphasis in it. So, I think everybody in an organization has to be trained about things such as data ethics. How is the data being collected? Are we using it for the right purpose? Data ownership, data privacy, data security, all kinds of issues that impact the manipulation of data, and so that’s part of the critical thinking process.

Hugo: Hopefully, this aspect of understanding on the part of people in society and other working professionals who aren’t data scientists will result in less burden on the data scientists. What I really mean by that is … Well, there are a few ways to frame it. The first way is I think it was probably Nate Silver who said this. Any quotation I don’t know who it was, I’ll just say it’s Nate Silver, generally. But it was probably Nate Silver who said something like, "When a data scientist gets something right, they’re thought of as a god, and when they get something wrong, they’re thought of as they’ve made the worst mistakes ever," as opposed to a job in which sometimes you get it right, and sometimes you get it wrong.

Hugo: Another way to frame it is it kind of viewed by people without data skills are like, "I have no idea how to deal with this, so this is what you’re going to do, and you have kind of … You’re a prophet, or you’re the holder of divine knowledge, or the high priest of data science", I like to call them, and whether this will actually help, as people develop more data skills who aren’t data scientists, will actually help bridge this gap in a lot of ways. So, how do you think about these types of issues and challenges when building data science curricula at Metis and elsewhere?

Debbie: Yeah. It’s very important for me to learn … I’m not an expert in the field of learning science, but it’s very important to me to learn how to best build curriculum that optimizes these critical thinking principles and questions that I’m talking about, and so it really depends on the curriculum. So, for example, we built with a team with Cathy O’Neil, who I know you’ve interviewed before, who I love, and a group of others, seven executive women with the funding from Moody’s Analytics and the help of Girls, Inc., we developed the first data science curriculum for high school girls of under-served backgrounds, and we deployed it in New York in several high schools.

Debbie: So, I think it was just this amazing experience because we try to emphasize focusing on the topic and what the consequences were of every single step in the process, from data collecting, to choosing the algorithm, to knowing how to measure the accuracy, the recall, the precision, everything that we were doing, where it comes from, how to choose the metric that was right for the problem at hand, et cetera, and so the intention was very conscious to be about how to get the most insight about the limitations and the successes of the challenge or the problem at hand.

Debbie: When I build curriculum for the Metis bootcamp currently in my position, I want the students to have a pretty broad set of tools with which they can crack really hard problems. So, I may not focus on getting every single clustering algorithm there is in the curriculum, but I will focus on how to analyze the results of the clustering algorithms that we will see, and how to know if we’re using the right algorithms for the problem at hand, and how to be able to ask that question of our colleagues, of our communities, et cetera, because we all have limitations to our knowledge.

Metis

Hugo: Yeah. There are two things there I want to focus on. The first is, as you said, at Metis, thinking about the actual problems, and thinking about the question at hand before even getting coding I think is incredibly important, and also, educating people through questions that really pertain to them and are interesting to them. So, students will ask me, "If I want to embark upon my first data science project, what would you suggest I do?" I say, "Well, what are you interested in," and if they have a fitness tracker, for example, I say, "Maybe you could analyze your own fitness data. If you’re a foodie, scrape Yelp reviews of restaurants and work with that type of stuff. If you love movies, if you’re a cinephile, the OMDB has a fantastic API."

Debbie: That’s exactly what we do at Metis. We have our students in the bootcamp use their own dataset, and they create their own project. So, it’s really cool. I encourage people to go to madeatmetis.com, and it’s a site where we have some of our greatest projects, and it’s incredible because you see people that had very basic math and programming skills coming in, and in three months they’re able to analyze contamination sources in the ocean, or some healthcare-related thing, or an app that helps you choose the best restaurant for crepes that evening, and stuff like … It’s really, really cool what you can do.

Hugo: Yeah, and I’ll build on that by saying I’ve been to several of Metis’s graduation presentations. What do you call them?

Debbie: Career Day.

Hugo: Yeah. They’re incredible, and seeing all the learner students there present the work they’ve done is amazing, and I know that … For example, you know I’ve had Emily Robinson on the podcast. I work with her now at DataCamp, and she completed Metis, and I think she went to Etsy straight from Metis. I could be wrong there.

Debbie: Yes. We love Emily.

Future of Data Science

Hugo: Yeah, incredible. So, we’re gonna wrap up in a few minutes, but I’d like to … We’ve talked about the state of play of critical thinking today, but I’d like to … It’s a prediction problem. So, what does the future of data science look like to you, Debbie?

Debbie: To me, it’s going to merge with the industry of IOT or the internet of things. That is, as we see the ubiquitous sensors, that these sensors are simply everywhere, from medical devices, to buildings that are smart buildings testing our comfort level, to apps that match our behavior, it’s-

Hugo: I mean, you’re right. We wear them, and we carry them in our pockets, right?

Debbie: Exactly, and just like the personal computer came to revolutionize the information technology field, the same way, IOT is going to revolutionize, and we’re gonna see a new paradigm where we’re going to collect substantial more amounts of data about ourselves, our behaviors, our connections, and so issues that have to do with data privacy, data ownership, security, analysis, insights are going become evermore important. So, what I predict is that with more automation, we’re gonna have more needs to have people that are not necessarily the data scientists working with the data, but are working in the field to analyze the ethical consequences of it to act as peer reviewing committees to see if there should be policies or regulations that should be enforced around certain applications, et cetera. So, that’s what I see for a future, more and more need for sort of adjacent professions that help with the data analysis process.

Hugo: Yeah, I think you’re right in terms of defining it anyway or describing it as a merging between data science and IOT and automation. I can’t quite remember, did you give a talk on the internet of things at the NYR… Jared’s conference, a few years ago?

Debbie: Yes, I did at the R… Yep. Yeah.

What is your favorite data science technique?

Hugo: Okay, great. Well, I loved that talk, and Jared puts all those talks up online, so I’ll find a link for that and put that in the show notes as well, if anyone’s interested. So, I want to get a bit technical. I’m wondering what one of your favorite data sciencey techniques or methodologies is, just something you love to do.

Debbie: I actually really, really love singular value decomposition, SVD. I’ve always loved linear algebra, and just the thought of being able to reduce the dimensionality of a problem is so sexy to me. In physics, we deal with all the time, and my first encounter with it was when I worked briefly with David Botstein, who’s … This is many, many years ago at Stanford. He’s one of the creators of Genentech, the biotech company, and we were analyzing the data coming from DNA microarrays, which basically compare a sample of healthy DNA with a sample that came from a patient in order to conclude whether the patient had cancer, and in the case of a positive answer, what type of breast cancer it was.

Debbie: So, it was really, really interesting because, obviously, there are so many genes in our genome that the dimension of the problem was humongous, and so to apply SVD and be able to reduce it to the dimensions that were most important enabled them to come up with pretty customized drugs that I have heard, because I have since stopped working in that topic, but I’ve heard are working quite well for different types of breast cancer. So, the applications of SVD are incredible, and so I don’t know, I just really like that conceptually, and anything that has to do with that, even NLP and, I don’t know, just seeing what you can get by sacrificing a bit of information is just really interesting to me.

Hugo: Well, I’m sold. I mean, you’ve motivated it through linear algebra, which I also love, and then you gave some incredibly important examples of its use, and for those of you out there who know of PCA, I’d definitely suggest you to check out SVD as well.

Debbie: Yeah.

Call to Action

Hugo: I’ve got one final question for you. Do you have a final call to action for our listeners out there?

Debbie: Yes, I do. I’ll repeat, Hugo, what I said in my Grace Hopper Celebration keynote speech a little over a year ago. Think deeply, be bold, and help others.

Hugo: I think that’s fantastic, Debbie, and what we’ll do is we’ll link to your Grace Hopper talk as well, because I think the way you explained in that talk all of these things, why it’s important to think deeply, be bold, and help others, which you’ve kind of gone through this talk as well, I think that talk can provide more context there also.

Debbie: Wonderful. This has been such an awesome conversation, Hugo. Thank you.

Hugo: Thank you so much, Debbie. It’s been an absolute pleasure having you on the show.

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In this tutorial, you will learn how to build a Raspberry Pi security camera using OpenCV and computer vision. The Pi security camera will be IoT capable, making it possible for our Raspberry Pi to to send TXT/MMS message notifications, images, and video clips when the security camera is triggered.

Back in my undergrad years, I had an obsession with hummus. Hummus and pita/vegetables were my lunch of choice.

I loved it.

I lived on it.

And I was very protective of my hummus — college kids are notorious for raiding each other’s fridges and stealing each other’s food. No one was to touch my hummus.

But — I was a victim of such hummus theft on more than one occasion…and I never forgot it!

I never figured out who stole my hummus, and even though my wife and I are the only ones who live in our house, I often hide the hummus in the back of the fridge (where no one will look) or under fruits and vegetables (which most people wouldn’t want to eat).

Of course, back then I wasn’t as familiar with computer vision and OpenCV as I do now. Had I known what I do at present, I would have built a Raspberry Pi security camera to capture the hummus heist in action!

Today I’m channeling my inner undergrad-self and laying rest to the chickpea bandit. And if he ever returns again, beware, my fridge is monitored!

To learn how to build a security camera with a Raspberry Pi and OpenCV, just keep reading!

Building a Raspberry Pi security camera with OpenCV

In the first part of this tutorial, we’ll briefly review how we are going to build an IoT-capable security camera with the Raspberry Pi.

Next, we’ll review our project/directory structure and install the libraries/packages to successfully build the project.

We’ll also briefly review both Amazon AWS/S3 and Twilio, two services that when used together will enable us to:

1. Upload an image/video clip when the security camera is triggered.
2. Send the image/video clip directly to our smartphone via text message.

From there we’ll implement the source code for the project.

And finally, we’ll put all the pieces together and put our Raspberry Pi security camera into action!

An IoT security camera with the Raspberry Pi

Figure 1: Raspberry Pi + Internet of Things (IoT). Our project today will use two cloud services: Twilio and AWS S3. Twilio is an SMS/MMS messaging service. S3 is a file storage service to help facilitate the video messages.

We’ll be building a very simple IoT security camera with the Raspberry Pi and OpenCV.

The security camera will be capable of recording a video clip when the camera is triggered, uploading the video clip to the cloud, and then sending a TXT/MMS message which includes the video itself.

We’ll be building this project specifically with the goal of detecting when a refrigerator is opened and when the fridge is closed — everything in between will be captured and recorded.

Therefore, this security camera will work best in the same “open” and “closed” environment where there is a large difference in light. For example, you could also deploy this inside a mailbox that opens/closes.

You can easily extend this method to work with other forms of detection, including simple motion detection and home surveillance, object detection, and more. I’ll leave that as an exercise for you, the reader, to implement — in that case, you can use this project as a “template” for implementing any additional computer vision functionality.

Project structure

Go ahead and grab the “Downloads” for today’s blog post.

Once you’ve unzipped the files, you’ll be presented with the following directory structure:

$ tree --dirsfirst
.
├── config
│   └── config.json
├── pyimagesearch
│   ├── notifications
│   │   ├── __init__.py
│   │   └── twilionotifier.py
│   ├── utils
│   │   ├── __init__.py
│   │   └── conf.py
│   └── __init__.py
└── detect.py

4 directories, 7 files

Today we’ll be reviewing four files:

• config/config.json

   : This commented JSON file holds our configuration. I’m providing you with this file, but you’ll need to insert your API keys for both Twilio and S3.

• pyimagesearch/notifications/twilionotifier.py

   : Contains the

  TwilioNotifier

    class for sending SMS/MMS messages. This is the same exact class I use for sending text, picture, and video messages with Python inside my upcoming Raspberry Pi book.

• pyimagesearch/utils/conf.py

   : The

  Conf

    class is responsible for loading the commented JSON configuration.

• detect.py

   : The heart of today’s project is contained in this driver script. It watches for significant light change, starts recording video, and alerts me when someone steals my hummus or anything else I’m hiding in the fridge.

Now that we understand the directory structure and files therein, let’s move on to configuring our machine and learning about S3 + Twilio. From there, we’ll begin reviewing the four key files in today’s project.

Installing package/library prerequisites

Today’s project requires that you install a handful of Python libraries on your Raspberry Pi.

In my upcoming book, all of these packages will be preinstalled in a custom Raspbian image. All you’ll have to do is download the Raspbian .img file, flash it to your micro-SD card, and boot! From there you’ll have a pre-configured dev environment with all the computer vision + deep learning libraries you need!

Note: If you want my custom Raspbian images right now (with both OpenCV 3 and OpenCV 4), you should grab a copy of either the Quickstart Bundle or Hardcopy Bundle of Practical Python and OpenCV + Case Studies which includes the Raspbian .img file.

This introductory book will also teach you OpenCV fundamentals so that you can learn how to confidently build your own projects. These fundamentals and concepts will go a long way if you’re planning to grab my upcoming Raspberry Pi for Computer Vision book.

In the meantime, you can get by with this minimal installation of packages to replicate today’s project:

• opencv-contrib-python

   : The OpenCV library.

• imutils

   : My package of convenience functions and classes.

• twilio

   : The Twilio package allows you to send text/picture/video messages.

• boto3

   : The

  boto3

    package will communicate with the Amazon S3 files storage service. Our videos will be stored in S3.

• json-minify

   : Allows for commented JSON files (because we all love documentation!)

To install these packages, I recommend that you follow my pip install opencv guide to setup a Python virtual environment.

You can then pip install all required packages:

$ workon <env_name> # insert your environment name such as cv or py3cv4
$ pip install opencv-contrib-python
$ pip install imutils
$ pip install twilio
$ pip install boto3
$ pip install json-minify

Now that our environment is configured, each time you want to activate it, simply use the

workon

Let’s review S3, boto3, and Twilio!

What is Amazon AWS and S3?

Figure 2: Amazon’s Simple Storage Service (S3) will be used to store videos captured from our IoT Raspberry Pi. We will use the boto3 Python package to work with S3.

Amazon Web Services (AWS) has a service called Simple Storage Service, commonly known as S3.

The S3 services is a highly popular service used for storing files. I actually use it to host some larger files such as GIFs on this blog.

Today we’ll be using S3 to host our video files generated by the Raspberry Pi Security camera.

S3 is organized by “buckets”. A bucket contains files and folders. It also can be set up with custom permissions and security settings.

A package called

boto3

Before we dive into

boto3

Let’s go ahead and create a bucket, resource group, and user. We’ll give the resource group permissions to access the bucket and then we’ll add the user to the resource group.

Step #1: Create a bucket

Amazon has great documentation on how to create an S3 bucket here.

Step #2: Create a resource group + user. Add the user to the resource group.

After you create your bucket, you’ll need to create an IAM user + resource group and define permissions.

• Visit the resource groups page to create a group. I named my example “s3pi”.
• Visit the users page to create a user. I named my example “raspberrypisecurity”.

Step #3: Grab your access keys. You’ll need to paste them into today’s config file.

Watch these slides to walk you through Steps 1-3, but refer to the documentation as well because slides become out of date rapidly:

Figure 3: The steps to gain API access to Amazon S3. We’ll use boto3 along with the access keys in our Raspberry Pi IoT project.

Obtaining your Twilio API keys

Figure 4: Twilio is a popular SMS/MMS platform with a great API.

Twilio, a phone number service with an API, allows for voice, SMS, MMS, and more.

Twilio will serve as the bridge between our Raspberry Pi and our cell phone. I want to know exactly when the chickpea bandit is opening my fridge so that I can take countermeasures.

Let’s set up Twilio now.

Step #1: Create an account and get a free number.

Go ahead and sign up for Twilio and you’ll be assigned a temporary trial number. You can purchase a number + quota later if you choose to do so.

Step #2: Grab your API keys.

Now we need to obtain our API keys. Here’s a screenshot showing where to create one and copy it:

Figure 5: The Twilio API keys are necessary to send text messages with Python.

A final note about Twilio is that it does support the popular What’s App messaging platform. Support for What’s App is welcomed by the international community, however, it is currently in Beta. Today we’ll be demonstrating standard SMS/MMS only. I’ll leave it up to you to explore Twilio in conjunction with What’s App.

Our JSON configuration file

There are a number of variables that need to be specified for this project, and instead of hardcoding them, I decided to keep our code more modular and organized by putting them in a dedicated JSON configuration file.

Since JSON doesn’t natively support comments, our

Conf

Let’s take a look at the commented JSON file now:

{
	// two constants, first threshold for detecting if the
	// refrigerator is open, and a second threshold for the number of
	// seconds the refrigerator is open
	"thresh": 50,
	"open_threshold_seconds": 60,

Lines 5 and 6 contain two settings. The first is the light threshold for determining when the refrigerator is open. The second is a threshold for the number of seconds until it is determined that someone left the door open.

Now let’s handle AWS + S3 configs:

// variables to store your aws account credentials
	"aws_access_key_id": "YOUR_AWS_ACCESS_KEY_ID",
	"aws_secret_access_key": "YOUR_AWS_SECRET_ACCESS_KEY",
	"s3_bucket": "YOUR_AWS_S3_BUCKET",

Each of the values on Lines 9-11 are available in your AWS console (we just generated them in the “What is Amazon AWS and S3?” section above).

And finally our Twilio configs:

// variables to store your twilio account credentials
	"twilio_sid": "YOUR_TWILIO_SID",
	"twilio_auth": "YOUR_TWILIO_AUTH_ID",
	"twilio_to": "YOUR_PHONE_NUMBER",
	"twilio_from": "YOUR_TWILIO_PHONE_NUMBER"
}

Twilio security settings are on Lines 14 and 15. The

"twilio_from"

Phone numbers can be formatted like this in the U.S.:

"+1-555-555-5555"

Loading the JSON configuration file

Our configuration file includes comments (for documentation purposes) which unfortunately means we cannot use Python’s built-in

json

Instead, we’ll use a combination of JSON-minify and a custom 

Conf

Let’s take a look at how to implement the

Conf

# import the necessary packages
from json_minify import json_minify
import json

class Conf:
	def __init__(self, confPath):
		# load and store the configuration and update the object's
		# dictionary
		conf = json.loads(json_minify(open(confPath).read()))
		self.__dict__.update(conf)

	def __getitem__(self, k):
		# return the value associated with the supplied key
		return self.__dict__.get(k, None)

This class is relatively straightforward. Notice that in the constructor, we use

json_minify

json.loads

The

__getitem__

Uploading key video clips and sending them via text message

Once our security camera is triggered we’ll need methods to:

• Upload the images/video to the cloud (since the Twilio API cannot directly serve “attachments”).
• Utilize the Twilio API to actually send the text message.

To keep our code neat and organized we’ll be encapsulating this functionality inside a class named

TwilioNotifier

# import the necessary packages
from twilio.rest import Client
import boto3
from threading import Thread

class TwilioNotifier:
	def __init__(self, conf):
		# store the configuration object
		self.conf = conf

	def send(self, msg, tempVideo):
		# start a thread to upload the file and send it
		t = Thread(target=self._send, args=(msg, tempVideo,))
		t.start()

On Lines 2-4, we import the Twilio

Client

boto3

Thread

From there, our

TwilioNotifier

Conf

This project only demonstrates sending messages. We’ll be demonstrating receiving messages with Twilio in an upcoming blog post as well as in the Raspberry Pi Computer Vision book.

The

send

• The string text

  msg

• The video file,

  tempVideo

   . Once the video is successfully stored in S3, it will be removed from the Pi to save space. Hence it is a temporary video.

The

send

Thread

Thus, the core text message sending logic is in the next method,

_send

def _send(self, msg, tempVideo):
		# create a s3 client object
		s3 = boto3.client("s3",
			aws_access_key_id=self.conf["aws_access_key_id"],
			aws_secret_access_key=self.conf["aws_secret_access_key"],
		)

		# get the filename and upload the video in public read mode
		filename = tempVideo.path[tempVideo.path.rfind("/") + 1:]
		s3.upload_file(tempVideo.path, self.conf["s3_bucket"],
			filename, ExtraArgs={"ACL": "public-read",
			"ContentType": "video/mp4"})

The

_send

Parameters (

msg

tempVideo

The

_send

• Initializing the

  s3

    client with the access key and secret access key (Lines 18-21).
• Uploading the file (Lines 25-27).

Line 24 simply extracts the

filename

Let’s go ahead and send the message:

# get the bucket location and build the url
		location = s3.get_bucket_location(
			Bucket=self.conf["s3_bucket"])["LocationConstraint"]
		url = "https://s3-{}.amazonaws.com/{}/{}".format(location,
			self.conf["s3_bucket"], filename)

		# initialize the twilio client and send the message
		client = Client(self.conf["twilio_sid"],
			self.conf["twilio_auth"])
		client.messages.create(to=self.conf["twilio_to"], 
			from_=self.conf["twilio_from"], body=msg, media_url=url)
		
		# delete the temporary file
		tempVideo.cleanup()

To send the message and have the video show up in a cell phone messaging app, we need to send the actual text string along with a URL to the video file in S3.

Note: This must be a publicly accessible URL, so ensure that your S3 settings are correct.

The URL is generated on Lines 30-33.

From there, we’ll create a Twilio

client

s3

Lines 38 and 39 actually send the message. Notice the

to

from_

body

media_url

Finally, we’ll remove the temporary video file to save some precious space (Line 42). If we don’t do this it’s possible that your Pi may run out of space if your disk space is already low.

The Raspberry Pi security camera driver script

Now that we have (1) our configuration file, (2) a method to load the config, and (3) a class to interact with the S3 and Twilio APIs, let’s create the main driver script for the Raspberry Pi security camera.

The way this script works is relatively simple:

• It monitors the average amount of light seen by the camera.
• When the refrigerator door opens, the light comes on, the Pi detects the light, and the Pi starts recording.
• When the refrigerator door is closed, the light turns off, the Pi detects the absence of light, and the Pi stops recording + sends me or you a video message.
• If someone leaves the refrigerator open for longer than the specified seconds in the config file, I’ll receive a separate text message indicating that the door was left open.

Let’s go ahead and implement these features.

Open up the

detect.py

# import the necessary packages
from __future__ import print_function
from pyimagesearch.notifications import TwilioNotifier
from pyimagesearch.utils import Conf
from imutils.video import VideoStream
from imutils.io import TempFile
from datetime import datetime
from datetime import date
import numpy as np
import argparse
import imutils
import signal
import time
import cv2
import sys

Lines 2-15 import our necessary packages. Notably, we’ll be using our

TwilioNotifier

Conf

VideoStream

imutils

Let’s define an interrupt signal handler and parse for our config file path argument:

# function to handle keyboard interrupt
def signal_handler(sig, frame):
	print("[INFO] You pressed `ctrl + c`! Closing refrigerator monitor" \
		" application...")
	sys.exit(0)

# construct the argument parser and parse the arguments
ap = argparse.ArgumentParser()
ap.add_argument("-c", "--conf", required=True, 
	help="Path to the input configuration file")
args = vars(ap.parse_args())

Our script will run headless because we don’t need an HDMI screen inside the fridge.

On Lines 18-21, we define a

signal_handler

We have a single command line argument to parse. The

--conf

Let’s perform our initializations:

# load the configuration file and initialize the Twilio notifier
conf = Conf(args["conf"])
tn = TwilioNotifier(conf)

# initialize the flags for fridge open and notification sent
fridgeOpen = False
notifSent = False

# initialize the video stream and allow the camera sensor to warmup
print("[INFO] warming up camera...")
# vs = VideoStream(src=0).start()
vs = VideoStream(usePiCamera=True).start()
time.sleep(2.0)

# signal trap to handle keyboard interrupt
signal.signal(signal.SIGINT, signal_handler)
print("[INFO] Press `ctrl + c` to exit, or 'q' to quit if you have" \
	" the display option on...")

# initialize the video writer and the frame dimensions (we'll set
# them as soon as we read the first frame from the video)
writer = None
W = None
H = None

Our initializations take place on Lines 30-52. Let’s review them:

• Lines 30 and 31 instantiate our

  Conf

    and

  TwilioNotifier

    objects.
• Two status variables are initialized to determine when the fridge is open and when a notification has been sent (Lines 34 and 35).
• We’ll start our

  VideoStream

    on Lines 39-41. I’ve elected to use a PiCamera, so Line 39 (USB webcam) is commented out. You can easily swap these if you are using a USB webcam.
• Line 44 starts our

  signal_handler

    thread to run in the background.
• Our video

  writer

    and frame dimensions are initialized on Lines 50-52.

It’s time to begin looping over frames:

# loop over the frames of the stream
while True:
	# grab both the next frame from the stream and the previous
	# refrigerator status
	frame = vs.read()
	fridgePrevOpen = fridgeOpen

	# quit if there was a problem grabbing a frame
	if frame is None:
		break

	# resize the frame and convert the frame to grayscale
	frame = imutils.resize(frame, width=200)
	gray = cv2.cvtColor(frame, cv2.COLOR_BGR2GRAY)
	
	# if the frame dimensions are empty, set them
	if W is None or H is None:
		(H, W) = frame.shape[:2]

Our

while

read

frame

frame

Line 59 sets our

fridgePrevOpen

Our

frame

On Line 67, we create a grayscale image from

frame

Our dimensions are set via Lines 70 and 71 during the first iteration of the loop.

Now let’s determine if the refrigerator is open:

# calculate the average of all pixels where a higher mean
	# indicates that there is more light coming into the refrigerator
	mean = np.mean(gray)

	# determine if the refrigerator is currently open
	fridgeOpen = mean > conf["thresh"]

Determining if the refrigerator is open is a dead-simple, two-step process:

1. Average all pixel intensities of our grayscale image (Line 75).
2. Compare the average to the threshold value in our configuration (Line 78). I’m confident that a value of

   50

     (in the

   config.json

     file) will be an appropriate threshold for most refrigerators with a light that turns on and off as the door is opened and closed. That said, you may want to experiment with tweaking that value yourself.

The

fridgeOpen

Let’s now determine if we need to start capturing a video:

# if the fridge is open and previously it was closed, it means
	# the fridge has been just opened
	if fridgeOpen and not fridgePrevOpen:
		# record the start time
		startTime = datetime.now()

		# create a temporary video file and initialize the video
		# writer object
		tempVideo = TempFile(ext=".mp4")
		writer = cv2.VideoWriter(tempVideo.path, 0x21, 30, (W, H),
			True)

As shown by the conditional on Line 82, so long as the refrigerator was just opened (i.e. it was not previously opened), we will initialize our video

writer

We’ll go ahead and grab the

startTime

tempVideo

writer

Now we’ll handle the case where the refrigerator was previously open:

# if the fridge is open then there are 2 possibilities,
	# 1) it's left open for more than the *threshold* seconds. 
	# 2) it's closed in less than or equal to the *threshold* seconds.
	elif fridgePrevOpen:
		# calculate the time different between the current time and
		# start time
		timeDiff = (datetime.now() - startTime).seconds

		# if the fridge is open and the time difference is greater
		# than threshold, then send a notification
		if fridgeOpen and timeDiff > conf["open_threshold_seconds"]:
			# if a notification has not been sent yet, then send a 
			# notification
			if not notifSent:
				# build the message and send a notification
				msg = "Intruder has left your fridge open!!!"

				# release the video writer pointer and reset the
				# writer object
				writer.release()
				writer = None
				
				# send the message and the video to the owner and
				# set the notification sent flag
				tn.send(msg, tempVideo)
				notifSent = True

If the refrigerator was previously open, let’s check to ensure it wasn’t left open long enough to trigger an “Intruder has left your fridge open!” alert.

Kids can leave the refrigerator open by accident, or maybe after a holiday, you have a lot of food preventing the refrigerator door from closing all the way. You don’t want your food to spoil, so you may want these alerts!

For this message to be sent, the

timeDiff

This message will include a

msg

msg

writer

Let’s now take care of the most common scenario where the refrigerator was previously open, but now it is closed (i.e. some thief stole your food, or maybe it was you when you became hungry):

# check to see if the fridge is closed
		elif not fridgeOpen:
			# if a notification has already been sent, then just set 
			# the notifSent to false for the next iteration
			if notifSent:
				notifSent = False

			# if a notification has not been sent, then send a 
			# notification
			else:
				# record the end time and calculate the total time in
				# seconds
				endTime = datetime.now()
				totalSeconds = (endTime - startTime).seconds
				dateOpened = date.today().strftime("%A, %B %d %Y")

				# build the message and send a notification
				msg = "Your fridge was opened on {} at {} " \
					"at {} for {} seconds.".format(dateOpened
					startTime.strftime("%I:%M%p"), totalSeconds)

				# release the video writer pointer and reset the
				# writer object
				writer.release()
				writer = None
				
				# send the message and the video to the owner
				tn.send(msg, tempVideo)

The case beginning on Line 120 will send a video message indicating, “Your fridge was opened on {{ day }} at {{ time }} for {{ seconds }}.”

On Lines 123 and 124, our

notifSent

False

Otherwise, if the notification has not been sent, we’ll calculate the

totalSeconds

Our

msg

Then the video

writer

Our final block finishes out the loop and performs cleanup:

# check to see if we should write the frame to disk
	if writer is not None:
		writer.write(frame)

# check to see if we need to release the video writer pointer
if writer is not None:
	writer.release()

# cleanup the camera and close any open windows
cv2.destroyAllWindows()
vs.stop()

To finish the loop, we’ll write the

frame

writer

When the loop exits, the

writer

Great job! You made it through a simple IoT project using a Raspberry Pi and camera.

It’s now time to place the bait. I know my thief likes hummus as much as I do, so I ran to the store and came back to put it in the fridge.

RPi security camera results

Figure 6: My refrigerator is armed with an Internet of Things (IoT) Raspberry Pi, PiCamera, and Battery Pack. And of course, I’ve placed some hummus in there for me and the thief. I’ll also know if someone takes a New Belgium Dayblazer beer of mine.

When deploying the Raspberry Pi security camera in your refrigerator to catch the hummus bandit, you’ll need to ensure that it will continue to run without a wireless connection to your laptop.

There are two great options for deployment:

1. Run the computer vision Python script on reboot.
2. Leave a

   screen

     session running with the Python computer vision script executing within.

Be sure to visit the first link if you just want your Pi to run the script when you plug in power.

While this blog post isn’t the right place for a full screen demo, here are the basics:

• Install screen via:

  sudo apt-get install screen

• Open an SSH connection to your Pi and run it:

  screen

• If the connection from your laptop to your Pi ever dies or is closed, don’t panic! The screen session is still running. You can reconnect by SSH’ing into the Pi again and then running

  screen -r

   . You’ll be back in your virtual window.
• Keyboard shortcuts for screen:
  • “ctrl + a, c”: Creates a new “window”.
  • “ctrl + a, p” and “ctrl + a, n”: Cycles through “previous” and “next” windows, respectively.
• For a more in-depth review of

  screen

   , see the documentation. Here’s a screen keyboard shortcut cheat sheet.

Once you’re comfortable with starting a script on reboot or working with

screen

Go ahead and plug in the battery pack, connect, and deploy the script (if you didn’t set it up to start on boot).

The commands are:

$ screen
# wait for screen to start
$ source ~/.profile
$ workon <env_name> # insert the name of your virtual environment
$ python detect.py --conf config/config.json

If you aren’t familiar with command line arguments, please read this tutorial. The command line argument is also required if you are deploying the script upon reboot.

Let’s see it in action!

Figure 7: Me testing the Pi Security Camera notifications with my iPhone.

I’ve included a full deme of the Raspberry Pi security camera below:

Interested in building more projects with the Raspberry Pi, OpenCV, and computer vision?

Figure 8: Catching a furry little raccoon with an infrared light/camera connected to the Raspberry Pi.

Are you interested in using your Raspberry Pi to build practical, real-world computer vision and deep learning applications, including:

• Computer vision and IoT projects on the Pi
• Servos, PID, and controlling the Pi with computer vision
• Human activity, home surveillance, and facial applications
• Deep learning on the Raspberry Pi
• Fast, efficient deep learning with the Movidius NCS and OpenVINO toolkit
• Self-driving car applications on the Raspberry Pi
• Tips, suggestions, and best practices when performing computer vision and deep learning with the Raspberry Pi

If so, you’ll definitely want to check out my upcoming book, Raspberry Pi for Computer Vision — to learn more about the book (including release date information) just click the link below and enter your email address:

From there I’ll ensure you’re kept in the know on the RPi + Computer Vision book, including updates, behind the scenes looks, and release date information.

Summary

In this tutorial, you learned how to build a Raspberry Pi security camera from scratch using OpenCV and computer vision.

Specifically, you learned how to:

• Access the Raspberry Pi camera module or USB webcam.
• Setup your Amazon AWS/S3 account so you can upload images/video when your security camera is triggered (other services such as Dropbox, Box, Google Drive, etc. will work as well, provided you can obtain a public-facing URL of the media).
• Obtain Twilio API keys used to send text messages with the uploaded images/video.
• Create a Raspberry Pi security camera using OpenCV and computer vision.

Finally, we put all the pieces together and deployed the security camera to monitor a refrigerator:

• Each time the door was opened we started recording
• After the door was closed the recording stopped
• The recording was then uploaded to the cloud
• And finally, a text message was sent to our phone showing the activity

You can extend the security camera to include other components as well. My first suggestion would be to take a look at how to build a home surveillance system using a Raspberry Pi where we use a more advanced motion detection technique. It would be fun to implement Twilio SMS/MMS notifications into the home surveillance project as well.

I hope you enjoyed this tutorial!

To download the source code to this post, and be notified when future tutorials are published here on PyImageSearch, just enter your email address in the form below!

Downloads:

If you would like to download the code and images used in this post, please enter your email address in the form below. Not only will you get a .zip of the code, I’ll also send you a FREE 17-page Resource Guide on Computer Vision, OpenCV, and Deep Learning. Inside you'll find my hand-picked tutorials, books, courses, and libraries to help you master CV and DL! Sound good? If so, enter your email address and I’ll send you the code immediately!

Email address:

The post Building a Raspberry Pi security camera with OpenCV appeared first on PyImageSearch.

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2. Reprogrammable Molecular Computing System (Caltech) -- The researchers were able to experimentally demonstrate 6-bit molecular algorithms for a diverse set of tasks. In mathematics, their circuits tested inputs to assess if they were multiples of three, performed equality checks, and counted to 63. Other circuits drew "pictures" on the DNA "scarves," such as a zigzag, a double helix, and irregularly spaced diamonds. Probabilistic behaviors were also demonstrated, including random walks as well as a clever algorithm (originally developed by computer pioneer John von Neumann) for obtaining a fair 50/50 random choice from a biased coin. Paper.
3. Dataforge UUCP -- it's like Cory Doctorow guestwrote our timeline: UUCP over SSH to give decentralized comms for freedom fighters.
4. Go for Industrial Programming (Peter Bourgon) -- I’m speaking today about programming in an industrial context. By that I mean: in a startup or corporate environment; within a team where engineers come and go; on code that outlives any single engineer; and serving highly mutable business requirements. [...] I’ve tried to select for areas that have routinely tripped up new and intermediate Gophers in organizations I’ve been a part of, and particularly those things that may have nonobvious or subtle implications. (via ceej)

Continue reading Four short links: 25 March 2019.

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The Stanford Open Policing Project just released a dataset for police traffic stops across the country:

Currently, a comprehensive, national repository detailing interactions between police and the public doesn’t exist. That’s why the Stanford Open Policing Project is collecting and standardizing data on vehicle and pedestrian stops from law enforcement departments across the country — and we’re making that information freely available. We’ve already gathered over 200 million records from dozens of state and local police departments across the country.

You can download the data as CSV or RDS, and there are fields for stop date, stop time, location, driver demographics, and reasons for the stop. As you might imagine, the data from various municipalities comes at varying degrees of detail and timespans. I imagine there’s a lot to learn here both from the data and from working with the data.

Tags: police, tickets, traffic

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Evaluating Machine Learning Models Fairness and Bias.

Generating Synthetic Classification Data using Scikit

Speed up predictions on low-power devices using Neural Compute Stick and OpenVINO

The analytics translator The Must-Have Role for AI-Driven Organizations.

Towards Automatic Text Summarization: Extractive Methods

Clean a complex dataset for modelling with recommendation algorithms

Unit Tests in R

How to Automatically Determine the Number of Clusters in your Data – and more

Visually explore Probability Distributions with vistributions

Zotero hacks: unlimited synced storage and its smooth use with rmarkdown

Variance decomposition and price segmentation in Insurance

On the poor performance of classifiers in insurance models

5 Amazing Deep Learning Frameworks Every Data Scientist Must Know! (with Illustrated Infographic)

Better Parallelization with Numba

Why Artificial Intelligence Needs to breath on Blockchain ?

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Semantic image parsing, which refers to the process of decomposing images into semantic regions and constructing the structure representation of the input, has recently aroused widespread interest in the field of computer vision. The recent application of deep representation learning has driven this field into a new stage of development. In this paper, we summarize three aspects of the progress of research on semantic image parsing, i.e., category-level semantic segmentation, instance-level semantic segmentation, and beyond segmentation. Specifically, we first review the general frameworks for each task and introduce the relevant variants. The advantages and limitations of each method are also discussed. Moreover, we present a comprehensive comparison of different benchmark datasets and evaluation metrics. Finally, we explore the future trends and challenges of semantic image parsing. Learning Deep Representations for Semantic Image Parsing: a Comprehensive Overview

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How to Build Applied Machine Learning Solutions from Unlabeled Data

Many industry experts consider unsupervised learning the next AI frontier, one that may hold the key to general artificial intelligence. Armed with the conceptual knowledge in this book, data scientists and machine learning practitioners will learn hands-on how to apply unsupervised learning to large unlabeled datasets using Python tools. You’ll uncover hidden patterns, gain deeper business insight, detect anomalies, perform automatic feature engineering and selection, and generate synthetic datasets. Author Ankur Patel-an applied machine-learning researcher and data scientist with expertise in financial markets-provides the concepts, intuition, and tools necessary for you to apply this technology to problems you tackle every day. Through the course of this book, you’ll learn how to build production-ready systems with Python.

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The cyphr package seems to provide a good choice for small research group that shares sensitive data over internet (e.g., DropBox). I did some simple experiment myself and made sure it can actually serve my purpose.

I did my experiment on two computers (using openssl): I created the test data on my Linux workstation running Manjaro then I tried to access the data on a Windows 7 laptop.

For creating the data (Linux workstation):

library(cyphr)

# Create the test data
data_dir <- file.path(“~/Dropbox/temp_files”, “data”)
dir.create(data_dir)
dir(data_dir)

# Encrypt the test data
cyphr::data_admin_init(data_dir)

key <- cyphr::data_key(data_dir)

filename <- file.path(data_dir, “iris.rds”)
cyphr::encrypt(saveRDS(iris, filename), key)
dir(data_dir)

# Cannot read the data with decrypting it
readRDS(filename)

# Read the decrypted version of the data
head(cyphr::decrypt(readRDS(filename), key))

For accessing the data (Windows laptop):

library(cyphr)

key <- data_key(“C:/Users/Ssong/Dropbox/temp_files/data”, path_user = “C:/Users/Ssong/.ssh”)

# Make data access request
data_request_access(“C:/Users/Ssong/Dropbox/temp_files/data”, 
path_user = “C:/Users/Ssong/.ssh”)

On Windows 7,  the system cannot locate the public located in “~/.ssh”, which is pretty dumb.

Going back to the Linux workstation to approve the data access request:

# Review the request and approve (to share with other users)
req <- data_admin_list_requests(data_dir)
data_admin_authorise(data_dir, yes = TRUE)
data_admin_list_keys(data_dir)

Now I can access the data on my Windows laptop:

key <- data_key(“C:/Users/Ssong/Dropbox/temp_files/data”, path_user = “C:/Users/Ssong/.ssh”)

d <- decrypt( readRDS( “C:/Users/Ssong/Dropbox/temp_files/data/iris.rds”), key)

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Frequent commenter Jonathan (another one) writes:

I realize that so many people bitch about the seminar showdown that you might need at one thank you. This year, I managed to re-read the bulk of Geng, and for that I thank you. I have not yet read any Sattouf, but it clearly has made an impression on you, so it’s on my list.

In thanks, my first brief foray into pseudo-Gengiana, I think I’ve got the tone roughly right, but I’m way short on whimsy, but this is what I managed in a sustained fifteen minute effort. Thanks again.

My fellow Americans:

As you are no doubt aware, I have completed my investigation and report. I write this to inform you of an unfortunate mishap from Friday. Many news outlets have reported that my final report was taken by security guard from my offices to the Justice Department. That is not true. In an attempt to maintain my obsessive secrecy, that was a dummy report, actually containing the text of an unpublished novel by David Foster Wallace that we found in Michael Cohen’s safe. We couldn’t understand it—maybe Bill Barr will have better luck.

The real one was handed to my intern, Jeff, in an ordinary interoffice envelope, and Jeff was told to drop it off at Justice on his way home. He lives nearby with six other interns. Not knowing what he had, he stopped off at the Friday Trivia Happy Hour at the Death and Taxes Pub, drank a little too much, and left the report there. We’ve gone back to look and nobody can find it.
So why not just print out another one? Or for that matter, why didn’t I just email the first report? As you’ve no doubt gleaned by now, computers and email aren’t my thing. As my successor at the FBI, Mr. Comey, demonstrated, email baffles just about all of us. And I don’t use a computer. So there isn’t another copy of the real report. I’ve got all my notes, though, so I ought to be able to cobble together a new report in a couple of months.

Apologies for the delay,
Robert Mueller

PS: Jeff has been chastised. We haven’t fired him, but in asking him about this he let slip that his parents didn’t pay taxes on the nanny who raised him and they may have strongly implied that he played on a high school curling team to get into college. His parents are going to jail and the nanny’s immigration status is being investigated. This requires a short re-opening of the investigation.

The mention of “Jeff” seems particularly Geng-like to me. Perhaps I’m reminded of “Ed.” Thinking of Geng makes me a bit sad, though, not just for her but because it reminds me of the passage of time. I associate Geng, Bill James, and Spy magazine with the mid-1980s. Ahhh, lost youth!

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Robust Re-Scaling to Better Recover Latent Effects in Data (rrscale)
Non-linear transformations of data to better discover latent effects. Applies a sequence of three transformations (1) a Gaussianizing transformation, ( …

Create Reproducible Research Projects (rosr)
Creates reproducible academic projects with integrated academic elements, including datasets, references, codes, images, manuscripts, dissertations, sl …

Group Sequential Design Class for Clinical Trials (seqmon)
S4 class object for creating and managing group sequential designs. It calculates the efficacy and futility boundaries at each look. It allows modifyin …

Tools for Managing SSH and Git Credentials (credentials)
Setup and retrieve HTTPS and SSH credentials for use with ‘git’ and other services. For HTTPS remotes the package interfaces the ‘git-credential’ utili …

Clustering and Classification Inference with U-Statistics (uclust)
Clustering and classification inference for high dimension low sample size (HDLSS) data with U-statistics. The package contains implementations of nonp …

Portfolio Safeguard: Optimization, Statistics and Risk Management (PSGExpress)
Solves optimization, advanced statistics, and risk management problems. Popular nonlinear functions in financial, statistical, and logistics applicatio …

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Two-thirds of bylines in American reporting credit men

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We received almost 400 applications for our 2019 internship program from students with very diverse backgrounds. After interviewing several dozen people and making some very difficult decisions, we are pleased to announce that these twelve interns have accepted positions with us for this summer:

• Therese Anders: Calibrated Peer Review. Prototype tools to conduct experiments to see whether calibrated peer review is a useful and feasible feedback strategy in introductory data science classes and industry workshops. (mentor: Mine Çetinkaya-Rundel)

• Malcolm Barrett: R Markdown Enhancements. Tidy up and refactoring the R Markdown code base. (mentor: Rich Iannone)

• Julia Blum: RStudio Community Sustainability. Study community.rstudio.com, enhance documentation and processes, and onboard new users. (mentor: Curtis Kephart)

• Joyce Cahoon: Object Scrubbers. Help write a set of methods to scrub different types of objects to reduce their size on disk. (mentors: Max Kuhn and Davis Vaughan)

• Daniel Chen: Grader Enhancements. Enhance [grader](https://github.com/rstudio-education/grader) to identify students’ mistakes when doing automated tutorials. (mentor: Garrett Grolemund)

• Marly Cormar: Production Testing Tools for Data Science Pipelines. Build on applicability domain methods from computational chemistry to create functions that can be included in a dplyr pipeline to perform statistical checks on data in production. (mentor: Max Kuhn)

• Desiree De Leon: Teaching and Learning with RStudio. Create a one-stop guide to teaching with RStudio similar to Teaching and Learning with Jupyter. (mentor: Alison Hill)

• Dewey Dunnington: ggplot2 Enhancements. Contribute to ggplot2 or an associated package (like scales) by writing R code for graphics and helping to manage a large, popular open source project. (mentor: Hadley Wickham)

• Maya Gans: Tidy Blocks. Prototype and evaluate a block-based version of the tidyverse so that young students can do simple analysis using an interface like Scratch. (mentor: Greg Wilson)

• Leslie Huang: Shiny Enhancements. Enhance Shiny’s UI, improve performance bottlenecks, fix bugs, and create a set of higher-order reactives for more sophisticated programming. (mentor: Barret Schloerke)

• Grace Lawley: Tidy Practice. Develop practice projects so learners can practice tidyverse skills using interesting real-world data. (mentor: Alison Hill)

• Yim Register: Data Science Training for Software Engineers. Develop course materials to teach basic data analysis to programmers using software engineering problems and data sets. (mentor: Greg Wilson)

We are very excited to welcome them all to the RStudio family, and we hope you’ll enjoy following their progress over the summer.

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Relational Forward Model (RFM)
The behavioral dynamics of multi-agent systems have a rich and orderly structure, which can be leveraged to understand these systems, and to improve how artificial agents learn to operate in them. Here we introduce Relational Forward Models (RFM) for multi-agent learning, networks that can learn to make accurate predictions of agents’ future behavior in multi-agent environments. Because these models operate on the discrete entities and relations present in the environment, they produce interpretable intermediate representations which offer insights into what drives agents’ behavior, and what events mediate the intensity and valence of social interactions. Furthermore, we show that embedding RFM modules inside agents results in faster learning systems compared to non-augmented baselines. As more and more of the autonomous systems we develop and interact with become multi-agent in nature, developing richer analysis tools for characterizing how and why agents make decisions is increasingly necessary. Moreover, developing artificial agents that quickly and safely learn to coordinate with one another, and with humans in shared environments, is crucial. …

Auto-Encoding Variational Bayes
How can we perform efficient inference and learning in directed probabilistic models, in the presence of continuous latent variables with intractable posterior distributions, and large datasets? We introduce a stochastic variational inference and learning algorithm that scales to large datasets and, under some mild differentiability conditions, even works in the intractable case. Our contributions is two-fold. First, we show that a reparameterization of the variational lower bound yields a lower bound estimator that can be straightforwardly optimized using standard stochastic gradient methods. Second, we show that for i.i.d. datasets with continuous latent variables per datapoint, posterior inference can be made especially efficient by fitting an approximate inference model (also called a recognition model) to the intractable posterior using the proposed lower bound estimator. Theoretical advantages are reflected in experimental results.
GitXiv …

CrossE
Knowledge graph embedding aims to learn distributed representations for entities and relations, and is proven to be effective in many applications. Crossover interactions — bi-directional effects between entities and relations — help select related information when predicting a new triple, but haven’t been formally discussed before. In this paper, we propose CrossE, a novel knowledge graph embedding which explicitly simulates crossover interactions. It not only learns one general embedding for each entity and relation as most previous methods do, but also generates multiple triple specific embeddings for both of them, named interaction embeddings. We evaluate embeddings on typical link prediction tasks and find that CrossE achieves state-of-the-art results on complex and more challenging datasets. Furthermore, we evaluate embeddings from a new perspective — giving explanations for predicted triples, which is important for real applications. In this work, an explanation for a triple is regarded as a reliable closed-path between the head and the tail entity. Compared to other baselines, we show experimentally that CrossE, benefiting from interaction embeddings, is more capable of generating reliable explanations to support its predictions. …

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Deep Text-to-Speech System with Seq2Seq Model

An ‘On The Fly’ Framework for Efficiently Generating Synthetic Big Data Sets

Self-Organization and Artificial Life

Dying ReLU and Initialization: Theory and Numerical Examples

Probabilistic Temperature Forecasting with a Heteroscedastic Autoregressive Ensemble Postprocessing model

A Data Mining Approach to Flight Arrival Delay Prediction for American Airlines

Algorithms for Verifying Deep Neural Networks

Spherical Principal Component Analysis

Ontology Based Global and Collective Motion Patterns for Event Classification in Basketball Videos

Minimizing Age of Information in Cognitive Radio-Based IoT Networks: Underlay or Overlay?

Emotion Action Detection and Emotion Inference: the Task and Dataset

A Deep Look into Neural Ranking Models for Information Retrieval

Spatiotemporal Feature Learning for Event-Based Vision

swCaffe: a Parallel Framework for Accelerating Deep Learning Applications on Sunway TaihuLight

Learning to find order in disorder

Visual Query Answering by Entity-Attribute Graph Matching and Reasoning

Practical Distributed Learning: Secure Machine Learning with Communication-Efficient Local Updates

Model-Based Task Transfer Learning

Change Point Detection in the Mean of High-Dimensional Time Series Data under Dependence

Deep Feature Selection using a Teacher-Student Network

DSPG: Decentralized Simultaneous Perturbations Gradient Descent Scheme

Adversarial Attacks on Deep Neural Networks for Time Series Classification

Learning Competitive and Discriminative Reconstructions for Anomaly Detection

Time Series Predict DB

In this work, we are motivated to make predictive functionalities native to database systems with focus on time series data. We propose a system architecture, Time Series Predict DB, that enables predictive query in any existing time series database by building an additional ‘prediction index’ for time series data. To be effective, such an index needs to be built incrementally while keeping up with database throughput, able to scale with volume of data, provide accurate predictions for heterogeneous data, and allow for ‘predictive’ querying with latency comparable to the traditional database queries. Building upon a recently developed model agnostic time series algorithm by making it incremental and scalable, we build such a system on top of PostgreSQL. Using extensive experimentation, we show that our incremental prediction index updates faster than PostgreSQL ( per data for prediction index vs per data for PostgreSQL) and thus not affecting the throughput of the database. Across a variety of time series data, we find that our incremental, model agnostic algorithm provides better accuracy compared to the best state-of-art time series libraries (median improvement in range 3.29 to 4.19x over Prophet of Facebook, 1.27 to 1.48x over AMELIA in R). The latency of predictive queries with respect to SELECT queries (0.5ms) is < 1.9x (0.8ms) for imputation and < 7.6x (3ms) for forecasting across machine platforms. As a by-product, we find that the incremental, scalable variant we propose improves the accuracy of the batch prediction algorithm which may be of interest in its own right.

readPTU: a Python Library to Analyse Time Tagged Time Resolved Data

Training Over-parameterized Deep ResNet Is almost as Easy as Training a Two-layer Network

Topic-Guided Variational Autoencoders for Text Generation

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In all of my undergraduate classes, I require a term project, done in groups of 3-4 students. Though the topic is specified, it is largely open-ended, a level of “freedom” that many students are unaccustomed to. However, some adapt quite well. The topic this quarter was to choose a CRAN package that does not use any C/C++, and try to increase speed by converting some of the code to C/C++.

Some of the project submissions were really excellent. I decided to place one on the course Web page, and chose this one. Nice usage of Rcpp and devtools (neither of which was covered in class), very nicely presented.

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Article: Are We Being Programmed?

Paper: Theories of Parenting and their Application to Artificial Intelligence

Paper: Online Explanation Generation for Human-Robot Teaming

Paper: Applying Probabilistic Programming to Affective Computing

Article: Artificial Intelligence and Society

Paper: Responses to a Critique of Artificial Moral Agents

Paper: Responsible and Representative Multimodal Data Acquisition and Analysis: On Auditability, Benchmarking, Confidence, Data-Reliance & Explainability

Paper: Machine Learning: A Dark Side of Cancer Computing

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“Within 10 years, data science will be so enmeshed within industry-specific applications and broad productivity tools that we may no longer think of it is a hot career. Just as generations of math and statistics students have gone on to fill all manner of roles in business and academia without thinking of themselves as mathematicians or statisticians, the newly minted data scientist grads will be tomorrow’s manufacturing engineers, marketing leaders and medical researchers.” Nate Oostendorp ( Mar 1, 2019 )

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Paul Alper pointed me to this news story, “Harvard Calls for Retraction of Dozens of Studies by Noted Cardiac Researcher: Some 31 studies by Dr. Piero Anversa contain fabricated or falsified data, officials concluded. Dr. Anversa popularized the idea of stem cell treatment for damaged hearts.”

I replied: Ahhh, Harvard . . . the reporter should’ve asked Marc Hauser for a quote.

Alper responded:

Marc Hauser’s research involved “cotton-top tamarin monkeys” while Piero Anversa was falsifying and spawning research on damaged hearts:

The cardiologist rocketed to fame in 2001 with a flashy paper claiming that, contrary to scientific consensus, heart muscle could be regenerated. If true, the research would have had enormous significance for patients worldwide.

I, and I suspect that virtually all of the other contributors to your blog know nothing** about cotton-top tamarin monkeys but are fascinated and interested in stem cells and heart regeneration. Consequently, are Hauser and Anversa separated by a chasm or should they be lumped together in the Hall of Shame? Put another way, do we have yet an additional instance of crime and appropriate punishment?

**Your blog audience is so broad that there well may be cotton-top tamarin monkey mavens out there dying to hit the enter key.

Good point. It’s not up to me at all: I don’t administer punishment of any sort; as a blogger I function as a very small news organization, and my only role is to sometimes look into these cases, bring them to others’ notice, and host discussions. If it were up to me, David Weakliem and Jay Livingston would be regular New York Times columnists, and Mark Palko and Joseph Delaney would be the must-read bloggers that everyone would check each morning. Also, if it were up to me, everyone would have to post all their data and code—at least, that would be the default policy; researchers would have to give very good reasons to get out of this requirement. (Not that I always or even usually post my data and code; but I should do better too.) But none of these things are up to me.

From Harvard’s point of view, perhaps the question is whether they should go easy on people like Hauser, a person who is basically an entertainer, and whose main crime was to fake some of his entertainment—a sort of Doris Kearns Goodwin, if you will—. and be tougher on people such as Anversa, whose misdeeds can cost lives. (I don’t know where you should put someone like John Yoo who advocated for actual torture, but I suppose that someone who agreed with Yoo politically would make a similar argument against, say, old-style apologists for the Soviet Union.)

One argument for not taking people like Hauser, Wansink, etc., seriously, even in their misdeeds, is that after the flaws in their methods were revealed—after it turned out that their blithe confidence (in Wansink’s case) or attacks on whistleblowers (in Hauser’s case) were not borne out by the data—these guys just continued to say their original claims were valid. So, for them, it was never about the data at all, it was always about their stunning ideas. Or, to put it another way, the data were there to modify the details of their existing hypotheses, or to allow them to gently develop and extend their models, in a way comparable to how Philip K. Dick used the I Ching to decide what would happen next in his books. (Actually, that analogy is pretty good, as one could just as well say that Dick he used randomness not so much to “decide what would happen” but rather “to discover what would happen” next.)

Anyway, to get back to the noise-miners: The supposed empirical support was just there for them to satisfy the conventions of modern-day science. So when it turned out that the promised data had never been there . . . so what, really? The data never mattered in the first place, as these researchers implicitly admitted by not giving up on any of their substantive claims. So maybe these profs should just move into the Department of Imaginative Literature and the universities can call it a day. The medical researchers who misreport their data: That’s a bigger problem.

And what about the news media, myself included? Should I spend more time blogging about medical research and less time blogging about social science research? It’s a tough call. Social science is my own area of expertise, so I think I’m making more of a contribution by leveraging that expertise than by opining on medical research that I don’t really understand.

A related issue is accessibility: people send me more items on social science, and it takes me less effort to evaluate social science claims.

Also, I think social science is important. It does not seem that there’s any good evidence that elections are determined by shark attacks or the outcomes of college football games, or that subliminal smiley faces cause large swings in opinion, or that women’s political preferences vary greatly based on time of the month—but if any (or, lord help us, all) of these claims were true, then this would be consequential: it would “punch a big hole in democratic theory,” in the memorable words of Larry Bartels.

Monkey language and bottomless soup bowls: I don’t care about those so much. So why have I devoted so much blog space to those silly cases? Partly its from a fascination with people who refuse to admit error even when it’s staring them in the face, partly because it can give insights into general issues and statistics and science, and partly because I think people can miss the point in these cases by focusing on the drama and missing out on the statistics; see for example here and here. But mostly I write more about social science because social science is my “thing.” Just like I write more about football and baseball than about rugby and cricket.

P.S. One more thing: Don’t forget that in all these fields, social science, medical science, whatever, the problem’s is not just with bad research, cheaters, or even incompetents. No, there are big problems even with solid research done by honest researchers who are doing their best but are still using methods that misrepresent what we learn from the data. For example, the ORBITA study of heart stents, where p=0.20 (actually p=0.09 when the data were analyzed more appropriately) was widely reported as implying no effect. Honesty and transparency—and even skill and competence in the use of standard methods—are not enough. Sometimes, as in the above post, it makes sense to talk about flat-out bad research and the prominent people who do it, but that’s only one part of the story.

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ShinyProxy is a novel, open source platform to deploy Shiny apps for the enterprise
or larger organizations.

Secured Embedding of Shiny Apps

Since version 2.0.1 ShinyProxy provides a REST API to manage (launch, shut down) Shiny apps and consume the content programmatically inside broader web applications or portals. This allows to cleanly separate the responsiblity for the Shiny apps (data science teams) and those broader applications (IT teams) while still achieving seamless integration between the two from the user’s perspective. With this release we go one step further and support the industry standard to protect REST APIs, namely OAuth 2.0.

In practice this means the following: when users of the portal log on, they typically authenticate with an OAuth2 provider (e.g. Auth0). This then allows the web application to access the ShinyProxy API on their behalf and launch the Shiny apps over the ShinyProxy API. We leave out the details on authorization codes and access tokens, but the core message is that you can now embed Shiny apps in virtually any other web application in a secure way. If you want an actual example,
please head to our Github page with ShinyProxy configuration examples, where a sample Node.js application is made available to demonstrate the full scenario.

Miscellaneous improvements

More generally, users are deploying ShinyProxy on a wide array of cloud platforms and using a great variety of authentication technologies. A lot of the experience gained can now be found in updated documentation with additional examples on e.g. AWS Cognito (here) or Microsoft Azure AD B2C (here), next to Google and Auth0 (here). These production deployments also called for more extensive documentation on logging with ShinyProxy and at that level we also introduced a new setting logging.requestdump to enable full request dump for advanced debugging. Then, for user convenience we introduced user-friendly URLs to access an app either via the standard ShinyProxy interface (/app/) or directly (/app_direct/) if needed.

Full release notes can be found on the downloads page and updated documentation can be found on https://shinyproxy.io. As always community support on this new release is available at

https://support.openanalytics.eu

Don’t hesitate to send in questions or suggestions and have fun with ShinyProxy!

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Distance Preserving Grid Layouts

Estimating Dynamic Conditional Spread Densities to Optimise Daily Storage Trading of Electricity

Global Fire Season Severity Analysis and Forecasting

On confidence intervals centered on bootstrap smoothed estimators

Episodic Memory Reader: Learning What to Remember for Question Answering from Streaming Data

Improving Neural Architecture Search Image Classifiers via Ensemble Learning

Show, Translate and Tell

Inference Without Compatibility

We consider hypothesis testing problems for a single covariate in the context of a linear model with Gaussian design when . Under minimal sparsity conditions of their type and without any compatibility condition, we construct an asymptotically Gaussian estimator with variance equal to the oracle least-squares. The estimator is based on a weighted average of all models of a given sparsity level in the spirit of exponential weighting. We adapt this procedure to estimate the signal strength and provide a few applications. We support our results using numerical simulations based on algorithm which approximates the theoretical estimator and provide a comparison with the de-biased lasso.

Distributed Constrained Online Learning

In this paper, we consider groups of agents in a network that select actions in order to satisfy a set of constraints that vary arbitrarily over time and minimize a time-varying function of which they have only local observations. The selection of actions, also called a strategy, is causal and decentralized, i.e., the dynamical system that determines the actions of a given agent depends only on the constraints at the current time and on its own actions and those of its neighbors. To determine such a strategy, we propose a decentralized saddle point algorithm and show that the corresponding global fit and regret are bounded by functions of the order of . Specifically, we define the global fit of a strategy as a vector that integrates over time the global constraint violations as seen by a given node. The fit is a performance loss associated with online operation as opposed to offline clairvoyant operation which can always select an action if one exists, that satisfies the constraints at all times. If this fit grows sublinearly with the time horizon it suggests that the strategy approaches the feasible set of actions. Likewise, we define the regret of a strategy as the difference between its accumulated cost and that of the best fixed action that one could select knowing beforehand the time evolution of the objective function. Numerical examples support the theoretical conclusions.

On Target Shift in Adversarial Domain Adaptation

Online Explanation Generation for Human-Robot Teaming

Cloud-Edge Coordinated Processing: Low-Latency Multicasting Transmission

Applying Probabilistic Programming to Affective Computing

A Context-Aware Citation Recommendation Model with BERT and Graph Convolutional Networks

Multimodal Deep Learning for Finance: Integrating and Forecasting International Stock Markets

Neuromorphic Hardware learns to learn

Content Differences in Syntactic and Semantic Representations

MFAS: Multimodal Fusion Architecture Search

Role of Bloom Filter in Big Data Research: A Survey

Selective Kernel Networks

Deep Neural Network Ensembles for Time Series Classification

Matching Entities Across Different Knowledge Graphs with Graph Embeddings

On Evaluation of Adversarial Perturbations for Sequence-to-Sequence Models

Improving Strong-Scaling of CNN Training by Exploiting Finer-Grained Parallelism

Tuning Hyperparameters without Grad Students: Scalable and Robust Bayesian Optimisation with Dragonfly

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Introduction:

We will identify anomalous products on the production line by using measurements from testing stations and deep learning models. Anomalous products are not failures, these anomalies are products close to the measurement limits, so we can display warnings before the process starts to make failed products and in this way the stations get maintenance.

 Before starting we need the next software installed and working:

– R language installed.
– All the R packages mentioned in the R sources.
– Testing stations data, I suggest to go station by station.
– H2O open source framework.
– Java 8 ( For H2O ). Open JDK: https://github.com/ojdkbuild/contrib_jdk8u-ci/releases
– R studio.

About the data: Since I cannot use my real data, for this article I am using SECOM Data Set from UCI Machine Learning Repository   

h2o.removeAll() ## Removes the data from the h2o cluster in preparation for our final model.

# Reading SECOM data file
allData = read.csv( “secom.data”, sep = ” “, header = FALSE, encoding = “UTF-8” )

# fixing the data set, there are a lot of NaN records
if( dim(na.omit(allData))[1] == 0 ){
  for( colNum in 1:dim( allData )[2] ){

    # Get valid values from the actual column values
    ValidColumnValues = allData[,colNum][!is.nan( allData[, colNum] )]

    # Check each value in the actual active column.
    for( rowNum in 1:dim( allData )[1] ){

    cat( “Processing row:”, rowNum, “, Column:”, colNum, “Data:”, allData[rowNum, colNum], “\n” )

    if( is.nan( allData[rowNum, colNum] ) ) {

      # Assign random valid value to our row,column with NA value

      allData[rowNum, colNum] = getValue
    }
  }
 }
}

# spliting all data, the fiirst 90% for training and the rest 10% for testing our model.
trainingData = allData[1:floor(dim(allData)[1]*.9),]
testingData = allData[(floor(dim(allData)[1]*.9)+1):dim(allData)[1],]

trainingData_hex = as.h2o( trainingData, destination_frame = “train_hex” )

# Set the input variables
featureNames = colnames(trainingData_hex)

# Creating the first model version.
trainingModel = h2o.deeplearning( x = featureNames

                                                         , model_id = “Station1DeepLearningModel”
                                                         , activation = “Tanh”
                                                         , autoencoder = TRUE
                                                         , reproducible = TRUE
                                                         , l1 = 1e-5
                                                         , ignore_const_cols = FALSE
                                                         , seed = 1234
                                                         , hidden = c( 400, 200, 400 ), epochs = 50 )

# Getting the anomalies from training data to set the min MSE( Mean Squared Error )
# value before setting a record as anomally
trainMSE = as.data.frame( h2o.anomaly( trainingModel
                                                                 , trainingData_hex
                                                                 , per_feature = FALSE ) )

# Check the first 30 descendent sorted trainMSE records to see our outliers
head( sort( trainMSE$Reconstruction.MSE , decreasing = TRUE ), 30)
# 0.020288603 0.017976305 0.012772556 0.011556780 0.010143009 0.009524983 0.007363854
# 0.005889714 0.005604329 0.005189614[11] 0.005185285 0.005118595 0.004639442 0.004497609
# 0.004438342 0.004419993 0.004298936 0.003961503 0.003651326 0.003426971 0.003367108
# 0.003169319 0.002901914 0.002852006 0.002772110 0.002765924 0.002754586 0.002748887
# 0.002619872 0.002474702

# Ploting errors of reconstructing our training data, to have a graphical view
# of our data reconstruction errors

plot( sort( trainMSE$Reconstruction.MSE ), main = ‘Reconstruction Error’, ylab = “MSE Value.” )

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Resampled Data Frames (strapgod)
Create data frames with virtual groups that can be used with ‘dplyr’ to efficiently compute resampled statistics, generate the data for hypothetical ou …

Binscatter Estimation and Inference (binsreg)
Provides tools for statistical analysis using the binscatter methods developed by Cattaneo, Crump, Farrell and Feng (2019a) <arXiv:1902.09608> an …

Bayesian Network Learning Improved Project (r.blip)
Allows the user to learn Bayesian networks from datasets containing thousands of variables. It focuses on score-based learning, mainly the ‘BIC’ and th …

Genetic Approach to Maximize Clustering Criterion (gama)
An evolutionary approach to performing hard partitional clustering. The algorithm uses genetic operators guided by information about the quality of ind …

Distance Object Manipulation Tools (disttools)
Provides convenient methods for accessing the data in ‘dist’ objects with minimal memory and computational overhead. ‘disttools’ can be used to extract …

Utilities to Extract and Process ‘YAML’ Fragments (yum)
Provides a number of functions to facilitate extracting information in ‘YAML’ fragments from one or multiple files, optionally structuring the informat …

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Over the last several years, the field of natural language processing has been propelled forward by an explosion in the use of deep learning models. This survey provides a brief introduction to the field and a quick overview of deep learning architectures and methods. It then sifts through the plethora of recent studies and summarizes a large assortment of relevant contributions. Analyzed research areas include several core linguistic processing issues in addition to a number of applications of computational linguistics. A discussion of the current state of the art is then provided along with recommendations for future research in the field. A Survey of the Usages of Deep Learning in Natural Language Processing

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WebSeg
In this paper, we improve semantic segmentation by automatically learning from Flickr images associated with a particular keyword, without relying on any explicit user annotations, thus substantially alleviating the dependence on accurate annotations when compared to previous weakly supervised methods. To solve such a challenging problem, we leverage several low-level cues (such as saliency, edges, etc.) to help generate a proxy ground truth. Due to the diversity of web-crawled images, we anticipate a large amount of ‘label noise’ in which other objects might be present. We design an online noise filtering scheme which is able to deal with this label noise, especially in cluttered images. We use this filtering strategy as an auxiliary module to help assist the segmentation network in learning cleaner proxy annotations. Extensive experiments on the popular PASCAL VOC 2012 semantic segmentation benchmark show surprising good results in both our WebSeg (mIoU = 57.0%) and weakly supervised (mIoU = 63.3%) settings. …

Decreasing-Trend-Nature (DTN)
We propose a novel diminishing learning rate scheme, coined Decreasing-Trend-Nature (DTN), which allows us to prove fast convergence of the Stochastic Gradient Descent (SGD) algorithm to a first-order stationary point for smooth general convex and some class of nonconvex including neural network applications for classification problems. We are the first to prove that SGD with diminishing learning rate achieves a convergence rate of $\mathcal{O}(1/t)$ for these problems. Our theory applies to neural network applications for classification problems in a straightforward way. …

Super-Resolution Erlangen Database (SupER)
Capturing ground truth data to benchmark super-resolution (SR) is challenging. Therefore, current quantitative studies are mainly evaluated on simulated data artificially sampled from ground truth images. We argue that such evaluations overestimate the actual performance of SR methods compared to their behavior on real images. To bridge this simulated-to-real gap, we introduce the Super-Resolution Erlangen (SupER) database, the first comprehensive laboratory SR database of all-real acquisitions with pixel-wise ground truth. It consists of more than 80k images of 14 scenes combining different facets: CMOS sensor noise, real sampling at four resolution levels, nine scene motion types, two photometric conditions, and lossy video coding at five levels. As such, the database exceeds existing benchmarks by an order of magnitude in quality and quantity. This paper also benchmarks 19 popular single-image and multi-frame algorithms on our data. The benchmark comprises a quantitative study by exploiting ground truth data and qualitative evaluations in a large-scale observer study. We also rigorously investigate agreements between both evaluations from a statistical perspective. One interesting result is that top-performing methods on simulated data may be surpassed by others on real data. Our insights can spur further algorithm development, and the publicy available dataset can foster future evaluations. …

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Airflow and superQuery

Top 5 Reasons to Move Enterprise Data Science Off the Laptop and to the Cloud

R 3.5.3 now available

‘X affects Y’. What does that even mean?

What is the Difference Between AI and Machine Learning

The importance of Graphing Your Data – Anscombe’s Clever Quartet!

R and labelled data: Using quasiquotation to add variable and value labels

Unsupervised Classification Project: Building a Movie Recommender with Clustering Analysis and K-Means

Dockerizing Python Flask app and Conda environment

Virtual, Headless, and Distributed (Oh My!)

Getting started with NLP using the PyTorch framework

It’s OK to use spreadsheets in data science

Image-to-Image Translation

EM Algorithm Explained in One Picture

Top 10 Artificial Intelligence Trends in 2019

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This book is designed to facilitate reproducibility in Econometrics. It does so by using open source software (R) and recently developed tools (R Markdown and bookdown) that allow the reader to engage in reproducible research. Illustrative examples are provided throughout, and a range of topics are covered. Assignments, exams, slides, and a solution manual are available for instructors.

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With all of the excitement surrounding cdata style control table based data transforms (the cdata ideas being named as the “replacements” for tidyr‘s current methodology, by the tidyr authors themselves!) I thought I would take a moment to describe how they work.

cdata defines two primary data manipulation operators: rowrecs_to_blocks() and blocks_to_rowrecs(). These are the fundamental transforms that convert between data representations. The two representations it converts between are:

• A world where all facts about an instance or record are in a single row (“rowrecs”).
• A world where all facts about an instance or record are in groups of rows (“blocks”).

It turns out once you develop the idea of specifying the data transformation as explicit data (an application of Erick S. Raymond’s admonition: “fold knowledge into data, so program logic can be stupid and robust.”), you have also a great tool for reasoning and teaching data transforms.

For example:

rowrecs_to_blocks() does the following. For each row record, make a replicant of the of the control table with values filled in. In relational terms rowrecs_to_blocks() is therefore a join of the data to the control table. Conversely blocks_to_rowrecs() combines groups of rows into single rows, so in relational terms it is an aggregation or projection. If each of these operations is faithful (keeps enough information around) they are then inverse of each other.

We share some nifty tutorials on the ideas here:

• The theory of data records (blocks and rows).
• How to graphically design your data transform.

One can build fairly clever illustrations and animations to teach the above.

The most common special cases of the above have been popularized in R as unpivot/pivot (pivot invented by Pito Salas), stack/unstack, melt/cast, or gather/spread. These special cases are handled in cdata by convenience functions unpivot_to_blocks() and pivot_to_rowrecs(). A great example of a “higher order” transform that isn’t one of the common ones is given here.

Note: the above theory and implementation is joint work of Nina Zumel and John Mount and can be found here. We would really appreciate any citations or credit you can send our way (or even politely correcting those who don’t attribute the work or attribute the work to others, as there are already a lot of mentions without credit or citation).

citation("cdata")

To cite package ‘cdata’ in publications use:

  John Mount and Nina Zumel (2019). cdata: Fluid Data Transformations. https://github.com/WinVector/cdata/,
  https://winvector.github.io/cdata/.

A BibTeX entry for LaTeX users is

  @Manual{,
    title = {cdata: Fluid Data Transformations},
    author = {John Mount and Nina Zumel},
    year = {2019},
    note = {https://github.com/WinVector/cdata/, https://winvector.github.io/cdata/},
  }

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1. Half of American households subscribe to “Amazon Prime”, a “club membership” for Amazon customers with monthly fees. And about half of these subscribes buy something from Amazon every week. If you are counting, this seems to imply that at least a quarter of all American households order something from Amazon every week.
2. How do the preprints that researchers post online freely differ from genuine published articles that underwent peer review? Maybe less than you’d expect:
   

   our results show that quality of reporting in preprints in the life sciences is within a similar range as that of peer-reviewed articles

3. Very low meat consumption might increase the long-term risk of dementia and Alzheimer’s.
4. We appear to be no closer to find a cure for Alzheimer’s despite billions being spent each year in research and clinical trials. Lower writes:
   

   Something is wrong with the way we’re thinking about Alzheimer’s (…) It’s been wrong for a long time and that’s been clear for a long time. Do something else.

5. Many researchers use “p values” (a statistical measure) to prove that their results are “significant”. Ioannidis argues that most research should not rely on p values.
6. Eating nuts improves cognition (nuts make you smart).
7. As we age, we become more prone to diabetes. According to an article in Nature, senescent cells in the immune system may lead to diabetes. Senescent cells that are cells that should be dead due to damage or too many divisions, but they refuse to die.
8. Hospitalizations for heart attacks have declined by 38% in the last 20 years and mortality is at all time low. Though clinicians and health professionals take the credit, I am not convinced we understand the source of this progress.
9. In stories, females identify more strongly with their own gender whereas males identify equally with either gender.
10. Theranos was a large company that pretended to be able to do better blood tests. The company was backed by several granted patents. Yet we know that Theranos technology did not work. The problem we are facing now is that Theranos patents, granted on false pretenses and vague claims, remain valid and will hurt genuine inventors in the future. If we are to have patents at all, they should only be granted for inventions that work. Nazer argues that the patent system is broken.
11. Smaller groups tend to create more innovative work, and larger groups less so.
12. The bones of older people become fragile. A leading cause of this problem is the fact stem cells in our bones become less active. It appears that this is caused by excessive inflammation. We can create it in young mice by exposing them to the blood serum of old mice. We can also reverse it in old mice by using an anti-inflammatory drug (akin to aspirin).
13. Gene therapy helped mice regain sight lost due to retinal degeneration. It could work in human beings too.
14. Based on ecological models, scientists predicted over ten years ago that polar bear populations would soon collapse. That has not happened: there may be several times more polar bears than decades ago. It is true that ice coverage is lower than it has been historically due to climate change, but it is apparently incorrect to assume that polar bears need thick ice; they may in fact thrive when the ice is thin and the summers are long. Crowford, a zoologist and professor at the University of Victory tells the tale in her book The Polar Bear Catastrophe That Never Happened.

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Rajesh Venkatachalapathy writes:

Recently, I had a conversation with a colleague of mine about the virtues of synthetic data and their role in data analysis. I think I’ve heard a sermon/talk or two where you mention this and also in your blog entries. But having convinced my colleague of this point, I am struggling to find good references on this topic.

I was hoping to get some leads from you.

My reply:

Hi, here are some refs: from 2009, 2011, 2013, also this and this and this from 2017, and this from 2018. I think I’ve missed a few, too.

If you want something in dead-tree style, see Section 8.1 of my book with Jennifer Hill, which came out in 2007.

Or, for some classic examples, there’s Bush and Mosteller with the “stat-dogs” in 1954, and Ripley with his simulated spatial processes from, ummmm, 1987 I think it was? Good stuff, all. We should be doing more of it.

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love_verse <- function(w1, w2, w3){
  glue::glue(
  "Love is {b}, {b} is love
   Love is {y}, {y} love
   Love is {u} to be loved", 
  b = w1, y = w2, u = w3)
}

As a return, parameters sometimes gives echoes of poetry.

love_verse('real', 'feeling', 'wanting')

Love is real, real is love
Love is feeling, feeling love
Love is wanting to be loved

love_verse('touch', 'reaching', 'asking')

Love is touch, touch is love
Love is reaching, reaching love
Love is asking to be loved

## refrain

Love is you
You and me
Love is knowing
We can be

love_verse('free', 'living', 'needing')

Love is free, free is love
Love is living, living love
Love is needing to be loved

https://www.youtube.com/watch?v=7er_xx7Wmg8

list(list(w1 = 'real',  w2 = 'feeling',  w3 = 'wanting'),
     list(w1 = 'touch', w2 = 'reaching', w3 = 'asking' ),
     list(w1 = 'free',  w2 = 'living',   w3 = 'needing')) %>% 
  purrr::map(function(x)do.call(love_verse, x))

[[1]]
Love is real, real is love
Love is feeling, feeling love
Love is wanting to be loved

[[2]]
Love is touch, touch is love
Love is reaching, reaching love
Love is asking to be loved

[[3]]
Love is free, free is love
Love is living, living love
Love is needing to be loved

We could also read title of this article as “strength of an R function exposed with a Lennon song”…

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The Guardian’s data editors in the UK, US and Australia explain how their work has influenced our journalism

The Datablog was launched in March 2009, starting in a corner of the Guardian website dedicated to the publication and analysis of data. In the last decade it has published thousands of stories and datasets on every topic imaginable, from Reading the Riots to how the UK fared in every Eurovision song contest, and its influence lives on throughout our data journalism.

How did it all begin? This is what its founder, Simon Rogers, remembers:

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Density estimation is an interdisciplinary topic at the intersection of statistics, theoretical computer science and machine learning. We review some old and new techniques for bounding sample complexity of estimating densities of continuous distributions, focusing on the class of mixtures of Gaussians and its subclasses. Some techniques in density estimation

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