It will take an unprecedented reduction in China’s emissions per head to stave off severe warming

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T-EDGE: Temporal WEighted MultiDiGraph Embedding for Ethereum Transaction Network Analysis

Power of the Few: Analyzing the Impact of Influential Users in Collaborative Recommender Systems

Clustered Multitask Nonnegative Matrix Factorization for Spectral Unmixing of Hyperspectral Data

Control Theory Meets POMDPs: A Hybrid Systems Approach

Be Your Own Teacher: Improve the Performance of Convolutional Neural Networks via Self Distillation

The Unexpected Unexpected and the Expected Unexpected: How People’s Conception of the Unexpected is Not That Unexpected

Graph Mining Meets Crowdsourcing: Extracting Experts for Answer Aggregation

Arena: A General Evaluation Platform and Building Toolkit for Multi-Agent Intelligence

Alpha MAML: Adaptive Model-Agnostic Meta-Learning

A Fast and Scalable Implementation Method for Competing Risks Data with the R Package fastcmprsk

AutoDispNet: Improving Disparity Estimation with AutoML

Shortest Path Algorithms between Theory and Practice

Utilizing graph algorithms is a common activity in computer science. Algorithms that perform computations on large graphs are not always efficient. This work investigates the Single-Source Shortest Path (SSSP) problem, which is considered to be one of the most important and most studied graph problems. This thesis contains a review of the SSSP problem in both theory and practice. In addition, it discusses a new single-source shortest-path algorithm that achieves the same time bound as the traditional Bellman-Ford-Moore algorithm but outperforms it and other state-of-the-art algorithms in practice. The work is comprised of three parts. The first discusses some basic shortest-path and negative-cycle-detection algorithms in literature from the theoretical and practical point of view. The second contains a discussion of a new algorithm for the single-source shortest-path problem that outperforms most state-of-the-art algorithms for several well-known families of graphs. The main idea behind the proposed algorithm is to select the fewest most-effective vertices to scan. We also propose a discussion of correctness, termination, and the proof of the worst-case time bound of the proposed algorithm. This section also suggests two different implementations for the proposed algorithm, the first runs faster while the second performs a fewer number of operations. Finally, an extensive computational study of the different shortest paths algorithms is conducted. The results are proposed using a new evaluation metric for shortest-path algorithms. A discussion of outcomes, strengths, and weaknesses of the various shortest path algorithms are also included in this work.

Graph-based Semi-Supervised & Active Learning for Edge Flows

Neural Metric Learning for Fast End-to-End Relation Extraction

Relation extraction (RE) is an indispensable information extraction task in several disciplines. RE models typically assume that named entity recognition (NER) is already performed in a previous step by another independent model. Several recent efforts, under the theme of end-to-end RE, seek to exploit inter-task correlations by modeling both NER and RE tasks jointly. Earlier work in this area commonly reduces the task to a table-filling problem wherein an additional expensive decoding step involving beam search is applied to obtain globally consistent cell labels. In efforts that do not employ table-filling, global optimization in the form of CRFs with Viterbi decoding for the NER component is still necessary for competitive performance. We introduce a novel neural architecture utilizing the table structure, based on repeated applications of 2D convolutions for pooling local dependency and metric-based features, without the need for global optimization. We validate our model on the ADE and CoNLL04 datasets for end-to-end RE and demonstrate gain (in F-score) over prior best results with training and testing times that are nearly four times faster — the latter highly advantageous for time-sensitive end user applications.

Multilinear Compressive Learning

Sequential training algorithm for neural networks

Enforcing constraints for time series prediction in supervised, unsupervised and reinforcement learning

Story Ending Prediction by Transferable BERT

Cross-referencing using Fine-grained Topic Modeling

Multinomial Distribution Learning for Effective Neural Architecture Search

Architectures obtained by Neural Architecture Search (NAS) have achieved highly competitive performance in various computer vision tasks. However, the prohibitive computation demand of forward-backward propagation in deep neural networks and searching algorithms makes it difficult to apply NAS in practice. In this paper, we propose a Multinomial Distribution Learning for extremely effective NAS, which considers the search space as a joint multinomial distribution, i.e., the operation between two nodes is sampled from this distribution, and the optimal network structure is obtained by the operations with the most likely probability in this distribution. Therefore, NAS can be transformed to a multinomial distribution learning problem, i.e., the distribution is optimized to have high expectation of the performance. Besides, a hypothesis that the performance ranking is consistent in every training epoch is proposed and demonstrated to further accelerate the learning process. Experiments on CIFAR-10 and ImageNet demonstrate the effectiveness of our method. On CIFAR-10, the structure searched by our method achieves 2.4\% test error, while being 6.0 (only 4 GPU hours on GTX1080Ti) faster compared with state-of-the-art NAS algorithms. On ImageNet, our model achieves 75.2\% top-1 accuracy under MobileNet settings (MobileNet V1/V2), while being 1.2 faster with measured GPU latency. Test code is available at https://…/MDENAS

Factor Models for High-Dimensional Tensor Time Series

Massively Parallel Computation via Remote Memory Access

We introduce the Adaptive Massively Parallel Computation (AMPC) model, which is an extension of the Massively Parallel Computation (MPC) model. At a high level, the AMPC model strengthens the MPC model by storing all messages sent within a round in a distributed data store. In the following round, all machines are provided with random read access to the data store, subject to the same constraints on the total amount of communication as in the MPC model. Our model is inspired by the previous empirical studies of distributed graph algorithms using MapReduce and a distributed hash table service. This extension allows us to give new graph algorithms with much lower round complexities compared to the best known solutions in the MPC model. In particular, in the AMPC model we show how to solve maximal independent set in rounds and connectivity/minimum spanning tree in rounds both using space per machine for constant . In the same memory regime for MPC, the best known algorithms for these problems require polylog rounds. Our results imply that the 2-Cycle conjecture, which is widely believed to hold in the MPC model, does not hold in the AMPC model.

Which Tasks Should Be Learned Together in Multi-task Learning?

Gradient tree boosting with random output projections for multi-label classification and multi-output regression

RaFM: Rank-Aware Factorization Machines

The Curious Case of Machine Learning In Malware Detection

Microblog Hashtag Generation via Encoding Conversation Contexts

Semantic flow in language networks

Evolving Rewards to Automate Reinforcement Learning

A Case Study: Exploiting Neural Machine Translation to Translate CUDA to OpenCL

Quantifying Robotic Swarm Coverage

On Selecting Stable Predictors in Time Series Models

Regions In a Linked Dataset For Change Detection

Things You May Not Know About Adversarial Example: A Black-box Adversarial Image Attack

Learning to Memorize in Neural Task-Oriented Dialogue Systems

DivGraphPointer: A Graph Pointer Network for Extracting Diverse Keyphrases

Structured Summarization of Academic Publications

Explaining Machine Learning Classifiers through Diverse Counterfactual Explanations

An Objective Evaluation Metric for image fusion based on Del Operator

Earlier Attention? Aspect-Aware LSTM for Aspect Sentiment Analysis

Butterfly: Robust One-step Approach towards Wildly-unsupervised Domain Adaptation

Reinforcement Learning for Learning of Dynamical Systems in Uncertain Environment: a Tutorial

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Information-driven bars for financial machine learning: imbalance bars

recorder: Validate Predictors in New Data

Becoming a machine learning company means investing in foundational technologies

Microsoft wants to apply AI ‘to the entire application developer lifecycle’

The human problem of AI

Computational Socioeconomics

Practical Strategies to Handle Missing Values

Writing Quotes like Aristotle with Recurrent Neural Networks

Stock Market Analysis Using ARIMA

A New Way to look at GANs

Enabling Cognitive Visual Question Answering

Creative Artificial Intelligence… Towards New Horizons

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Creators of podcast Running from Cops watched 846 episodes and compared the numbers they found with national crime figures

Reality TV can fail to live up to its name, conveying a version of the world that is a sidestep from the truth. And Cops was a show that was crucial to the genre – it’s not only the longest-running reality show in history, it’s also one of the first.

A new podcast, Running from Cops, explores how the TV show helped to shape the same criminal justice system that it depicted. Dan Taberski tracks down some of the people whose crimes and arrests were broadcast for all to see and uncovers how the show was made.

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Computational Methods for Numerical Analysis with R is an overview of traditional numerical analysis topics presented using R. This guide shows how common functions from linear algebra, interpolation, numerical integration, optimization, and differential equations can be implemented in pure R code. Every algorithm described is given with a complete function implementation in R, along with examples to demonstrate the function and its use. Computational Methods for Numerical Analysis with R is intended for those who already know R, but are interested in learning more about how the underlying algorithms work. As such, it is suitable for statisticians, economists, and engineers, and others with a computational and numerical background.

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Computing General Equilibrium (CGE)
Developing general equilibrium models, computing general equilibrium and simulating economic dynamics with structural dynamic models in LI (2019, ISBN: …

C Resource Cleanup via Exit Handlers (cleancall)
Wrapper of .Call() that runs exit handlers to clean up C resources. Helps managing C (non-R) resources while using the R API.

Basket Trial Analysis (basket)
Implementation of multisource exchangeability models for Bayesian analyses of prespecified subgroups arising in the context of basket trial design and …

Identifiability of Linear Structural Equation Models (SEMID)
Provides routines to check identifiability or non-identifiability of linear structural equation models as described in Drton, Foygel, and Sullivant (20 …

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The vast quantity of information brought by big data as well as the evolving computer hardware encourages success stories in the machine learning community. In the meanwhile, it poses challenges for the Gaussian process (GP), a well-known non-parametric and interpretable Bayesian model, which suffers from cubic complexity to training size. To improve the scalability while retaining the desirable prediction quality, a variety of scalable GPs have been presented. But they have not yet been comprehensively reviewed and discussed in a unifying way in order to be well understood by both academia and industry. To this end, this paper devotes to reviewing state-of-the-art scalable GPs involving two main categories: global approximations which distillate the entire data and local approximations which divide the data for subspace learning. Particularly, for global approximations, we mainly focus on sparse approximations comprising prior approximations which modify the prior but perform exact inference, and posterior approximations which retain exact prior but perform approximate inference; for local approximations, we highlight the mixture/product of experts that conducts model averaging from multiple local experts to boost predictions. To present a complete review, recent advances for improving the scalability and model capability of scalable GPs are reviewed. Finally, the extensions and open issues regarding the implementation of scalable GPs in various scenarios are reviewed and discussed to inspire novel ideas for future research avenues. When Gaussian Process Meets Big Data: A Review of Scalable GPs

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“Maturity is the capacity to endure uncertainty.” John Finley

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EENA: Efficient Evolution of Neural Architecture

Fairness in Machine Learning with Tractable Models

Knowledge-Based Sequential Decision-Making Under Uncertainty

Vector Field Neural Networks

Non-negative matrix factorization based on generalized dual divergence

Model interpretation through lower-dimensional posterior summarization

Online Multivariate Anomaly Detection and Localization for High-dimensional Settings

Simple Black-box Adversarial Attacks

FlexNGIA: A Flexible Internet Architecture for the Next-Generation Tactile Internet

An Essay on Optimization Mystery of Deep Learning

Reference-Based Sequence Classification

Spectral Metric for Dataset Complexity Assessment

Stochastically Dominant Distributional Reinforcement Learning

DeepSwarm: Optimising Convolutional Neural Networks using Swarm Intelligence

Recurrent Kalman Networks: Factorized Inference in High-Dimensional Deep Feature Spaces

Cleaned Similarity for Better Memory-Based Recommenders

AM-LFS: AutoML for Loss Function Search

Merging versus Ensembling in Multi-Study Machine Learning: Theoretical Insight from Random Effects

POPQORN: Quantifying Robustness of Recurrent Neural Networks

The vulnerability to adversarial attacks has been a critical issue for deep neural networks. Addressing this issue requires a reliable way to evaluate the robustness of a network. Recently, several methods have been developed to compute for neural networks, namely, certified lower bounds of the minimum adversarial perturbation. Such methods, however, were devised for feed-forward networks, e.g. multi-layer perceptron or convolutional networks. It remains an open problem to quantify robustness for recurrent networks, especially LSTM and GRU. For such networks, there exist additional challenges in computing the robustness quantification, such as handling the inputs at multiple steps and the interaction between gates and states. In this work, we propose (ropagated-utut uantified Rbustness for Ns), a general algorithm to quantify robustness of RNNs, including vanilla RNNs, LSTMs, and GRUs. We demonstrate its effectiveness on different network architectures and show that the robustness quantification on individual steps can lead to new insights.

Online Distributed Estimation of Principal Eigenspaces

Principal components analysis (PCA) is a widely used dimension reduction technique with an extensive range of applications. In this paper, an online distributed algorithm is proposed for recovering the principal eigenspaces. We further establish its rate of convergence and show how it relates to the number of nodes employed in the distributed computation, the effective rank of the data matrix under consideration, and the gap in the spectrum of the underlying population covariance matrix. The proposed algorithm is illustrated on low-rank approximation and -means clustering tasks. The numerical results show a substantial computational speed-up vis-a-vis standard distributed PCA algorithms, without compromising learning accuracy.

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My colleague Wayne Thompson has written a series of blogs about machine learning best practices. In this series' fifth post, Autotune models to avoid local minimum breakdowns, Wayne discusses two autotune methods, grid search and Bayesian optimization. According to another colleague’s paper, Automated Hyperparameter Tuning for Effective Machine Learning, Bayesian optimization is currently popular for hyperparameter optimization. Recently, I read a post on Github which demonstrated the Bayesian optimization procedure through a great demo using Python, and I wondered if I could build the same with the SAS matrix language, SAS/IML. In this article, I will show you how Bayesian optimization works through this simple demo.

Revisit Bayesian optimization

Bayesian optimization builds a surrogate model for the black-box function between hyperparameters and the objective function based on the observations and uses an acquisition function to select the next hyperparameter.

1. Surrogate model

Functions between hyperparameters and objective function are often black-box functions, and Gaussian Process regression models are popular because of its capability to fit black-box functions with limited observations. More details about Gaussian Process regression, please refer to the book Gaussian Processes for Machine Learning.

2. Acquisition function and Location Propose function

The acquisition function evaluates points in the search space and the location propose function finds points which will likely lead to maximum improvement and are worth trying. The acquisition function trades off exploitation and exploration. Exploitation selects points having high objective predictions, while exploration selects points having high variance. There are several acquisition functions, and I used expected improvement, which is the same as in the GitHub post that I'm modeling.

3. Sequential optimization procedure

Bayesian optimization is a sequential optimization procedure. The algorithm follows:

For t=1, 2, ... do

• Find the next sampling point by optimizing the acquisition function over the Gaussian Process (GP).
• Obtain a possibly noisy sample from the objective function.
• Add the sample to the previous samples and update the GP.

end for

Implementation with SAS/IML

1. Gaussian Process Regression

In the code, the SAS macro gpRegression is used to fit a Gaussian Process regression model through maximizing the marginal likelihood. More details, please read chapter 5 of Gaussian Processes for Machine Learning.

2. Bayesian optimization

The SAS macro bayesianOptimization includes two functions: the acquisition function and location propose function.

3. Visualization

Finally, the macro plotAll shows you the step-by-step optimization procedure visually.

The code for these macros and following demo codes are available on my GitHub project.

Demo implementation with SAS/IML

proc iml;
   %gpRegression;
   %bayesianOptimization;  
 
   * Target function;
   start f(X, noise=0);
       return (-sin(3*X) - X##2 + 0.7*X + noise * randfun(nrow(X), "Normal"));
   finish;   
 
   * Search space of sampling points;
   X = T(do(-1, 1.99, 0.01));
   call randseed(123);
   Y = f(X, 0);   
 
   * Initialize samples;
   X_train ={-0.9, 1.1};
   noise = 0.2;
   Y_train = f(X_train, noise);  
 
   * Initial parameters of GP regression model;
   gprParms = {1 1 0};
 
   * Max iterations for sequential Bayesian Optimization;
   n_iter = 15;
   do i=1 to n_iter;
      * Update Gaussian process with existing samples;
      gprParms = gprFit(gprParms);
 
      * Obtain next sampling point from the acquisition function (acquisition);
      proposeResults = proposeLocation(X, X_train, Y_train, gprParms);
      X_next = proposeResults$"max_x";
      if X_next=. then leave;
 
      * Obtain next noisy sample from the objective function;
      Y_next = f(X_next, noise);
 
      * Add sample to previous samples;
      X_train = X_train//X_next;
      Y_train = Y_train//Y_next;  
 
      * Save all proposed sampling points into a matrix;
      allProposed = allProposed//(j(1, 1, i)||X_next);
   end;
 
   * Save all proposed sampling points into a SAS dataset;
   create allProposed from allProposed [colname={"Iteration" "X"}];
   append from allProposed;
   close allProposed;
run;
quit;

Visualize the step-by-step Bayesian optimization procedure

Figure 1: Target function and initial two samples.

Figure 2: Proposed location and acquisition function plot of the first two iterations.

Let's skip to the last two iterations.

Figure 3: Proposed location and acquisition function plot of the last two iterations.

To demonstrate the whole procedure visually, I created an animation file.

Figure 4: Animation of the step-by-step optimization.

The following two plots show the convergence trend along with iterations. The left plot displays distance between consecutive proposed points by iteration, and starting from iteration 9, the distance is close to zero. The right plot shows the value of the best selected sample, and starting from iteration 8, the values almost didn’t change.

Figure 5: Distance between consecutive proposed points by iteration.

The full code is available at Github.

The post Bayesian optimization in SAS appeared first on The SAS Data Science Blog.

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Porcellio Scaber Algorithm (PSA)
Bio-inspired algorithms have received a significant amount of attention in both academic and engineering societies. In this paper, based on the observation of two major survival rules of a species of woodlice, i.e., porcellio scaber, we design and propose an algorithm called the porcellio scaber algorithm (PSA) for solving optimization problems, including differentiable and non-differential ones as well as the case with local optimums. Numerical results based on benchmark problems are presented to validate the efficacy of PSA. …

GeoSay
Automatic extraction of buildings in remote sensing images is an important but challenging task and finds many applications in different fields such as urban planning, navigation and so on. This paper addresses the problem of buildings extraction in very high-spatial-resolution (VHSR) remote sensing (RS) images, whose spatial resolution is often up to half meters and provides rich information about buildings. Based on the observation that buildings in VHSR-RS images are always more distinguishable in geometry than in texture or spectral domain, this paper proposes a geometric building index (GBI) for accurate building extraction, by computing the geometric saliency from VHSR-RS images. More precisely, given an image, the geometric saliency is derived from a mid-level geometric representations based on meaningful junctions that can locally describe geometrical structures of images. The resulting GBI is finally measured by integrating the derived geometric saliency of buildings. Experiments on three public and commonly used datasets demonstrate that the proposed GBI achieves the state-of-the-art performance and shows impressive generalization capability. Additionally, GBI preserves both the exact position and accurate shape of single buildings compared to existing methods. …

Frequent Pattern Mining
The problem of frequent pattern mining is that of finding relationships among the items in a database. The problem can be stated as follows. Given a database D with transactions T1 … TN, determine all patterns P that are present in at least a fraction s of the transactions. The fraction s is referred to as the minimum support. The parameter s can be expressed either as an absolute number, or as a fraction of the total number of transactions in the database. Each transaction Ti can be considered a sparse binary vector, or as a set of discrete values representing the identifiers of the binary attributes that are instantiated to the value of 1. The problem was originally proposed in the context of market basket data in order to find frequent groups of items that are bought together. Thus, in this scenario, each attribute corresponds to an item in a superstore, and the binary value represents whether or not it is present in the transaction. Because the problem was originally proposed, it has been applied to numerous other applications in the context of data mining,Web log mining, sequential pattern mining, and software bug analysis. …

Random KNN Feature Selection (RKNN-FS)
We present RKNN-FS, an innovative feature selection procedure for ‘small n, large p problems.’ RKNN-FS is based on Random KNN (RKNN), a novel generalization of traditional nearest-neighbor modeling. RKNN consists of an ensemble of base k-nearest neighbor models, each constructed from a random subset of the input variables. To rank the importance of the variables, we define a criterion on the RKNN framework, using the notion of support. A two-stage backward model selection method is then developed based on this criterion. Empirical results on microarray data sets with thousands of variables and relatively few samples show that RKNN-FS is an effective feature selection approach for high-dimensional data. RKNN is similar to Random Forests in terms of classification accuracy without feature selection. However, RKNN provides much better classification accuracy than RF when each method incorporates a feature-selection step. Our results show that RKNN is significantly more stable and more robust than Random Forests for feature selection when the input data are noisy and/or unbalanced. Further, RKNN-FS is much faster than the Random Forests feature selection method (RF-FS), especially for large scale problems, involving thousands of variables and multiple classes. …

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Transparency in Maintenance of Recruitment Chatbots

Edge-Assisted Hierarchical Federated Learning with Non-IID Data

Deep Compressed Sensing

BrainTorrent: A Peer-to-Peer Environment for Decentralized Federated Learning

Stability of Linear Structural Equation Models of Causal Inference

We consider the numerical stability of the parameter recovery problem in Linear Structural Equation Model () of causal inference. A long line of work starting from Wright (1920) has focused on understanding which sub-classes of allow for efficient parameter recovery. Despite decades of study, this question is not yet fully resolved. The goal of this paper is complementary to this line of work; we want to understand the stability of the recovery problem in the cases when efficient recovery is possible. Numerical stability of Pearl’s notion of causality was first studied in Schulman and Srivastava (2016) using the concept of condition number where they provide ill-conditioned examples. In this work, we provide a condition number analysis for the . First we prove that under a sufficient condition, for a certain sub-class of that are \emph{bow-free} (Brito and Pearl (2002)), the parameter recovery is stable. We further prove that \emph{randomly} chosen input parameters for this family satisfy the condition with a substantial probability. Hence for this family, on a large subset of parameter space, recovery is numerically stable. Next we construct an example of on four vertices with \emph{unbounded} condition number. We then corroborate our theoretical findings via simulations as well as real-world experiments for a sociology application. Finally, we provide a general heuristic for estimating the condition number of any instance.

AlgoNet: $C^\infty$ Smooth Algorithmic Neural Networks

Deep Learning for Multi-Scale Changepoint Detection in Multivariate Time Series

How Case Based Reasoning Explained Neural Networks: An XAI Survey of Post-Hoc Explanation-by-Example in ANN-CBR Twins

Contrastive Fairness in Machine Learning

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I’ve started growing yeast in my closet-turned-laboratory. There’s a reason why I am growing yeast, but that’ll be for another post. For this experiment, I wanted to use my new hemocytometer to do cell counts periodically over the next few days to gather data.

A nutrient-rich bioreactor (an Erlenmeyer flask with wort) was left at room temperature with plenty of aeration (a magnetic stirrer) for about 2.5 days. My collected data is below.

| hour | cell count |
|------|------------|
| 0    | 20         |
| 12.5 | 21         |
| 17.5 | 28         |
| 23   | 34         |
| 36.5 | 34         |
| 42.5 | 31         |
| 48   | 32         |
| 65   | 32         |

Modelling

As I mentioned in my previous post, counting cells is a very noisy process, so we want to keep that in mind as we analysis this data. We have two options to proceed:

1. Assume each sample is independent, and run the same Bayesian model outlined in the previous article on each observed count, and plot the posterior distributions over time. This has the advantage of not assuming any parametric form of growth, but it has the serious disadvantage of not pooling any of the information (i.e. information at time 23 is very relevant to inference at time 17.5 and 36.5).
2. Assume some parametric growth model with unknown parameters, and fit to these parameters.

I like option two, as it’s more of a challenge, and it can be used for interpolation within the data points and extrapolation outside of the observed data points.

Typically microorganism growth after inoculation has 3 phases: lag-phase, log-phase and stationary phase. The lag-phase is a period where the organisms become accustomed to their new environment, and have low reproduction. The log-phase is a poorly-named phase that represents the period of high (exponential) reproduction. Finally, after the medium has been depleted or the organism concentration has become too high, the organisms stop reproducing and they enter the stationary phase. This type of growth looks a lot like logistic growth, so let’s use that model:

$$(\text{yeast/mL})_t = P_0 + \frac{K}{1 + \exp(-r\cdot(t - \delta))}$$

The lag-phase is modeled by the \(\delta\) parameter - the larger this is, the longer the lag-phase went on for. From sources, the lag-phase usually lasts less than 24h. Given my initial bioreactor conditions, a lookup table suggests I should see about 50% growth. Furthermore, using the volume of the medium and the estimated concentration of my inoculate, I have an estimate for my initial concentration. All these give me priors for my estimates.

Inference

We can model this in PyMC3 like so (this is modified code from my previous yeast-counting blog article).

import pymc3 as pm

MILLION = 1e6
TOTAL_SQUARES = 25
SQUARES_COUNTED = 4

yeast_counted =    np.array([20, 21,   28,   34, 34,   31,   32, 32])
hours_since_inoc = np.array([0,  12.5, 17.5, 23, 36.5, 42.5, 48, 65])
n_obs = yeast_counted.shape[0]


def logistic(t, K, r, delta_t):
    return K / (1 + np.exp(-r * (t - delta_t)))


with pm.Model() as model:

    K = pm.Normal("K", mu=50 * MILLION, sd=25 * MILLION) # about 50% growth was expected
    P0 = pm.Normal("P0", mu=100 * MILLION, sd=25 * MILLION)
    r = pm.Exponential("r", lam=2.5)
    delta_t = pm.Uniform("delta_t", lower=0, upper=24) # lag phase stops in the first 24 hours

    yeast_conc = P0 + logistic(hours_since_inoc, K, r, delta_t)

    shaker1_volume = pm.Normal("shaker1 volume (mL)", mu=9.0, sigma=0.05, shape=n_obs)
    shaker2_volume = pm.Normal("shaker2 volume (mL)", mu=9.0, sigma=0.05, shape=n_obs)

    yeast_slurry_volume = pm.Normal("initial yeast slurry volume (mL)", mu=1.0, sigma=0.01, shape=n_obs)
    shaker1_to_shaker2_volume =    pm.Normal("shaker1 to shaker2 (mL)", mu=1.0, sigma=0.01, shape=n_obs)

    dilution_shaker1 = pm.Deterministic("dilution_shaker1", yeast_slurry_volume  / (yeast_slurry_volume + shaker1_volume))
    final_dilution_factor = pm.Deterministic("dilution_shaker2", dilution_shaker1 * shaker1_to_shaker2_volume / (shaker1_to_shaker2_volume + shaker2_volume))

    volume_of_chamber = pm.Gamma("volume of chamber (mL)", mu=0.0001, sd=0.0001 / 20)

    # why is Poisson justified? in my final shaker, I have yeast_conc * final_dilution_factor * shaker2_volume number of yeast
    # I remove volume_of_chamber / shaker2_volume fraction of them, hence it's a binomial with very high count, and very low probability.
    yeast_visible = pm.Poisson("cells in visible portion", mu=yeast_conc * final_dilution_factor * volume_of_chamber, shape=n_obs)

    number_of_counted_cells = pm.Binomial("number of counted cells", yeast_visible, SQUARES_COUNTED/TOTAL_SQUARES, observed=yeast_counted, shape=n_obs)

    trace = pm.sample(2000, tune=20000)

We are mostly interested in our posteriors for the parameters of the growth model.

Actually, that’s not true: we aren’t really interested in the parameters. Most don’t have an easy interpretation (except for delta_t). What we are really interested in is the posterior of the growth curve. Recall this is a distribution. To demonstrate this, we can sample from the parameters’ posteriors and drop those values into the growth curve. For example, if we sampled 4 times:

Each of these curves look very different, which should give us pause when we make inference about our growth. What happens if we keep sampling growth curves, and then average over all of them - what does that curve look like? What about the error bars on that? This is easy to do (and part of the reason I appreciate Bayesian computation). On the same graph, I’m also going to plot hundreds of potential realizations, as it’s important not to get too focused on the mean as being the “truth” - there is still lots of variation!

Lovely. We can see an estimate for our initial concentration was about 122M ± 18M yeast/mL, and our final concentration was about 191M ± 15M yeast/mL. Eyeballing, the lag phase stopped just prior to 8h (though we need to reconcile this with the posterior mean of the delta_t is 13.5).

What was our estimated yield? I mentioned previously that 50% is expected - how did we do? This computation is also easy in Bayesian inference, we just look at the distribution of the ratio of yeast/mL at time 60 over yeast/mL at time 0. Doing this, the average value of this distribution is 59%.

Conclusion

This was a fun little experiment to mix statistics and biology. Further extensions include adding covariates, and modeling death of cells too (there is a finite amount of energy in the medium, so this should happen eventually). For now, however, I’m washing the yeast and eventually going to dehydrate them.

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A sampling of the submissions received this month

This month, we explored the concept of artisanal data: a dataset collected entirely on your own—electronically, manually, via surveys, or by observation. Guest author Mike Cisneros challenged us to analyze and find the conclusions that we can have full confidence in because we are the true stewards of the data.  

Fifty-three readers submitted their bespoke visualizations. Accountability was a recurring theme: many commented that their intent was to hold themselves responsible to achieving a goal—or that this exercise enlightened them to begin doing so. Not surprisingly, as a result of this hot topics included exercise, weight loss, and spending. It was neat to see the range—both in approaches and tools—that readers applied when creating their visualizations and we encourage you to scroll through the entire post to be inspired by how your peers collected, analyzed and were influenced by their unique datasets.

When reflecting on the submissions, Mike observed the thoughtful considerations participants applied:

“There are many lessons to be gleaned here; not only from the data you chose to collect and the way in which you presented it, but also from the issues and considerations raised in the process. In setting out the challenge to collect your own data this month, I had worried that it might be too burdensome for people; thankfully, dozens of you proved me wrong, and I thank all of you for your efforts.”

Scroll through the entire post to see further commentary from Mike with examples of these underlying themes: data can be humanizing (Andre and Alyssa), visual metaphors can be evocative (Hilje, Kate and Tiffany) and individual experiences can be universal (Julia and Penola).

Other standout entries include Colin and Lotte, who applied an effective takeaway title to their exercise trends while Liz selected clean, uncluttered charts to highlight trends in her personal hobby, reading. Jared took a trip down memory lane with a cool visual timeline of his evolving professional development and soft skills while Lance employed annotations with categorization to visualize the length of names in his family. Several readers discovered something perhaps previously unknown: Haley realized the effect of Amazon Prime on her spending habits, Rebekah validated how she’s been occupying her time post-grad school, Tania discovered the impact of clicking on Gmail ads, and Pris evaluated consistency in implementing her New Year’s resolution.

As an added bonus, Cole highlighted the benefit of having guest author this month: she was able to participate! Her submission provided a peek into the labor-intensive process of writing her second book— storytelling with data: let’s practice!—which will be published soon.

To everyone who submitted examples: THANK YOU for taking the time to create and share your work! The submissions are posted below in alphabetical order. If you tweeted or thought you submitted one but don't see it here, upload your submission as a .png here and we'll work to include any late entries this week (just a reminder that tweeting on its own isn't enough—we don't have time to scrape Twitter for entries.)

The next monthly challenge will launch on June 1st. Until then, check out the archives of previous month’s challenges on our #SWDchallenge page. Happy reading!

Adam

For this months #SWDChallenge I have pulled together my Work Train travel for 2019 up to the end of April. I travel quite a bit for my role as Snr Data & Viz officer and we generally are required to travel for product development meetings, team planning meetings, current project face to face meetings and team working days. Our core team is disparately located around the UK, meaning meet ups are not always quick commutes.
Interactive viz | Blog

Alexander

Interactive visualization of organic home garden productivity over time, including soil amendment and environmental effects. Total production by growing season & vegetable category is on top. Selected by filter, the lower graph displays individual vegetable yields with environmental input data. Future year iterations with sufficient historical data may include a yield forecast.
Interactive viz

Alyssa’s submission exemplifies how data can be humanizing. Mike notes “Alyssa’s submission hit on several key topics in data visualization: trust, both between collector and visualizer and trust in the accuracy of the observations; careful handling of personally-identifiable information (PII); the importance of not depicting subjective categories as having absolute values; and in being transparent about what data is not shown, as well as what is shown.”

Alyssa

I created this dataset from the narrative sleep log of an anonymous patient at the Counseling Center. They kept incredible detailed notes, and any uncertainty is reflected in the design (missing data, not putting precise labels on hours slept, etc). I feel incredibly lucky to have been trusted with this dataset and hope that the final product reflects one part of the way PTSD impacted the patient's life. A note on the design: the amounts of sleep designated as incapacitated/impaired/operational/rested are intentionally not labelled for three reasons. First, everyone's sleep needs are different, so the number of hours of sleep isn't as informative as the impact that sleep has on a person's life. Second, I want to avoid pissing contests over sleep deprivation ("wow, you consider THAT impaired? I haven't slept more than that in fifteen years," etc). Third, the number of hours of sleep in the log were rounded to the half hour, and according to the patient may have been off by 15-20 minutes since it's difficult to know the precise moment they fell asleep. Therefore, I would prefer to give a vaguer impression (low end of operational, high end of impaired, etc) rather than facilitate falsely precise estimates of the number of hours the patient slept.

The humanizing factor carries over to Andre’s submission. Mike notes, “Andre turned the challenge into an opportunity to combine his interests with his young son’s interests, allowing them to work together on a visualization they could both enjoy. While we hope, at times, to make human connections through the outputs of our data visualization process, Andre showed us that we can also strengthen human connections through its creation.”

Andre

My 5 year old son, Túlio, absolutely loves pokemon cards. He doesn't know yet all the rules but is fascinated by the cards' types, numbers, colors and powers. Since he spends A LOT OF TIME looking and analyzing each one of them, I thought it would be interesting to build a visualization showing all of his cards. After cataloging all 153 of them, we made a histogram and a bar plot with pencil and paper. Then I thought it would be a good idea to show the correlation between the cards's "attack damage" and "health points". I also used color to distinguish the card's "evolution stages". Túlio is really getting into data visualization and I am really getting into pokemon cards!

Anthony

This entry has the most personal data: my own blood pressure and heart rate. The motivation was to obtain a view over time of these data so that I could track trends and also to share it with my physician. The data was collected from the OMRON BP786N blood pressure monitor, and then recorded in a simple CSV file containing date, systolic pressure, diastolic pressure and heart rate. A script called "bpadd" records the data and then calls a decksh script to visualize and show the data.

Arthur

In my kitchen ceiling there is a slow onset water damage that seems to happen over time. The upstairs neighbor has no water near the floor that could be responsible for this. A contractor suggested it must be condensation build-up running down onto the celling, slowly causing this damage. I wanted to investigate this further and confirm that rain was not running down inside the walls to cause this damage. To this end, I built a crude moisture sensor using a couple transistors, resistors and two needles I could stick into the drywall. To this I attached an Arduino with a timer flash drive logger in order to measure the moisture over time. I then plotted precipitation on top of this moisture data using a JavaScript chart library to see if rain has anything to do with this. This data was collected from the Midwest in June, so it was hot outside. I believe the spikes visible in the chart correlate with the air conditioner removing moisture from the air and the sensor is measuring the moisture over the surface of the wall rather than internally. This was a fun project where data visualization helped me see that rain does lead to an overall increase in moisture within the drywall!

Ash

Starting in March 2019, I really got into data visualization (viz) and starting practicing with data viz community projects, like the #SWDchallenge. Practice fosters improvement and learning! This month’s #SWDchallenge involved collecting our own data, and I have been keeping my track of my weight. Here, we look at my 2019 weight with a focus on the time (before and) after I really got into data viz. It looks like some of my weight loss is correlated with my new found data viz enthusiasm!
LinkedIn

Bill

My family participates in an annual Thanksgiving Day 5K run, the Trinity Turkey Trot in Princeton NJ. I have an informal approach to getting in shape for this and other 5Ks, with mixed results. Peter Drucker says that “you can't manage what you can't measure.” With this adage in mind, I started tracking my workouts in late 2015. The free MapMyRun web site, sponsored by Under Armour, provides the tools I need. I draw each course I run on a road map of the area and store the course for future reference and comparison. By course and date, I record information on individual workouts: length, time, and number of steps. I also track time spent doing other types of exercise. MapMyRun calculates Average Pace per Mile. I was able to download my MapMyRun workout records to a .csv file. I then imported it into Excel, when my first assumption, “the data is clean”, was dashed. Date of workout was either in DD-MMM-YY format or a string “MMM. DD, YYYY”. Rather than exercising Excel functions or manually correcting rows, I imported the dataset to Tableau Public, which decoded the formatting, and set me up to use Tableau Public to build the chart. I kept Workout Types that were relevant to the analysis of my running, and discarded others. Average Pace per Mile values were generally reasonable. I discarded rows with zero or extremely large numbers. I anticipated that my running pace leading up to a race would impact my 5K race time. After looking at the data, I think that the number of workouts weeks before a race are also important. The chart itself took several iterations to get to where it adequately showed what I envisioned. Not perfect, but close enough.

Brent

This submission tracked all the expenses that I had for my cars from when I purchased my first car in July 2012 up to April 2019. This was the 3rd of 4 visualizations; starting with total overall expenses, then stripping out major expenses before getting to minor expense breakdown. It was eye opening to see how much I used to spend on gasoline and on maintenance!

Bryan

If you are often tired and then track your sleep but don't change any of your sleep habits, then mostly what you'll learn is that you aren't getting enough sleep (which you already knew because you are tired). I did find out that I tend to get a little more sleep on Thursday and Friday evenings, when I would have expected to get the most on the weekends. The missing days are when I went to bed but didn't put my fitness tracker on. (I only wear it at night to track my sleep.) I used the FitBit API and an R script to get the raw data. Tableau was what I used to create the visualization. You can hover over each day and see the waterfall of that night's sleep.
Interactive viz

Catherine

I wanted to evaluate my grocery expenses before and after signing up for the $5 Meal Plan service. It also occurred to me that other food expenses such as restaurants, fast food, coffee shops, etc. should be included since groceries could be substituted for eating out and vice versa. I pulled my dataset from Mint.com, after re-categorizing many transactions, and used Power BI to create the visualization.

Cole

One benefit of a guest #SWDchallenge is that I get to participate! My submission plots my progress over the past year writing my second book, storytelling with data: let's practice! General learnings: I write best when I travel and have a harder time concentrating at home (home days are better spent planning content or editing). I also write well from cafes: the background buzz puts me in my head in a way that works well for getting words out. Also: next time, I should collect better data if I want to make a graph—it would have been great to have other metrics, like word count, and also I found myself wishing for more frequent and consistent data points over time. This is only part of the picture: the book includes over 100 hands-on exercises and more than 250 visuals. I'm looking forward to sharing it with you and it should be available this fall!

Colin

I started wanting to know how many days I had walked 10,000 steps or more.  So I downloaded my fitbit data for the last 30 days. As I work some days and provide childcare on others as well as family days out, I spliced the data by weekday to see if there were any trends. I created a bar chart of average steps to show which days I was less likely to hit my 10k steps target. The line chart breaks this up to show that on two days I hit my target less often. But it also highlighted that on the other days there was a large variance between the number of steps counted. Analysing the data as aggregate bar charts and individual points on a line made me think about different ways I could improve my average step count. Looking back over my activity for April made me realize how varied my walking patterns were for each day of the month.
Blog

Crystal

This month's #SWDchallenge gave me the push to create something I've been wanting to visualize for a while now, a timeline of my dog's life. Next week he will be 15 years old!
Interactive | Twitter

Dennis

After reading the book Dear Data I started collecting some of my personal data with the purpose of visualising it later this year. With this months #SWDChallenge I had a great opportunity to start visualising one of these datasets. I decided to visualise the data about the cups of coffee I drink during the day.

Dmitrijs

Blog

Doug

I've tracked our home utility use for years as a means to monitor the efficiency of the heating system. Several years ago we replaced an old furnace, and I used this challenge to estimate the annual savings. While I knew the new furnace was saving us money, the annual savings was less than expected.

Elżbieta

I wanted to visualize my grocery shopping from last couple of months. Did I spend more every month? Did I place more orders? Simple curiosity!
Tableau

Frans

Earlier this year I used the Strava web connector to import my running data into Tableau. I was aiming to make a visual exploration on my running activities. Although I knew them quite well, I was wondering if a lot of difference would appear, for instance in intensity, location and length of the activities between 2017 and 2018. I think it did. I not just started more running in 2018, I also enlarged my running area. Especially by preparing for a big ultra run in Austria.

Gianni

Because of a health problem, for some months the only physical activity I can do is walk. To stimulate myself a little I use a heart rate monitor and these are the data from September to November 2018. I can select a date and see how much I walked that day, how long and the length of my stride.
Interactive viz | Blog

Haley

I downloaded my order history from Amazon and saw that I started ordering a lot more in 2016, the year I signed up for Amazon Prime. That caught my attention, so I pulled out some other data points that I found interesting too. This was created in Tableau.

Hanna

I use the library a lot and wanted to explore how many items I had on loan each day during 2018. The number of items went from 7 to 24 and I always had something on loan. Unfortunately I didn't have time to add annotation, but some things I can direct you to. Like March with the sun out and people enjoying the snowy and sunny season after the long dark polar night or the road trip we took in July.

Hilje’s submission demonstrates that visual metaphor can be evocative. Mike writes, “The design replicates the look and feel of a festival map. As she explains in her blog, the stories themselves are, in many cases, as interesting as (or more interesting than) the aggregated data. Her choices in what she chose to emphasize, and how, truly honor that consideration.”

Hilje

I collected data on the ultimate festival experience. You can read the entire story on my blog.

Jared

I initially wanted to created a timeline of well, something. After a bit of a brainstorm it hit me. I've recently been reflecting on past roles, and the skills I've been learning along the way, so why not visualize that?
Blog

Jason

For the May 2019 #SWDChallenge, we were challenged to work with a dataset that we have collected or created ourselves and use that data to create any type of chart we would like. I decided to create a visual profile of the content that I consume via Twitter and Podcasts. I would love to see a content profile on friends, family and the people I engage with online. Digital Marketers are already building this type of stuff into their algorithms, I'm sure. For my visualization, I decided to create a chart that is often used for population comparisons...a Population Pyramid. Although this isn't the type of data normally used in a Population Pyramid, I thought it was an effective way to represent the data. Hopefully you agree, but please reach out if you have feedback or suggestions.
Website

Joost

As a BI Consultant in the Netherlands, I travel a lot to my clients across the country. Ever since I started working as a consultant in 2014, I have been saving all the locations I visit in Google Maps. For this months #SWDChallenge I downloaded all these locations from Google Takeout and loaded them into Power BI. I visualized the result with a heatmap.

Julia’s submission shows us how individual experiences can be universal. Mike comments, “Julia used a technique that I always appreciate, which is to use real-life, universal comparisons that help audiences grasp the magnitude of certain things; in this case, comparing the length of yarn she has used for her knitting projects over the last six years to the distance between two cities in Europe.”

Julia

I was curious how my history of knitting projects summaries. I took my data from Ravelry and plotted it using R and gimp.
Link

Kate also shows us the power of a visual metaphor. Mike commented, “Kate’s animated coffee drinking viz also made use of an interesting visual metaphor, in the sense that she designed a radar chart that was reminiscent, in motion, of a coffee stain slowly spreading across a table. Sometimes these small touches make our work memorable in a way that a less-considered visual approach might not.”

Kate

I’d like to share an updated animated viz of all the coffee I drank in Italy while on vacation in February. I had fun trying to visualize this using a clock and learned some new animation tricks. You can watch my animation and read all about the “rules” of Italian coffee drinking and whether or not I followed these “rules” at my blog.

Kelly

In January 2019, I bought a pack of 14 colored bands for my Fitbit. I tracked the color I wore each day, wondering which would end up being the most-used. I actively tried to avoid wearing black or gray, but still wore those neutrals one out of every three days. The biggest surprise was pink at number two, because I rarely wear pink clothing or accessories! I realized that this particular pink is fairly close to my skin tone, so I was treating it as a neutral.

Lance

While it took me some time to settle on what data to use for this challenge when I settled on this topic I had a lot of fun putting it together (in Tableau). While the topic might be a little different I have complete confidence in the quality of the data and the conclusions it produced!

Lisa

This month’s #SWDChallenge by guest author, Mike Cisneros, inspired me to put to use a data sample I tracked in Observe, Collect, Draw: A Visual Journal. I visualized the data using a bar chart and added annotations and images to bring life to the chart.
Link

Liz

I chose to use my Goodreads data from this year for this challenge. This visualization went through a few iterations, so big thanks to my boss, Chris, for helping me refine it! I made this visualization with Tableau.
Website

Lotte

My entry could also have the subtitle “How not to train for a 10K run”. In the spring of ’18 I signed up for a 10K run in October. After the run, my hip started causing problems and I had to cut down on my exercise. I am down to running 3K and only slowly increasing the distance. Loads of people do 10K runs and I wondered why I couldn’t do the same without injuries. The chart clearly shows the steep increase in distance. It does not show that I also played with speed and altitude. Everything you’re not supposed to do at once. The chart also shows that when I started training for the run, I also skipped the visits to my rowing club, missing out on maintaining some big muscle groups. Since the data set is mine, I did a bit of manipulation with the data. April, for instance, showed that I had been out riding. I knew that was not true; I had simply chosen the wrong type of workout in my tracker and I changed it to rowing. I also changed an orienteering run in October to running for simplicity. I considered adding comments in the chart but chose to leave the space on the right-hand side empty and let the lack of exercise “do all the noise”.
A 5K run is coming up in June and I have learned my lesson… :-)

Maggie

I visualized Netflix activity data to for our Gilmore Girls watching trends in the Spring of 2019 using Excel. What I found was that the more we disliked a season, the more episodes we watched per day (quicker rate). So we like to SAVOR our favorites.

Markos

For my submission I used weight and nutrition data stored in MyFitnessPal. Particularly I wanted to explore any connection between an effort I have been making in reducing my carbohydrates and my long lasting goal of weight loss. The goal was to show if there was a visible correlation.

Max

Inspired by my university experience, I decided to do an introspection about my erratic (and often inadequate) sleep schedule. Doctors usually recommend between 7 and 9 hours of sleep. I used my sleep patterns from my Fitbit to visualize how I sleep. This helps me see where I can improve upon in terms of budgeting my daily schedule.

Mohit

It was my first freelancing SAP HANA implementation project which involved creation of new ABAP reports on SAP HANA system. As the project was critical for go-live, I worked on weekends too and sometimes extended for more than 9 hours per day. DECO report was an MIS report which was a mini project itself. My aim was to project the object which I worked upon and the time spent on it; for which the Gantt Chart was the perfect choice.

Patrick

Hi, when the description of this months challenge came up I knew exactly what topic I would use. The main love of my life (apart from wife and kids obviously) is exercise and in particular being outside. Out of interest in 2007 I started keeping very simple records of how much I did. When I look back on it now over 11 years, it's like a barometer of some of the main milestones and events in my life. I also use it to make sure I'm always at a certain level of exercise as I get older and busier with family and work.

Paul C

Number of steps and heartbeats per minute since purchasing my Smart Watch.

Paul T

I entered a 6 week fitness challenge and got a bit carried away. Lost 11kg in 6 weeks and had a lot of fun doing so (oddly).

Penola demonstrates how individual experiences can be universal. Mike notes, “I loved the way that Penola combined two numeric variables with a qualitative variable, because the story of her viz wasn’t in how a stock price fluctuated over time, but rather in how her friend reacted to those variables. The humble line chart, presented in this manner, conveyed emotion and connected with an audience through that universal recognition of hope, excitement, panic, sadness, and relief.”

Penola

I chose to use personal data of texts received from a friend investing in the stock market for the 1st time.  Being an dedicated & passionate vegan, she wanted to invest in the Beyond Meat IPO and show support.  Texts received from her were numerous - I did not include every detailed text - just those that highlighted her experience.  Approval was granted to use texts.

Petra

This was my first challenge, need to learn more about data viz.
Link 

Pris

My 2019 New Years Resolution was to become more consistent with my meditation. I collected my meditation data from the Headspace app to create a visualization showing my sessions completed and trends.

Rebekah

I used notes I leave on all the recipes I try in my cookbooks as the data for this challenge, creating a basic bar chart to show the number of new recipes I tried each month over a two year span. My hypothesis was the year post-grad school would have a significantly higher numbers per month compared to the year during grad school.
Link

Rodrigo

After suffering a TBI in January 2015 Alice's life changed forever and a intense routine of therapies is now her new normal. This visualization helps us to keep track of her claims with our health insurance plan.
Link

Ross

Four years ago my wife and I had our first child. I had a new job at Tableau and was baby in the data visualization world. We had a lot of challenges keeping track of when and who was feeding our baby. "There's got to be an app for that!" There was. We started logging everything and kept it up for the other two babies that came along. We had all this data and started to ask questions like, "when do we drop this nap?", "When do we go from 5 bottles a day to 4?". The App had some decent visualizations, good for looking at daily perspectives and none for comparing other kids. I exported the data as a csv and went to town.
Interactive viz

Samo

In this challenge, I looked into my effort of lowering my commute costs and how efficient are my changes.
interactive viz

Sandra

Kea is a pet parrot with a disease that has no cure, requires injections to manage symptoms, and requires careful weight monitoring. The data used are her weights recorded in 2019. I learned that the longer days (more vitamin D) have no obvious effect on her weight. House guests and the injections likely lead to a decrease in weight, but not always. I already knew she had stayed above the concern level of 540 grams. I used different colored and larger markers for the injection dates, to note her benchmark high weight, and for a special condition of multiple tornadoes in the area. The injections add to her stress, which can lead to weight loss; and the tornadoes were an unusual event that added to everyone's stress. Annotating the benchmark high weight added info and was helpful since that value is above the highest axis value shown. Since it's the only point above 565, eliminating the '570' value on the axis got rid of visual clutter. I used thicker orange lines to note when there were house guests, and thin gray lines otherwise. House guests can add to her stress, which leads to weight loss. I added annotations for context of the vertical axis, legend info, and for the horizontal line at 540 grams. I added title as an annotation to better control font size and color, and position. I used a white text box to cover up the legend of 535 on the vertical axis, which wasn't relevant but was needed to get the axis values that I wanted. I eliminated the horizontal axis and the grid lines on the vertical axis because they didn't add information. I intentionally started vertical axis values shown at the 'concern level' of 540 rather than lower values, such as 500 for the 'critical' level. Changes of 3 grams or more can be significant, especially if there are multiple days with decreases. The minor tick marks (hidden) are 1 gram changes. (Scale is accurate to 0.5 grams.) I explored eliminating markers for 'normal' days and decided to use very small markers of the same color as the connecting lines. Thought this added information without being visually intrusive. I tested printing in grayscale to make sure color choices did not lead to visual confusion on a non-color printer. Avoided red/green issue for colored markers.
Website

Seonaid

I chose to download my twitter archive for analysis... the initial impetus was that I noticed that I have been primarily retweeting recently, and I wondered what my patterns of use have been over the years that I have been using Twitter. The most interesting thing I saw was that since I tend to spend the summer outside, and often on the road, my August tweets are only about 2% of the total. I'm basically offline for the month of August, and this has apparently been consistent for the last 9 years.
Link

Simon

For this month’s challenge I attempted to learn a new technique in Tableau, a matrix style view.  Using made up data I built this. Happy with the outcome and with real data there may well be some worthwhile trends and stories to pick out in future versions.
Interactive viz

Sohini

This is an analysis on the groceries I have bought over time.
Interactive viz

Tania

Since I first saw Gmail ads, I have always insisted I would never be the kind of person to click on them due to how creepy they are. Now that I can easily get all my data from here, I thought I'd put this assumption to the test.

Tiffany demonstrates that visual metaphor can be evocative. Mike notes, “Tiffany’s tale of KonMari-ing her closet was presented in a manner that built slowly over time as the audience interacted with it, mimicking the way the piles would grow and be sorted in a real-life KonMari process.”

Tiffany

Interactive data viz best seen on desktop. The data collected was an inventory of the items in my closet and their resulting fate during a KonMari decluttering session. The data took some time to collect, making the decluttering even harder!
Blog

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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** Nuit Blanche is now on Twitter: @NuitBlog **

Dear Igor,
I'm a long-time fan of your blog and want to share our two recent NIPS papers with you. One is a theory paper on unfolding sparse recovery algorithms into deep networks (and a spotlight oral of NIPS'18); the other is an empirical exploration of applying orthogonality regularizations to training deep CNNs, with many techniques inspired by sparse optimization.
The first paper proves the theoretical linear convergence (as upper bound) of unfolded ISTA networks (LISTA), and proposes two new structures (weight and threshold) to facilitate that fast converegnce and significantly boost performance. The work is done in collaboration with Jialin Liu (http://www.math.ucla.edu/~liujl11/) and Wotao Yin (http://www.math.ucla.edu/~wotaoyin/) in Math@UCLA.
Preprint: https://arxiv.org/abs/1808.10038Github: https://github.com/xchen-tamu/linear-lista-cpss 

The second paper proposes several orthogonality regularizations on CNN weights, by penalizing the distance between the Gram matrix of weights and identity under different metrics. We show that orthogonality evidently accelerates and stabilizes the empirical training convergence, as well as improve as final accuracies. The mose powerful regularization was derived from Restrcited Isometry Property (RIP).

Preprint: https://arxiv.org/abs/1810.09102Github: https://github.com/nbansal90/Can-we-Gain-More-from-Orthogonality

It would be great if you could distribute their informtion to potential interested audience on nuit-blanche.
Best regards,
--
Xiaohan Chen
Dept. Computer Science & Engineering
Texas A&M University, College Station, TX, U.S.
Webpage: http://people.tamu.edu/~chernxh/

In recent years, unfolding iterative algorithms as neural networks has become an empirical success in solving sparse recovery problems. However, its theoretical understanding is still immature, which prevents us from fully utilizing the power of neural networks. In this work, we study unfolded ISTA (Iterative Shrinkage Thresholding Algorithm) for sparse signal recovery. We introduce a weight structure that is necessary for asymptotic convergence to the true sparse signal. With this structure, unfolded ISTA can attain a linear convergence, which is better than the sublinear convergence of ISTA/FISTA in general cases. Furthermore, we propose to incorporate thresholding in the network to perform support selection, which is easy to implement and able to boost the convergence rate both theoretically and empirically. Extensive simulations, including sparse vector recovery and a compressive sensing experiment on real image data, corroborate our theoretical results and demonstrate their practical usefulness. We have made our codes publicly available: this https URL.

This paper seeks to answer the question: as the (near-) orthogonality of weights is found to be a favorable property for training deep convolutional neural networks, how can we enforce it in more effective and easy-to-use ways? We develop novel orthogonality regularizations on training deep CNNs, utilizing various advanced analytical tools such as mutual coherence and restricted isometry property. These plug-and-play regularizations can be conveniently incorporated into training almost any CNN without extra hassle. We then benchmark their effects on state-of-the-art models: ResNet, WideResNet, and ResNeXt, on several most popular computer vision datasets: CIFAR-10, CIFAR-100, SVHN and ImageNet. We observe consistent performance gains after applying those proposed regularizations, in terms of both the final accuracies achieved, and faster and more stable convergences. We have made our codes and pre-trained models publicly available: this https URL.

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People misinterpret charts all of the time, because they go in with the wrong expectations before they even fully interpret what a chart is about. Read More

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Learn to experiment with R to make analyses and figures more reproducible

If you’re in the UK and not too far from York you might be interested in a Royal Society of Biology course which forms part of the Industry Skills Certificate. More details at this link

Introduction to Reproducible Analyses in R

24 June 2019 from 10:00 until 16:00

The course is aimed at researchers at all stages of their careers interested in experimenting with R to make their analyses and figures more reproducible.

No previous coding experience is assumed and you can work on your own laptop or use a computer at the training venue, the University of York.

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Facebook has undertaken a number of efforts to increase transparency and facilitate accountability and oversight by providing insight into our process for creating metrics that are meaningful and relevant both internally to our teams and externally to the broader community of people who use Facebook. To inform this process, we have a set of principles that govern how we think about metrics and analytics. The principles are grounded both in Facebook’s company values and in research principles on transparency and accountability.

We developed metrics to comport with these principles. But we also wanted to ensure we had meaningful input from experts who had studied transparency in the context of governance. This involved both exploring the existing range of academic research around data transparency specifically and governance models more generally, and building a formal process for seeking and incorporating expert feedback.

To ensure we could appropriately balance benefits and risks of transparency in creating valid and informative metrics, we established a formal process to solicit feedback and provide a public assessment of our metrics. We established the Data Transparency Advisory Group (DTAG), which comprises international experts in measurement, statistics, criminology, and governance, with the core function of providing an independent, public assessment of our Community Standards Enforcement Report (CSER) specifically and our measurement efforts related to content moderation more broadly.

Defining research-based criteria for data transparency

A long history of social science research has contributed to our understanding of the effects of transparency, including economic and political science research on the role of transparency in building effective and efficient governance (Stiglitz, 2000; Lindstedt and Naurin, 2010; Brunetti and Weder, 2003) and political philosophy and legal theory on the role of transparency and open deliberation in the civilizing effect on political behavior and generating procedural fairness (Cohn, White, and Sanders, 2000; Elster, 1998).

These bodies of research have been reviewed and applied to social media in several different contexts, notably in the Santa Clara Principles, a theory- and research-based set of recommendations for tech companies. Taken together, this social science and legal literature focuses on transparency as a key tool to ensure accountability and fairness in institutions charged with defining and enforcing rules and standards. We support the spirit of the Santa Clara Principles on Transparency and Accountability in Content Moderation and, informed by the DTAG report’s findings on the challenges of content moderation at scale, are committed to continuing to share more about how we enforce our Community Standards in the future.

At the same time, it is worth noting that transparency is not without its limitations and risks, especially when that transparency involves data and metrics. Karr (2008) summarizes three key concerns, typically associated with public use of government information, which also apply to the data that technology companies would release on content moderation:

• Addressing an inherent tension between the comprehensiveness of the data and the comprehensibility of information to individuals not intimately familiar with underlying processes.
• Managing the trade-off between providing appropriate levels of detail to ensure the data is useful while also ensuring there are appropriate protections for private or confidential information.
  • The risk of misinterpretation is higher for data based on information collected as part of operational processes. Often, these data are not structured in a way that purpose-built data sets (e.g., census data) are and thus can be difficult to interpret and face higher potential for misinterpretation. This issue often arises with crime enforcement statistics that are typically derived from police reports and court data used for individuals in these systems to execute their core functions rather than for measurement purposes.
  • This issue often arises with crime enforcement statistics that are often derived from police reports and court data used for individuals in these systems to execute their core functions rather than for measurement purposes.
• Some information that is valuable for transparency is also sensitive and/or dangerous to release publicly.

Drawing insights from this research on transparency, we developed metrics focused on two distinct but related components.

First, did the metric reflect how we think, prioritize, and assess ourselves internally? The reason for this criterion is that it allows external scrutiny and public assessment of the problem space and the outcomes of our efforts, which can enable accountability.

Second, does the metric allow insight into our processes or actions? Although aggregate counts are not sufficient to provide process insights, the metrics we release provide the information needed to understand the frequency and nature of actions we take and for others to judge for themselves whether those actions appear appropriate in the context of the overall problem space.

Approach to external assessment

Naturally, this process resulted in metrics that balanced some of the external requests and suggestions with the technical constraints and realities of enforcement at scale. The next part of the measurement process then related to whether the metrics we viewed as most relevant and operationally feasible were also metrics that met the objective of allowing insight and ultimately public accountability for our moderation processes. This is why we established the DTAG.

The DTAG was asked to answer this core question: Do the publicly available metrics provide accurate and meaningful measures of the problem area and Facebook’s activities to address it? It was not set up to audit Facebook’s data labeling, data use, or privacy protection practices. As such, the DTAG’s findings reflect its review of the processes and information provided to the group, but not unrestricted access to Facebook systems and processes. This approach helped balance the critical role of external review of our processes with protections for user privacy and complexities in the underlying data architecture that would have limited relevance for external analysts.

To support their assessment, Facebook provided the DTAG with detailed confidential information about how we develop our policies, how we detect violations of these policies at scale, and how we have developed measurement-specific processes to sample, label, and quantify violations of policies. These measurement processes were intended to create analytically rigorous data that would accurately capture the scale and scope of content violations on the platform for different types of violations.

The DTAG members were not given access to user data and did not audit the underlying data used to construct the metrics, but they were provided with more detailed breakdowns of the counts and inputs into the metrics. They also had access to the engineers and data scientists who designed and executed these metrics to answer questions or concerns and provide any requested details on how the metrics were developed.

The group reviewed, assessed, and provided feedback about our approach to measurement along two parallel tracks. First, we worked closely with the group to present our existing metrics, how and why we developed them, technical constraints, as well as best practices in how these metrics should be defined and calculated. This step was critical to bring a range of outside expertise directly into our analytic process — for technical statistical applications, but also to ensure these metrics would comport with best practices. We used their findings both to improve how we defined our metrics and to ensure the information we released alongside the numbers usefully informed readers about our processes and practices.

Second, the group was charged with providing an external report detailing our methods in the context of our processes to provide an external assessment of whether these metrics were in fact a reasonable approach to measuring violations of Facebook’s rules and standards. The DTAG was among the first set of external technical experts who were exposed to the scale and scope of Facebook’s measurement operation and then permitted to freely publish their independent assessment. They recently released their external report including these assessments and their overall recommendations.

This report was reviewed only to ensure no predefined confidential information was included. The findings and recommendations are those of the DTAG and represent an external perspective on the metrics and measures contained in the CSER specifically and Facebook’s efforts to conduct rigorous measurement on violations of its rules and standards more generally.

Summary of DTAG findings and recommendations

After a rigorous review, the DTAG found our processes reasonable and that our core metrics are consistent with best practices from other settings. In particular, the DTAG noted that with hundreds of thousands of pieces of content added every minute, the processes combining automated and human detection and review were appropriate. The findings thus also highlighted the inherent trade-offs and technical challenges that must be balanced in building an effective detection and enforcement regime at scale. The DTAG concluded that the metrics in the CSER were reasonable ways of measuring violations of our Community Standards and that they comport with the best practices that are most analogous to metrics of crime currently published by a number of different governmental agencies globally. For more detailed information on the DTAG findings, see this Newsroom post.

Based on its assessment, the DTAG also offered a number of suggestions that Facebook is now systematically reviewing and determining how best to address. The DTAG offered 15 recommendations in its report.

Table 1 below summarizes the DTAG recommendations and how Facebook is incorporating its feedback into our broader transparency and measurement efforts. Of the 15 recommendations:

• Five recommendations will be implemented in upcoming reports, briefings, or other settings.
• Six recommendations are being actively explored to determine how best to operationalize the suggestion.
• Four recommendations are being considered for alternative solutions, in the context of the underlying concerns or issues that the DTAG raised. The DTAG’s proposed approaches may not be feasible or optimal given other constraints.

DTAG recommendation #1: Release accuracy rates. Measuring accuracy is complex for a number of reasons. One of the major reasons in particular is that there is a range of “ambiguous” content — meaning specific kinds of text, images, or videos about which reasonable people might disagree when assessing whether these violate our Community Standards. Given this complexity, it can be difficult to define whether the content was “accurately” labeled and therefore establish standard measures of accuracy based on false positives, false negatives, and true positives, true negatives. To address this issue, we are working to refine our policies to reduce the content that is “ambiguous.” In practice though, given the range of topics and issues covered under the Community Standards, there will always be ambiguous content, and thus in parallel, we are exploring what could serve as a meaningful metric for accuracy that is robust to the inclusion (or exclusion) of ambiguous content.

DTAG recommendation #2: Release review-and-appeal rates and reversal rates separately from an accuracy metric. Facebook is planning to release metrics that capture the amount of content that is appealed and how much content it restores. These metrics will help provide transparency about additional aspects of the governance and moderation process distinct from the accuracy rates discussed above.

DTAG recommendation #3: Provide information about the percentage of posts that are actioned by automation and the percentage actioned by humans. Such a metric could help highlight that while Facebook may want to increase automatic detection of content that violates our standards, in many cases we may not want to increase automatic actions for specific violation types. We currently share the percent of content that is detected before anyone reports it, but humans then review some of this content. And how useful automation technology is in removing content varies. For instance, such actions might be more relevant for imagery depicting adult sexual activity rather than content that may be hate speech or harassment, which requires greater language and cultural context to assess. As a result, we agree it may be helpful in the future to more explicitly define automated detection versus automated actions along with their relative accuracy, and we will continue to explore ways to do this in a manner that is both meaningful and accurate.

DTAG recommendation #4: Check reviewers’ judgments not only against an internal “correct” interpretation of the Community Standards but also against users’ interpretations of the Community Standards. Although such comparisons are useful in some settings, we do not believe they represent meaningful measures against which Facebook would operate. This is because our internal research suggests users are often unaware or do not understand the Community Standards themselves or the processes by which they are applied. Moreover, when users report, the rates at which their reports can be actioned are very low. There are three possible reasons for these low rates: a lack of context on Facebook’s side that would illuminate what is wrong; a misunderstanding about how we apply our Community Standards; and sometimes, there is abusive mass reporting. Taken together, these findings show that Facebook should do more to help users understand the rules and inform their reporting. We have already begun some of this work and, in that context, will explore ways to more systematically research how users interpret these Community Standards in the broad range of cultural and regional settings in which our platforms are used.

DTAG recommendation #5: Report prevalence measures not only as a percentage of the total estimated number of views but also as a percentage of the total estimated number of posts. This was one of the most technically challenging suggestions, and we discussed it extensively with the DTAG. The idea was that we develop a violating content rate — that is, a measure of prevalence in which a unit of observation is an individual piece of content, and the measure is the fraction of all content that is violating. This rate would serve as a supplement to the current prevalence measure, which is based on views of content. So even though our current viewership-based prevalence metric is more of a “consumption metric” — indicating how much of violating content is (intentionally or not) consumed — the proposed content-based prevalence measure is a “production metric” — indicating the amount of violating content out of how much material exists on the platform. In discussions, we explored whether it was feasible to estimate the number of distinct posts that contribute to violating viewership. Initially, we explored whether a content-based metric can be constructed with the Hansen-Hurwitz estimator using the sampling rate of views and the number of views each sampled post received in the given time frame. The DTAG agreed, however, that such an approach would be limited because: (1) the uncertainty on this population estimate would likely be very large because the viewership distribution of material is heavily skewed; (2) the views-based prevalence sampling has been optimized to minimize error by focusing on material that is more likely to be viewed, and so content that is not viewed by anyone would skew the distribution; and (3) such a count would require sampling continuously in real-time or risk missing content that is proactively removed. In such conditions, the underlying assumption that the number of views is proportional to the population of content would not hold. Moreover, the degree to which such a sample might be biased would be different for various types of violations. These discussions with the DTAG made clear that in order to construct a consistent estimate of a violating content rate, we would need an entirely new and separate labeling and measurement effort. Given this, we considered this metric as an interesting addition but not a priority effort relative to other suggestions for which we are working to improve or expand metrics. We are exploring other ways to provide insight into “production” of violating content through more targeted analysis and research.

DTAG recommendation #6: Explore ways of relating prevalence metrics to real-world harm. We do not believe such a relationship could be meaningfully established in the context of our Content Standards Enforcement Report, but we certainly view it as part of a broader research agenda that is active both inside and outside of Facebook. Extensive research by Facebook and external scholars has found that misinformation and disinformation are associated with a range of harms that vary by regional, political, and social context. While the causal relationship between online information and offline behaviors, including violence, is still being explored, both internal Facebook work and external scholarly research have highlighted risks from amplification and rapid spread of information facilitated by social media platforms. (See, for instance, work by Dunn et al., 2017, on health information.) Facebook continues to explore these issues both through internal research and through support of external research (e.g., our recent call for proposals).

DTAG recommendation #7: Explore ways of accounting for the seriousness of a violation in the prevalence and proactivity metrics. This suggestion is also part of a broader effort by both research and data science teams. But there are a number of complexities related to constructing valid and reliable measures that are relevant across broad violation types and consistent in global contexts. This difficulty is similar to the complexity in measuring severity in the context of crime both in determining meaningful concepts and in designing feasible and valid measures. (See, for example, Greenfield, 2013; Sherman, et al., 2016; and Ramchand, et al., 2009) .

DTAG recommendation #8: Report prevalence measures in subpopulations. The DTAG also had a number of suggestions on releasing more disaggregated data related to content standards enforcement. These breakdowns are feasible for these count-based metrics but may not be for prevalence because of the current stratified sampling approach. Despite some technical constraints, we recognize the value in having different subpopulations of the various metrics and the value of exploring which breakdowns may be most useful and the ways in which we may present and share such information.

DTAG recommendation #9: Report actioned content and proactively actioned content as a proportion of estimated violating content. This recommendation relies on the creation of a content rate metric discussed in recommendation #5. We are exploring ways we can more transparently discuss and quantify how actioned content and prevalence rates are related to help readers better understand how to compare metrics based on distinct units of observation (e.g., compare views-based rates to content-based counts).

DTAG recommendation #10: Break out actioned content measures by type of action taken. We agree that this additional detail would be useful in understanding the way different policy and enforcement tools are used to balance various principles of maintaining voice on important issues — such as discussions of suicide or graphic depictions of human rights violations — while providing protections for users who might be made to feel unsafe or emotionally triggered by such content. We are exploring appropriate breakdowns of this metric to ensure it meaningfully captures some of these issues.

DTAG recommendation #11: Explore ways of accounting for changes in the Community Standards and changes in technology when reporting metrics in the CSER. This is an important point, and we agree with the DTAG. Policy changes could drive changes in metrics too. Currently, much of our narrative discussion focuses on changes in technology, and we are exploring how to include policy changes in the narrative, as well as how to account for these changes, to allow for consistency over time. In the interim, we have released a recent updates section to our Community Standards webpage, which can allow readers to identify changes in the Community Standards over time.

DTAG recommendation #12: Explore ways to enhance bottom-up (as opposed to top-down) governance. The DTAG offered suggestions related to exploring additional partnerships, diversifying input into our processes, and integrating expert evaluations more broadly. These suggestions are a critical and growing component of our ongoing efforts in the content moderation and governance space. We are exploring a range of ways to engage experts and conduct evaluations such as the DTAG — in particular, with our Content Policy Research Initiative workshops and funding opportunities — to help researchers better understand and study our policies and processes. We have also engaged in a range of collaborative processes in designing oversight mechanisms, including an open solicitation for public comments.

DTAG recommendation #13: Enhance components of procedural justice in the Community Standards enforcement and appeal-and-review process.
Over the past year, Facebook has engaged in dozens of sessions to help experts and users better understand how we set the rules and enforce them at scale. Facebook also conducts user research, which involves both qualitative and quantitative methods, to understand what users think about the rules as well as how we could more clearly communicate these rules. We also built and continue to scale an appeals process and increased communication with users on how we enforce these rules, consistent with principles of procedural justice. As part of this work, Facebook continues to research and test ways to better inform users of our rules consistent with the principles of procedural justice and transparency. (See, for example, work with Tyler, et al., 2018). Work in this area has and will continue to be a core aspect of Facebook’s content governance efforts.

DTAG recommendation #14: Publicly release anonymized or otherwise aggregated versions of the data used to calculate prevalence and other metrics in the CSER.
We are exploring ways to make accessible — either via public release or based on a more moderated application-based process (similar to access to sensitive government data) — anonymized or otherwise aggregated versions of the data used to calculate prevalence, content actioned, and proactive detection rate metrics.

DTAG recommendation #15: Modify the formatting, presentation, and text of CSER documents to make them more accessible and intelligible to readers. This recommendation, though not related to the metrics themselves, is critical for identifying ways that we could meaningfully enhance transparency. We incorporated many of these suggestions into our narrative descriptions and explanations, including improving the clarity of some of descriptions, discussing how policy changes affected movements in the metrics, and generally improving accessibility of the report. Many of these changes will be reflected in upcoming reports, and we will continue to consider how best to ensure that the language and details which accompany the metrics can be most clearly expressed.

Next steps and future collaborations

Facebook will release the third iteration of its Community Standards Enforcement Report, which reflects a number of the DTAG’s recommendations along with Facebook’s own efforts to expand its measurement efforts. Facebook will continue to explore ways to expand and improve its Community Standards enforcement transparency by working with external experts. We have conducted dozens of engagements with researchers globally to increase awareness about and research regarding our policies (including explicit efforts to support more extensive research collaborations).

We are building innovative ways to share data, and in parallel, we are working to identify new ways to expand research that can improve understanding of Facebook scale and constraints while preserving independence of external analysis. Working with experts to ensure we are developing, enforcing, and reporting on our Community Standards will continue to be a key tool in ensuring that Facebook is a safe and inclusive platform globally.

References

Brunetti, Aymo and Weder, Beatrice (2003). “A Free Press Is Bad News for Corruption,” Journal of Public Economics, 87(7–8): 1801–24

Cohn, E. S., White, S. O. & Sanders, J. (2000). Distributive and procedural justice in seven nations. Law and Human Behavior, 24, 553-579.

Dawes, Sharon S. (2010). Stewardship and Usefulness: Policy Principles for Information-Based Transparency. Government Information Quarterly, Volume 27, Issue 4, Pages 377-383.

Efron, B. (1987). “Better Bootstrap Confidence Intervals,” Journal of the American Statistical Association, Vol. 82, No. 397. 82 (397): 171–185. doi:10.2307/2289144. JSTOR 2289144.

Elster, J. (1998). Deliberation and constitution making. In Deliberative Democracy, ed. Jon Elster. New York: Cambridge University Press, pp. 97-122.

Greenfield, V. A. and Paoli, L. (2013). “A Framework to Assess the Harms of Crimes.” British Journal of Criminology, 53(5): 864–886.

Karr, A. F. (2008). Citizen access to government statistical information. In Digital Government (pp. 503-529). Springer, Boston, MA.

Lindstedt, C. & Naurin, D. (2010). Transparency is not enough: Making transparency effective in reducing corruption. International Political Science Review, 31(3), 301-322.

Ramchand, R., MacDonald, J. M., Haviland, A., et al. “A Developmental Approach for Measuring the Severity of Crimes,” Journal of Quantitative Criminology (2009), 25: 129.

Lawrence Sherman, Peter William Neyroud, Eleanor Neyroud; The Cambridge Crime Harm Index: Measuring Total Harm from Crime Based on Sentencing Guidelines, Policing: A Journal of Policy and Practice, Volume 10, Issue 3, 1 September 2016, Pages 171–183

Stiglitz, Joseph E. (2000). “The Contributions of the Economics of Information to Twentieth Century Economics,” Quarterly Journal of Economics, 115(4): 1441–78.

Tyler, T. R., Boeckmann, R J., Smith, H J. & Huo, Yuen J. (1997). Social Justice in a Diverse Society. Boulder: Westview Press.

Tyler, T. R. (2000). Social justice: Outcome and procedure. International Journal of Psychology, 35, 117-125.

Tyler, T. R. (2006). Psychological perspectives on legitimacy and legitimation. Annual Review of Psychology, 57, 375-400.

The post Exploring feedback from data and governance experts: A research-based response to the Data Transparency Advisory Group report appeared first on Facebook Research.

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Shelly Tan, for The Washington Post, has been counting on-screen deaths in Game of Thrones over the past few years. As the season ended, Tan described her process in an entertaining Twitter thread:

This graphic had a lot of numbers, so here are the final ones:

– 5 years of working on this project
– 6887 deaths
– 290 character illustrations
– Far too many hours of sleep lost

And now, at the end of it all, my watch has finally ended. Thanks for following along pic.twitter.com/w7VUPjJHE8

— Shelly Tan (@Tan_Shelly) May 22, 2019

I kept thinking about how her process transfers to counting all things. You know, like the decennial Census. The hand-wavy process always seems so straightforward. It’s like, sure, it’ll take a while, but the challenge is just time. But then you get into it, and there’s all these small bumps along the way that make everything more complicated. And then you’re like, great, well, I’ve already come this far. Better keep on counting.

Tags: counting, Game of Thrones

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This extensive post covers NLP use cases, basic examples, Tokenization, Stop Words Removal, Stemming, Lemmatization, Topic Modeling, the future of NLP, and more.

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Data science has been called the sexiest career of 2019. What is data science, really, and how can you get your foot in the door of this exciting career?

The post What is Data Science? appeared first on Dataquest.

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Video is a natural way for us to understand three dimensional and time varying information. Read this short post on how to achieve the creation of videos from still images.

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The pandas library is a powerful tool for multiple phases of the data science workflow, including data cleaning, visualization, and exploratory data analysis. However, the size and complexity of the pandas library makes it challenging to discover the best way to accomplish any given task.

In this in-depth tutorial, which I presented at PyCon 2019, you'll use pandas to answer questions about a real-world dataset. Through each exercise, you'll learn important data science skills as well as "best practices" for using pandas. By the end of the tutorial, you'll be more fluent at using pandas to correctly and efficiently answer your own data science questions.

This is an intermediate level tutorial, so if you're new to pandas, I recommend starting with my other video series: Easier data analysis with pandas.

If you want to follow along with the exercises at home, you can download the dataset and notebook from GitHub.

Here are some of the topics covered in the video:

• adjusting for bias in your dataset
• handling missing values
• choosing an appropriate plot
• customizing your plot
• using the datetime data type
• filtering using loc versus query
• using multiple aggregation functions
• checking for small sample sizes
• method chaining
• verifying your results using random samples
• evaluating a "stringifed" Python container
• applying a custom function to a Series
• writing lambda functions

Let me know if you have any questions, and I'm happy to answer them!

P.S. If you like this video, you should check out my interactive pandas course, Analyzing Police Activity with pandas.

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Julia Silge is joining us as one of our keynote speakers at EARL London 2019. We can’t wait to hear Julia’s full keynote, but until then she kindly answered a few questions. Julia shared with us what we can expect from her address – which will focus on how Stack Overflow uses R and their recent developer survey.

Hi Julia! Tell us about the StackOverflow Developer Survey and your role at Stack Overflow

The Stack Overflow Developer Survey is the largest and most comprehensive survey of people who code around the world each year. This year, we had almost 90,000 respondents who shared their opinions on topics including their favourite technologies, their priorities in looking for a job, and what music they listen to while coding. I am the data scientist who works on this survey, and I am involved throughout the process from initial design to writing copy about results. We have an amazing team who works together on this project, including a project manager, designers, community managers, marketers, and developers.

My role focuses on data analysis. Before the survey was fielded, I worked with one of our UX researchers on question writing, so that our expectations for data analysis were aligned, as well as using data from previous years’ surveys and our site to choose which technologies to include this year. After the survey was fielded, I cleaned and analyzed the data, created data visualizations, and wrote the text for both our developer-facing and business-facing reports.

Why did you use R to analyse the survey?

All of our data science tooling at Stack Overflow is R-centric, but specifically, with our annual survey, we are working with a complex dataset on a tight schedule and the R ecosystem provides the fluent data analysis tools we need to deliver compelling results on time. From munging complicated raw data to creating beautiful visualizations to delivering data deliverables via an API, R is the right tool for the job for us.

Were there results from the survey this year that came as a surprise?

This is such a rich dataset to get to work with, full of interesting things to notice! One result this year that I didn’t expect ahead of time was with our question about whether a respondent eventually wanted to move from technical work into people management. We found that younger, less experienced respondents were more likely to say that they wanted to make the switch! Once I thought about it more carefully, I came to think that those more experienced folks with an interest in managing probably had already shifted careers and were not there to answer that question anymore. Another result that was a surprise to me was just how many different kinds of metal people listen to, more than I even knew existed!

Do you see the gender imbalance improving?

Although our annual survey has a broad capacity for informing useful and actionable conclusions, including about gender, our results don’t represent everyone in the developer community evenly. We know that people from marginalized groups and underrepresented groups in tech participate on Stack Overflow at lower rates than they participate in the software workforce. This means that we undersample such groups in our survey (because of how we invite respondents to the survey, mostly on our site itself). Over the past few years, we have seen incremental improvement in the proportion of responses that are from marginalized or underindexed groups such as minority genders or minority racial/ethnic groups; we are so happy to see this because we want to hear from everyone who codes, everywhere. We believe the biggest driver of this kind of positive change is and will continue to be improving the balance of who participates on Stack Overflow itself, and we are committed to making Stack Overflow a more welcoming and inclusive platform. This kind of work can be difficult and slow, but we are in it for the long haul.

What future trends might you be able to predict from the survey?

One trend we’ve seen over the past several years that I expect to continue is the normalization of salaries for data work. Several years ago, people who worked as data scientists were extreme outliers in salary. Salaries for data scientists have started to move toward the norm for software engineering work, especially if you control for education (for example, comparing a data scientist with a master’s degree to a software engineer with a master’s degree). I don’t see this as entirely bad news, because it is associated with some standardization of data science as a role and increased industry agreement about what a data scientist is, what a data engineer is, how to hire for these roles, and what career paths might look like.

Given Python’s rise again this year, do you see this continuing? How will this affect the use of R?

Python has exhibited a meteoric rise over the past several years and is the fastest-growing major programming language in the world. Python has been climbing in the ranks of our survey over the past several years, edging past first PHP, then C#, then Java this year. It currently sits just below SQL in the ranking. I have a hard time imagining that next year more developers will say they use Python than say they use SQL! You can dig this interview up next year and point out my prediction failure if I am wrong.

In terms of R and R’s future, it’s important to note that R’s use has also been growing dramatically on Stack Overflow, both absolutely and relatively. R is now a top 10 to top 15 programming language (both in questions asked and traffic). Data technologies are in general growing a lot, and there are many factors that go into an individual or an organization deciding to embrace R, or Python, or both.

Thanks Julia! 

You can catch Julia and a whole host of other brilliant speakers at EARL London on 10-12 September at The Tower Hotel London.

We have discounted early bird tickets available for a limited time – please visit the EARL site for more information, we hope to see you there!

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AI is a tricky subject to wrap your head around, that is why we talked to experts of IBM. We were enlightened by Romeo Kienzler, head of IoT at IBM and frequent speaker at Data Natives. Next, Matthias Biniok, lead Watson Architect DACH at IBM, who designed CIMON, the smiling

The post Why we need to open up AI black boxes right now appeared first on Dataconomy.

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Let’s say you are interested in counting the concentration of cells in some sample. This is a pretty common task: sperm counts, blood cell counts, plankton counts. Microbiologists are always counting. Let’s use the example of yeast counting, which is traditional in beer and wine making. The brewery has a sample of yeast slurry, a highly concentrated amount of yeast, and they would like to know how concentrated it is, so they can add the correct amount to a batch.

The first step is to dilute your sample. The original concentration could be as high as billions per mL, so even a fraction of a mL is going to be still too concentrated to properly count. This is solved by successive dilutions of the original sample:

Source: https://kenanfellows.org/kfp-cp-sites/cp24/cp24/activity-3-lab-culturing-yeast-cells-media/index.html

Each time we transfer to a new test tube, we dilute the sample by a factor of 10.

After this is done, a very small amount of the final diluted slurry is added to a hemocytometer. A hecocytometer is a glass slide with a visible grid that an observer can place under a microscope and count cells on. Under the microscope, it looks like this (where yellow dots represent cells):

Source: https://di.uq.edu.au/community-and-alumni/sparq-ed/sparq-ed-services/using-haemocytometer

The hemocytometer is designed such that a known quantity of volume exists under the inner 25 squares (usually 0.0001 mL). The observer will apriori pick 5 squares to count cells in, typically the 4 corner squares and the middle square. (Why only 5? Unlike this image above, there could be thousands of cells, and counting all 25 squares would take too long). Since we know the volume of the 25 squares, and the dilution rate, we can recover our original slurry concentration:

Given I counted 49 yeast and my dilution was 1000x, my estimate is 2.45B yeast/mL. Great! We are done, right? No way, consider all the sources of uncertainty we glossed over:

1. Did we accurately measure out exactly 9mL of water in each test tube?
2. Did we accurately extract 1mL of slurry between each test tube?
3. Did we get lucky/unlucky with our 0.0001 mL sample for the hemocytometer?
4. Did the hemocytometer manufacturer have some QA over the volume of the chamber?
5. Did we get lucky/unlucky with cells numbers in the 5 counting squares?

So we should expect high variance in our estimate because of the many sources of noise, and because they are layered on top of one another. Let’s redo this with Bayesian statistics so we can model our uncertainty.

Here’s the code for an observation of 49 yeast cells counted. Each source of noise is a random variable. I’ve added some priors that I think are sensible. 

import pymc3 as pm

BILLION = 1e9
TOTAL_SQUARES = 25

squares_counted = 5
yeast_counted = 49

with pm.Model() as model:
    yeast_conc = pm.Normal("cells/mL", mu=2 * BILLION, sd=0.4 * BILLION)

    shaker1_volume = pm.Normal("shaker1 volume (mL)", mu=9.0, sd=0.05)
    shaker2_volume = pm.Normal("shaker2 volume (mL)", mu=9.0, sd=0.05)
    shaker3_volume = pm.Normal("shaker3 volume (mL)", mu=9.0, sd=0.05)

    yeast_slurry_volume = pm.Normal("initial yeast slurry volume (mL)", mu=1.0, sd=0.01)
    shaker1_to_shaker2_volume =    pm.Normal("shaker1 to shaker2 (mL)", mu=1.0, sd=0.01)
    shaker2_to_shaker3_volume =    pm.Normal("shaker2 to shaker3 (mL)", mu=1.0, sd=0.01)

    dilution_shaker1 = yeast_slurry_volume       / (yeast_slurry_volume + shaker1_volume)
    dilution_shaker2 = shaker1_to_shaker2_volume / (shaker1_to_shaker2_volume + shaker2_volume)
    dilution_shaker3 = shaker2_to_shaker3_volume / (shaker2_to_shaker3_volume + shaker3_volume)
    final_dilution_factor = dilution_shaker1 * dilution_shaker2 * dilution_shaker3

    volume_of_chamber = pm.Gamma("volume of chamber (mL)", mu=0.0001, sd=0.0001 / 20)

    # why is Poisson justified? in my final shaker, I have yeast_conc * final_dilution_factor * shaker3_volume number of yeast
    # I remove volume_of_chamber / shaker3_volume fraction of them, hence it's a binomial with very high count, and very low probability.
    yeast_visible = pm.Poisson("cells in visible portion", mu=yeast_conc * final_dilution_factor * volume_of_chamber)

    number_of_counted_cells = pm.Binomial("number of counted cells", yeast_visible, squares_counted/TOTAL_SQUARES, observed=yeast_counted)

    trace = pm.sample(5000, tune=1000)

pm.plot_posterior(trace, varnames=['cells/mL'])

The posterior for cells/mL is below:

We can see that the width of the credible interval is about a billion. That’s surprisingly large. And that makes sense: we only have a single, noisy observation. We can see the influence of the prior here as well. Note that the posterior’s mean is about 2.25B, much closer to the priors’ mean of 2B than our naive estimate of 2.45B above. This brings up another point: using the naive formula above is like saying: “I observed a single coin flip, saw heads, so all coin flips are heads.” Sounds silly, but it’s identical inference. With Bayesian statistics, we get to lie in a much more reassuring bed!

Read the next article in this series, modelling growth. 

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Passably-human automated text generation is a reality. How do we best go about detecting it? As it turns out, being too predictably human may actually be a reasonably good indicator of not being human at all.

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So. I was reading the London Review of Books the other day and came across this passage by the philosopher Kieran Setiya:

Some of the most striking discoveries of experimental philosophers concern the extent of our own personal inconsistencies . . . how we respond to the trolley problem is affected by the details of the version we are presented with. It also depends on what we have been doing just before being presented with the case. After five minutes of watching Saturday Night Live, Americans are three times more likely to agree with the Tibetan monks that it is permissible to push someone in front of a speeding train carriage in order to save five. . . .

I’m not up on this literature, but I was suspicious. Watching a TV show for 5 minutes can change your view so strongly?? I was reminded of the claim from a few years ago, that subliminal smiley faces had huge effects on attitudes toward immigration—it turns out the data showed no such thing. And I was bothered, because it seemed that a possibly false fact was being used as part of a larger argument about philosophy. The concept of “experimental philosophy”—that’s interesting, but only if the experiments make sense.

So I thought I’d look into this particular example.

I started by googling *saturday night live trolley problem* which led me to this article in Slate by Daniel Engber, “Does the Trolley Problem Have a Problem?: What if your answer to an absurd hypothetical question had no bearing on how you behaved in real life?”

OK, so Engber’s skeptical too. I searched in the article for Saturday Night Live and found this passage:

Trolley-problem studies also tell us people may be more likely to favor the good of the many over the rights of the few when they’re reading in a foreign language, smelling Parmesan cheese, listening to sound effects of people farting, watching clips from Saturday Night Live, or otherwise subject to a cavalcade of weird and subtle morality-bending factors in the lab.

Which contained a link to this two-page article in Psychological Science by Piercarlo Valdesolo and David DeSteno, “Manipulations of Emotional Context Shape Moral Judgment.”

From that article:

The structure of such dilemmas often requires endorsing a personal moral violation in order to uphold a utilitarian principle. The well-known footbridge dilemma is illustrative. In it, the lives of five people can be saved through sacrificing another. However, the sacrifice involves pushing a rather large man off a footbridge to stop a runaway trolley before it kills the other five. . . . the proposed dual-process model of moral judgment suggests another unexamined route by which choice might be influenced: contextual sensitivity of affect. . . .

We examined this hypothesis using a paradigm in which 79 participants received a positive or neutral affect induction and immediately afterward were presented with the footbridge and trolley dilemmas embedded in a small set of nonmoral distractors.[1] The trolley dilemma is logically equivalent to the footbridge dilemma, but does not require consideration of an emotion-evoking personal violation to reach a utilitarian outcome; consequently, the vast majority of individuals select the utilitarian option for this dilemma.[2]

Here are the two footnotes to the above passage:

[1] Given that repeated consideration of dilemmas describing moral violations would rapidly reduce positive mood, we utilized responses to the matched set of the footbridge and trolley dilemmas as the primary dependent variable.

[2] Precise wording of the dilemmas can be found in Thomson (1986) or obtained from the authors.

I don’t understand footnote 1 at all. From my reading of it, I’d think that a matched set of the dilemmas corresponds to each participant in the experiment getting both questions, and then in the analysis having the responses compared. But from the published article it’s not clear what’s going on, as only 77 people seem to have been asked about the trolley dilemma compared to 79 asked about the footbridge—I don’t know what happened to those two missing responses—and, in any case, the dependent or outcome variable in the analyses are the responses to each question, one at a time. I’m not saying this to pick at the paper; I just don’t quite see how their analysis matches their described design. The problem isn’t just two missing people, it’s also that the numbers don’t align. In the data for the footbridge dilemma, 38 people get the control condition (“a 5-min segment taken from a documentary on a small Spanish village”) and 41 get the treatment (“a 5-min comedy clip taken from ‘Saturday Night Live'”). The entire experiment is said to have 79 participants. But for the trolley dilemma, it says that 40 got the control and 37 got the treatment. Maybe data were garbled in some way? The paper was published in 2006 so long before data sharing was any sort of standard, and this little example reminds us why we now think it good practice to share all data and experimental conditions.

Regarding footnote 2: I don’t have a copy of Thomson (1986) at hand, but some googling led me to this description by Michael Waldmann and Alex Wiegmann:

In the philosopher’s Judith Thomson’s (1986) version of the trolley dilemma, a situation is described in which a trolley whose brakes fail is about to run over five workmen who work on the tracks. However, the trolley could be redirected by a bystander on a side track where only one worker would be killed (bystander problem). Is it morally permissible for the bystander to throw the switch or is it better not to act and let fate run its course?

Now for the data. Valdesolo and DeSteno find the following results:

– Flip-the-swithch-on-the-trolley problem (no fat guy, no footbridge): 38/40 flip the switch under the control condition, 33/37 flip the switch under the “Saturday Night Live” condition. That’s an estimated treatment effect of -0.06 with standard error 0.06.

– Footbridge problem (trolley, fat guy, footbridge): 3/38 push the man under the control condition, 10/41 push the man under the “Saturday Night Live” condition. That’s an estimated treatment effect of 0.16 with standard error 0.08.

So from this set of experiments alone, I would not say it’s accurate to write that “After five minutes of watching Saturday Night Live, Americans are three times more likely to agree with the Tibetan monks that it is permissible to push someone in front of a speeding train carriage in order to save five.” For one thing, it’s not clear who the participants are in these experiments, so the description “Americans” seems too general. But, beyond that, we have a treatment with an effect -0.06 +/- 0.06 in one experiment and 0.16 +/- 0.08 in another: the evidence seems equivocal. Or, to put it another way, I wouldn’t expect such a large difference (“three times more likely”) to replicate in a new study or to be valid in the general population. (See for example section 2.1 of this paper for another example. The bias occurs because the study is noisy and there is selection on statistical significance.)

At this point I thought it best to dig deeper. Setiya’s article is a review of the book, “Philosophy within Its Proper Bounds,” by Edouard Machery. I looked up the book on Amazon, searched for “trolley,” and found this passage:

From this I learned that were some follow-up experiments. The two papers cited are Divergent effects of different positive emotions on moral judgment, by Nina Strohminger, Richard Lewis, and David Meyer (2011), and To push or not to push? Affective influences on moral judgment depend on decision frame, by Bernhard Pastötter, Sabine Gleixner, Theresa Neuhauser, and Karl-Heinz Bäuml (2013).

I followed the link to both papers. Machery describes these as replications, but none of the studies in question are exact replications, as the experimental conditions differ from the original study. Strohminger et al. use audio clips of comedians, inspirational stories, and academic lectures: no Saturday Night Live, no video clips at all. And Pastötter et al. don’t use video or comedy: they use audio clips of happy or sad-sounding music.

I’m not saying that these follow-up studies have no value or that they should not be considered replications of the original experiment, in some sense. I’m bringing them up partly because details matter—after all, if the difference between a serious video and a comedy video could have a huge effect on a survey response, one could also imagine that it makes a difference whether stimuli involve speech or music, or whether they are audio or video—but also because of the flexibility, the “researcher degrees of freedom,” involved in whether to consider something as a replication at all. Recall that when a study does not successfully replicate, a common reaction is to point out differences between the old and new experimental conditions and then declare that that the new study was not a real replication. But if the new study’s results are in the same direction as the old’s, then it’s treated as a replication, no questions asked. So the practice of counting replications has a heads-I-win, tails-you-lose character. (For an extreme example, recall Daryl Bem’s paper where he claimed to present dozens of replications of his controversial ESP study. One of those purported replications was entitled “Further testing of the precognitive habituation effect using spider stimuli.” I think we can be pretty confident that if the spider experiment didn’t yield the desired results, Bem could’ve just said it wasn’t a real replication because his own experiment didn’t involve spiders at all.)

Anyway, that’s just terminology. I have no problem with the Strohminger et al. and Pastötter et al. studies, which we can simply call follow-up experiments.

And, just to be clear, I agree that there’s nothing special about an SNL video or for that matter about a video at all. My concern about the replication studies is more of a selection issue: if a new study doesn’t replicate the original claim, then a defender can say it’s not a real replication. I guess we could call that “the no true replication fallacy”! Kinda like those notorious examples where people claimed that a failed replication didn’t count because it was done in a different country, or the stimulus was done for a different length of time, or the outdoor temperature was different.

The real question is, what did they find and how do these findings relate to the larger claim?

And the answer is, it’s complicated.

First, the two new studies only look at the footbridge scenario (where the decision is whether to push the fat man), not the flip-the-switch-on-the-trolley scenario, which is not so productive to study because most people are already willing to flip the switch. So the new studies to not allow comparison the two scenarios. (Strohminger et al. used 12 high conflict moral dilemmas; see here)

Second, the two new studies looked at interactions rather than main effects.

The Strohminger et al. analysis is complicated and I didn’t follow all the details, but I don’t see a direct comparison estimating the effect of listening to comedy versus something else. In any case, though, I think this experiment (55 people in what seems to be a between-person design) would be too small to reliably estimate the effect of interest, considering how large the standard error was in the original N=79 study.

Pastötter et al. had no comedy at all and found no main effect; rather, as reported by Machery, they found an effect whose sign depended on framing (whether the question was asked as, “Do you think it is appropriate to be active and push the man?” or “Do you think it is appropriate to be passive and not push the man?”:

I guess the question is, does the constellation of these results represent a replication of the finding that “situational cues or causal factors influencing people’s affective states—emotions or moods—have consistent effects on people’s general judgments about cases”?

And my answer is: I’m not sure. With this sort of grab bag of different findings (sometimes main effects, sometimes interactions) with different experimental conditions, I don’t really know what to think. I guess that’s the advantage of large preregistered replications: for all their flaws, they give us something to focus on.

Just to be clear: I agree that effects don’t have to be large to be interesting or important. But at the same time it’s not enough to just say that effects exist. I have no doubt that affective states affect survey responses, and these effects will be of different magnitudes and directions for different people and in different situations (hence the study of interactions as well as main effects). There have to be some consistent or systematic patterns for this to be considered a scientific effect, no? So, although I agree that effects don’t need to be large, I also don’t think a statement such as “emotions influence judgment” is enough either.

One thing that does seem clear, is that details matter, and lots of the details get garbled in the retelling. For example, Setiya reports that “Americans are three times more likely” to say they’d push someone, but that factor of 3 is based on a small noisy study on an unknown population, and for which I’ve not seen any exact replication, so to make that claim is a big leap of faith, or of statistical inference. Meanwhile, Engber refers to the flip-the-switch version of the dilemma, for which case the data show no such effect of the TV show. More generally, everyone seems to like talking about Saturday Night Live, I guess because it evokes vivid images, even though the larger study had no TV comedy at all but compared clips of happy or sad-sounding music.

What have we learned from this journey?

Reporting science is challenging, even for skeptics. None of the authors discussed above—Setiya, Engber, or Machery—are trying to sell us on this research, and none of them have a vested interest in making overblown claims. Indeed, I think it would be fair to describe Setiya and Engber as skeptics in this discussion. But even skeptics can get lost in the details. We all have a natural desire to smooth over the details and go for the bigger story. But this is tricky when the bigger story, whatever it is, depends on details that we don’t fully understand. Presumably our understanding in 2018 of affective influences on these survey responses should not depend on exactly how an experiment was done in 2006—but the description of the effects are framed in terms of that 2006 study, and with each lab’s experiment measuring something a bit different, I find it very difficult to put everything together.

This relates to the problem we discussed the other day, of psychology textbooks putting a complacent spin on the research in their field. The desire for a smooth and coherent story gets in the way of the real-world complexity that motivates this research in the first place.

There’s also another point that Engber emphasizes, which is the difference between a response to a hypothetical question, and an action in the external world. Paradoxically, one reason why I can accept that various irrelevant interventions (for example, watching a comedy show or a documentary film) could have a large effect on the response to the trolley question is that this response is not something that most people have thought about before. In contrast, I found similar claims involving political attitudes and voting (for example, the idea that 20% of women change their presidential preference depending on time of the month) to be ridiculous, on part because most people already have settled political views. But then, if the only reason we find the trolley claims plausible is that people aren’t answering them thoughtfully, then we’re really only learning about people’s quick reactions, not their deeper views. Quick reactions are important too; we should just be clear if that’s what we’re studying.

P.S. Edouard Machery and Nina Strohminger offered useful comments that influenced what I wrote above.

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In February, Facebook launched a request for proposals focused on content policies, specifically around hate speech and preventing offline harm. We were interested in supporting research that will help us develop better content policies and assess possible interventions. We asked for proposals that took a variety of approaches, including experimental and observational studies, along with qualitative and analytic research to understand the mechanisms by which online rhetoric influences offline events.

We received 184 proposals from 38 countries; a selection committee comprising members of the integrity research and policy teams evaluated them. We received proposals on a broad range of relevant research questions that are well-positioned to contribute to the global discussion on content policy issues. Thank you to all the researchers who took the time to submit a proposal, and congratulations to the winners.

Research award winners

Comparative Thematic Analysis Online Comms Strategy of Global Terrorist Organizations
Stevie Weinberg, Deborah Housen-Couriel, Rami Efrati, Eitan Azani, Michael Barak, Uri Ben Yaakov, Doron Rokah, Erez Kreiner, Sigalit Maor-Hirsh, Gabriel Weimann, Assaf Moghadam, Boaz Ganor, Yaakov Perry (International Institute for Counter-Terrorism)

Defending Online and Offline Civility: Analyzing and Debunking Hate Speech
Michael Hameleers, Toni van der Meer (University of Amsterdam)

Examining the Techniques and Tools Used by Intimate Partner Abusers Online
Nicola Dell (Cornell University), Savita Bailur (Caribou Digital)

Fair or Flawed: Experiments on Perceptions of Hate Speech Moderation
João Fernando Ferreira Gonçalves (Erasmus University Rotterdam), Gina Masullo Chen (The University of Texas at Austin), Marisa Torres da Silva (Nova University Lisbon)

Facebook content policy and hate in Zimbabwe
Patience Zirima, Prisiel Samu (Media Monitoring Project of Zimbabwe)

Hate Speech Detection via Deep Learning from Very Large Datasets
Amir Adler (Massachusetts Institute of Technology)

Identifying and Analyzing Hate in News Comments in Facebook
Fabrício Benevenuto (Universidade Federal de Minas Gerais)

Identifying and Examining Islamophobic Speech and Imagery
Anisah Beth Bagasra, Burton Speakman (Kennesaw State University)

Identifying Pull and Push Factors Impacting Reaction to Facebook Posts
Muhammad Umer Khan (Centre for Peace, Security and Developmental Studies and The Grief Directory), Fatima Ali Haider, Narmeen Hamid (The Grief Directory), Fizza Batool (Centre for Peace, Security and Developmental Studies)

Monitoring Cross-Platform Trends in Hate Speech
Jeremy Blackburn (University of Alabama at Birmingham), Barry Bradlyn (University of Illinois at Urbana-Champaign)

Networked Crowdsourcing: An Online Experiment in Content Moderation
Damon Centola, Douglas Guilbeault (University of Pennsylvania)

Pixels Hurt More Than Sticks and Stones: Confronting Cyber-Bullying on Facebook
Tom Kwanya, Angela Kogos, Claudior Onsare, Erick Ogolla, Lucy Kibe (The Technical University of Kenya)

Racial Bias in Reports and Evaluations of Potentially Harmful Speech
Nathan N. Cheek (The Trustees of Princeton University)

Regulating Hate Speech in the Asia Pacific
Katharine Gelber, Kirril Shields (University of Queensland), Aim Sinpeng, Fiona Martin (University of Sydney)

Social Media Platforms and Dirty Political Campaigns
Ernesto Schargrodsky (Universidad Torcuato Di Tella), Rafael Di Tella (Harvard Business School), Sebastian Galiani (University of Maryland)

Terrorist Content Classifier
Charlie Winter, Shiraz Maher (King’s College London)

The How and Where of Hate Speech: A 100 US City Mixed-Methods Study
Rumi Chunara, Stephanie Cook (New York University)

Tracking Causalities of Escalation Towards Dangerous Speech
Anulekha Nandi, Ritu Srivastava (Digital Empowerment Foundation)

Transparency on the Removal of Harmful Speech: Users, Platforms, and Law
Fabricio Bertini Pasquot Polido, Gustavo Ramos Rodrigues, Lahis Pasquali Kurtz, Lucas Costa dos Anjos, Luiza Couto Chaves Brandão, Paloma Rocillo Rolim do Carmo (Institute for Research on Internet & Society)

—

To view our currently open research awards and to subscribe to our email list, visit our Research Awards page.

The post Announcing the winners of the Content Policy Research on Social Media Platforms research awards appeared first on Facebook Research.

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Here is the latest data science news for May 2019.

From Data Science 101

• REAL TALK WITH A DATA SCIENTIST: THE FUTURE OF DATA WRANGLING
• WHAT IS ON THE MICROSOFT DATA SCIENCE CERTIFICATION EXAM?

General Data Science

• Microsoft Build 2019 – This is a huge conference hosted by Microsoft for the developer community. Many of the presentation are available to watch online. Not all are data science/AI related, but many are.
• Google I/O 2019 Videos – Google’s big annual conference. Nearly all of the sessions are recorded. There are lots of AI talks and demos.
• AWS DeepRacer – Learn reinforcement learning by programming an autonomous car and competing in races.
• Data Science Version Control – Just what the name says. This is exciting.
• Microsoft Learning Paths for Developers – Various free trainings
• Data Science Interview Questions – An very complete PDF of data science interview topics and sample questions.

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Global e-commerce is among the fastest growing industries globally, experiencing 18% growth in 2018. Worldwide, consumers purchased $2.86 trillion worth of e-goods in 2018, compared to $2.43 trillion in 2017.

Because digital commerce is data-driven, the industry is ripe territory for AI. However, lack of knowledge and uncertainty remain the most prominent obstacles to this technology gaining a stronger foothold. To address these obstacles, deepsense.ai and Google Cloud co-organized a business breakfast to discuss the challenges and opportunities and share their remarks on artificial intelligence (AI) in e-commerce. Joining Google and deepsense.ai were experts from BeeCommerce.pl, Sotrender, and iProspect, all companies deliver sophisticated tools for digital business.

Plato’s data cave

“When it comes to building AI applications, it’s all about the data,” said Paweł Osterreicher, Director of Strategy & Business Development at deepsense.ai, during his presentation. He pointed out that the simplest analytics in smaller businesses can be done within an Excel spreadsheet or pen and paper. Preparing a simple segmentation within a client group or spotting best-performing products don’t pose a huge challenge. But those are only the tip of the iceberg. “The more sophisticated insights we gain, the more complicated the task becomes. And that’s where specialized software comes in,” he said.

“The greatest challenge is a lack of flexibility. There is no jack-of-all-trades among the popular tools, and each has its limitations. The problem is when a tool doesn’t fit a company’s needs. And, to be honest, that’s a common situation,” Osterreicher continued. Companies thus often need to tweak the tools at their disposal to make them fit or get used to missing insights from their data.

“Most companies process only a fraction of their data and operate with only half the picture. They are like the prisoners in Plato’s cave, watching only the shadows customers cast on the wall, with no access to or true grasp of their real form.”

The only way to analyze data in a convenient and cost-effective way is to leverage machine learning models. Machines are able to effectively spot patterns even in seemingly insignificant details.

“Sometimes information about how long customers hover over a button or how they go about filling in an online form is a first step to obtaining meaningful information. The model is only as good as the data it was built on,” concludes Osterreicher.

Retail reinvented

In another presentation, Jakub Skuratowicz focused on the technical aspects of how companies use AI. There are numerous ways for companies to benefit from AI, be it building engagement, personalizing the user experience or detecting fraud.

Google’s expert showed a new application of image search for omnichannel commerce. First applied by the Nordstrom clothing company, the app-enabled users to take a photograph of an item and then search for it in the shop’s database. Thus, the customer could quickly buy the product online or check its availability.

“By using Google Cloud Platform-delivered machine learning tools, the company reached 95% accuracy in recognizing an item shown in a photograph”

AI also thrives in recommendation engines. “It was common to recommend the user another version of the product – a different size of a dress, for example. That’s pointless. Why would one need another of the same dress, only slightly bigger?” Skuratowicz asked. Instead, the AI-powered model recommended products that complemented the one that had been searched for, like sunglasses or a scarf to go with the dress.

Skuratowicz also showed how AI spots fraudulent transactions in international e-commerce. “Manual or semi-automatic checking can be effective, but machine learning makes it more scalable,”  he said. By applying AI-based solutions, the international logistics provider Pitney Bowes boosted the accuracy of its fraudulent transaction detection by 80% while reducing false-positives by 50%.

The mind barrier

The presentations were followed by a panel discussion on machine learning in e-commerce. As the panelists remarked, the AI-powered future of e-commerce is a challenge that not all companies are ready for.

In response to a question about the state of data-proficiency in e-commerce companies, Arkadiusz Wiśniewski, Director of Data and Technology at iProspect, had this to say:

“some data are easy to collect, while others provide a challenge, so we have an incomplete view. The legal situation in Europe poses an additional challenge, so it is better to focus on the data owned and make the best use of it.”

“Data-readiness depends to a great extent on company size. But most businesses lack the skills and data to effectively apply machine learning techniques,” agreed Jarosław Trybuchowicz, owner of beecommerce.pl.

The panelists agreed that the situation is hard even though data is becoming a commodity. “Sometimes the problem is the opposite. Despite having huge amounts of data, companies don’t get insights from it. They simply don’t know what questions to ask and what insights to look for,” added deepsense.ai’s Borys Sobiegraj.

The panelists likewise agreed that the key to success for enterprises employing machine learning is to know and properly organize their own data. Getting the data is the first challenge; “deciding what to do with it is a different story altogether,” said Jakub Nowacki, Lead Machine Learning Engineer at Sotrender. “Another challenge is extracting value that often lies in matching the data from different sources. If a company is unable to determine the impact of a sales campaign, then what is the purpose of analytics?” he added.

A question-answer session and networking time followed the discussion panel. The next business breakfast is planned for Q3.

###

About deepsense.ai:

brand-manager-at-deepsense

The post Shadows of customers on the wall – key takeaways from the “AI in e-commerce” business breakfast appeared first on deepsense.ai.

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Design thinking continues to be all the rage amongst organizations of all kinds – from academia to startups, to agencies and consultancies, or large enterprises. The concept is popular today not because it’s new per se, but its approach to problem-solving fits well with the digital transformation that companies are

The post Three Critical Aspects of Design Thinking for Big Data Solutions appeared first on Dataconomy.

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The O’Reilly Data Show Podcast: Jike Chong on the many exciting opportunities for data professionals in the U.S. and China.

In this episode of the Data Show, I spoke with Jike Chong, chief data scientist at Acorns, a startup focused on building tools for micro-investing. Chong has extensive experience using analytics and machine learning in financial services, and he has experience building data science teams in the U.S. and in China.

We had a great conversation spanning many topics, including:

• Potential applications of data science in financial services.

• The current state of data science in financial services in both the U.S. and China.

• His experience recruiting, training, and managing data science teams in both the U.S. and China.

Continue reading Applications of data science and machine learning in financial services.

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Deep Fakes, GPU-Friendly Codec, Retro OS, and Production Readiness

1. Few-Shot Adversarial Learning of Realistic Neural Talking Head Models -- astonishing work, where you can essentially do deep-fakes from one or two photos. See the YouTube clip for amazing footage of it learning from historical photos and even a painting. (via Dmitry Ulyanov)
2. Basis Universal GPU Texture Codec -- open source codec for a super-compressed image file format that can be quickly transcoded to something ready for GPUs. See this Hacker News comment for a very readable explanation of why it's important for game developers.
3. Serenity -- open source OS for x86 machines, which seems like Unix with Windows 98 UI.
4. The ML Test Score: A Rubric for ML Production Readiness and Technical Debt Reduction -- We present a rubric as a set of 28 actionable tests, and offer a scoring system to measure how ready for production a given machine learning system is. With an implementation in Excel.

Continue reading Four short links: 23 May 2019.

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“Advanced Analytics is “the analysis of all kinds of data using sophisticated quantitative methods (for example, statistics, descriptive and predictive data mining, simulation and optimization) to produce insights that traditional approaches to business intelligence (BI) – such as query and reporting – are unlikely to discover.”” rapidminer ( 2014 )

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This Tuesday Prof. Oren Etsioni announced on his keynote talk at the Data Science Summit, that the Seattle Allen Institute opens an Israeli Branch:

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Rotation Equivariant Vector Field Networks
We propose a method to encode rotation equivariance or invariance into convolutional neural networks (CNNs). Each convolutional filter is applied with several orientations and returns a vector field that represents the magnitude and angle of the highest scoring rotation at the given spatial location. To propagate information about the main orientation of the different features to each layer in the network, we propose an enriched orientation pooling, i.e. max and argmax operators over the orientation space, allowing to keep the dimensionality of the feature maps low and to propagate only useful information. We name this approach RotEqNet. We apply RotEqNet to three datasets: first, a rotation invariant classification problem, the MNIST-rot benchmark, in which we improve over the state-of-the-art results. Then, a neuron membrane segmentation benchmark, where we show that RotEqNet can be applied successfully to obtain equivariance to rotation with a simple fully convolutional architecture. Finally, we improve significantly the state-of-the-art on the problem of estimating cars’ absolute orientation in aerial images, a problem where the output is required to be covariant with respect to the object’s orientation. …

Kernel Graph Convolutional Neural Network
Graph kernels have been successfully applied to many graph classification problems. Typically, a kernel is first designed, and then an SVM classifier is trained based on the features defined implicitly by this kernel. This two-stage approach decouples data representation from learning, which is suboptimal. On the other hand, Convolutional Neural Networks (CNNs) have the capability to learn their own features directly from the raw data during training. Unfortunately, they cannot handle irregular data such as graphs. We address this challenge by using graph kernels to embed meaningful local neighborhoods of the graphs in a continuous vector space. A set of filters is then convolved with these patches, pooled, and the output is then passed to a feedforward network. With limited parameter tuning, our approach outperforms strong baselines on 7 out of 10 benchmark datasets. …

Graph Optimized Convolutional Network (GOCN)
Graph Convolutional Networks (GCNs) have been widely studied for graph data representation and learning tasks. Existing GCNs generally use a fixed single graph which may lead to weak suboptimal for data representation/learning and are also hard to deal with multiple graphs. To address these issues, we propose a novel Graph Optimized Convolutional Network (GOCN) for graph data representation and learning. Our GOCN is motivated based on our re-interpretation of graph convolution from a regularization/optimization framework. The core idea of GOCN is to formulate graph optimization and graph convolutional representation into a unified framework and thus conducts both of them cooperatively to boost their respective performance in GCN learning scheme. Moreover, based on the proposed unified graph optimization-convolution framework, we propose a novel Multiple Graph Optimized Convolutional Network (M-GOCN) to naturally address the data with multiple graphs. Experimental results demonstrate the effectiveness and benefit of the proposed GOCN and M-GOCN. …

RONA
The soaring demand for intelligent mobile applications calls for deploying powerful deep neural networks (DNNs) on mobile devices. However, the outstanding performance of DNNs notoriously relies on increasingly complex models, which in turn is associated with an increase in computational expense far surpassing mobile devices’ capacity. What is worse, app service providers need to collect and utilize a large volume of users’ data, which contain sensitive information, to build the sophisticated DNN models. Directly deploying these models on public mobile devices presents prohibitive privacy risk. To benefit from the on-device deep learning without the capacity and privacy concerns, we design a private model compression framework RONA. Following the knowledge distillation paradigm, we jointly use hint learning, distillation learning, and self learning to train a compact and fast neural network. The knowledge distilled from the cumbersome model is adaptively bounded and carefully perturbed to enforce differential privacy. We further propose an elegant query sample selection method to reduce the number of queries and control the privacy loss. A series of empirical evaluations as well as the implementation on an Android mobile device show that RONA can not only compress cumbersome models efficiently but also provide a strong privacy guarantee. For example, on SVHN, when a meaningful $(9.83,10^{-6})$-differential privacy is guaranteed, the compact model trained by RONA can obtain 20$\times$ compression ratio and 19$\times$ speed-up with merely 0.97% accuracy loss. …

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Let’s say you have an initial population of (micro-)organisms, and you are curious about their survival rates. A common summary statistic of their survival is the half-life. How might you collect data to measure their survival? Since we are dealing with micro-organisms, we can’t track individual lifetimes. What we might do is periodically count the number of organisms still alive. Suppose our dataset looks like:

T = [0,    2,   4,   7  ]  # in hours
N = [1000, 914, 568, 112]

I’ll present two so-so solutions to finding the half-life, and then one much better solution.

Solution 1: Linear interpolation

We can plot this over time:

We can eyeball the half-life to be about 4.3h - note that this is a linear interpretation between two points, and thus this method doesn’t consider all the data (i.e. it’s not a global method).

Solution 2: curve-fitting an exponential model

Exponential death is a common model in ecology because of it’s simplicity. We can try to find a \(\beta\) value such that the sum of squares of observed values minus \(1000 \exp(\beta t) \) is minimized. That’s not hard to do with scipy’s minimize functions. The best estimate for \(\beta\) is about 0.17. But, as we can see, it’s not a very good fit:

We could choose a more flexible model (like a Weibull distribution), but we will still run up against a fundamental problem: the variance on the estimates will be very high because we are only considering 4 data points, and adding more parameters to the fitting model will only make things worse.

Solution 3: consider the entire population and censoring

Think again about how the data was collected for a moment. We took a count, waited a few hours, and took a count again. The delta in the population are composed of individuals died sometime in that interval. So what we have is a case of interval censoring. That is, I know that 86 individuals died sometime between 0 and 2 (lower and upper bound), 346 died sometime between 2 and 4 (lower and upper bound), etc. Finally, we are left with 112 that are right censored, that is, we stopped watching and don’t observe their death.

We can use survival analysis to answer this problem (hey, let’s use lifelines!). Importantly, we can treat all 1000 organisms as individual observations to make the inference stronger. First, we’ll do some data manipulation. Some notes below.

df = pd.DataFrame({
  "deltas": [86, 346, 456, 112],
  "start":  [0,  2,   4,   7],
  "stop":   [2,  4 ,  7,   np.inf],
  "observed_death": [False, False, False, False]
})

print(df)
"""
   deltas  start  stop  observed_death
0      86      0   2.0           False
1     346      2   4.0           False
2     456      4   7.0           False
3     112      7   inf           False
"""

We have observed_death as always False, because we don’t have exact measurements on any of the deaths (that is, I have no organisms where I can say “this guy lived exactly X hours”). Why do I have the infinity in the last row? Well, we don’t observe the final 112 organisms die either, but we know they will die between hour 7 and infinity, so we code that in too.

from lifelines import WeibullFitter

wf = WeibullFitter()

wf.fit_interval_censoring(
  df['start'], 
  df['stop'], 
  df['observed_death'], 
  weights=df['deltas']
)

wf.print_summary()

"""
<lifelines.WeibullFitter: fitted with 4 observations, 4 censored>
number of subjects = 4
  number of events = 0
    log-likelihood = -1182.357
        hypothesis = lambda_ != 1, rho_ != 1

---
         coef  se(coef)  lower 0.95  upper 0.95      p  -log2(p)
lambda_  5.09      0.07        4.94        5.23 <0.005       inf
rho_     2.49      0.08        2.35        2.64 <0.005    282.95
"""

Note the very small standard errors. And if we plot the resulting survival curve, we see an excellent fit.

From this, we can report the half-life, or even better is to present the survival distribution, since it has the most information in it.

Multiple cultures

Let's say we actually have two cultures we are working with, and take population measurements at the same time. However we have different environments for each of the cultures: one has more double the sugar concentration in the medium than the other. We can model this using a regression survival model:

culture_1 = pd.DataFrame({
  "deltas": [86, 346, 456, 112],
  "start":  [0,  2,   4,   7],
  "stop":   [2,  4 ,  7,   np.inf],
  "conc_sugars": [0.15, 0.15, 0.15, 0.15], 
  "observed_death": [False, False, False, False]
})


culture_2 = pd.DataFrame({
  "deltas": [50, 202, 566, 182],
  "start":  [0,  2,   4,   7],
  "stop":   [2,  4 ,  7,   np.inf],
  "conc_sugars": [0.30, 0.30, 0.30, 0.30], 
  "observed_death": [False, False, False, False]
})
df = pd.concat([culture_2, culture_1])

from lifelines import WeibullAFTFitter

w_aft = WeibullAFTFitter().fit_interval_censoring(df, lower_bound_col='start', upper_bound_col='stop', event_col='observed_death', weights_col='deltas')

So what is the impact of sugar on microorganisms death? The coefficient associated with sugar concentration in this AFT model is interpreted as "higher means live longer". We get a coefficient of 0.90. Thus organisms with 0.15 sugar concentration "experience" time at a 14.4% faster rate than organisms with 0.30 sugar concentration. (Why? \(\exp(0.90 (0.30-0.15))\) ) and their median life is 0.64 hours less.

Conclusion

This is a simple case of when you want to use interval censoring instead of more naive ways. By thinking about the data generating process, we gain lots of statistical efficiency and better predictions. 

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One of the reasons I’m really excited about autograd is because it enables me to be able to transform my abstract parameters into business-logic. Let me explain with an example. Suppose I am modeling customer churn, and I have fitted a Weibull survival model using maximum likelihood estimation. I have two parameter estimates: lambda-hat and rho-hat. I also have their covariance matrix, which tells me how much uncertainty is present in the estimates (in lifelines, this is under the variance_matrix_ property). From this, I can plot the survival curve, which is fine, but what I really want is a measure of lifetime value.

Suppose customers give us $10 each time period for the first 3 time periods, and then $30 each time period afterwards. For a single user, the average LTV (up to timeline) calculation might look like:

# create a Weibull model with fake data
wf = WeibullFitter().fit(np.arange(1, 100))

from autograd import numpy as np

def LTV(params, timeline):
    lambda_, rho_ = params
    sf = np.exp(-(timeline/lambda_) ** rho_)
    clv = 10 * (timeline <= 3) * sf + 30 * (timeline > 3) * sf
    return clv.sum()

timeline = np.arange(10)
params = np.array([wf.lambda_, wf.rho_])

LTV(params, timeline)
# 214.76

This gives me a point estimate. But I also want the variance, since there is uncertainty in lambda-hat and rho-hat. There is a technique called the delta-method that allows me to transform variance from one domain to another. But to use that, I need the gradient of LTV w.r.t to lambda and rho. For this problem, I could probably write out the gradient, but it would be messy and error-prone. I can use autograd instead to do this.

from autograd import grad
gradient_LTV = grad(LTV)

gradient_LTV(params, timeline)
# array([ 0.15527043, 10.78900217])

The output of the above is the gradient at the params value. Very easy. Now, if I want the variance of the LTV, the delta methods tells me to multiply gradient by the covariance matrix and the gradient’s transpose (check: this should return a scalar and not a vector/matrix):

var = gradient_LTV(params, timeline)\
          .dot(wf.variance_matrix_)\
          .dot(gradient_LTV(params, timeline))
# 3.127

So, my best estimate of LTV (at timeline=10) is 214.76 (3.127). From this, we can build confidence intervals, etc.

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Intelligence can be defined as a predominantly human ability to accomplish tasks that are generally hard for computers and animals. Artificial Intelligence [AI] is a field attempting to accomplish such tasks with computers. AI is becoming increasingly widespread, as are claims of its relationship with Biological Intelligence. Often these claims are made to imply higher chances of a given technology succeeding, working on the assumption that AI systems which mimic the mechanisms of Biological Intelligence should be more successful. In this article I will discuss the similarities and differences between AI and the extent of our knowledge about the mechanisms of intelligence in biology, especially within humans. I will also explore the validity of the assumption that biomimicry in AI systems aids their advancement, and I will argue that existing similarity to biological systems in the way Artificial Neural Networks [ANNs] tackle tasks is due to design decisions, rather than inherent similarity of underlying mechanisms. This article is aimed at people who understand the basics of AI (especially ANNs), and would like to be better able to evaluate the often wild claims about the value of biomimicry in AI. The relationship between Biological and Artificial Intelligence

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Data Markets to support AI for All: Pricing, Valuation and Governance

FAT-DeepFFM: Field Attentive Deep Field-aware Factorization Machine

The Statistical Finite Element Method

IPC: A Benchmark Data Set for Learning with Graph-Structured Data

End-to-End Entity Resolution for Big Data: A Survey

Transfer Entropy in Continuous Time

Joint Learning of Neural Networks via Iterative Reweighted Least Squares

Data Processing Protocol for Regression of Geothermal Times Series with Uneven Intervals

On Conditioning GANs to Hierarchical Ontologies

Recent Advances in Diversified Recommendation

An Information Theoretic Interpretation to Deep Neural Networks

MAIA: A Microservices-based Architecture for Industrial Data Analytics

Machine Learning based English Sentiment Analysis

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Andrie de Vries is the author of “R for Dummies” and a Solutions Engineer at RStudio

Phillip (Armand) Bester is a medical scientist, researcher, and lecturer at the Division of Virology, University of the Free State, and National Health Laboratory Service (NHLS), Bloemfontein, South Africa

In this post we complete our series on analysing the HIV pandemic in Africa. Previously we covered the bigger picture of HIV infection in Africa, and a pipeline for drug resistance testing of samples in the lab.

Then, in part 3 we saw that sometimes the same patient’s genotype must be repeatedly analysed in the lab, from samples taken years apart.

Let’s say we have genotyped a patient five years ago and we have a current genotype sequence. It should be possible to retrieve the previous sequence from a database of sequences without relying on identifiers only or at all. Sometimes when someone remarries they may change their surname or transcription errors can be made, which makes finding previous samples tedious and error-prone. So instead of using patient information to look for previous samples to include, we can rather use the sequence data itself and then confirm the sequences belong to the same patient or investigate any irregularities. If we suspect mother-to-child transmission from our analysis, we confirm this with the healthcare worker who sent the sample.

In this final part, we discuss how the inter- and intra-patient HIV genetic distances were analyzed using logistic regression to gain insights into the probability distribution of these two classes. In other words, the goal is to find a way to tell whether two genetic samples are from the same person or from two different people.

Samples from the same person can have slightly different genetic sequences, due to mutations and other errors. This is especially useful in comparing samples of genetic material from retroviruses.

library(readr)
library(dplyr)
library(ggplot2)

## Warning: package 'ggplot2' was built under R version 3.5.2

pt_distance <- 
  read_csv("dist_sample_10.csv.zip", col_types = "ccdccf")

head(pt_distance)

## # A tibble: 6 x 6
##   sample1                sample2                 distance sub   area  type 
##                                              
## 1 KI_797.67744.AB874124… KI_481.67593.AB873933.…   0.0644 B     INT   Inter
## 2 502-2794.39696.JF3202… WC3.27170.EF175209.B.U…   0.0418 B     INT   Inter
## 3 KI_882.67653.AB874186… KI_813.67589.AB874131.…   0.0347 B     INT   Inter
## 4 HTM360.13332.DQ322231… C11-2069070.63977.AB87…   0.0487 B     INT   Inter
## 5 O5598.34737.GQ372062.… LM49.4011.AF086817.B.T…   0.0360 B     INT   Inter
## 6 GKN.45901.HQ026515.B.… C11-2069083.65198.AB87…   0.0699 B     INT   Inter

pt_distance %>% 
  mutate(
    type = forcats::fct_rev(type)
  ) %>% 
  ggplot(aes(x = distance, fill = type)) +
  geom_histogram(binwidth = 0.001) +
  facet_grid(rows = vars(type), scales = "free_y") +
  scale_fill_manual(values = c("red", "blue")) +
  coord_cartesian(xlim = c(0, 0.1)) +
  ggtitle("Histogram of phylogenetic distance by type")

pt_sample <- 
  pt_distance %>% 
  sample_n(1e5)
model <- glm(type ~ distance, data = pt_sample, family = binomial)

## Warning: glm.fit: fitted probabilities numerically 0 or 1 occurred

summary(model)

## 
## Call:
## glm(formula = type ~ distance, family = binomial, data = pt_sample)
## 
## Deviance Residuals: 
##     Min       1Q   Median       3Q      Max  
## -3.4035  -0.0050  -0.0010  -0.0002   8.4904  
## 
## Coefficients:
##              Estimate Std. Error z value Pr(>|z|)    
## (Intercept)    5.7887     0.1796   32.23   <2e-16 ***
## distance    -355.1454     9.3247  -38.09   <2e-16 ***
## ---
## Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
## 
## (Dispersion parameter for binomial family taken to be 1)
## 
##     Null deviance: 23659.2  on 99999  degrees of freedom
## Residual deviance:  1440.5  on 99998  degrees of freedom
## AIC: 1444.5
## 
## Number of Fisher Scoring iterations: 12

newdata <-  data.frame(distance = seq(0, 0.05, by = 0.001))
pred <- predict(model, newdata, type = "response")

plot_inter <- 
  pt_sample %>% 
  filter(distance <= 0.05, type == "Inter") %>% 
  sample_n(2000)
  
plot_intra <- 
  pt_sample %>% 
  filter(distance <= 0.05, type == "Intra") %>% 
  sample_n(2000)

threshold <-  with(newdata, approx(pred, distance, xout = 0.5))$y

ggplot() +
  geom_point(data = plot_inter, aes(x = distance, y = 0), alpha = 0.05, col = "blue") +
  geom_point(data = plot_intra, aes(x = distance, y = 1), alpha = 0.05, col = "red") +
  geom_rug(data = plot_inter, aes(x = distance, y = 0), col = "blue") +
  geom_rug(data = plot_intra, aes(x = distance, y = 0), col = "red") +
  geom_line(data = newdata, aes(x = distance, y = pred)) +
  annotate(x = 0.005, y = 0.9, label = "Type == intra", geom = "text", col = "red") +
  annotate(x = 0.04, y = 0.1, label = "Type == inter", geom = "text", col = "blue") +
  geom_vline(xintercept = threshold, col = "grey50") +
  ggtitle("Model results", subtitle = "Predicted probability that Type == 'Intra'") +
  xlab("Phylogenetic distance") +
  ylab("Probability")

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So, a programmer, a frequentist, and a bayesian walk into a bar. No this post
isn’t really on the path to some politically incorrect stereotypical humor. Jut
trying to make it fun and catch your attention. As the title implies this post
is really about applying the differing viewpoints and methodologies inherent in
those approaches to statistics. To be honest I’m not even going to spend a lot
time on the details of methods, I want to focus on the conclusions each of these
people would draw after analyzing the same data using their favored methods.
This post isn’t really so much about how they would proceed but more about what
they would conclude at the end of the analysis. I make no claim about which of
these fine people have the best way of doing things although I was raised a
frequentist, I am more and more enamored of bayesian methods and while my tagline
is accurate “R Lover !a programmer” I will admit a love for making computers do
the hard work for me so if that involves a little programming, I’m all for
it.

library(rvest)
library(readr)
library(dplyr)
library(ggplot2)
library(ggstatsplot)
library(BayesFactor)

male_100_html <- read_html("http://www.alltime-athletics.com/m_100ok.htm")
male_100_pres <- male_100_html %>%
  html_nodes(xpath = "//pre")
male_100_htext <- male_100_pres %>%
  html_text()
male_100_htext <- male_100_htext[[1]]

male_100 <- readr::read_fwf(male_100_htext, skip = 1, n_max = 3178,
                            col_types = cols(.default = col_character()),
                            col_positions = fwf_positions(
                              c(1, 16, 27, 35, 66, 74, 86, 93, 123),
                              c(15, 26, 34, 65, 73, 85, 92, 122, 132)
                            ))

male_100 <- male_100 %>%
  select(X2, X4) %>% 
  transmute(timing = X2, runner = X4) %>%
  mutate(timing = gsub("A", "", timing),
         timing = as.numeric(timing)) %>%
  filter(runner %in% c("Usain Bolt", "Asafa Powell", "Yohan Blake",
                       "Justin Gatlin", "Maurice Greene", "Tyson Gay")) %>%
  mutate_if(is.character, as.factor) %>%
  droplevels
male_100

## # A tibble: 520 x 2
##    timing runner       
##              
##  1   9.58 Usain Bolt   
##  2   9.63 Usain Bolt   
##  3   9.69 Usain Bolt   
##  4   9.69 Tyson Gay    
##  5   9.69 Yohan Blake  
##  6   9.71 Tyson Gay    
##  7   9.72 Usain Bolt   
##  8   9.72 Asafa Powell 
##  9   9.74 Asafa Powell 
## 10   9.74 Justin Gatlin
## # … with 510 more rows

male_100$runner <- forcats::fct_reorder(male_100$runner, male_100$timing)

male_100 %>%
  group_by(runner) %>%
  summarise(mean_timing = mean(timing)) %>%
  arrange(mean_timing)

## # A tibble: 6 x 2
##   runner         mean_timing
##                   
## 1 Usain Bolt            9.90
## 2 Asafa Powell          9.94
## 3 Tyson Gay             9.95
## 4 Justin Gatlin         9.96
## 5 Yohan Blake           9.96
## 6 Maurice Greene        9.97

male_100 %>%
  group_by(runner) %>%
  summarise(median_timing = median(timing)) %>%
  arrange(median_timing)

## # A tibble: 6 x 2
##   runner         median_timing
##                     
## 1 Usain Bolt              9.9 
## 2 Asafa Powell            9.95
## 3 Yohan Blake             9.96
## 4 Justin Gatlin           9.97
## 5 Maurice Greene          9.97
## 6 Tyson Gay               9.97

ggbetweenstats(data = male_100, 
               x = runner, 
               y = timing,
               type = "p",
               var.equal = FALSE,
               pairwise.comparisons = TRUE,
               partial = FALSE,
               effsize.type = "biased",
               point.jitter.height = 0, 
               title = "Parametric (Mean) testing assuming unequal variances",
               ggplot.component = ggplot2::scale_y_continuous(breaks = seq(9.6, 10.4, .2), 
                                                              limits = (c(9.6,10.4))),
               messages = FALSE
              )

ggbetweenstats(data = male_100, 
               x = runner, 
               y = timing,
               type = "np",
               var.equal = FALSE,
               pairwise.comparisons = TRUE,
               partial = FALSE,
               effsize.type = "biased",
               point.jitter.height = 0, 
               title = "Non-Parametric (Rank) testing",
               ggplot.component = ggplot2::scale_y_continuous(breaks = seq(9.6, 10.4, .2), 
                                                              limits = (c(9.6,10.4))),
               messages = FALSE
              )

ggbetweenstats(data = male_100, 
               x = runner, 
               y = timing,
               type = "bf",
               var.equal = FALSE,
               pairwise.comparisons = TRUE,
               partial = FALSE,
               effsize.type = "biased",
               point.jitter.height = 0, 
               title = "Bayesian testing",
               messages = FALSE
              )

anovaBF(timing ~ runner, data = male_100, rscaleFixed = .707)

## Bayes factor analysis
## --------------
## [1] runner : 19.04071 ±0.01%
## 
## Against denominator:
##   Intercept only 
## ---
## Bayes factor type: BFlinearModel, JZS

compare_runners_bf <- function(df, runner1, runner2) {
  
  ds <- df %>%
    filter(runner %in% c(runner1, runner2)) %>%
    droplevels %>% 
    as.data.frame
  zzz <- ttestBF(formula = timing ~ runner, data = ds)
  yyy <- extractBF(zzz)
  xxx <- paste0("The evidence provided by the data corresponds to odds of ", 
                round(yyy$bf,0), 
                ":1 that ", 
                runner1, 
                " is faster than ",
                runner2 )
  return(xxx)
}

compare_runners_bf(male_100, "Usain Bolt", "Asafa Powell")

## [1] "The evidence provided by the data corresponds to odds of 5:1 that Usain Bolt is faster than Asafa Powell"

compare_runners_bf(male_100, "Usain Bolt", "Tyson Gay")

## [1] "The evidence provided by the data corresponds to odds of 5:1 that Usain Bolt is faster than Tyson Gay"

compare_runners_bf(male_100, "Usain Bolt", "Justin Gatlin")

## [1] "The evidence provided by the data corresponds to odds of 21:1 that Usain Bolt is faster than Justin Gatlin"

compare_runners_bf(male_100, "Usain Bolt", "Yohan Blake")

## [1] "The evidence provided by the data corresponds to odds of 8:1 that Usain Bolt is faster than Yohan Blake"

compare_runners_bf(male_100, "Usain Bolt", "Maurice Greene")

## [1] "The evidence provided by the data corresponds to odds of 1355:1 that Usain Bolt is faster than Maurice Greene"

Who’s Cauchy and why does he matter?

Earlier I made light of the fact that the output from ggbetweenstats had
r_Cauchy = 0.707 and anovaBF uses rscaleFixed = .707. Now we need to spend
a little time actually understanding what that’s all about. Cauchy is
Augustin-Louis Cauchy and
the reason that’s relevant is that BayesFactor makes use of his distribution as
a default. I’m not even
going to try and take you into the details of the math but it is important we
have a decent understanding of what we’re doing to our data.

The BayesFactor
package
has a few built-in “default” named settings. They all have the same shape; the
only differ by their scale, denoted by r. The three named defaults are medium =
0.707, wide = 1, and ultrawide = 1.414. “Medium”, is the default. The scale
controls how large, on average, the expected true effect sizes are. For a
particular scale 50% of the true effect sizes are within the interval (−r,r).
For the default scale of “medium”, 50% of the prior effect sizes are within the
range (−0.7071,0.7071). Increasing r increases the sizes of expected effects;
decreasing r decreases the size of the expected effects.

BayesFactor blog site – February 23, 2014

Let’s compare it to a frequentist test we’re all likely to know, the t-test,
(we’ll use the Welch variant). Our initial hypothesis is that Bolt’s mean times
are different than Powell’s mean times (two-sided) and then test the one-sided
that Bolt is faster. Then let’s go a little crazy and run it one sided but
specify the mean difference 0.038403 of a second faster that we “see” in our data
mu = -0.038403.

  justtwo <- male_100 %>%
    filter(runner %in% c("Usain Bolt", "Asafa Powell")) %>%
    droplevels %>% 
    as.data.frame
  t.test(formula = timing ~ runner, data = justtwo)

## 
##  Welch Two Sample t-test
## 
## data:  timing by runner
## t = -2.5133, df = 111.58, p-value = 0.01339
## alternative hypothesis: true difference in means is not equal to 0
## 95 percent confidence interval:
##  -0.06868030 -0.00812721
## sample estimates:
##   mean in group Usain Bolt mean in group Asafa Powell 
##                   9.904930                   9.943333

  t.test(formula = timing ~ runner, data = justtwo, alternative = "less")

## 
##  Welch Two Sample t-test
## 
## data:  timing by runner
## t = -2.5133, df = 111.58, p-value = 0.006694
## alternative hypothesis: true difference in means is less than 0
## 95 percent confidence interval:
##         -Inf -0.01306002
## sample estimates:
##   mean in group Usain Bolt mean in group Asafa Powell 
##                   9.904930                   9.943333

  t.test(formula = timing ~ runner, data = justtwo, alternative = "less", mu = -0.038403)

## 
##  Welch Two Sample t-test
## 
## data:  timing by runner
## t = -4.9468e-05, df = 111.58, p-value = 0.5
## alternative hypothesis: true difference in means is less than -0.038403
## 95 percent confidence interval:
##         -Inf -0.01306002
## sample estimates:
##   mean in group Usain Bolt mean in group Asafa Powell 
##                   9.904930                   9.943333

Hopefully that last one didn’t trip you up and you recognized by definition if
the mean difference in our sample data is -0.038403 then the p value should
reflect 50/50 p value?

Let’s first just try different r_Cauchy values with ttestBF.

  justtwo <- male_100 %>%
    filter(runner %in% c("Usain Bolt", "Asafa Powell")) %>%
    droplevels %>% 
    as.data.frame
  ttestBF(formula = timing ~ runner, data = justtwo, rscale = "medium")

## Bayes factor analysis
## --------------
## [1] Alt., r=0.707 : 5.164791 ±0%
## 
## Against denominator:
##   Null, mu1-mu2 = 0 
## ---
## Bayes factor type: BFindepSample, JZS

  ttestBF(formula = timing ~ runner, data = justtwo, rscale = "wide")

## Bayes factor analysis
## --------------
## [1] Alt., r=1 : 4.133431 ±0%
## 
## Against denominator:
##   Null, mu1-mu2 = 0 
## ---
## Bayes factor type: BFindepSample, JZS

  ttestBF(formula = timing ~ runner, data = justtwo, rscale = .2)

## Bayes factor analysis
## --------------
## [1] Alt., r=0.2 : 6.104113 ±0%
## 
## Against denominator:
##   Null, mu1-mu2 = 0 
## ---
## Bayes factor type: BFindepSample, JZS

Okay the default medium returns just what we reported earlier 5:1 odds. Going
wider gets us 4:1 and going narrower (believing the difference is smaller) takes
us to 6:1. Not huge differences but noticeable and driven by our data.

Let’s investigate directional hypotheses with ttestBF. First let’s ask what’s the evidence that Bolt is faster than Powell NB the order is driven by factor level in the dataframe not the order in the filter command below. Also note that faster is a lower number

  justtwo <- male_100 %>%
    filter(runner %in% c("Usain Bolt", "Asafa Powell")) %>%
    droplevels %>% 
    as.data.frame
  # notice these two just return the same answer in a different order
  ttestBF(formula = timing ~ runner, data = justtwo, nullInterval = c(0, Inf))

## Bayes factor analysis
## --------------
## [1] Alt., r=0.707 0

  ttestBF(formula = timing ~ runner, data = justtwo, nullInterval = c(-Inf, 0))

## Bayes factor analysis
## --------------
## [1] Alt., r=0.707 -Inf<0    : 10.28646   ±0%
## [2] Alt., r=0.707 !(-Inf<0) : 0.04312062 ±0%
## 
## Against denominator:
##   Null, mu1-mu2 = 0 
## ---
## Bayes factor type: BFindepSample, JZS

So the odds that Bolt has a bigger number i.e. is slower than Powell is 0.04:1
and the converse is the odds that Bolt has a smaller timing (is faster) is 10:1.
You can feel free to put these in the order that makes the most sense to your
workflow. They’re always going to be mirror images.

And yes in some circumstances it is perfectly rational to combine the
information by dividing those odds. See this blog post for a research
scenario
but accomplishing it is trivial. Running this code snippet essentially combines
what we know in both directions of the hypothesis.

  justtwo <- male_100 %>%
    filter(runner %in% c("Usain Bolt", "Asafa Powell")) %>%
    droplevels %>% 
    as.data.frame
  powellvbolt <- ttestBF(formula = timing ~ runner, data = justtwo, nullInterval = c(-Inf, 0))
  powellvbolt[1]/powellvbolt[2]

## Bayes factor analysis
## --------------
## [1] Alt., r=0.707 -Inf<0 : 238.5509 ±0%
## 
## Against denominator:
##   Alternative, r = 0.707106781186548, mu =/= 0 !(-Inf<0) 
## ---
## Bayes factor type: BFindepSample, JZS

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Rivals to succeed Theresa May are jockeying for position

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For almost five years, the entire CRAN repository of R packages has been archived on a daily basis at MRAN. If you use CRAN snapshots from MRAN, we'd love to hear how you use them in this survey. If you're not familiar with the concept, or just want to learn more, read on.

Every day since September 17, 2014, we (Microsoft and, before the acquisition, Revolution Analytics) have archived a snapshot of the entire CRAN repository as a service to the R community. These daily snapshots have several uses:

• As a longer-term archive of binary R packages. (CRAN keeps an archive of package source versions, but binary versions of packages are kept for a limited time. CRAN keeps package binaries only for the current R version and the prior major version, and only for the latest version of the package). 
• As a static CRAN repository you can use like the standard CRAN repository, but frozen in time. This means changes to CRAN packages won't affect the behavior of R scripts in the future (for better or worse). options(repos="https://cran.microsoft.com/snapshot/2017-03-15/") provides a CRAN repository that works with R 3.3.3, for example — and you can choose any date since September 17, 2014.
• The checkpoint package on CRAN provides a simple interface to these CRAN snapshots, allowing you use a specific CRAN snapshot by specifying a date, and making it easy to manage multiple R project each using different snapshots.
• Microsoft R Open, Microsoft R Client, Microsoft ML Server and SQL Server ML Services all use fixed CRAN repository snapshots from MRAN by default.
• The rocker project provides container instances for historical versions of R, tied to an appropriate CRAN snapshot from MRAN suitable for the corresponding R version.

Browse the MRAN time machine to find specific CRAN snapshots by date. (Tip: click the R logo to open the snapshot URL in its own new window.)

MRAN and the CRAN snapshot system was created at a time when reproducibility was an emerging concept in the R ecosystem. Now, there are several methods available to ensure that your R code works consistently, even as R and CRAN changes. Beyond virtualization and containers, you have packages like packrat and miniCRAN, RStudio's package manager, and the full suite of tools for reproducible research.

As CRAN has grown and changes to packages have become more frequent, maintaining MRAN is an increasingly resource-intensive process. We're contemplating changes, like changing the frequency of snapshots, or thinning the archive of snapshots that haven't been used. But before we do that we'd  like to hear from the community first. Have you used MRAN snapshots? If so, how are you using them? How many different snapshots have you used, and how often do you change that up? Please leave your feedback at the survey link below by June 14, and we'll use the feedback we gather in our decision-making process. Responses are anonymous, and we'll summarize the responses in a future blog post. Thanks in advance!

Take the MRAN survey here.

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For almost five years, the entire CRAN repository of R packages has been archived on a daily basis at MRAN. If you use CRAN snapshots from MRAN, we'd love to hear how you use them in this survey. If you're not familiar with the concept, or just want to learn more, read on.

Every day since September 17, 2014, we (Microsoft and, before the acquisition, Revolution Analytics) have archived a snapshot of the entire CRAN repository as a service to the R community. These daily snapshots have several uses:

• As a longer-term archive of binary R packages. (CRAN keeps an archive of package source versions, but binary versions of packages are kept for a limited time. CRAN keeps package binaries only for the current R version and the prior major version, and only for the latest version of the package). 
• As a static CRAN repository you can use like the standard CRAN repository, but frozen in time. This means changes to CRAN packages won't affect the behavior of R scripts in the future (for better or worse). options(repos="https://cran.microsoft.com/snapshot/2017-03-15/") provides a CRAN repository that works with R 3.3.3, for example — and you can choose any date since September 17, 2014.
• The checkpoint package on CRAN provides a simple interface to these CRAN snapshots, allowing you use a specific CRAN snapshot by specifying a date, and making it easy to manage multiple R project each using different snapshots.
• Microsoft R Open, Microsoft R Client, Microsoft ML Server and SQL Server ML Services all use fixed CRAN repository snapshots from MRAN by default.
• The rocker project provides container instances for historical versions of R, tied to an appropriate CRAN snapshot from MRAN suitable for the corresponding R version.

Browse the MRAN time machine to find specific CRAN snapshots by date. (Tip: click the R logo to open the snapshot URL in its own new window.)

MRAN and the CRAN snapshot system was created at a time when reproducibility was an emerging concept in the R ecosystem. Now, there are several methods available to ensure that your R code works consistently, even as R and CRAN changes. Beyond virtualization and containers, you have packages like packrat and miniCRAN, RStudio's package manager, and the full suite of tools for reproducible research.

As CRAN has grown and changes to packages have become more frequent, maintaining MRAN is an increasingly resource-intensive process. We're contemplating changes, like changing the frequency of snapshots, or thinning the archive of snapshots that haven't been used. But before we do that we'd  like to hear from the community first. Have you used MRAN snapshots? If so, how are you using them? How many different snapshots have you used, and how often do you change that up? Please leave your feedback at the survey link below by June 14, and we'll use the feedback we gather in our decision-making process. Responses are anonymous, and we'll summarize the responses in a future blog post. Thanks in advance!

Take the MRAN survey here.

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Big data technologies are used to achieve any type of analytics in a fast and predictable way, thus enabling better human and machine level decision making. Principles of distributed computing are the keys to big data technologies and analytics. The mechanisms related to data storage, data access, data transfer, visualization and predictive modeling using distributed processing in multiple low cost machines are the key considerations that make big data analytics possible within stipulated cost and time practical for consumption by human and machines. However, the current literature available in big data analytics needs a holistic perspective to highlight the relation between big data analytics and distributed processing for ease of understanding and practitioner use. This book fills the literature gap by addressing key aspects of distributed processing in big data analytics. The chapters tackle the essential concepts and patterns of distributed computing widely used in big data analytics. This book discusses also covers the main technologies which support distributed processing. Finally, this book provides insight into applications of big data analytics, highlighting how principles of distributed computing are used in those situations. Practitioners and researchers alike will find this book a valuable tool for their work, helping them to select the appropriate technologies, while understanding the inherent strengths and drawbacks of those technologies.

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(TL;DR: You can add vectors that have the same number of elements.)

LaTeX and MathJax warning for those viewing my feed: please view
directly on website!

You want to know how to rhyme, you better learn how to add
It’s mathematics

Mos Def in ‘Mathematics’

Last
time,
we learnt about scalar multiplication. Let’s get to adding vectors
together!

Today’s topic: vector addition

We will follow the notation in Goodfellow, Ian, et
al.. If our vector
has elements that are real numbers, then we can say that
is a -dimensional vector.

We can also say that lies in some set of all vectors
that have the same dimensions as itself. This might be a bit abstract at first,
but it’s not too bad at all.

Let’s define two vectors:

They have two elements. They are, therefore, two-dimensional vectors.

What are some other two dimensional vectors made up of real numbers? We
could have:

There are infinitely many vectors with two elements that we could come up
with! How can we describe this infinite set of vectors made up of real
numbers? We can say that our two-dimensional vectors made up of real
numbers lie in this set:

What in the world does this mean?

Cartesian products

To understand what the above product means, let’s use a simplified
example. Let’s define sets of integers like so:

What is the result of ? We can depict this operation in a
matrix:

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Also: The Data Fabric for Machine Learning; 10 Free Must-Read Books for ML and Data Science; Another 10 Free Must-See Courses for Machine Learning and Data Science; WTF is a Tensor?!?

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As I was preparing some graphics for a presentation recently, I started digging into some of the different color palette options. My motivation was entirely about creating graphics that weren’t too visually overwhelming, which I found the default “rainbow” palette to be.

But as the creators of the viridis R package point out, we also need to think about how people with colorblindness might struggle with understanding graphics. If you create figures in R, I highly recommend checking it out at the link above!

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Data Bank for Statistical Analysis and Visualization (datarium)
Contains data organized by topics: categorical data, regression model, means comparisons, independent and repeated measures ANOVA, mixed ANOVA and ANCOVA.

Analyze Lines of R Code the Tidy Way (tidycode)
Analyze lines of R code using tidy principles. This allows you to input lines of R code and output a data frame with one row per function included. Add …

Interface to the ‘Zoltar’ Forecast Repository API (zoltr)
Zoltar’ <https://…/> is a website that provides a repository of model forecast resu …

Create Full Text Browsers from Annotated Token Lists (tokenbrowser)
Create browsers for reading full texts from a token list format. Information obtained from text analyses (e.g., topic modeling, word scaling) can be us …

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We know that more education usually equals more income, but as the cost of education continues to rise, the challenge to earn a college degree also increases. Read More

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Article: Racial Bias in Conversational Artificial Intelligence

Article: Building inclusion, fairness, and ethics into machine learning

Paper: Software Engineering for Fairness: A Case Study with Hyperparameter Optimization

Paper: From What to How. An Overview of AI Ethics Tools, Methods and Research to Translate Principles into Practices

Paper: Contrastive Fairness in Machine Learning

Article: Ian McEwan on His New Novel and Ethics in the Age of A.I.

Article: The human problem of AI

Article: The Future of Life Institute (FLI)

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Parsing Structured Documents with Custom Entity Extraction

The Almighty Policy Gradient in Reinforcement Learning

Achieving Artificial General Intelligence (AGI) using Self Models

Integrating Machine Learning Models within Matured Business Process

Should You Be Recommending Deep Learning Solutions in Your Company?

Automated data report storytelling in R

Customer Support Chatbots: Easier & More Effective Than You Think

An Introductory Guide to Computer Vision

R Studio Shortcuts and Tips – part 2

Part 2: Simple EDA in R with inspectdf

Understanding the 3 most common loss functions for Machine Learning Regression

Reinforcement learning basics: stationary and non-stationary multi-armed bandit problem

Detection Free Human Instance Segmentation using Pose2Seg and PyTorch

Machine Learning in Python NumPy: Neural Network in 9 Steps

Deep Learning for Clinical Diagnostics

Can we generate Automatic Cricket Commentary using Neural Networks ?

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Yesterday in our discussion of easy ways to improve your graphs, a commenter wrote:

I recently read and enjoyed several articles about alternatives to the rainbow color palette. I particularly like the sections where they show how each color scheme looks under different forms of color-blindness and/or in black and white.

Here’s a couple of them (these are R-centric but relevant beyond that):

The viridis color palettes, by Bob Rudis, Noam Ross and Simon Garnier

Somewhere over the Rainbow, by Ross Ihaka, Paul Murrell, Kurt Hornik, Jason Fisher, Reto Stauffer, Claus Wilke, Claire McWhite, and Achim Zeileis.

I particularly like that second article, which includes lots of examples.

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The University of Edinburgh is happy to announce our upcoming event as part of the Jupyter Community Workshop series funded by Bloomberg. The University will be hosting a three-day event, the core aspect of this event being a hackathon focused on adding improvements, fixes and extra documentation for the nbgrader extension. Alongside this we will also hold an afternoon of talks highlighting how Jupyter can be used in education at varying levels. The event will take place on 29 to 31 May at the University of Edinburgh, with the afternoon of talks taking place on 30 May.

The first and main part of the event will be the nb grader hackathon. nbgrader is a Jupyter extension that allows for the creation and marking of notebook-based assignments. Here at the University, we have adopted nbgrader and our developers have integrated the extension into our Jupyter service Noteable. The hackathon will focus on improving the core features and extending the abilities of nbgrader; by adding such features, it will be easier for institutions to adopt and embed both Jupyter and nbgrader into their teaching practice.

The second, equally important part of our event is a series of talks aimed at highlighting the uses of Jupyter within education. As part of developing our local Jupyter service, we have uncovered many use cases across the University of how Jupyter can be adopted in a variety of disciplines and scenarios that we are keen to share. We will also be able to showcase an institutional approach to adopting and supporting Jupyter at scale. On top of this, there is also the opportunity to hear from many of our hackathon attendees. This series of talks is aimed at academic colleagues, and teaching and support staff at any level of education and includes an evening networking event to allow attendees to further explore how they may introduce Jupyter to their institution.

What are we working on?

We have worked with our local developers and scoured the nbgrader Github repo to devise a plan of attack for the hackathon in terms of features and improvement. We’re keen to engage with the wider community regarding these goals and have created a post on the Jupyter Discourse to allow further discussion.

• Support for Multiple course/Multiple classes. Instructors that teach multiple course using nbgrader or students enrolled on multiple course. Multiple Courses (ref: PR #1040) vs Support for multiple classes via Jupyterhub groups (PR #893)
• Considerations for LTI use: Users/Courses not in the database at startup
• Support for Multiple markers for one assignment (part of issue #1030, which extends #998)
• API Tests have hard-coded file copy methods to pre-load the system to enable testing, and os.file_exists-type tests for release & submit tests
• Generation of feedback copies for students within the formgrader UI (to mirror the existing terminal command). Also consider ability to disseminate this feedback back to students within nbgrader.

Want to get involved?

If you would like to be involved in the hackathon, we still have an amount of funding left for travel and accommodation. We are looking for participants who have a good understanding of Jupyter and nbgrader who would be able to attend all three days of the event. If you would be able to attend, please complete the following form: [https://edin.ac/2vP8bFS].

If you can’t attend but want to have a say on what is worked on during the hackathon then join the discussion on the Jupyter Discourse (if you’re new to Jupyter this is an excellent place to head to for community discussions)

If you’d like to come along to our Jupyter community afternoon on 30 May, book a place via Eventbrite.

University of Edinburgh Jupyter Community nbgrader Hackathon was originally published in Jupyter Blog on Medium, where people are continuing the conversation by highlighting and responding to this story.

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Joelle Pineau, the Co-Managing Director of Facebook AI Research (FAIR) and head of FAIR Montreal, is one of six recipients of the Governor General’s Innovation Awards. The award recognizes Canadian leaders for their groundbreaking innovations and positive impact on the quality of life in the country.

Pineau’s research focuses on developing new models and algorithms for planning and learning in complex, partially observable domains. She is recognized for applying these algorithms to problems in robotics and in health care. Pineau is also a vocal advocate for increasing diversity among researchers and academics in the AI community.

In addition to leading Facebook AI’s research efforts in Montreal, she is also an associate professor at McGill University, where she co-directs the Reasoning and Learning Lab.

Pineau sat down to share her health care-related work and how AI can have a positive impact on the world. See the Facebook AI blog for the full Q&A.

The post Facebook AI’s Joelle Pineau receives Governor General’s Innovation Award appeared first on Facebook Research.

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SQL injection is a common form of data theft. I am hopeful we can make SQL injection protection more common.

The 2018 TrustWave Global Security Report listed SQL Injection as the second most common technique for web attacks, trailing only cross-site scripting (XSS) attacks. This is a 38% increase from the previous year. That same report also shows SQL Injection ranked fifth on a list of vulnerabilities that can be identified through simple penetration testing.

You may look at the increase and think “whoa, attacks are increasing”. But I believe that what we are seeing is a rising awareness in security. No longer the stepchild, security is a first-class citizen in application design and deployment today. As companies focus on security, they deploy tools and systems to help identify exploits, leading to more reporting of attacks.

SQL Injection is preventable. That’s the purpose of this post today, to help you understand what SQL Injection is, how to identify when it is happening, and how to prevent it from being an issue.

SQL Injection Explained

SQL injection is the method where an adversary appends a SQL statement to the input field inside a web page or application, thereby sending their own custom request to a database. That request could be to read data, or download the entire database, or even delete all data completely.

The most common example for SQL injection attacks are found inside username and password input boxes on a web page. This login design is standard for allowing users to access a website. Unfortunately, many websites do not take precautions to block SQL injection on these input fields, leading to SQL injection attacks.

Let’s look at a sample website built for the fictional Contoso Clinic. The source code for this can be found at https://github.com/Microsoft/azure-sql-security-sample.

On the Patients page you will find an input field at the top, next to a ‘Search’ button, and next to that a hyperlink for ‘SQLi Hints’.

Clicking on the SQLi Hints link will display some sample text to put into the search field.

I’m going to take the first statement and put it into the search field. Here is the result:

This is a common attack vector, as the adversary can use this method to determine what version of SQL Server is running. This is also a nice reminder to not allow your website to return such error details to the end user. More on that later.

Let’s talk a bit about how SQL injection works under the covers.

How SQL Injection works

The vulnerability in my sample website is the result of this piece of code:

return View(db.Patients.SqlQuery
("SELECT * FROM dbo.Patients
WHERE [FirstName] LIKE '%" + search + "%'
OR [LastName] LIKE '%" + search + "%'
OR [StreetAddress] LIKE '%" + search + "%'
OR [City] LIKE '%" + search + "%'
OR [State] LIKE '%" + search + "%'").ToList());

This is a common piece of code used by many websites. It is building a dynamic SQL statement based upon the input fields on the page. If I were to search the Patients page for ‘Rock’, the SQL statement sent to the database would then become:

SELECT * FROM dbo.Patients
WHERE [FirstName] LIKE '%Rock%'
OR [LastName] LIKE '%Rock%'
OR [StreetAddress] LIKE '%Rock%'
OR [City] LIKE '%Rock%'
OR [State] LIKE '%Rock%'

In the list of SQLi hints on that page you will notice that each example starts with a single quote, followed by a SQL statement, and at the end is a comment block (the two dashes). For the example I chose above, the resulting statement is as follows:

SELECT * FROM dbo.Patients
WHERE [FirstName] LIKE '%' OR CAST(@@version as int) = 1 --%'
OR [LastName] LIKE '%' OR CAST(@@version as int) = 1 --%'
OR [StreetAddress] LIKE '%' OR CAST(@@version as int) = 1 --%'
OR [City] LIKE '%' OR CAST(@@version as int) = 1 --%'
OR [State] LIKE '%' OR CAST(@@version as int) = 1 --%'

This results in the conversion error shown above. This also means that I can do interesting searches to return information about the database. Or I could do malicious things, like drop tables.

Chance are you have code like this, somewhere, right now. Let’s look at how to find out what your current code looks like.

SQL Injection Discovery

Discovering SQL injection is not trivial. You must examine your code to determine if it is vulnerable. You must also know if someone is actively trying SQL injection attacks against your website. Trying to roll your own solution can take considerable time and effort.

There are two tools I can recommend you use to help discover SQL injection.

Test Websites with sqlmap

One method is to use sqlmap, an open-source penetration testing project that will test websites for SQL injection vulnerabilities. This is a great way to uncover vulnerabilities in your code. However, sqlmap will not tell you if someone is actively using SQL injection against your website. You will need to use something else for alerts.

Azure Threat Detection

If you are using Azure SQL Database, then you have the option to enable Azure Threat Detection. This feature will discover code vulnerabilities as well as alert you to attacks. It also checks for anomalous client login, data exfiltration, and if a harmful application is trying to access your database.

(For fairness, I should mention that AWS WAF allows for SQL injection detection, but their process is a bit more manual that Azure).

If you try to roll your own discovery, you will want to focus on finding queries that have caused errors. Syntax errors, missing objects, permission errors, and UNION ALL errors are the most common. You can find a list of the common SQL Server error message numbers here.

It warrants mentioning that not all SQL injection attacks are discoverable. But when it comes to security, you will never eliminate all risk, you take steps to lower your risk. SQL injection discovery is one way to lower your risk.

SQL Injection Protection

Detection of SQL Injection vulnerabilities and attacks are only part of the solution. In an ideal world, your application code would not allow for SQL Injection. Here’s a handful of ways you can lower your risk of SQL injection attacks.

Parameterize Your Queries

Also known as ‘prepared statements’, this is a good way to prevent SQL injection attacks against the database. For SQL Server, prepared statements are typically done using the sp_executesql() system stored procedure.

Prepared statements should not allow an attacker to change the nature of the SQL statement by injecting additional code into the input field. I said “should”, because it is possible to write prepared statements in a way that would still be vulnerable to SQL injection. You must (1) know what you are doing and (2) learn to sanitize your inputs.

Traditionally, one argument against the use of prepared statements centers on performance. It is possible that a prepared statement may not perform as well as the original dynamic SQL statement. However, if you are reading this and believe performance is more important than security, you should reconsider your career in IT before someone does that for you.

Use Stored Procedures

Another method available are stored procedures. Stored procedures offer additional layers of security that prepared statements may not allow. While prepared statements require permissions on the underlying tables, stored procedures can execute against objects without the user having similar direct access.

Like prepared statements, stored procedures are not exempt from SQL injection. It is quite possible you could put vulnerable code into a stored procedure. You must take care to compose your stored procedures properly, making use of parameters. You should also consider validating the input parameters being passed to the procedure, either on the client side or in the procedure itself.

Use EXECUTE AS

You could use a security method such as EXECUTE AS to switch the context of the user as you make a request to the database. As mentioned above, stored procedures somewhat act in this manner by default. But EXECUTE AS can be used directly for requests such as prepared statements or ad-hoc queries.

Remove Extended Stored Procedures

Disabling the use of extended stored procedures is a good way to limit your risk with SQL injection. Not because you won’t be vulnerable, but because you limit the surface area for the attacker. By disabling these system procedures you limit a common way that an attacker can get details about your database system.

Sanitize Error Messages

You should never reveal error messages to the end user. Trap all errors and redirect to a log for review later. The less error information you bubble up, the better.

Use Firewalls

Whitelisting of IP addresses is a good way to limit activity from anomalous users. Use of VPNs and VNETs to segment traffic can also reduce your risk.

Summary

The #hardtruth here is that every database is susceptible to SQL injection attacks. No one platform is more at risk than any other. The weak link here is the code being written on top of the database. Most code development does not emphasize security enough, leaving themselves open to attacks.

When you combine poor database security techniques along with poor code, you get the recipe for SQL Injection.

REFERENCES

2018 TrustWave Global Security Report
Contoso Clinic Demo Application
sqlmap: Automatic SQL injection and database takeover tool
Azure SQL Database threat detection
Working with SQL Injection Match Conditions
How to Detect SQL Injection Attacks
sp_executesql (Transact-SQL)
EXECUTE AS (Transact-SQL)
Server Configuration Options (SQL Server)

The post SQL Injection Protection appeared first on Thomas LaRock.

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Principal component analysis (PCA) is very useful for doing some basic quality control (e.g. looking for batch effects) and assessment of how the data is distributed (e.g. finding outliers). A straightforward way is to make your own wrapper function for prcomp and ggplot2, another way is to use the one that comes with M3C (https://bioconductor.org/packages/devel/bioc/html/M3C.html) or another package. M3C is a consensus clustering tool that makes some major modifications to the Monti et al. (2003) algorithm so that it behaves better, it also provides functions for data visualisation.

Let’s have a go on an example cancer microarray dataset.

# M3C loads an example dataset mydata with metadata desx
library(M3C)
# do PCA
pca(mydata,colvec=c('gold'),printres=TRUE)

So, now what prcomp has done is extracted the eigenvectors of the data’s covariance matrix, then projected the original data samples onto them using linear combination. This yields PC scores which are plotted on PC1 and PC2 here (eigenvectors 1 and 2). The eigenvectors are sorted and these first two contain the highest variation in the data, but it might be a good idea to look at additional PCs, which is beyond this simple blog post and function.

You can see above there are no obvious outliers for removal here, which is good for cluster analysis. However, were there outliers, we can label all samples with their names using the ‘text’ parameter.

library(M3C)
pca(mydata,colvec=c('gold'),printres=TRUE,text=colnames(mydata))

Now other objectives would be comparing samples with batch to make sure we do not have batch effects driving the variation in our data, and comparing with other variables such as gender and age. Since the metadata only contains tumour class we are going to use that next to see how it is related to these PC scores.

This is a categorical variable, so the ‘scale’ parameter should be set to 3, ‘controlscale’ is set to TRUE because I want to choose the colours, and ‘labels’ parameter passes the metadata tumour class into the function. I am increasing the ‘printwidth’ from its default value because the legend is quite wide.

For more information see the function documentation using ?pca.

# first reformat meta to replace NA with Unknown
desx$class <- as.character(desx$class)
desx$class[is.na(desx$class)] <- as.factor('Unknown')
# next do the plot
pca(mydata,colvec=c('gold','skyblue','tomato','midnightblue','grey'),
labels=desx$class,controlscale=TRUE,scale=3,printres=TRUE,printwidth=25)

So, now it appears that the variation that governs these two PCs is indeed related to tumour class which is good. But, what if the variable is continuous, and we wanted to compare read mapping rate, or read duplication percentage, or age with our data? So, a simple change of the parameters can allow this too. Let’s make up a continuous variable, then add this to the plot. In this case we change the ‘scale’ parameter to reflect we are using continuous data, and the spectral palette is used for the colours by default.

randomvec <- seq(1,50)
pca(mydata,labels=randomvec,controlscale=TRUE,scale=1,legendtitle='Random',
printres=TRUE,printwidth=25)

So, since this is a random variable, we can see it has no relationship with our data. Let’s just define a custom scale now. So we change ‘scale’ to 2, then use the ‘low’ and ‘high’ parameters to define the scale colour range.

pca(mydata,labels=randomvec,controlscale=TRUE,scale=2,legendtitle='Random',
printres=TRUE,,printwidth=25,low='grey',high='red')

Super easy, yet pretty cool. The idea here is just to minimise the amount of code hanging around for doing basic analyses like these. You can rip the code from here: https://github.com/crj32/M3C/blob/master/R/pca.R. Remember if your features are on different scales, the data needs transforming to be comparable beforehand.

M3C is part of a series of cluster analysis tools that we are releasing, the next is ‘Spectrum’, a fast adaptive spectral clustering tool, which is already on CRAN (https://cran.r-project.org/web/packages/Spectrum/index.html). Perhaps there will be time to blog about that in the future.

For quantitative analysis of drivers in the variation on data, I recommend checking out David Watson’s great function in the ‘bioplotr’ package called ‘plot_drivers’ (https://github.com/dswatson/bioplotr). This compares the PCs with categorical and continuous variables and performs univariate statistical analysis on them producing a very nice plot.

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