“Hi everyone, I’m Sarah! I’m a Research Data Scientist at the Alan Turing Institute and I’m also an operator of mybinder.org. It’s really cool seeing how many people here are interested in BinderHub!”

And it is cool. Really cool! But also a bit scary as a room full of Research Software Engineers (each of them much further on in their careers than I am) suddenly turn to me, eager for the knowledge I was surely about to impart to them.

But let’s rewind a bit.

Joining the Binder community

Its May 2019 and I’m attending the Research Software Reactor sprint jointly hosted by Microsoft and Imperial College London. This is a 3-day hackathon where researchers from different areas (though all with a computing background) come together to collaboratively build cloud-based resources on Microsoft’s Azure platform.

As for me, I’m only 6 months into my role at the Turing, having graduated from my PhD in Astrophysics at the start of the year. Also, my role as a “Binder Operator” is barely 2 months old… which is why I’m starting to feel nervous about the amount of interest in the room! This also happens to be the second hackathon I’ve attended ever, so the adrenaline is high.

So, what is this “Binder” that we’re all so excited about?

Binder is an amazing resource that can host reproducible and interactive code in a web browser. Great… what does that mean? It means that if I have some scripts or notebooks in a repository (like this one) and I describe the packages in a configuration file (such as requirements.txt), then I can go to mybinder.org, copy the URL of the repository into the form and hit launch. This will begin a series of events culminating in my notebook appearing in a browser window with all of the packages installed, and the code will just run.

Sounds like magic, right? You can even combine Binder with Jupyter Books to create interactive documents! Below is a comic explaining how a scientist may use Binder.

The user experience of mybinder.org. Comic courtesy of Juliette Taka.

BinderHub is the technology powering Binder (or where the magic happens). It is a multi-user server that can create a custom, user-specified computing environment and make it accessible via a URL. It utilizes different tools to make this possible and can be deployed onto either a cloud provider or an on-premise compute cluster. These tools are depicted in the below illustration.

A pictorial representation of the different tools constituting BinderHub. This image was created by Scriberia for The Turing Way community and is used under a CC-BY licence. Zenodo record.

Since BinderHub is a cloud-neutral technology (mybinder.org itself runs on Google Cloud and OVH.com), I previously worked on refining the documentation around deploying BinderHub on Azure and ran workshops teaching people how to use Binder and deploy BinderHub. It was this work that lead to me being invited to join the Binder team. Being a maintainer for an open-source project involves checking if the service is still running smoothly and being an active, friendly member of the community — one who can answer questions when they arise.

Now that we’ve covered a bit of background, let’s get back to my slightly uncomfortable moment at the sprint.

Day 1: An unexpected leadership position

Everybody in the room is now trying to whittle down which projects we should work on — all of which are awesome! The magic of BinderHub is that it covers so many aspects of software engineering tools and practices, such as continuous integration/deployment and Kubernetes. The BinderHub idea is quickly amassing a lot of satellite projects!

“So Sarah, is it OK if I name you leader of ‘Team BinderHub’?” My second uncomfortable moment. Gerard Gorman, Senior Lecturer in the Department of Earth Sciences at Imperial and co-organizer of the sprint, has just elected me leader of my first ever hack project. If I’m honest, I’d intended to spend the sprint ironing out some niggles with a colleague. But I’ve always been a “learn by doing” person so I agree and desperately begin wracking my brain for a project to give my team for the next 3 days.

After a bit of shuffling (where for a while it seemed like most of the attendees would be joining ‘Team BinderHub’!), I finally assemble a team. My teammates are: Tania Allard, a Microsoft Developer Advocate; Tim Greaves and Diego Alonso Álvarez, Research Software Engineers at Imperial; and Gerard himself.

The project I decide to bring to the table is one that I’d started but had stalled. The process of deploying a BinderHub can be quite long (usually an hour) and consists mainly of typing stuff into the command line. So a couple of months prior, I’d begun designing a set of scripts that would install the relevant tools, deploy a BinderHub on Azure and connect it to a Docker Hub account, retrieve various pieces of information (IP addresses, logs, etc.) and then remove the BinderHub from the cloud. However, my bash scripting and operating system knowledge is not especially strong. Within the team, we have a bit of a discussion around the Deploy to Azure feature — a button that can be copy-pasted into the README of a GitHub project and facilitates a one-click deployment of the project to Azure. It seems like the perfect hack is to combine my scripts with the deploy button and make deploying BinderHub as easy as possible.

Tim is a bash scripting, containerizing pro and has a little experience with the Azure “blue button” from the OKPy project. I ask him to check my setup script that installs the required Command Line Interfaces (CLIs) and explain that I’d like it to be generalized for different operating systems.

Gerard is a BinderHub enthusiast and is keen to get one deployed as a teaching resource at Imperial. As a starter task, I ask him to read up on how the blue button works.

Diego has never heard of Binder or BinderHub before and is quite confused as to what the rest of the team are so excited about! I suggest that he works through my Zero to BinderHub workshop in order to bring him up to speed with the concepts. This is also the perfect opportunity to get feedback on my workshop if parts are not clear! I encourage him to open an issue describing any problems he comes across or extra information he’d like to see.

And just like that, I find I’ve delegated myself out of a job!

Now Imposter Syndrome is beginning to creep up on me. Not only is it taking four extra people to pull together my work and make it usable, but I am also unsure how I would assist them in these tasks I’d set them. Especially Tim, as the complexity of what I wanted the bash scripts to achieve was the reason this project stalled in the first place.

Except there’s one very important aspect of any software project I’ve not mentioned yet: Documentation!

Since starting my position at the Turing, I’ve come to fully appreciate how fundamental good documentation is to the success of a project. Clearly-written instructions covering the purpose of the project, how to install/run the code, and what kind of inputs/outputs to expect make it much easier for a new person to quickly get to grips with the project. And as result, it’s far more likely to be referenced and reused. While my team begin familiarizing themselves with the infrastructure and goals of my project, I begin an overhaul of the documentation whilst keeping an eye on the repository to manage incoming issues and pull requests.

Take that, Imposter Syndrome!

Day 2: The team makes progress

It’s the second day of the sprint and ‘Team BinderHub’ gather again, our enthusiasm not diminished yet!

I very quickly set goals for the day. I want the button to work by the end of the day as I’m hoping the final day can be used to work on an idea Tania has to use Azure’s DevOps Pipelines to automatically update the deployed BinderHub as new commits come into the host repository. This would be a very handy feature for those (like me!) maintaining BinderHubs at their own institutions. Anything to automate and reduce the number of commands we have to type!

I ask Tim to begin working on the deploy script itself, to add tests where necessary and tidy up some of the parsing of the variables. The next steps are to build a Dockerfile that runs the deploy script and an ARM (Azure Resource Manager) template that controls the form that the blue button links to.

Again, I’m managing the documentation, keeping up with changes we make to the code-base and functionality. Similarly, I keep watch over the repository to manage incoming pull requests and merge conflicts and also make a start on the amendments to the BinderHub workshop Diego has compiled.

My Imposter Syndrome is definitely subsiding as I begin to feel more like I understand the skills of my team and we are all making the best use of our time.

Day 3: Document, document, document

For the third and final day of the sprint we are in a new venue: the Microsoft Reactor. This is a workspace in the Shoreditch area of London where we are offered free pizza and cookies and a DJ to provide the soundtrack to our code. (OK, less an actual DJ, more of a software engineer with Spotify Premium. 😜) What I will say though, Microsoft’s beverage-making facilities have nothing on the Turing’s iPad coffee maker! 😉

Our goals for the last day? Consolidate and document! Ideally get the button working if possible, but the top priority is to make it as easy as possible for the team (or someone new!) to come along to the repository and finish what we have started.

We decide that there isn’t enough time left or infrastructure in place to implement the Azure DevOps Pipeline for automatic upgrades; instead, Tania begins working on a tutorial so we can implement it later.

Tim and I end up in a bit of GitHub hell as we realize that the code to create the Kubernetes cluster is in the setup script, not the deploy script. We refactor some parts so that all of the resources are deployed from the deploy script, and this also means that the Dockerfile only needs to find one script to execute. However, this refactoring causes a complicated merge conflict and some of the bug fixes Tim implemented disappear in a squash merge. (This sounded difficult enough to resolve that I’ve been put off learning about squash merges since!) As team leader, I try to orchestrate whose pull request should be merged first so that all the right code ends up in master.

What did we learn and do?

By the end of the sprint, we don’t quite have a working button deployment, but we do have:

• a set of streamlined scripts for auto-deployment based on the contents of a JSON file,
• an ARM template and Dockerfile that will provide the backend to the blue button after some further debugging,
• a plan to move the project forwards after the sprint.

So what did I learn from those three days?

Coding with other people is fun!

Paired programming is something we try to achieve at the Turing, but it can be difficult to do depending on the project and the time constraints of those working on it.

This was the first time I’d experienced true collaboration. Where I had an idea that I wasn’t sure how to implement, and someone with the skills had helped me shape it and realize it. It gave me a sense of community and belonging. I hope I’ve forged connections with ‘Team BinderHub’ that will last the duration of our careers and we can work together again.

There’s a role for everyone in a team and these are equally important

Even if it’s reviewing code or writing documentation, these are as important (arguably, more so) than the code itself. Code that does what you think it’s doing and has been explained well will have a much longer lifespan than code that is difficult to follow, regardless of how clever it is, and poorly documented.

I found my strength as a leader

You might remember at the beginning of this blog post I mentioned that I’d never led a hack project before, so I also learned a lot about my leadership capabilities.

I think I did well. I identified the strengths of each of my team members and gave them a task suited to them whilst letting them explore new concepts, offering my own insight and opinions when required.

I also think that it was a good choice for me to not be too involved in the coding aspect of this project. Managing the flow into the repository and updating the documentation as new code came in meant that I managed to maintain an overall perspective of the project and could switch gears as questions came in from different areas. I don’t think I could have maintained such a view if I’d been buried in code, and I can always learn from the scripts that we’ve developed at a later point.

Hackathons are not where projects end

While the first 80% of a project to get the infrastructure in place can be achieved in a short amount of time like a hackathon, the last 20% is hard and often takes longer. But this extra effort is necessary for the software to be taken up by others.

‘Team BinderHub’ continued working on this project over Slack and GitHub to finally make our version 1 release on June 11th — almost 3 weeks after the end of the sprint!

If you’d like to try the button to deploy your own BinderHub (or contribute a new feature!), the repo can be found here 👉 github.com/alan-turing-institute/binderhub-deploy. Look for the button below!

Thank You! 💖

I’d like to thank a few people who made this possible:

• Gerard, Imperial College, Tania and Lee Stott from Microsoft for organising such an inspiring event;
• ‘Team BinderHub’ for coming along on this wild ride with me;
• The Binder Team for accepting me into the community and giving me the space to develop such projects;
• and The Turing Way team who introduced me to Binder and the value of community (and documentation!).

—

Note: this is cross-posted with the Turing Institute blog.

Diving into Leadership to Build Push-Button Code was originally published in Jupyter Blog on Medium, where people are continuing the conversation by highlighting and responding to this story.

Continue Reading…

Collapse

Read More

The way we control our data isn’t working. Data is as vulnerable as ever. Download this white paper, which outlines lessons about how data science and governance programs can, if implemented properly, reinforce each other’s objective.

Continue Reading…

Collapse

Read More

Scanning all new published packages on PyPI I know that the quality is often quite bad. I try to filter out the worst ones and list here the ones which might be worth a look, being followed or inspire you in some way.

• bsfc
Bayesian Spectral Fitting Code (BSFC)

• dbscan1d
dbscan1d is a package for DBSCAN on 1D arrays. (https://…/sklearn.cluster.DBSCAN.html ) does not have a special case for 1D, where calculating the full distance matrix is wasteful. It is much better to simply sort the input array and performing efficient bisects for finding closest points. Here are the results of running the simple profile script included with the package. In every case DBSCAN1D is much faster than scikit learn’s implementation.

• kinlin
WIP: PyTorch based framework

• macad-gym
Learning environments for Multi-Agent Connected Autonomous Driving (MACAD) with OpenAI Gym compatible interfaces

• pyTokenizer
A streaming tokenizer.

• syllogio-identifyPropositions
Identify natural language propositions in a written argument.

• TeaML
Automated Modeling in Financial Domain. TeaML is a simple and design friendly automatic modeling learning framework.

• timeseriesql
A Pythonic query language for time series data

• trendln
Support and Resistance Trend lines Calculator for Financial Analysis

• deepstack
DeepStack: Ensembling Keras Deep Learning Models into the next Performance Level

Continue Reading…

Collapse

Read More

A study found that a hospital program significantly reduced the number of hospitalizations and emergency department visits. Great. But then the researchers realized that the data was recoded incorrectly, and the program actually increased hospitalizations and emergency department visits. Not so great.

They retracted their paper:

The identified programming error was in a file used for preparation of the analytic data sets for statistical analysis and occurred while the variable referring to the study “arm” (ie, group) assignment was recoded. The purpose of the recoding was to change the randomization assignment variable format of “1, 2” to a binary format of “0, 1.” However, the assignment was made incorrectly and resulted in a reversed coding of the study groups. Even though the data analyst created and conducted some test analysis programs, they were of the type that did not show any labeling of the arm categories, only the “arm” variable in a regression, for example.

Here’s the original, now-retracted study. And here’s the revised one.

Data can be tricky and could lead to unintended consequences if you don’t handle it correctly. Be careful out there.

Tags: recode, retraction

Continue Reading…

Collapse

Read More

We are excited to share a free extract of Zumel, Mount, Practical Data Science with R, 2nd Edition, Manning 2019: Evaluating a Classification Model with a Spam Filter.

This section reflects an important design decision in the book: teach model evaluation first, and as a step separate from model construction.

It is funny, but it takes some effort to teach in this way. New data scientists want to dive into the details of model construction first, and statisticians are used to getting model diagnostics as a side-effect of model fitting. However, to compare different modeling approaches one really needs good model evaluation that is independent of the model construction techniques.

This teaching style has worked very well for us both in R and in Python (it is considered one of the merits of our LinkedIn AI Academy course design):

One of the best data science courses I’ve taken. The course focuses on model selection and evaluation which are usually underestimated. Thanks to John Mount, the teacher and the co-authors of Practical Data Science with R. hashtag#AI200

(Note: Nina Zumel, leads on the course design, which is the heavy lifting, John Mount just got tasked to be the one delivering it.)

Zumel, Mount, Practical Data Science with R, 2nd Edition is coming out in print very soon. Here is a discount code to help you get a good deal on the book:

Take 37% off Practical Data Science with R, Second Edition by entering fcczumel3 into the discount code box at checkout at manning.com.

Continue Reading…

Collapse

Read More

Follow this step-by-step tutorial using Tensorflow to setup a DC/OS Data Science Engine as a PaaS for enabling distributed multi-node, multi-GPU model training.

Continue Reading…

Collapse

Read More

No; I was all horns and thorns
Sprung out fully formed, knock-kneed and upright
— Joanna Newsom

Far be it for me to be accused of liking things. Let me, instead, present a corner of my hateful heart. (That is to say that I’m supposed to be doing a really complicated thing right now and I don’t want to so I’m going to scream into a void for a little while.)

The object of my ire: The 8-Schools problem.

Now, for those of you who aren’t familiar with the 8-schools problem, I suggest reading any paper by anyone who’s worked with Andrew (or has read BDA). It’s a classic.

So why hate on a classic?

Well, let me tell you. As you can well imagine, it’s because of a walrus.

I do not hate walruses (I only hate geese and alpacas: they both know what they did), but I do love metaphors. And while sometimes a walrus is just a walrus, in this case it definitely isn’t.

The walrus in question is the Horniman Walrus (please click the link to see my smooth boy!). The Horniman walrus is a mistake that you an see, for a modest fee, at a museum in South London.

The story goes like this: Back in the late 19th century someone killed a walrus, skinned it, hopefully did some other things to it, and sent it back to England to be stuffed and mounted. Now, it was the late 19th century and it turned out that the English taxidermist maybe didn’t know what a walrus looked like. (The museum’s website claims that “only a few people had ever seen a live walrus” at this point in history which, even for a museum, is really [expletive removed] white.)

But hey. He had a sawdust. He had glue. He had other things that are needed to stuff and mount a dead animal. So he took his dead animal and his tools, introduced them to each other and proudly displayed the results.

(Are you seeing the metaphor?)

Now, of course, this didn’t go well. Walruses, if you’ve never seen one, are huge creatures with loose skin folds. The taxidermist did not know this and so he stuffed the walrus full leading to a photoshop disaster of a walrus. Smooth like a beachball. A glorious mistake. And a genuine tourist attraction.

So this is my first problem. Using a problem like 8 schools as default test for algorithms has a tendency to lead to over-stuffed algorithms that are tailored to specific models. This is not a new problem. You could easily call it the NeurIPS Problem (aka how many more ways do you want to over-fit MNIST?). (Yes, I know NeurIPS has other problems as well. I’m focussing on this one.)

A different version of this problem is a complaint I remember from back in my former life when I cared about supercomputers. This was before the whole “maybe you can use big computers on data” revolution. In these dark times, the benchmarks that mattered were the speed at which you could multiply two massive dense matrices, and the speed at which you could do a dense LU decomposition of a massive matrix. Arguably neither of these things were even then the key use of high-performance computers, but as the metrics became goals, supercomputer architectures emerged that could only be used to their full capacity on very specialized problems that had enough arithmetic intensity to make use of the entire machine. (NB: This is quite possibly still true, although HPC has diversified from just talking about Cray-style architectures)

So my problem, I guess, is with benchmark problems in general.

A few other specific things:

Why so small? 8 Schools has 8 observations, which is not very many observations. We have moved beyond the point where we need to include the data in a table in the paper.

Why so meta? The weirdest thing about the 8 Schools problem is that it has the form

with appropriate priors on and . The thing here is that the observation standard deviations are known. Why? Because this is basically a meta-analysis. So 8-schools is a very specialized version of a Gaussian multilevel model. Buy fixing the observation standard deviation, the model has a much nicer posterior than the equivalent model with an unknown observation standard deviation. Hence, 8-schools doesn’t even test an algorithm on  an ordinary linear mixed model.

But it has a funnel! So does Radford Neal’s funnel distribution (in more than 17 dimensions). Sample from that instead.

But it’s real data! Firstly, no it isn’t. You grabbed it out of a book. Secondly, the idea that testing inference algorithms on real data is somehow better than systematically testing on simulated data is just wrong. We’re supposed to be statisticians so let me ask you this: How does an algorithm’s success on real data set A generalize to the set of all possible data sets? (Hint: It doesn’t.)

So, in conclusion, I am really really really sick of seeing the 8-schools data set.

Postscript: There’s something I want to clarify here: I am not saying that empirical results are not useful for evaluating inference algorithms. I’m saying that it’s only useful if the computational experiments are clear. Experiments using well-designed simulated data are unbelievably important. Real data sets are not.

Why? Because real data sets are not indicative of data that you come across in practice. This is because of selection bias! Real data sets that are used to demonstrate algorithms come in two types:

1. Data that is smooth and lovely (like 8-Schools or an over-stuffed walrus)
2. Data that is pointy and unexpected (like StackLoss, which famously has an almost singular design matrix, or this excellent photo a friend of mine once took)

Basically this means that if you have any experience with a problem at all, you can find a data set that makes y0ur method look good or that demonstrates a flaw in a competing method, or makes your method look bad. But this choice is opaque to people who are not experts in the problem at hand. Well-designed computational experiments on the other hand are clear in their aims (eg. this data has almost co-linear covariates, or this data has outliers, or this data should be totally pooled).

Simulated data is clearer, more realistic, and more honest when evaluating or even demonstrating algorithms.

Continue Reading…

Collapse

Read More

Even though I’m still in my studies, here’s a list of the most important things I’ve learned (as of yet).

Continue Reading…

Collapse

Read More

• Improving Natural Language Inference with a Pretrained Parser
• Performance of Recommender Systems: Based on Content Navigator and Collaborative Filtering
• Epistemic Logic Programs: A Different World View
• Value of Information in Probabilistic Logic Programs
• Information Extraction Tool Text2ALM: From Narratives to Action Language System Descriptions
• On the Strong Equivalences of LPMLN Programs
• Strong Equivalence for LPMLN Programs
• BigData Applications from Graph Analytics to Machine Learning by Aggregates in Recursion
• A Temporal Module for Logical Frameworks
• Induction of Non-monotonic Logic Programs To Explain Statistical Learning Models
• Conversational AI : Open Domain Question Answering and Commonsense Reasoning
• Distributed Machine Learning on Mobile Devices: A Survey
• An Adaptive Parareal Algorithm
• Distance Geometry and Data Science
• Knowledge representation and diagnostic inference using Bayesian networks in the medical discourse
• To Aid Statistical Inference, Emphasize Unconditional Descriptions of Statistics
• Simultaneous Speech Recognition and Speaker Diarization for Monaural Dialogue Recordings with Target-Speaker Acoustic Models
• Exploring Benefits of Linear Solver Parallelism on Modern Nonlinear Optimization Applications
• Split Deep Q-Learning for Robust Object Singulation
• Don’t cross that stop line: Characterizing Traffic Violations in Metropolitan Cities
• Detecting Generalized Replay Attacks via Time-Varying Dynamic Watermarking
• Spherical View Synthesis for Self-Supervised 360 Depth Estimation
• The grid theorem for vertex-minors
• Physics-guided Convolutional Neural Network (PhyCNN) for Data-driven Seismic Response Modeling
• Spectral Extremal Results for Hypergraphs
• First Steps Towards Full Model Based Motion Planning and Control of Quadrupeds: A Hybrid Zero Dynamics Approach
• Localization driven superradiant instability
• On the weights of dual codes arising from the GK curve
• The Explanation Game: Explaining Machine Learning Models with Cooperative Game Theory
• Identity-Aware Deep Face Hallucination via Adversarial Face Verification
• How auto- and cross-correlations in link dynamics influence diffusion in non-Markovian temporal networks
• Extracting evidence of supplement-drug interactions from literature
• Thermalization of entangling power with arbitrarily weak interactions
• Adjusted QMLE for the spatial autoregressive parameter
• NEMO: Future Object Localization Using Noisy Ego Priors
• CAMAL: Context-Aware Multi-scale Attention framework for Lightweight Visual Place Recognition
• On the Closed Form Expression of Elementary Symmetric Polynomials and the Inverse of Vandermonde Matrix
• Dynamics of Deep Neural Networks and Neural Tangent Hierarchy
• Generation mechanism of cell assembly to store information about hand recognition
• Decision-Directed Data Decomposition
• Multimodal Continuation-style Architectures for Human-Robot Interaction
• Finiteness of Record values and Alternative Asymptotic Theory of Records with Atom Endpoints
• Dynamic Graph Attention for Referring Expression Comprehension
• Recursive Graphical Neural Networks for Text Classification
• Weighed Domain-Invariant Representation Learning for Cross-domain Sentiment Analysis
• Analysis of the hospital records from AOK Plus
• Multiple Human Tracking using Multi-Cues including Primitive Action Features
• Automated Lane Change Decision Making using Deep Reinforcement Learning in Dynamic and Uncertain Highway Environment
• Gate Decorator: Global Filter Pruning Method for Accelerating Deep Convolutional Neural Networks
• 3D $H^2$-nonconforming tetrahedral finite elements for the biharmonic equation
• Renyi Differentially Private ADMM Based L1 Regularized Classification
• Predicting Electricity Consumption using Deep Recurrent Neural Networks
• Transfer Learning with Dynamic Adversarial Adaptation Network
• Dual Adversarial Co-Learning for Multi-Domain Text Classification
• Adaptive Graphical Model Network for 2D Handpose Estimation
• The Generalized Bregman Distance
• Quantifying Causation
• Adversarial Representation Learning for Robust Patient-Independent Epileptic Seizure Detection
• On a conjecture about a class of permutation quadrinomials
• Data Mapping for Restricted Boltzmann Machine
• Modeling Conversation Structure and Temporal Dynamics for Jointly Predicting Rumor Stance and Veracity
• Sample-specific repetitive learning for photo aesthetic assessment and highlight region extraction
• Computational multiscale methods for first-order wave equation using mixed CEM-GMsFEM
• CrackGAN: A Labor-Light Crack Detection Approach Using Industrial Pavement Images Based on Generative Adversarial Learning
• A Signal Separation Method for Exceeding the Channel Capacity of BPSK Input
• An operational test for existence of a consistent increasing quasi-concave value function
• Diversified Arbitrary Style Transfer via Deep Feature Perturbation
• The Variant-Rule, Another Logically Universal Rule
• IR-NAS: Neural Architecture Search for Image Restoration
• Pre-trained Language Model for Biomedical Question Answering
• Prolog Coding Guidelines: Status and Tool Support
• Exploiting Partial Knowledge in Declarative Domain-Specific Heuristics for ASP
• Diffusion-Based Molecular Communication Channel in Presence of a Probabilistic Absorber: Single Receptor Model and Congestion Analysis
• Mutex Graphs and Multicliques: Reducing Grounding Size for Planning
• Generating Local Search Neighborhood with Synthesized Logic Programs
• A Human-Centered Data-Driven Planner-Actor-Critic Architecture via Logic Programming
• Quantified Constraint Handling Rules
• Entanglement Sustainability in Quantum Radar
• Towards Shape Biased Unsupervised Representation Learning for Domain Generalization
• Extended Magic for Negation: Efficient Demand-Driven Evaluation of Stratified Datalog with Precise Complexity Guarantees
• Google vs IBM: A Constraint Solving Challenge on the Job-Shop Scheduling Problem
• A Rule-Based System for Explainable Donor-Patient Matching in Liver Transplantation
• Natural Language Generation for Non-Expert Users
• An ASP-based Approach for Attractor Enumeration in Synchronous and Asynchronous Boolean Networks
• Encoding Selection for Solving Hamiltonian Cycle Problems with ASP
• Advances in Big Data Bio Analytics
• Class Feature Pyramids for Video Explanation
• Towards Ethical Machines Via Logic Programming
• Reasoning about Qualitative Direction and Distance between Extended Objects using Answer Set Programming
• Design of a Solver for Multi-Agent Epistemic Planning
• Reasoning in Highly Reactive Environments
• Research Report on Automatic Synthesis of Local Search Neighborhood Operators
• Distributed Answer Set Coloring: Stable Models Computation via Graph Coloring
• Memory Management in Resource-Bounded Agents
• A Cloud-Native Globally Distributed Financial Exchange Simulator for Studying Real-World Trading-Latency Issues at Planetary Scale
• An NMPC Approach using Convex Inner Approximations for Online Motion Planning with Guaranteed Collision Freedom
• Exploring Reciprocal Attention for Salient Object Detection by Cooperative Learning
• Rates of convergence in invariance principles for random walks on linear groups via martingale methods
• Layer-adapted meshes: Milestones in 50 years of history
• Voting with Random Classifiers (VORACE)
• SINR Analysis of Different Multicarrier Waveforms over Doubly Dispersive Channels
• On the packing coloring of base-3 Sierpiński and $H$ graphs
• Global Temporal Representation based CNNs for Infrared Action Recognition
• NatCSNN: A Convolutional Spiking Neural Network for recognition of objects extracted from natural images
• SPARCAS: A Decentralized, Truthful Multi-Agent Collision-free Path Finding Mechanism
• SalsaNet: Fast Road and Vehicle Segmentation in LiDAR Point Clouds for Autonomous Driving
• Galerkin Finite Element Method for Nonlinear Riemann-Liouville and Caputo Fractional Equations
• Transferable Feature Representation for Visible-to-Infrared Cross-Dataset Human Action Recognition
• Evaluating Effects of Tuition Fees: Lasso for the Case of Germany
• LoRa Physical Layer Evaluation for Point-to-Point Links and Coverage Measurements in Diverse Environments
• Extremal Principle: Nonlinear Characterizations of Non-Intersection Properties
• Long-Term Progress and Behavior Complexification in Competitive Co-Evolution
• Text Length Adaptation in Sentiment Classification
• Hypergraph partitions
• Large e-retailer image dataset for visual search and product classification
• An Empirical Study on Arrival Rates of Limit Orders and Order Cancellation Rates in Borsa Istanbul
• Scalable Deep Unsupervised Clustering with Concrete GMVAEs
• Beyond polarization: the asymmetry of vaccine controversies in France
• An Unpaired Sketch-to-Photo Translation Model
• Memory-Augmented Neural Networks for Machine Translation
• Bayesian Strategies for Likelihood Ratio Computation in Forensic Voice Comparison with Automatic Systems
• Quantitative Impact of Label Noise on the Quality of Segmentation of Brain Tumors on MRI scans
• On infinitesimal generators of sublinear Markov semigroups
• A Survey on Rain Removal from Video and Single Image
• Higher order Trace Finite Element Methods for the Surface Stokes Equation
• Corporate IT-support Help-Desk Process Hybrid-Automation Solution with Machine Learning Approach
• Probabilistic Atlases to Enforce Topological Constraints
• A Hierarchical Two-tier Approach to Hyper-parameter Optimization in Reinforcement Learning
• Modeling the occurrence of events subject to a reporting delay via an EM algorithm
• Nonquenched rotators ease flocking and memorise it
• Singular optimal control of stochastic Volterra integral equations
• Bifurcation Spiking Neural Network
• The Generalized Fractional Benjamin-Bona-Mahony Equation: Analytical and Numerical Results
• Limited-budget output consensus for descriptor multiagent systems with energy constraints
• Data-driven model of the power-grid frequency dynamics
• Stopping Criteria for Value and Strategy Iteration on Concurrent Stochastic Reachability Games
• A Lexical, Syntactic, and Semantic Perspective for Understanding Style in Text
• Sensor Fusion for Magneto-Inductive Navigation
• Subword ELMo
• Using BERT for Word Sense Disambiguation
• Conditional Information and Inference in Response-Adaptive Allocation Designs
• Design and Realization of a Reflectarray Compact Antenna Test Range
• Message Reduction in the Local Model is a Free Lunch
• On the Infinite Lucchesi-Younger Conjecture I
• Advancing subgroup fairness via sleeping experts
• Anomaly Detection As-a-Service
• Hamilton-Jacobi-Bellman Equation for Control Systems with Friction
• Laplacian Matrix for Dimensionality Reduction and Clustering
• Continual learning: A comparative study on how to defy forgetting in classification tasks
• RUN-CSP: Unsupervised Learning of Message Passing Networks for Binary Constraint Satisfaction Problems
• DeepGait: Planning and Control of Quadrupedal Gaits using Deep Reinforcement Learning
• Quantum process tomography with unknown single-preparation input states
• Enriching BERT with Knowledge Graph Embeddings for Document Classification
• When Maximum Stable Set can be solved in FPT time
• Nonparametric Estimation of the Random Coefficients Model: An Elastic Net Approach
• A polynomial time approximation schema for maximum k-vertex cover in bipartite graphs
• Nonparametric estimation of conditional cure models for heavy-tailed distributions and under insufficient follow-up
• Semantically Interpretable Activation Maps: what-where-how explanations within CNNs
• On compatibility/incompatibility of two discrete probability distributions in the presence of incomplete specification
• Generalized permutahedra: Minkowski linear functionals and Ehrhart positivity
• Optimization of the Belief-Propagation Algorithm for Distributed Detection by Linear Data-Fusion Techniques
• Hybrid Precoding for mmWave Massive MIMO with One-Bit DAC
• Pose-aware Multi-level Feature Network for Human Object Interaction Detection
• Bibliothèque de la communauté assomptionniste : saisie informatique et classement Dewey
• On-Device User Intent Prediction for Context and Sequence Aware Recommendation
• Introduction to the Tezos Blockchain
• Line-of-Sight Deep-Space Autonomous Navigation
• Protection of helical transport in Quantum Spin Hall samples: the role of symmetries on edges
• Look-Ahead SCOPF (LASCOPF) for Tracking Demand Variation via Auxiliary Proximal Message Passing (APMP) Algorithm
• Learning from Bandit Feedback: An Overview of the State-of-the-art
• Unsupervised Writer Adaptation for Synthetic-to-Real Handwritten Word Recognition
• Simple, Scalable Adaptation for Neural Machine Translation
• Grid Anchor based Image Cropping: A New Benchmark and An Efficient Model
• Environmental Hotspot Identification in Limited Time with a UAV Equipped with a Downward-Facing Camera
• Collective sampling through a Metropolis-Hastings like method: kinetic theory and numerical experiments
• Visual Tracking by means of Deep Reinforcement Learning and an Expert Demonstrator
• Bounding Radon’s number via Betti numbers in the plane
• Word Recognition, Competition, and Activation in a Model of Visually Grounded Speech
• The Impact of Operating Environment on Efficiency of Public Libraries
• Cutting Music Source Separation Some Slakh: A Dataset to Study the Impact of Training Data Quality and Quantity
• Exploring Bit-Slice Sparsity in Deep Neural Networks for Efficient ReRAM-Based Deployment
• Regularization in Generalized Semiparametric Mixed-Effects Model for Longitudinal Data
• Hierarchical Meta-Embeddings for Code-Switching Named Entity Recognition
• Near Coverings and Cosystolic Expansion — an example of topological property testing
• Student Engagement Detection Using Emotion Analysis, Eye Tracking and Head Movement with Machine Learning
• Asymptotic preserving $P_N$ methods for haptotaxis equations
• Bias In, Bias Out? Evaluating the Folk Wisdom
• AI Modelling and Time-series Forecasting Systems for Trading Energy Flexibility in Distribution Grids
• Efficient Computation of Multi-Modal Public Transit Traffic Assignments using ULTRA
• k-Relevance Vectors for Pattern Classification
• Visual Measurement Integrity Monitoring for UAV Localization
• Regular matroids have polynomial extension complexity
• No-Regret Learning in Unknown Games with Correlated Payoffs
• Extremely Weak Supervised Image-to-Image Translation for Semantic Segmentation
• An Automated Engineering Assistant: Learning Parsers for Technical Drawings
• A note on alternating direction method of multipliers with generalized augmented terms for constrained sparse least absolute deviation
• From Bipedal Walking to Quadrupedal Locomotion: Full-Body Dynamics Decomposition for Rapid Gait Generation
• Construction of Machine Learned Force Fields with Quantum Chemical Accuracy: Applications and Chemical Insights
• From Farey fractions to the Klein quartic and beyond
• Statistical and machine learning ensemble modelling to forecast sea surface temperature
• Learning Discrepancy Models From Experimental Data
• Dynamical systems on chain complexes and canonical minimal resolutions
• Estimating maternal mortality using data from national civil registration vital statistics systems: A Bayesian hierarchical bivariate random walk model to estimate sensitivity and specificity of reporting
• Semantic and Cognitive Tools to Aid Statistical Inference: Replace Confidence and Significance by Compatibility and Surprise
• Re-ID Driven Localization Refinement for Person Search
• Code-Switched Language Models Using Neural Based Synthetic Data from Parallel Sentences
• Decoupling stochastic optimal control problems for efficient solution: insights from experiments across a wide range of noise regimes
• Random concave functions on an equilateral lattice with periodic hessians
• Unsupervised Segmentation of Fire and Smoke from Infra-Red Videos
• The dimension of the boundary of a Liouville quantum gravity metric ball

Continue Reading…

Collapse

Read More

Improving Natural Language Inference with a Pretrained Parser

Performance of Recommender Systems: Based on Content Navigator and Collaborative Filtering

Epistemic Logic Programs: A Different World View

Value of Information in Probabilistic Logic Programs

Information Extraction Tool Text2ALM: From Narratives to Action Language System Descriptions

On the Strong Equivalences of LPMLN Programs

Strong Equivalence for LPMLN Programs

BigData Applications from Graph Analytics to Machine Learning by Aggregates in Recursion

A Temporal Module for Logical Frameworks

Induction of Non-monotonic Logic Programs To Explain Statistical Learning Models

Conversational AI : Open Domain Question Answering and Commonsense Reasoning

Distributed Machine Learning on Mobile Devices: A Survey

An Adaptive Parareal Algorithm

Distance Geometry and Data Science

Knowledge representation and diagnostic inference using Bayesian networks in the medical discourse

To Aid Statistical Inference, Emphasize Unconditional Descriptions of Statistics

Continue Reading…

Collapse

Read More

SDA is a suite of software developed at Berkeley for the web-based analysis of survey data. The Berkeley SDA archive (http://sda.berkeley.edu) lets you run various kinds of analyses on a number of public datasets, such as the General Social Survey. It also provides consistently-formatted HTML versions of the codebooks for the surveys it hosts. This is very convenient! For the gssr package, I wanted to include material from the codebooks as tibbles or data frames that would be accessible inside an R session. Processing the official codebook from its native PDF state into a data frame is, though technically possible, a rather off-putting prospect. But SDA has done most of the work already by making the pages available in HTML. I scraped the codebook pages from them instead. This post contains the code I used to do that.

Although I haven’t looked in detail, it seems that SDA has almost identical codebooks for the other surveys it hosts. so this code could be adapted for use with them. There will be some differences—e.g. the GSS has a “Text of this Question” field along with marginal summaries of the variable for each question in the survey, while the ANES seems to lack that field. But it seems clear that the HTML/CSS structure that SDA output is basically the same across datasets.

Here’s the code for the GSS documentation. There’s a GitHub repository that will allow you to reproduce what you see here. I’ve included the html files in the repository so you don’t have to scrape the SDA site. Do not try to slurp up the content of the SDA site in a way that is rude to their server.

Libraries

library(tidyverse)
library(rvest)

Scrape the GSS codebook from SDA

This next code chunk shows how we got the codebook data, but it is not evaluated (we set eval = FALSE), because we only need to do it once. We use sprintf() to generate a series of numbers with leading zeros, of the form 001, 002, 003, and so on. The 261 is hard-coded for this particular directory, but we should really grab the directory listing, evaluate how many files it lists (of the sort we want), and then use that number instead.

## Generate vector of doc page urls
urls <- paste0("https://sda.berkeley.edu/D3/GSS18/Doc/", 
               "hcbk", sprintf('%0.4d', 1:261), ".htm")


## Grab the codebook pages one at a time
doc_pages <- urls %>% 
  map(~ {
    message(glue::glue("* parsing: {.x}"))
    Sys.sleep(5) # try to be polite
    safely(read_html)(.x)
  })

Save the scraped webpages locally

There’s a gotcha with objects like doc_pages: they cannot be straightforwardly saved to R’s native data format with save(). The XML files are stored with external pointers to their content and cannot be “serialized” in a way that saves their content properly. If you try, when you load() the saved object you will get complaints about missing pointers. So instead, we’ll unspool our list and save each page individually. Then if we want to rerun this analysis without crawling everything again, we will load them in from our local saved versions using read_html().

Again, this code chunk is shown but not run, as we only do it once.

## Get a list containing every codebook webpage, 
## Drop the safely() error codes from the initial scrape (after we've checked them), 
## and also drop any NULL entries
page_list <- pluck(doc_pages, "result") %>% 
  compact()

## Make a vector of clean file names of the form "raw/001.htm"
## One for every page we grabbed. Same order as the page_list.
## We use sprintf to get numbers of the form 001, 002, 003 etc.
fnames <-paste0("raw/", 
                sprintf('%0.4d', 1:length(doc_pages)),
                ".htm") 

## Walk the elements of the page list and the file names to 
## save each HTML file under is respective local file name
walk2(page_list, fnames, ~ write_xml(.x, file = .y))

The walk() and walk2() functions are very handy for processing batches of items when you want to produce a “side-effect” of the function you’re mapping, such as a plot or (in this case) a saved file.

Read in the pages from the local directory

Using the local data we’ve saved, we read in a list of all the web pages. Our goal is to get them into a tractable format (a tibble or data frame). From there we can write some functions to, e.g., query the codebook directly from the console, or alterantively produce the codebook in a format suitable for integrating into the R help system via a package.

## The names of all the files we just created
local_urls <- fs::dir_ls("raw/")

## Read all the pages back in, from local storage 
doc_pages <- local_urls %>% 
  map(~ {
    safely(read_html)(.x)
  })

## Are there any errors?
doc_pages %>% pluck("error") %>% 
  flatten_dfr()

## # A tibble: 0 x 0

## quick look at first five items in the list
summary(doc_pages)[1:5,]

##              Length Class  Mode
## raw/0001.htm 2      -none- list
## raw/0002.htm 2      -none- list
## raw/0003.htm 2      -none- list
## raw/0004.htm 2      -none- list
## raw/0005.htm 2      -none- list

## Quick look inside the first record
doc_pages[[1]]

## $result
## {html_document}
## 
## [1] \n
## [2] \n
\n
\n
 General Social Survey 1972-2018 Cumula ...
## 
## $error
## NULL

Parse the pages

Next, we parse every webpage to extract a row for every variable. There are multiple variables per page.

Functions

## Page of variables to list of variables and their info, 
parse_page <- function(x){
  html_nodes(x, ".dflt") %>%
    map(~ html_nodes(.x, ".noborder")) %>%
    map(~ html_table(.x))
}

## Length of each list element
## Standard GSS Qs will have 4 elements
## Ids recodes and other things will have 3
get_lengths <- function(x){
  map(x, length)
}

get_names <- function(x){
  map(x, names)
}

## Variable short names and descriptions
get_var_ids <- function(x){
  x %>% map_dfr(1) %>%
    select(id = X1, description = X3) %>%
    as_tibble()
}


## Question Text
get_text <- function(x, y){
  if(y[[1]] == 3) {
    return(NA_character_)
  } else {
    stringr::str_trim(x[[2]])
  }
}

## Question Marginals
get_marginals <- function(x, y){
  if(y[[1]] == 3) {
    tmp <- x[[2]]
  } else {
    tmp <- x[[3]]
  }
  
  if(ncol(tmp) == 2) {
    as_tibble(tmp) %>%
      select(cases = X1, range = X2)
  } else {
    tmp <- as_tibble(tmp[, colSums(is.na(tmp)) != nrow(tmp)]) %>%
      janitor::clean_names()
    tmp$value <- as.character(tmp$value)
    tmp
  }
}

## Add an id column
add_id <- function(x, y){
  x %>% add_column(id = y)
}

## Question Properties
get_props <- function(x, y){
  if(y[[1]] == 3) {
    tmp <- x[[3]]
    colnames(tmp) <- c("property", "value")
    tmp <- as_tibble(tmp)
    tmp$property <- stringr::str_remove(tmp$property, ":")
    tmp
  } else {
    tmp <- x[[4]]
    colnames(tmp) <- c("property", "value")
    tmp <- as_tibble(tmp)
    tmp$property <- stringr::str_remove(tmp$property, ":")
    tmp
  }
}

## Take the functions above and process a page to a tibble of cleaned records

process_page <- function(x){
  page <- parse_page(x)
  q_vars <- get_var_ids(page)
  lens <- get_lengths(page)
  keys <- q_vars$id
  
  q_text <- map2_chr(page, lens, ~ get_text(.x, .y))
  q_text <- stringr::str_trim(q_text)
  q_text <- stringr::str_remove_all(q_text, "\n")
  q_text <- tibble(id = keys, q_text = q_text)
  q_text <- q_text %>%
    mutate(q_text = replace_na(q_text, "None"))
  q_marginals <- map2(page, lens, ~ get_marginals(.x, .y)) %>%
    set_names(keys) 
  q_marginals <- map2(q_marginals, keys, ~ add_id(.x, .y))
  
  q_props <- map2(page, lens, ~ get_props(.x, .y)) %>%
    set_names(keys) 
  q_props <- map2(q_props, keys, ~ add_id(.x, .y))
  
  q_tbl <- q_vars %>% 
    add_column(properties = q_props) %>% 
    add_column(marginals = q_marginals) %>%
    left_join(q_text) %>%
    rename(text = q_text)
  
  q_tbl

  }

Make the tibble

Parse the GSS variables into a tibble, with list columns for the marginals and the variable properties.

gss_doc <-  doc_pages %>% 
  pluck("result") %>% # Get just the webpages
  compact() %>%
  map(process_page) %>%
  bind_rows()

Look at the outcome

gss_doc

## # A tibble: 6,144 x 5
##    id     description      properties   marginals   text                   
##                                                 
##  1 CASEID YEAR + Responde… 
##  2 YEAR   GSS year for th… 
##  3 ID     Respondent ID n… 
##  4 AGE    Age of responde… 
##  5 SEX    Respondents sex  
##  6 RACE   Race of respond… 
##  7 RACEC… What Is R's rac… 
##  8 RACEC… What Is R's rac… 
##  9 RACEC… What Is R's rac… 
## 10 HISPA… Hispanic specif… 
## # … with 6,134 more rows

gss_doc$id <- tolower(gss_doc$id)

gss_doc %>% filter(id == "race") %>% 
  select(text)

## # A tibble: 1 x 1
##   text                                   
##                                     
## 1 24. What race do you consider yourself?

gss_doc %>% filter(id == "race") %>% 
  select(marginals) %>% 
  unnest(cols = c(marginals))

## # A tibble: 4 x 5
##   percent n      value label id   
##          
## 1    80.3 52,033 1     WHITE RACE 
## 2    14.2 9,187  2     BLACK RACE 
## 3     5.5 3,594  3     OTHER RACE 
## 4   100   64,814   Total RACE

gss_doc %>% filter(id == "sex") %>% 
  select(text)

## # A tibble: 1 x 1
##   text                     
##                       
## 1 23. Code respondent's sex

gss_doc %>% filter(id == "sex") %>% 
  select(marginals) %>% 
  unnest(cols = c(marginals))

## # A tibble: 3 x 5
##   percent n      value label  id   
##           
## 1    44.1 28,614 1     MALE   SEX  
## 2    55.9 36,200 2     FEMALE SEX  
## 3   100   64,814   Total  SEX

gss_doc %>% filter(id == "fefam") %>% 
  select(text)

## # A tibble: 1 x 1
##   text                                                                     
##                                                                       
## 1 252. Now I'm going to read several more statements. As I read each one, …

gss_doc %>% filter(id == "fefam") %>% 
  select(properties) %>% 
  unnest(cols = c(properties))

## # A tibble: 3 x 3
##   property           value   id   
##                    
## 1 Data type          numeric FEFAM
## 2 Missing-data codes 0,8,9   FEFAM
## 3 Record/column      1/1114  FEFAM

Save the data object as efficiently as we can

Shown here but not run.

save(gss_doc, file = "data/gss_doc.rda", 
     compress = "xz") 

# tools::checkRdaFiles("data")

Continue Reading…

Collapse

Read More

I kinda like this little article which I wrote a couple years ago while on the train from the airport. It will appear in the journal Socius. Here’s how it begins:

Science is in crisis. Any doubt about this status has surely been been dispelled by the loud assurances to the contrary by various authority figures who are deeply invested in the current system and have written things such as, “Psychology is not in crisis, contrary to popular rumor . . . Crisis or no crisis, the field develops consensus about the most valuable insights . . . National panels will convene and caution scientists, reviewers, and editors to uphold standards.” (Fiske, Schacter, and Taylor, 2016). When leaders go to that much trouble to insist there is no problem, it’s only natural for outsiders to worry.

The present article is being written for a sociology journal, which is appropriate for two reasons. First, sociology includes the study of institutions and communities; modern science is both an institution and a community, and as such it would be of interest to me as a citizen and a political scientist, even beyond my direct involvement as a practicing researcher. Second, sociology has a tradition of questioning; it is a field from whose luminaries I hope never to hear platitudes such as “Crisis or no crisis, the field develops consensus about the most valuable insights.” Sociology, like statistics and political science, is inherently accepting of uncertainty and variation. Following Karl Popper, Thomas Kuhn, Imre Lakatos, and Deborah Mayo, we cheerfully build our theories as tall and broad as we can, in the full awareness that reality will knock them down. We know that one of the key purposes of data analysis is to “kill our darlings,” and we also know that the more specific we make our models, the more we learn from their rejection. Structured modeling and thick description go together.

Just as we learn in a local way from our modeling failures, we can learn more globally from crises in entire subfields of science. When I say that the replication crisis is also an opportunity, this is more than a fortune-cookie cliche; it is also a recognition that when a group of people make a series of bad decisions, this motivates a search for what went wrong in their decision-making process.

A full discussion of the crisis in science would include three parts:

1. Evidence that science is indeed in crisis: at the very least, a series of examples of prominent products of mainstream science that were seriously flawed but still strongly promoted by the scientific community, and some evidence or at least speculation that such problems are prevalent enough to be worth our concern.

2. A discussion of what has gone wrong in the ideas and methods of scientific inquiry and in the process by which scientific claims are promoted and disseminated within the community and the larger society. This discussion could include specific concerns about statistical methods such as null hypothesis significance testing, and also institutional issues such as the increasing pressure on research to publish large numbers of articles.

3. Proposed solutions, which again range from research methods (for example, the suggestion to perform within-person, rather than between-person, comparisons wherever possible) to rules such as preregistration of hypotheses, to changes in the system of scientific publication and credit.

I and others have written enough on topics 1 and 2, and since this article has been solicited for a collection on Fixing Science, I’ll restrict my attention to topic 3: what to do about the problem?

I then continue:

If you’ve gone to the trouble to pick up (or click on) this volume in the first place, you’ve probably already seen, somewhere or another, most of the ideas I could possibly propose on how science should be fixed. My focus here will not be on the suggestions themselves but rather on what are our reasons for thinking these proposed innovations might be good ideas. The unfortunate paradox is that the very aspects of “junk science” that we so properly criticize—the reliance on indirect, highly variable measurements from nonrepresentative samples, open-ended data analysis, followed up by grandiose conclusions and emphatic policy recommendations drawn from questionable data— all seem to occur when we suggest our own improvements to the system. All our carefully-held principles seem to evaporate when our emotions get engaged. . . .

After some discussion of potential solutions, I conclude:

The foregoing review is intended to be thought provoking, but not nihilistic. One of the most important statistical lessons from the recent replication crisis is that certainty or even near-certainty is harder to come by then most of us had imagined. We need to make some decisions in any case, and as the saying goes, deciding to do nothing is itself a decision. Just as an anxious job-interview candidate might well decide to chill out with some deep breaths, full-body stretches, and a power pose, those of us within the scientific community have to make use of whatever ideas are nearby, in order to make the micro-decisions that, in the aggregate, drive much of the directions of science. And, when considering larger ideas, proposals for educational requirements or recommendations for new default statistical or research methods or reorganizations of the publishing system, we need to recognize that our decisions will necessarily rely much more on logic and theory than on direct empirical evidence. This suggests in turn that our reasoning be transparent and openly connected to the goals and theories that motivate and guide our attempts toward fixing science.

It’s fun, writing an article like this from first principles, with no position to defend, just trying to think things through.

Continue Reading…

Collapse

Read More

In this research guide, we’ll look at deep learning papers aimed at synthesizing video frames within an existing video.

Continue Reading…

Collapse

Read More

TL;DR

Why use object-oriented programming in Shiny applications? It’ll help organizize organize the code in your application!  

Organize Your Shiny Code with Object-Oriented Programming

Classes are used widely in all R programming — usually the S3 ones. Even if you’ve never heard of them, as an R user you’re for sure familiar with object classes like data.frame. The magic of classes makes same functions (like print or plot) operate differently for specific cases. This system also allows you to define methods and attributes dedicated for object – thus basing your code around objects, not functions. How can it be useful in Shiny app? Well, for advanced apps it helps you in organizing your code. When designing a Shiny app it is often the way it should work – usually the user is interacting with some specific data structure that requires e.g. exploration, modification, saving, exporting etc. What is more, Shiny apps contain much more additional stuff required for production-ready applications that will work great when being organizized organized in a class system.

Let us go through this functionality. 

You may wonder what objects can be stored in the app. Well, there might be ‘settings’ with private fields of configuration and public methods to get or modify them. There might be a ‘user data’ class with all of the values specific for the logged-in user and methods to read them. The data probably comes from some database, the connection to which may be another class, as well as the log builder. And some specific spatial dataset used on this new screen that required unusual functions to operate on. And so on…

The point is this: once your app grows with new functionalities you will end up with tons of functions organized between multiple ‘utils-something’ scripts and a bunch of lists with stored current values. Using object oriented programming (OOP) in the Shiny App allows developers to organize the code in the packs object-attributes-functions. It will introduce a clear system of getting the current state of the piece of functionality, the operations that can be performed with it, the auxiliary functions, the initial state of the object (which can depend on the particular user access rights, which might be very useful!).

In Appsilon we recommend using an R6 class system. What is R6? To make a long story short, it is a modern, fast and simple implementation of object-oriented programming (OOP) in R. To learn more about the system, check Hadley’s Advanced R book.

How do we recommend organizing the code with the class system introduced? Keep each class in the separated script with a name similar to the class name, and store them all together in a folder separated from other code e.g. ui definitions of modules (folders structure might be problematic when developing a Shiny app as a package – doing it has pros and cons. In Appsilon we do not package our apps as it gives us more freedom with building the apps). Once the code is imported (either in a package or separately with e.g. modules::use function) the class needs to be initialized in the global.R script with the new() method (automatically available for all classes) and attached to some object. The class, its attributes and methods can be used everywhere in the code – but you’ve gained a clear overview of the purpose of the method call and what object it modifies and where to find the details about this particular functionality.

Here’s a practice example: 

# in global.R
logger_manager = LoggerManager$new()

# in logger_manager.R
LoggerManager <- R6Class(
  "LoggerManager",
  private = list(
    ...
  ),
  public = list(
    initialize = function() {
      ...
    },
    log_input = function(
     ...
    ) {
      ...
    }
  )
)

It might not be obvious from the beginning which classes will be used in the code – Shiny apps often start as a simple prototype to finally become some advanced production solution. Just don’t be afraid and always have in mind that classes are a good solution to organize your code once your app goes big! 

Thanks for reading!  Questions? Comments? Add them below and/or find me on Twitter @dubelmarcin.  You can also check out the other posts in the “Super Solutions for Shiny Architecture Series”: #1 Using Session Data, #2 Javascript is your friend, and #3 Softcoding Constants in the App.   

And don’t forget to sign up for our newsletter!

Article Super Solutions for Shiny Apps #4 of 5: Using R6 Classes comes from Appsilon Data Science | End­ to­ End Data Science Solutions.

Continue Reading…

Collapse

Read More

Bayesian networks are really useful for many applications and one of those is to simulate new data. Bayes nets represent data as a probabilistic graph and from this structure it is then easy to simulate new data. This post will demonstrate how to do this with bnlearn.

Fit a Bayesian network

Before simulating new data we need a model to simulate data from. Using the same Australian Institute of Sport dataset from my previous post on Bayesian networks we’ll set up a simple model. For convenience I’ll subset the data to 6 variables.

library(DAAG)
library(tidyverse)

# ais data from the DAAG package
ais_sub <- ais %>% dplyr::select(sex, sport, pcBfat, hg, rcc, hc)

The variables sex and sport are pretty straight forward. The remaining four are

• pcBfat – percent of body fat
• hg – hemoglobin concentration
• rcc – red cell count
• hc – hematocrit percentage

I’ve allowed the data to learn the structure of the network, bar one arc, sport to percentage of body fat. The details are not shown here, but check out the post above on how to fit the structure algorithmically (also I suggest heading to the bnlearn doco which has great examples of a number of networks that can be downloaded). The structure is defined by the string and converted to a bn class object.

library(visNetwork)
library(bnlearn)

# set structure
bn_struct <- model2network("[sex][sport|sex][hg|sex][pcBfat|sex:sport][hc|hg:pcBfat][rcc|hc]")
bn_struct

## 
##   Random/Generated Bayesian network
## 
##   model:
##    [sex][hg|sex][sport|sex][pcBfat|sex:sport][hc|hg:pcBfat][rcc|hc] 
##   nodes:                                 6 
##   arcs:                                  7 
##     undirected arcs:                     0 
##     directed arcs:                       7 
##   average markov blanket size:           2.67 
##   average neighbourhood size:            2.33 
##   average branching factor:              1.17 
## 
##   generation algorithm:                  Empty

# plot network - code for function at end of post
plot.network(bn_struct)

Now that we have set the structure of the model it is fit to the data with bn.fit using maximum likelihood estimation.

bn_mod <- bn.fit(bn_struct, data = ais_sub, method = "mle")

The output is quite detailed so it’s worth running bn_mod to view the conditional probability tables and Gaussian distributions.

Simulate data

New data is simulated from a Bayes net by first sampling from each of the root nodes, in this case sex. Then followed by the children conditional on their parent(s) (e.g. sport | sex and hg | sex) until data for all nodes has been drawn. The numbers on the nodes below indicate the sequence in which the data is simulated, noting that rcc is the terminal node.

From this point it’s easy to simulate new data using rbn. Here we simulate a dataset the same size as the original, but you can simulate as many rows as needed.

ais_sim <- rbn(bn_mod, 202)
head(ais_sim)

##         hc       hg    pcBfat      rcc sex   sport
## 1 38.00754 12.43565 13.772499 3.917082   f    Swim
## 2 45.54250 15.79388 13.586402 4.824458   m   Field
## 3 49.87429 17.31542  5.308675 5.814398   m  T_400m
## 4 49.05707 17.19443  9.230973 5.337367   m  W_Polo
## 5 37.66307 12.99088 13.685909 4.020170   f     Gym
## 6 42.33715 14.62894 15.147165 4.440556   f Netball

Done. We now have a fully synthetic dataset which retains the properties of the original data. And it only took a few lines of code.

An important property of generating synthetic data is that it doesn’t use real data to do so, meaning any predictors need to be simulated first (my post on the synthpop package explains this in more detail). This property is retained since the data is generated sequentially as per the structure of network. Also, when using synthpop the order in which the variables are simulated needs to be set. The order can alter the accuracy of simulated dataset and so it’s important to spend the time to get it right. For a Bayesian network the order is determined by the structure, so in effect this step is already done.

Compare original and simulated datasets

The original and simulated datasets are compared in a couple of ways 1) observing the distributions of the variables 2) comparing the output from various models and 3) comparing conditional probability queries. The third test is more of a sanity check. If the data is generated from the original Bayes net then a new one fit on the simulated data should be approximately the same. The more rows we generate the closer the parameters will be to the original values.

The variable distributions are very close to the original with only a small amount of variation, mostly observed in sport. Red cell count may have a slight bi-modal distribution but in most part it’s a good fit. This amount of variation is reasonable since there are only 202 simulated observations. Simulating more rows will be a closer fit but there are often practical considerations for retaining the same size dataset.

For the second check, two linear models are fit to the original and simulated data to predict hematocrit levels with sex, hemoglobin concentration, percentage of body fat and red cell count as predictors. Sport was left out of the model since it was not a strong predictor of hc and only increased the error.

# fit models
glm_og <- glm(hc ~ hg + rcc + pcBfat + sex, data = ais_sub)
glm_sim <- glm(hc ~ hg + rcc + pcBfat + sex, data = ais_sim)

# print summary
summary(glm_og)

## 
## Call:
## glm(formula = hc ~ hg + rcc + pcBfat + sex, data = ais_sub)
## 
## Deviance Residuals: 
##     Min       1Q   Median       3Q      Max  
## -3.9218  -0.4868   0.0523   0.5470   2.8983  
## 
## Coefficients:
##             Estimate Std. Error t value Pr(>|t|)    
## (Intercept)  5.15656    1.04109   4.953 1.57e-06 ***
## hg           1.64639    0.11520  14.291  < 2e-16 ***
## rcc          3.04366    0.31812   9.568  < 2e-16 ***
## pcBfat      -0.02271    0.01498  -1.517    0.131    
## sexm        -0.20182    0.23103  -0.874    0.383    
## ---
## Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
## 
## (Dispersion parameter for gaussian family taken to be 0.888242)
## 
##     Null deviance: 2696.92  on 201  degrees of freedom
## Residual deviance:  174.98  on 197  degrees of freedom
## AIC: 556.25
## 
## Number of Fisher Scoring iterations: 2

summary(glm_sim)

## 
## Call:
## glm(formula = hc ~ hg + rcc + pcBfat + sex, data = ais_sim)
## 
## Deviance Residuals: 
##     Min       1Q   Median       3Q      Max  
## -2.2117  -0.6232   0.0089   0.5910   2.0073  
## 
## Coefficients:
##              Estimate Std. Error t value Pr(>|t|)    
## (Intercept)  5.318057   0.953131   5.580  7.9e-08 ***
## hg           1.633765   0.107235  15.235  < 2e-16 ***
## rcc          2.905111   0.299397   9.703  < 2e-16 ***
## pcBfat      -0.001506   0.014768  -0.102    0.919    
## sexm         0.319853   0.220904   1.448    0.149    
## ---
## Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
## 
## (Dispersion parameter for gaussian family taken to be 0.7520993)
## 
##     Null deviance: 3014.20  on 201  degrees of freedom
## Residual deviance:  148.16  on 197  degrees of freedom
## AIC: 522.64
## 
## Number of Fisher Scoring iterations: 2

The coefficients and test statistics of the models are very similar, so both datasets result in the same conclusions. Percent of body fat is the least accurate but still make the same conclusion. In practice you should fit more models to assess the quality of the simulated data.

As mentioned the third is more of a sanity check but it is also a good demonstration of the process. By fitting the same structure to the simulated data we expect to estimate the same parameters and calculate very similar conditional probabilities. Here we simulate 20 000 observations to better estimate the parameters. The conditional probability for the athletes red cell count given the sport they compete in i.e. what is the probability the athletes red cell count will be greater than where is the 33rd and 66th percentile?

library(progress) 

# fit bayes net with the same structure using simulated
ais_sim <- rbn(bn_mod, 2e4)
bn_mod_sim <- bn.fit(bn_struct, ais_sim, method = "mle")

# sport - mcpquery function at end of post - it generalises bnlearn::cpquery
# rcc is continuous so we're calculating the probability rcc > some value, here the 33rd and 66th percentile 
# the function replaces xx and yy with actually values and evaluates the text
given <- "sport == 'xx'"
event <- "rcc > yy"
vals <- as.matrix(expand.grid(sport = unique(ais_sub$sport), rcc = quantile(ais_sub$rcc, c(0.33, 0.66))))
orig <- mcpquery(bn_mod, values = vals, token = c("xx", "yy"), event, given, n = 1e6) %>% spread(rcc, cp)

## P( rcc > yy | sport == 'xx' )

sim <- mcpquery(bn_mod_sim, values = vals, token = c("xx", "yy"), event, given, n = 1e6) %>% spread(rcc, cp)

## P( rcc > yy | sport == 'xx' )

# join for display
left_join(orig, sim, by = "sport", suffix = c("_orig", "_sim"))

## # A tibble: 10 x 5
##    sport   `4.4533_orig` `4.9466_orig` `4.4533_sim` `4.9466_sim`
##                                        
##  1 B_Ball          0.687        0.310         0.682       0.302 
##  2 Field           0.764        0.386         0.768       0.384 
##  3 Gym             0.477        0.0658        0.475       0.0717
##  4 Netball         0.444        0.0584        0.442       0.0575
##  5 Row             0.652        0.270         0.654       0.271 
##  6 Swim            0.752        0.370         0.758       0.376 
##  7 T_400m          0.767        0.388         0.769       0.386 
##  8 T_Sprnt         0.822        0.449         0.826       0.445 
##  9 Tennis          0.640        0.251         0.639       0.249 
## 10 W_Polo          0.945        0.571         0.944       0.566

The conditional probabilities from the simulated data are very close to the original as expected. Now we can be confident that our simulated data can be used as an alternative to the original.

Impute data

Another useful property of Bayes nets is to impute missing values. This is easily done using impute. We’ll remove 25% of the observations from variables hg and hc, and allow the Bayes net to impute them.

ais_miss <- ais_sub
miss_id <- sample(1:nrow(ais_sub), 50)
ais_miss[miss_id, c("hg", "hc")] <- NA

# table counting the NA values in hg and hc
apply(ais_miss[,c("hg", "hc")], 2, function(x) table(is.na(x)))

##        hg  hc
## FALSE 152 152
## TRUE   50  50

The table confirms there are 50 missing observations from hemoglobin and hematocrit variables. Now impute using Bayesian likelihood weighting.

ais_imp <- impute(bn_mod, data = ais_miss, method = "bayes-lw")

Plotting the imputed against the true values shows the Bayes net imputed the missing values quite well.

I’ve only tested and shown two variables but the others would perform similarly for the subset of data I have chosen. This data is normally distributed so I expected it to work well, however if your data has more complex relationships you’ll need to be more rigorous with defining the structure.

Code bits

# plot network function
plot.network <- function(structure, ht = "400px", cols = "darkturquoise", labels = nodes(structure)){
  if(is.null(labels)) labels <- rep("", length(nodes(structure)))
  nodes <- data.frame(id = nodes(structure),
                      label = labels,
                      color = cols,
                      shadow = TRUE
                      )

  edges <- data.frame(from = structure$arcs[,1],
                      to = structure$arcs[,2],
                      arrows = "to",
                      smooth = FALSE,
                      shadow = TRUE,
                      color = "black")

  return(visNetwork(nodes, edges, height = ht, width = "100%"))
}

# conditional probability query functions
mcpquery <- function(mod, values, token, event, given, ns = 1e4){
  cat("P(", event, "|", given, ")\n")
  UseMethod("mcpquery", values)
}

# numeric
mcpquery.numeric <- function(mod, values, token, event, given, ns = 1e4){
  y <- rep(NA, length(values))
  pb <- progress_bar$new(
    format = "time :elapsedfull // eta :eta // :k of :n // P( :event | :given )", 
    clear = FALSE, total = length(values))
  for(k in 1:length(values)){
    givenk <- gsub(token, values[k], given)
    eventk <- gsub(token, values[k], event)
    pb$tick(token = list(k = k, n = length(values), event = eventk, given = givenk))
    y[k] <- eval(parse(text = paste0("cpquery(mod,", eventk, ",", givenk, ", n = ", ns, ", method = 'ls')")))
  }
  return(tibble(values = values, cp = y) %>% arrange(desc(cp)))
}

# character
mcpquery.character <- function(mod, values, token, event, given, ns = 1e4){
  y <- rep(NA, length(values))
  pb <- progress_bar$new(
    format = "time :elapsedfull // eta :eta // :k of :n // P( :event | :given )", 
    clear = FALSE, total = length(values))
  for(k in 1:length(values)){
    givenk <- gsub(token, values[k], given)
    eventk <- gsub(token, values[k], event)
    pb$tick(token = list(k = k, n = length(values), event = eventk, given = givenk))
    y[k] <- eval(parse(text = paste0("cpquery(mod,", eventk, ",", givenk, ", n = ", ns, ", method = 'ls')")))
  }
  return(tibble(values = values, cp = y) %>% arrange(desc(cp)))
}

# matrix
mcpquery.matrix <- function(mod, values, token, event, given, ns = 1e4){

  n <- nrow(values)
  y <- rep(NA, n)

  pb <- progress_bar$new(
    format = "time :elapsedfull // eta :eta // :k of :n // P( :event | :given )", 
    clear = FALSE, total = n)

  for(k in 1:n){
    givenk <- given
    eventk <- event
    for(j in 1:ncol(values)){
      givenk <- gsub(token[j], values[k,j], givenk)
      eventk <- gsub(token[j], values[k,j], eventk)
    }
    pb$tick(token = list(k = k, n = n, event = eventk, given = givenk))
    y[k] <- eval(parse(text = paste0("cpquery(mod,", eventk, ",", givenk, ", n = ", ns, ", method = 'ls')")))
  }
  out <- as.tibble(values) %>%
    bind_cols(tibble(cp = y))
  colnames(out)[1:ncol(values)] <- colnames(values)
  return(out)
}


# compare the synthetic and original data frames
df <- ais_sub %>% 
  mutate(type = "orig") %>% 
  bind_rows(
    rbn(bn_mod, 202) %>% 
      mutate(type = "sim")
    ) # %>% 
gg_list <- list()
grp_var <- "type"
vars <- colnames(df)[colnames(df) != grp_var]
for(k in 1:length(vars)){
  var_k <- vars[k]
  gg_list[[k]] <- ggplot(df, aes_string(x = var_k, fill = grp_var, col = grp_var))
  if(is.numeric(df[[var_k]])){
    gg_list[[k]] <- gg_list[[k]] + geom_density(alpha = 0.85, size = 0)
  }else{
    gg_list[[k]] <- gg_list[[k]] + geom_bar(position = "dodge")
  }
  gg_list[[k]] <- gg_list[[k]] + 
    theme(
      axis.text.x = element_text(angle = 90),
      axis.title.x = element_blank()
    ) +
    labs(title = var_k)
}

The post Simulating data with Bayesian networks appeared first on Daniel Oehm | Gradient Descending.

Continue Reading…

Collapse

Read More

Riinu and I are sitting in Frankfurt airport discussing the paper retracted in JAMA this week.

During analysis, the treatment variable coded [1,2] was recoded in error to [1,0]. The results of the analysis were therefore reversed. The lung-disease self-management program actually resulted in more attendances at hospital, rather than fewer as had been originally reported.  

Recode check

Checking of recoding is such an important part of data cleaning – we emphasise this a lot in HealthyR courses – but of course mistakes happen.

Our standard approach is this:

library(finalfit)
colon_s %>%
  mutate(
    sex.factor2 = forcats::fct_recode(sex.factor,
      "F" = "Male",
      "M" = "Female")
  ) %>%
  count(sex.factor, sex.factor2)
# A tibble: 2 x 3
  sex.factor sex.factor2     n
               
1 Female     M             445
2 Male       F             484

The miscode should be obvious.

check_recode()

However, mistakes may still happen and be missed. So we’ve bashed out a useful function that can be applied to your whole dataset. This is not to replace careful checking, but may catch something that has been missed. 

The function takes a data frame or tibble and fuzzy matches variable names. It produces crosstables similar to above for all matched variables. 

So if you have coded something from sex to sex.factor it will be matched. The match is hungry so it is more likely to match unrelated variables than to miss similar variables. But if you recode death to mortality it won’t be matched. 

Here’s a walk through.

# Install
devtools::install_github('ewenharrison/finalfit')
library(finalfit)
library(dplyr)
# Recode example
colon_s_small = colon_s %>%
  select(-id, -rx, -rx.factor) %>%
  mutate(
    age.factor2 = forcats::fct_collapse(age.factor,
      "<60 years" = c("<40 years", "40-59 years")),
    sex.factor2 = forcats::fct_recode(sex.factor,
    # Intentional miscode
      "F" = "Male",
      "M" = "Female")
  )
# Check
colon_s_small %>%
  check_recode()
$index
# A tibble: 3 x 2
  var1        var2       
               
1 sex.factor  sex.factor2
2 age.factor  age.factor2
3 sex.factor2 age.factor2
$counts
$counts[[1]]
# A tibble: 2 x 3
  sex.factor sex.factor2     n
               
1 Female     M             445
2 Male       F             484
$counts[[2]]
# A tibble: 3 x 3
  age.factor  age.factor2     n
                
1 <40 years   <60 years      70
2 40-59 years <60 years     344
3 60+ years   60+ years     515
$counts[[3]]
# A tibble: 4 x 3
  sex.factor2 age.factor2     n
                
1 M           <60 years     204
2 M           60+ years     241
3 F           <60 years     210
4 F           60+ years     274

As can be seen, the output takes the form of a list length 2. The first is an index of matched variables. The second is crosstables as tibbles for each variable combination. sex.factor2 can be seen as being miscoded. sex.factor2 and age.factor2 have been matched, but should be ignored.

Numerics are not included by default. To do so:

out = colon_s_small %>%
  select(-extent, -extent.factor,-time, -time.years) %>% # choose to exclude variables
  check_recode(include_numerics = TRUE)
out
# Output not printed for space

Miscoding in survival::colon dataset?

When doing this just today, we noticed something strange in our example dataset, survival::colon.

The variable node4 should be a binary recode of nodes greater than 4. But as can be seen, something is not right!

We’re interested in any explanations those working with this dataset might have.

# Select a tibble and expand
out$counts[[9]] %>%
  print(n = Inf)
# Compressed output shown
# A tibble: 32 x 3
   nodes node4     n
     
 1     0     0     2
 2     1     0   269
 3     1     1     5
 4     2     0   194
 5     3     0   124
 6     3     1     1
 7     4     0    81
 8     4     1     3
 9     5     0     1
10     5     1    45
# … with 22 more rows

There we are then, a function that may be useful in detecting miscoding. So useful in fact, that we have immediately found probable miscoding in a standard R dataset.

Continue Reading…

Collapse

Read More

Today the biggest book fair of the world starts again in Frankfurt, Germany. I thought this might be a good opportunity to do you some good!

Springer is one of the most renowned scientific publishing companies in the world. Normally, their books are quite expensive but also in the publishing business Open Access is a megatrend.

If you want to use R in a little fun project to find the latest additions of open access books to their program read on!

The idea is to create an R script which you can run from time to time to see whether there are new titles available. So, we need some place to store the retrieved data in a persistent manner: a database! For our purposes here most database systems would be total overkill but there is one great solution available: the amazing RSQLite package (on CRAN).

This package brings its own lightweight database with it, no need to install any additional software! And it is fully SQL compatible (for Structured Query Language, the industry standard of relational database management systems) like any decent database software.

So, you only have to install the RSQLite package and then load the DBI package (for database interface). To render the output table in an appealing form we will use the htmlTable package (on CRAN).

Have a look at the following fully documented code which should (hopefully) be quite clear:

library(DBI)
library(htmlTable)
# inital search for English books from 2019
springer_initial <- read.csv("https://link.springer.com/search/csv?facet-content-type=%22Book%22&previous-end-year=2019&date-facet-mode=in&facet-language=%22En%22&showAll=false&query=&facet-end-year=2019&previous-start-year=2019&facet-start-year=2019", encoding = "UTF-8")
# current search for English books from 2020 - has to be updated in the following years!
springer_search <- read.csv("https://link.springer.com/search/csv?previous-end-year=2020&facet-content-type=%22Book%22&date-facet-mode=in&previous-start-year=2020&facet-language=%22En%22&showAll=false&query=&facet-start-year=2020&facet-end-year=2020", encoding = "UTF-8")

# open database connection
springer_db <- dbConnect(RSQLite::SQLite(), "my-db.sqlite")

# initialize database
if (!dbExistsTable(springer_db, "search")) {
  dbWriteTable(springer_db, "search", springer_initial)
}

# read current search table, replace it with new search and compare both
springer_search_old <- dbReadTable(springer_db, "search")
dbRemoveTable(springer_db, "search")
dbWriteTable(springer_db, "search", springer_search)
new_books <- setdiff(springer_search_old, dbReadTable(springer_db, "search"))
if (nrow(new_books) > 0) htmlTable(new_books[c("Item.Title", "Authors", "URL")])

[showing only a subset of the more than 200 (!) free titles in 2019]

# close database connection
dbDisconnect(springer_db)

And you thought Christmas was yet to come, right!

As an aside, the last entry is an especially interesting case: it is the first machine-generated research book! The “author” Beta Writer was developed in a joint effort and in collaboration between Springer and researchers from Goethe University, Frankfurt. The book is a cross-corpora auto-summarization of current texts from SpringerLink, organized by means of a similarity-based clustering routine in coherent chapters and sections. It automatically condenses a large set of papers into a reasonably short book. More technical details of this fascinating endeavor, with the potential to revolutionize scientific publishing, can be found in the preface of the book.

By clicking on the link you will directly be directed to the respective book page, where you can download the pdf and in most cases also an epub file (bonus tip: in most cases you can also download a free version of the book for your kindle on amazon.com). To get clickable links you need to render an HTML markdown document. Otherwise, if you run it in RStudio directly you will have to copy and paste the links into your browser.

You just have to run the script from time to time to see what is new!

If you want to customize the data retrieved from link.springer.com have a look at their search interface:

You can customize your search by changing the values in the blue boxes. To get the URL which you can paste in the read.csv function above just right click on the button with the down arrow at the upper right corner (marked by the blue arrow) and choose “Copy link address” in the context menu.

In case you want to completely reset the database you can use the following function (with care):

# function for resetting the springer database
reset_springer_db <- function() {
  springer_db <- dbConnect(RSQLite::SQLite(), "my-db.sqlite")
  dbRemoveTable(springer_db, "search")
  dbDisconnect(springer_db)
}

One small thing: although I tried my very best there still seems to be an issue with the encoding… some special characters, like the German umlauts äöüÄÖÜ, are just not rendered. If you have a solution for me please leave it in the comments and I will add it to the post (or perhaps even write a post on the issues of encoding in R, RStudio and Windows).

Continue Reading…

Collapse

Read More

In the post (https://statcompute.wordpress.com/2017/01/08/an-example-of-merge-layer-in-keras), it was shown how to build a merge-layer DNN by using the Keras Sequential model. In the example below, I tried to scratch a merge-layer DNN with the Keras functional API in both R and Python. In particular, the merge-layer DNN is the average of a multilayer perceptron network and a 1D convolutional network, just for fun and curiosity. Since the purpose of this exercise is to explore the network structure and the use case of Keras API, I didn’t bother to mess around with parameters.

Continue Reading…

Collapse

Read More

Proper Balancing for Cross Validation

Line Detection: Make an Autonomous Car see Road Lines

Fully self-driving passenger cars are not ‘just around the corner’. Elon Musk claims that Teslas will have a ‘full self-driving’ capability by the end of 2020. Especially, he says that Tesla’s hardware is already ready for Autonomous drive, and what is left is just an update on their current software, which many brilliant scientists are working on it. The first instinct to us, humans, as drivers, is probably to look in front of us and decide where should the car move; at which direction, between which lines, etc. As every Autonomous Vehicle comes with a camera in a front, one very important task its to decide the border in which the car should move in between. For humans, we draw lines on the roads. Now we will teach an Autonomous Vehicle to see these lines. I promise it will be fun

How to Estimate ROI and Costs for Machine Learning and Data Science Projects

Creating a Search Engine for Finding Code

Explaining Predictions: Boosted Trees Post-hoc Analysis (Xgboost)

Developing a prescriptive recommender system through Matrix Factorization

A Guide to Integrating Text Analytics into Tableau

R for Industrial Engineers — Quality Control Charts

Introduction to Matrix Profiles

Active Learning: getting the most out of limited data

From scikit-learn to Spark ML

Understanding BERT: Is it a Game Changer in NLP?

6 Deep Learning models – When should you use them?

Detecting SET cards using transfer learning

Understanding Optimizers

Modeling Bank’s Churn Rate with AdaNet: A Scalable, Flexible Auto-Ensemble Learning Framework

A theoretical survey on Mahalanobis-Taguchi system

Continue Reading…

Collapse

Read More

Machine Learning and Judgement (mnj)
Perform FlexBoost in R. FlexBoost is a newly suggested algorithm based on AdaBoost by adjusting adaptive loss functions. Not only FlexBoost but also other machine learning algorithms (e.g. Support Vector Machines) will be added. For more details on FlexBoost see Jeon, Y. S., Yang, D. H., & Lim, D. J. (2019) <doi:10.1109/access.2019.2938356>.

Download and Manage Optional Package Data (pkgfilecache)
Manage optional data for your package. The data can be hosted anywhere, and you have to give a Uniform Resource Locator (URL) for each file. File integrity checks are supported. This is useful for package authors who need to ship more than the 5 Megabyte of data currently allowed by the the Comprehensive R Archive Network (CRAN).

Utilities for Fundamental Geo-Spatial Data (fgdr)
Read and Parse for Fundamental Geo-Spatial Data (FGD) which downloads XML file from providing site (<https://…/menu.php> ). The JPGIS format file provided by FGD so that it can be handled as an R spatial object such as ‘sf’ and ‘raster’ or ‘stars’. Supports the FGD version 4.1, and accepts fundamental items and digital elevation models.

Tree Structured Hidden Markov Model (treeHMM)
Used for Inference, Prediction and Parameter learning for tree structured Hidden Markov Model. The package propose a new architecture of Hidden Markov Model(HMM) known as Tree Structured HMM which could be used in various applications which involves graphs, trees etc.

Read and Write ‘Excel’ Sheets into and from List of Data Frames (xlsx2dfs)
Reading and writing sheets of a single ‘Excel’ file into and from a list of data frames. Eases I/O of tabular data in bioinformatics while keeping them in a human readable format.

Continue Reading…

Collapse

Read More

Scanning all new published packages on PyPI I know that the quality is often quite bad. I try to filter out the worst ones and list here the ones which might be worth a look, being followed or inspire you in some way.

• tempeh
Machine Learning Performance Testing Framework

• torch3d
Datasets and network architectures for 3D deep learning in PyTorch

• trains-agent
Trains-Agent DevOps for deep learning (DevOps for TRAINS)

• tree-lstm
pytorch tree lstm package. This repository contains a Pytorch Implementation of ‘Improved Semantic Representations From Tree-Structured Long Short-Term Memory Networks ‘ (https://…/1503.00075 ). This contains two type of tree-lstm (Child sum, N-ary). This was tested by Python 3.6, Pytorch 1.3.0., and this internally uses dgl 0.4.0 This repository referenced https://…/tree_lstm.py

• trelawney
Generic Interpretability package. Trelawney is a general interpretability package that aims at providing a common api to use most of the modern interpretability methods to shed light on sklearn compatible models (support for Keras and XGBoost are tested).

• arus
Activity Recognition with Ubiquitous Sensing

• cma-es
Covariance Matrix Adaptation Evolution Strategy (CMA-ES) implemented with TensorFlow v2. The CMA-ES (Covariance Matrix Adaptation Evolution Strategy) is an evolutionary algorithm for difficult non-linear non-convex black-box optimisation problems in continuous domain. It is considered as state-of-the-art in evolutionary computation and has been adopted as one of the standard tools for continuous optimisation in many (probably hundreds of) research labs and industrial environments around the world.

• mozilla-fldp
Federated Learning Experimentation

• musco-pytorch
MUSCO: Multi-Stage COmpression of Neural Networks

• waymo-od-tf2-0
Waymo Open Dataset libraries.

Continue Reading…

Collapse

Read More

We want to know how you use rOpenSci packages and resources so we can give them, their developers, and your examples more visibility.

It’s valuable to both users and developers of a package to see how it has been used “in the wild”. This goes a long way to encouraging people to keep up development knowing there are others who appreciate and build on their work. This also helps people imagine how they might use a package to address their research question, and provides some code to give them a head-start.

We have a dedicated Use Cases category in our public discussion forum and we encourage you to browse and add to it. As of September 2019, there are > 50 use cases, covering > 30 packages. More than half of these have been added by community members. These complement the > 800 citations of our tools in published works.

Examples

• visdat¹, skimr², assertr³, Exploring and understanding a new data set. Sharla Gelfand used these packages to demonstrate how she approached a data set on public transit delays. She shared her code, slide deck, and an explanatory blog post. [Use case].

• nasapower⁴, rnaturalearth⁵, Can rainfall be a useful predictor of epidemic risk across temporal and spatial scales? Emerson Del Ponte worked with Adam Sparks to access rainfall data for a specific time period of soybean growth over multiple seasons in two states in Brazil. It’s being used to explore associations between rainfall and patterns of dispersal of a soybean fungal disease. Adam shared the code he used to access the data and create the maps for the presentation Emerson shared [Use case].

• rOpenSci package development guide used in teaching and manuscript review⁶. Tiffany Timbers, her teaching assistants, and students used our guide in teaching and evaluation in their Collaborative Software Development course in the University of British Columbia’s Master of Data Science program [Use case]. Hao Ye used the guide in his review of a manuscript that included an R package [Use case].

Browse the use cases for applications in academia, industry, government, or “just for fun”, with examples on biodiversity, ecology, text processing, bibliometrics, workflows and reproducibility, weather, public health, bicycle networks, agronomy, epidemiology, surveys, seafood mislabelling, tweets about fires, and others!

What’s your use case?

If your use case is published on the web somewhere, please tell us about it in the forum. Here’s the template we created to guide you.

When you post your use case in the forum we’ll tweet about it from @rOpenSci and we might feature it, with attribution, in our biweekly newsletter.

Developers and users will thank you!

Continue Reading…

Collapse

Read More

I am collaborating with a number of folks who think a lot about palliative or supportive care for people who are facing end-stage disease, such as advanced dementia, cancer, COPD, or congestive heart failure. A major concern for this population (which really includes just about everyone at some point) is the quality of life at the end of life and what kind of experiences, including interactions with the health care system, they have (and don’t have) before death.

A key challenge for researchers is figuring out how to analyze events that occur just before death. For example, it is not unusual to consider hospitalization in the week or month before death as a poor outcome. For example, here is a paper in the Journal of Palliative Care Medicine that describes an association of homecare nursing and reduced hospitalizations in the week before death. While there is no denying the strength of the association, it is less clear how much of that association is causal.

In particular, there is the possibility of selection bias that may be result when considering only patients who have died. In this post, I want to describe the concept of selection bias and simulate data that mimics the process of end-stage disease in order to explore how these issues might play out when we are actually evaluating the causal effect of an exposure or randomized intervention.

n = 5000
set.seed(748347)

income <- rnorm(n); 
bp <- rnorm(n)

logitSelect <- -2 + 2*income + 2*bp
pSelect <- 1/(1+exp(-logitSelect))
select <- rbinom(n, 1, pSelect)

dPop <- data.table(income, bp, select)
dSample <- dPop[select == 1]

bDef <- defData(varname = "S0", formula = "0.4;0.4;0.2",
                     dist = "categorical")

P <- t(matrix(c( 0.7, 0.2, 0.1, 0.0,
                 0.0, 0.4, 0.4, 0.2,
                 0.0, 0.0, 0.6, 0.4,
                 0.0, 0.0, 0.0, 1.0),
              nrow = 4))

pDef <- defDataAdd(varname = "hospital", formula = "-2 + u",
                   dist = "binary", link = "logit")
pDef <- defDataAdd(pDef, varname = "death", 
                   formula = "-2 + u + homenurse * 1.5",
                   dist = "binary", link = "logit")

set.seed(272872)

dd <- genData(10000, bDef)
dd <- trtAssign(dd, grpName = "homenurse")

dp <- addMarkov(dd, transMat = P, 
                chainLen = 4, id = "id", 
                pername = "seq", start0lab = "S0",
                varname = "u")

dp <- addColumns(pDef, dp)
dp <- trimData(dp, seqvar = "seq", eventvar = "death")

d1 <- dp[seq == 1]

d1[, mean(death)]

## [1] 0.6109

fit1 <- glm(hospital ~ homenurse, data=d1[death==1], 
            family = "binomial")
fit2 <- glm(hospital ~ homenurse + u, data=d1[death==1], 
            family = "binomial")
fit3 <- glm(hospital ~ homenurse, data=d1, 
            family = "binomial")

library(stargazer)

stargazer(fit1, fit2, fit3, type = "text",
          column.labels = c("died", "died - adjusted", "all"), 
          omit.stat = "all", omit.table.layout = "-asn")

## 
## =============================================
##                   Dependent variable:        
##           -----------------------------------
##                        hospital              
##             died    died - adjusted    all   
##              (1)          (2)          (3)   
## homenurse -0.222***     -0.061       -0.049  
##            (0.053)      (0.057)      (0.040) 
##                                              
## u                      1.017***              
##                         (0.039)              
##                                              
## Constant   0.108**     -2.005***    -0.149***
##            (0.042)      (0.092)      (0.028) 
##                                              
## =============================================

dDied <- dp[death == 1]
nrow(dDied)/nrow(d1)

## [1] 0.9658

fit4 <- glm(hospital ~ homenurse, data=dDied, family = "binomial")
fit5 <- glm(hospital ~ homenurse + u, data=dDied, family = "binomial")

stargazer(fit4, fit5, type = "text",
          omit.stat = "all", omit.table.layout = "-asn")

## 
## ==============================
##           Dependent variable: 
##           --------------------
##                 hospital      
##              (1)        (2)   
## homenurse -0.383***   -0.048  
##            (0.041)    (0.045) 
##                               
## u                    1.020*** 
##                       (0.028) 
##                               
## Constant   0.296***  -2.028***
##            (0.030)    (0.070) 
##                               
## ==============================

Continue Reading…

Collapse

Read More

Judith Tanur writes:

The Rachel Tanur Memorial Prize for Visual Sociology recognizes students in the social sciences who incorporate visual analysis in their work. The contest is open worldwide to undergraduate and graduate students (majoring in any social science). It is named for Rachel Dorothy Tanur (1958–2002), an urban planner and lawyer who cared deeply about people and their lives and was an acute observer of living conditions and human relationships.

The 2020 Rachel Tanur Memorial Prize is now open for applications. Entries for the 2020 competition must be received by January 22, 2020. Winners will be notified by March 30, 2020. Up to three cash prizes will be awarded at the IV International Sociological Association (ISA) Forum of Sociology, “Challenges of the 21st Century: Democracy, Environment, Inequalities, Intersectionality,” to be held in Porto Alegre, Brazil on July 14-18, 2020. Attendance at the forum is not a requirement but is encouraged. Prizes, supported by the Mark Family Foundation, will be awarded by the Research Committee on Visual Sociology of the ISA. The first prize will be $2,500 USD, the second $1,500, and the third $500. The prize is awarded biennially. For more information and to apply please go to racheltanurmemorialprize.org

Continue Reading…

Collapse

Read More

We present the state of the art in representing and reasoning with fuzzy knowledge in Semantic Web Languages such as triple languages RDF/RDFS, conceptual languages of the OWL 2 family and rule languages. We further show how one may generalise them to so-called annotation domains, that cover also e.g. temporal and provenance extensions. An Introduction to Fuzzy and Annotated Semantic Web Languages

Continue Reading…

Collapse

Read More

Continue Reading…

Collapse

Read More

In May, we launched the second Testing and Verification request for proposals (TAV RFP) in response to the high quality of submissions of last year’s TAV RFP. The winners of the 2018 TAV RFP were invited to a one-day workshop at the 2018 Facebook TAV Symposium to present  their winning proposals and network with symposium attendees. Following the success of last year’s model, the 2019 TAV RFP winners are also invited to this year’s TAV Symposium, which will take place in Facebook London on November 20 and 21. For those interested in attending, registration is now open.

For this year’s TAV RFP, we were interested in proposals that tackled any topics on testing and verification with the potential to have profound impact on the tech sector, based on advances on the theory and practice of testing and verification. In particular, we welcomed proposals that tackled test flakiness and pay-as-you-go verification. For more details on these topics, as well as proposal requirements, eligibility, and timing, visit the 2019 TAV RFP page.

The winners have been selected and are listed below. “We are excited that, once again, we received over 100 proposals, and of such high quality,” says Mark Harman, Research Scientist and Facebook TAV co-chair. “We are really excited to see this research develop, and to see the deployment of advanced research in industry.

“Despite doubling the funding available this year, there were many excellent proposals that we were sadly unable to fund this round. Such was the quality of the proposals we received,” says Mark. “We are very grateful to the scientific research community for engaging so enthusiastically with this call for proposals.”

Research award winners

Principal investigators are listed first unless otherwise noted.

A scalable infrastructure for fuzzy-driven root causing of flaky tests
Filomena Ferrucci (University of Salerno), Pasquale Salza (University of Zurich), and Valerio Terragni (Università della Svizzera italiana)

Action-based test carving
Gordon Fraser (University of Passau) and Alessio Gambi (University of Passau)

Cyclic proofs of program incorrectness
James Brotherston (University College London)

Detecting flaky test failures of system user interactive tests
Mike Papadakis (University of Luxembourg), Renaud Rwemalika (University of Luxembourg), and Yves Le Traon (University of Luxembourg)

Moka: Improving app testing with automated mocking
Mattia Fazzini (University of Minnesota), Alessandra Gorla (IMDEA Software Institute), and Allessandro Orso (Georgia Tech)

Null pointer dereferences in the wild
Cindy Rubio Gonzalez (University of California, Davis)

Probabilistic testing in the presence of flaky tests
Weihang Wang (State University of New York — University at Buffalo)

Search-based inducement and repair of latent test flakiness
Philip McMinn (University of Sheffield)

Static prediction of test flakiness
Breno Alexandro Ferreira de Miranda (Federal University of Pernambuco, Brazil), Antonia Bertolino (Istituto di Scienza e Tecnologie dell’Informazione – CNR), Emilio Cruciani (Gran Sasso Science Institute), and Roberto Verdecchia (Gran Sasso Science Institute)

Test oracle inference — supervised learning over execution traces
Ajitha Rajan (University of Edinburgh)

—

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 2019 Testing and Verification research awards appeared first on Facebook Research.

Continue Reading…

Collapse

Read More

Paper: Bayesian analysis of longitudinal studies with treatment by indication

Paper: Causal inference and machine learning approaches for evaluation of the health impacts of large-scale air quality regulations

Paper: Non-Causal Tracking by Deblatting

Paper: On the Separability of Classes with the Cross-Entropy Loss Function

Article: The Chicken or the egg? Experiments Can Help Determine Two-Way Causality

Paper: Dynamic causal modelling of phase-amplitude interactions

Paper: Quantifying Causation

Paper: A Rule-Based System for Explainable Donor-Patient Matching in Liver Transplantation

Continue Reading…

Collapse

Read More

Local Orthogonal Decomposition
Inverted file and asymmetric distance computation (IVFADC) have been successfully applied to approximate nearest neighbor search and subsequently maximum inner product search. In such a framework, vector quantization is used for coarse partitioning while product quantization is used for quantizing residuals. In the original IVFADC as well as all of its variants, after residuals are computed, the second production quantization step is completely independent of the first vector quantization step. In this work, we seek to exploit the connection between these two steps when we perform non-exhaustive search. More specifically, we decompose a residual vector locally into two orthogonal components and perform uniform quantization and multiscale quantization to each component respectively. The proposed method, called local orthogonal decomposition, combined with multiscale quantization consistently achieves higher recall than previous methods under the same bitrates. We conduct comprehensive experiments on large scale datasets as well as detailed ablation tests, demonstrating effectiveness of our method. …

Quantitative Discourse Analysis
Quantitative Discourse Analysis is basically looking at patterns in language. …

Fast and Accurate Timing Error Prediction Framework (FATE)
Deep neural networks (DNN) are increasingly being accelerated on application-specific hardware such as the Google TPU designed especially for deep learning. Timing speculation is a promising approach to further increase the energy efficiency of DNN accelerators. Architectural exploration for timing speculation requires detailed gate-level timing simulations that can be time-consuming for large DNNs that execute millions of multiply-and-accumulate (MAC) operations. In this paper we propose FATE, a new methodology for fast and accurate timing simulations of DNN accelerators like the Google TPU. FATE proposes two novel ideas: (i) DelayNet, a DNN based timing model for MAC units; and (ii) a statistical sampling methodology that reduces the number of MAC operations for which timing simulations are performed. We show that FATE results in between 8 times-58 times speed-up in timing simulations, while introducing less than 2% error in classification accuracy estimates. We demonstrate the use of FATE by comparing to conventional DNN accelerator that uses 2’s complement (2C) arithmetic with an alternative implementation that uses signed magnitude representations (SMR). We show that that the SMR implementation provides 18% more energy savings for the same classification accuracy than 2C, a result that might be of independent interest. …

MetaForest
A requirement of classic meta-analysis is that the studies being aggregated are conceptually similar, and ideally, close replications. However, in many fields, there is substantial heterogeneity between studies on the same topic. Similar research questions are studied in different laboratories, using different methods, instruments, and samples. Classic meta-analysis lacks the power to assess more than a handful of univariate moderators, or to investigate interactions between moderators, and non-linear effects. MetaForest, by contrast, has substantial power to explore heterogeneity in meta-analysis. It can identify important moderators from a larger set of potential candidates, even with as little as 20 studies (Van Lissa, in preparation). This is an appealing quality, because many meta-analyses have small sample sizes. Moreover, MetaForest yields a measure of variable importance which can be used to identify important moderators, and offers partial prediction plots to explore the shape of the marginal relationship between moderators and effect size. …

Continue Reading…

Collapse

Read More

Validating and testing our supervised machine learning models is essential to ensuring that they generalize well. SAS Viya makes it easy to train, validate, and test our machine learning models.

Training, validation and test data sets

Training data are used to fit each model. Training a model involves using an algorithm to determine model parameters (e.g., weights) or other logic to map inputs (independent variables) to a target (dependent variable). Model fitting can also include input variable (feature) selection. Models are trained by minimizing an error function.

For illustration purposes, let’s say we have a very simple ordinary least squares regression model with one input (independent variable, x) and one output (dependent variable, y). Perhaps our input variable is how many hours of training a dog or cat has received, and the output variable is the combined total of how many fingers or limbs we will lose in a single encounter with the animal.

In ordinary least squares regression, the parameters are estimated that minimize the sum of the squared errors between the observed data and the predicted model. This is illustrated below where the predicted y = β₀ + β₁x. The y variable is on the vertical axis and the x variable is on the horizontal axis.

Validation data are used with each model developed in training, and the prediction errors are calculated. Depending on the model and the software, these prediction errors can be used to decide:

• When to terminate the selection process
• What effects (e.g., inputs, interactions, etc.) to include as the selection process proceeds, and/or
• Which model to select

The validation errors calculated vary from model to model and may be things such as the the average squared error (ASE), mean squared error (MSE), error sum of squares (SSE), the negative log-likelihood, etc. The validation ASE is often used in VDMML.

Note: “Average Squared Error and Mean Squared Error might appear similar. But they describe two completely different measures, where each is appropriate only for specific models. In linear models, statisticians routinely use the mean squared error (MSE) as the main measure of fit. The MSE is the sum of squared errors (SSE) divided by the degrees of freedom for error. (DFE is the number of cases [observations]less the number of weights in the model.) This process yields an unbiased estimate of the population noise variance under the usual assumptions.

The MSE is not a useful estimator of the generalization error, even in linear models, unless the number of cases is much larger than the number of weights.”
- From Enterprise Miner documentation.

The validation data may be used several times to build the final model.

Test data is a hold-out sample that is used to assess the final selected model and estimate its prediction error. Test data are not used until after the model building and selection process is complete. Test data tell you how well your model will generalize, i.e., how well your model performs on new data. By new data I mean data that have not been involved in the model building nor the model selection process in any way.

The test data should never be used for fitting the model, for deciding what effects to include, nor for selecting from among candidate models. In addition, be careful of any leakage of information from the test data set into the other data sets. For example, if you take a mean of all of the data to impute missing values, do that separately for each of the three data sets (training, validation, and test). Otherwise, you will leak information from one data set to another.

Partitioning the Data

Simple random sampling: The observations selected for the subset of the data are randomly selected, i.e., each observation has an equal probability of being chosen.

Stratified sampling: The data are divided into segments or “strata,” and then observations are randomly selected from each stratum. For example, for large cat training, you might want to stratify your sample by lions and tigers to ensure that your training, validation, and test data sets all include the proportion of lions and tigers that exist in the total population. As shown below, in this case we take a random sample of 10% of the tigers and a random sample of 10% of the lions.

Oversampling: Oversampling is commonly used when you are looking at rare events, such as cancer cases. You may have a data set with 10,000 people and only 100 cancer cases. You may wish to oversample the cancer cases to get, for example, a 90:10 ratio of non-cancer to cancer cases. You could use 100% of the cancer cases (all 100) and a 9% random sample of the non-cancer cases (900).

How partitioning is accomplished

In VA|VS|VDMML Visual Interface

Partitioning became easier in the VA|VS|VDMML visual interface in 17w47 (December 2017) with VA|VS|VDMML 8.2 on Viya 3.3. To partition data, click the icon to the right of the data set name, and select Add partition data item, as shown below.

You may select either simple random sampling or stratified sampling and type the training percentage. You may also select a random number seed if you wish.

You may choose:

• two partitions (training and validation) or
• three partitions (training, validation, and test)

They will be assigned numbers as follows:

• 0 = Validation
• 1 = Training
• 2 = Test

Note to anyone dealing with old versions of the software:

In the earlier (17w12, March 2012) release of VA/VS/VDMML 8.1 on Viya 3.2 you needed to have a binary partition indicator variable in your data set with your data already partitioned if you wished to partition the data into Training and Validation data sets. For example, the partition indicator variable could be called “Partition” and could have two values, “Training” and “Validation.” Or it could be called Training and the two values could be 0 and 1. It doesn’t matter what the name of the variable was, but it had to have only two values. As a data preparation step you had to set the partition indicator variable, indicating which value indicates Training observations and which value indicates validation observations. In 8.1, if you did not have a binary partition variable already in your data set, you could not partition automatically on the fly.

There is no rule of thumb for deciding how much of your data set to apportion into training, validation, and test data. This should be decided by a data scientist or statistician familiar with the data. A common split is 50% for training, 25% for validation, and 25% for testing.

Cross-validation is another method, but is not done automatically with the visual interface. For more information on cross-validation methods see: Funda Gunes’s blog on cross validation in Enterprise Miner or documentation on the SAS Viya CROSSVALIDATION statement.

Using SAS Viya procedures

PROC PARTITION lets you divide data into training, validation and test. In addition, most VS and VDMML supervised learning models have a PARTITION statement. (PROC FACTMAC is an exception.) Code for a partition statement within a PROC FOREST could look something like the code below.

This code would partition the full data set into 50% training data, 25% validation data, and 25% test data.

ALERT: If you have the same number of computer nodes, specifying the SEED= option in the PARTITION statement lets you repeatedly create the same partition data tables. However, changing the number of compute nodes changes the initial distribution of data, resulting in different partition data tables.

You can exercise more control over the partitioning of the input data table if you have created a partition variable in your data set. Then you must designate:

1. The variable in the input data table as the partition variable (e.g., “role,” in the example below)
2. A formatted value of that variable for each role (e.g., ‘TRAIN’, ‘VAL’, and ‘TEST’ as shown below)

Example code:

As I mentioned earlier, you can commonly use your validation data set to determine which model to select, or even when to stop the model selection process. For example, this is how you would do that within the PROC REGSELECT, SELECTION statement, METHOD= option:

• Stopping the Selection Process. Specify STOP= VALIDATE. “At step k of the selection process, the best candidate effect to enter or leave the current model is determined. Here, ‘best candidate’ means the effect that gives the best value of the SELECT= criterion; this criterion does not need to be based on the validation data. The Validation ASE for the model with this candidate effect added or removed is computed. If this Validation ASE is greater than the Validation ASE for the model at step k, then the selection process terminates at step k.”
• Choosing the Model. Specify CHOOSE= VALIDATE. Then “the Validation ASE will be computed for your models at each step of the selection process. The smallest model at any step that yields the smallest Validation ASE will be selected.”

– Quoted from PROC REGSELECT documentation

Summary

SAS Viya makes it easy to train, validate, and test our machine learning models. This is essential to ensuring that our models not only fit our existing data, but that they will perform well on new data.

Now you know everything you need to know about training cats and dogs. Go ahead and try this at home. If you are as smart as the dolphins pictured below, you might even be able to train a human!

References and more information

• SAS VDMML 8.4: Procedures Documentation
• SAS VS 8.4: Procedures Documentation
• Rick Wicklin’s blog Create training, validation, and test data sets in SAS
• Doug Wielenga on Train-Validate-Test question

The post Training, validation and testing for supervised machine learning models appeared first on The SAS Data Science Blog.

Continue Reading…

Collapse

Read More

“If you’re not doing some things that are crazy, then you’re doing the wrong things.” Larry Page ( 2013 )

Continue Reading…

Collapse

Read More

As an engineer, scientist, or researcher, you may want to take advantage of this new and growing technology, but where do you start? The best place to begin is to understand what the concept is, how to implement it, and whether it’s the right approach for a given problem.

Continue Reading…

Collapse

Read More

SQL Server performance objects are found inside the Performance Monitor tool, also known as perfmon. If you are using Performance Monitor for gathering resource metrics for SQL Server then you are familiar with a screen such as this one:

You can see I have navigated to the SQL Server Plan Cache counter, selected Cache Hit Ratio, and an instance of Extended Stored Procedures. You will also note in the lower left I have enabled “Show description”. This results in the text at the bottom, “Ratio between cache hits and lookups”.

That text is referring to the counter itself, and not to the instance. If I toggle to another instance, such as SQL plans, the text doesn’t change. I have an idea what SQL plans means, but I’m also smart enough to know I don’t know everything. So, where would one find information about the instances?

Those details can be found here: Use SQL Server Objects. From there we can go to the SQL Server, Plan Cache Object page, where we will find the following details:

That’s a lot more detail than I was expecting! Now I know exactly what this counter will consider to be a plan. These details provide more context to the metric, helping users understand what they are measuring.

Having SQL Server performance objects documented is important, and you should review them. Otherwise you run a risk of collecting the wrong metrics.

The post Using SQL Server Performance Objects appeared first on Thomas LaRock.

Continue Reading…

Collapse

Read More

Selecting the perfect machine learning model is part art and part science. Learn how to review multiple models and pick the best in both competitive and real-world applications.

Continue Reading…

Collapse

Read More

The problem: We have data, and we need to create models (xgboost, random forest, regression, etc). Each one of them has its constraints regarding data types.
Many strange errors appear when we are creating models just because of data format.

The new version of funModeling 1.9.3 (Oct 2019) aimed to provide quick and clean assistance on this.

Cover photo by: @franjacquier_

tl;dr;code

Based on some messy data, we want to run a random forest, so before getting some weird errors, we can check…

Example 1:

# install.packages("funModeling")
library(funModeling)
library(tidyverse)

# Load data
data=read_delim("https://raw.githubusercontent.com/pablo14/data-integrity/master/messy_data.txt", delim = ';')

# Call the function:
integ_mod_1=data_integrity_model(data = data, model_name = "randomForest")

# Any errors?
integ_mod_1

## 
## ✖ {NA detected} num_vessels_flour, thal, gender
## ✖ {Character detected} gender, has_heart_disease
## ✖ {One unique value} constant

Regardless the "one unique value", the other errors need to be solved in order to create a random forest.

Alghoritms have their own data type restrictions, and their own error messages making the execution a hard debugging task… data_integrity_model will alert with a common error message about such errors.

Introduction

data_integrity_model is built on top of data_integrity function. We talked about it in the post: Fast data exploration for predictive modeling.

It checks:

• NA
• Data types (allow non-numeric? allow character?)
• High cardinality
• One unique value

Supported models

It takes the metadata from a table that is pre-loaded with funModeling

head(metadata_models)

## # A tibble: 6 x 6
##   name         allow_NA max_unique allow_factor allow_character only_numeric
##                                               
## 1 randomForest FALSE            53 TRUE         FALSE           FALSE       
## 2 xgboost      TRUE            Inf FALSE        FALSE           TRUE        
## 3 num_no_na    FALSE           Inf FALSE        FALSE           TRUE        
## 4 no_na        FALSE           Inf TRUE         TRUE            TRUE        
## 5 kmeans       FALSE           Inf TRUE         TRUE            TRUE        
## 6 hclust       FALSE           Inf TRUE         TRUE            TRUE

The idea is anyone can add the most popular models or some configuration that is not there.
There are some redundancies, but the purpose is to focus on the model, not the needed metadata.
This way we don’t think in no NA in random forest, we just write randomForest.

Some custom configurations:

• no_na: no NA variables.
• num_no_na: numeric with no NA (for example, useful when doing deep learning).

Embed in a data flow on production

Many people ask for typical questions when interviewing candidates. I like these ones: "How do you deal with new data?" or "What are the considerations you have when you do a deploy?"

Based on our first example:

integ_mod_1

## 
## ✖ {NA detected} num_vessels_flour, thal, gender
## ✖ {Character detected} gender, has_heart_disease
## ✖ {One unique value} constant

We can check:

integ_mod_1$data_ok

## [1] FALSE

data_ok is a flag useful to stop a process raising an error if anything goes wrong.

More examples

Example 2:

On mtcars data frame, check if there is any variable with NA:

di2=data_integrity_model(data = mtcars, model_name = "no_na")

# Check:
di2

## ✔ Data model integrity ok!

Good to go?

di2$data_ok

## [1] TRUE

Example 3:

data_integrity_model(data = heart_disease, model_name = "pca")

## 
## ✖ {NA detected} num_vessels_flour, thal
## ✖ {Non-numeric detected} gender, chest_pain, fasting_blood_sugar, resting_electro, thal, exter_angina, has_heart_disease

Example 4:

data_integrity_model(data = iris, model_name = "kmeans")

## 
## ✖ {Non-numeric detected} Species

Any suggestions?

If you come across any cases which aren’t covered here, you are welcome to contribute: funModeling’s github.

How about time series? I took them as: numeric with no na (model_name = num_no_na). You can add any new model by updating the table metadata_models.

And that’s it.

---

In case you want to understand more about data types and qualilty, you can check the Data Science Live Book

Have data fun!

You can found me at: Linkedin & Twitter.

Continue Reading…

Collapse

Read More

A recent survey outlined the main neural architecture search methods used to automate the design of deep learning systems.

Continue Reading…

Collapse

Read More

In this tutorial, you will learn the three primary reasons your validation loss may be lower than your training loss when training your own custom deep neural networks.

I first became interested in studying machine learning and neural networks in late high school. Back then there weren’t many accessible machine learning libraries — and there certainly was no scikit-learn.

Every school day at 2:35 PM I would leave high school, hop on the bus home, and within 15 minutes I would be in front of my laptop, studying machine learning, and attempting to implement various algorithms by hand.

I rarely stopped for a break, more than occasionally skipping dinner just so I could keep working and studying late into the night.

During these late-night sessions I would hand-implement models and optimization algorithms (and in Java of all languages; I was learning Java at the time as well).

And since they were hand-implemented ML algorithms by a budding high school programmer with only a single calculus course under his belt, my implementations were undoubtedly prone to bugs.

I remember one night in particular.

The time was 1:30 AM. I was tired. I was hungry (since I skipped dinner). And I was anxious about my Spanish test the next day which I most certainly did not study for.

I was attempting to train a simple feedforward neural network to classify image contents based on basic color channel statistics (i.e., mean and standard deviation).

My network was training…but I was running into a very strange phenomenon:

My validation loss was lower than training loss!

How could that possibly be?

• Did I accidentally switch the plot labels for training and validation loss? Potentially. I didn’t have a plotting library like matplotlib so my loss logs were being piped to a CSV file and then plotted in Excel. Definitely prone to human error.
• Was there a bug in my code? Almost certainly. I was teaching myself Java and machine learning at the same time — there were definitely bugs of some sort in that code.
• Was I just so tired that my brain couldn’t comprehend it? Also very likely. I wasn’t sleeping much during that time of my life and could have very easily missed something obvious.

But, as it turns out it was none of the above cases — my validation loss was legitimately lower than my training loss.

It took me until my junior year of college when I took my first formal machine learning course to finally understand why validation loss can be lower than training loss.

And a few months ago, brilliant author, Aurélien Geron, posted a tweet thread that concisely explains why you may encounter validation loss being lower than training loss.

I was inspired by Aurélien’s excellent explanation and wanted to share it here with my own commentary and code, ensuring that no students (like me many years ago) have to scratch their heads and wonder “Why is my validation loss lower than my training loss?!”.

To learn the three primary reasons your validation loss may be lower than your training loss, just keep reading!

Why is my validation loss lower than my training loss?

In the first part of this tutorial, we’ll discuss the concept of “loss” in a neural network, including what loss represents and why we measure it.

From there we’ll implement a basic CNN and training script, followed by running a few experiments using our freshly implemented CNN (which will result in our validation loss being lower than our training loss).

Given our results, I’ll then explain the three primary reasons your validation loss may be lower than your training loss.

What is “loss” when training a neural network?

Figure 1: What is the “loss” in the context of machine/deep learning? And why is my validation loss lower than my training loss? (image source)

At the most basic level, a loss function quantifies how “good” or “bad” a given predictor is at classifying the input data points in a dataset.

The smaller the loss, the better a job the classifier is at modeling the relationship between the input data and the output targets.

That said, there is a point where we can overfit our model — by modeling the training data too closely, our model loses the ability to generalize.

We, therefore, seek to:

1. Drive our loss down, thereby improving our model accuracy.
2. Do so as fast as possible and with as little hyperparameter updates/experiments.
3. All without overfitting our network and modeling the training data too closely.

It’s a balancing act and our choice of loss function and model optimizer can dramatically impact the quality, accuracy, and generalizability of our final model.

Typical loss functions (also called “objective functions” or “scoring functions”) include:

• Binary cross-entropy
• Categorical cross-entropy
• Sparse categorical cross-entropy
• Mean Squared Error (MSE)
• Mean Absolute Error (MAE)
• Standard Hinge
• Squared Hinge

A full review of loss functions is outside the scope of this post, but for the time being, just understand that for most tasks:

• Loss measures the “goodness” of your model
• The smaller the loss, the better
• But you need to be careful not to overfit

To learn more about the role of loss functions when training your own custom neural networks, be sure to:

• Read this intro on parameterized learning and linear classification.
• Go through the following tutorial on Softmax Classifiers.
• Refer to this guide on Multi-class SVM loss.

Additionally, if you would like a complete, step-by-step guide on the role of loss functions in machine learning/neural networks, make sure you read Deep Learning for Computer Vision with Python where I explain parameterized learning and loss methods in detail (including code and experiments).

Project structure

Go ahead and use the “Downloads” section of this post to download the source code. From there, inspect the project/directory structure via the

tree

$ tree --dirsfirst
.
├── pyimagesearch
│   ├── __init__.py
│   └── minivggnet.py
├── fashion_mnist.py
├── plot_shift.py
└── training.pickle

1 directory, 5 files

Today we’ll be using a smaller version of VGGNet called MiniVGGNet. The

pyimagesearch

Our

fashion_mnist.py

Today’s training script generates a

training.pickle

plot_shift.py

Let’s dive into the three reasons now to answer the question, “Why is my validation loss lower than my training loss?”.

Reason #1: Regularization applied during training, but not during validation/testing

Figure 2: Aurélien answers the question: “Ever wonder why validation loss > training loss?” on his twitter feed (image source). The first reason is that regularization is applied during training but not during validation/testing.

When training a deep neural network we often apply regularization to help our model:

1. Obtain higher validation/testing accuracy
2. And ideally, to generalize better to the data outside the validation and testing sets

Regularization methods often sacrifice training accuracy to improve validation/testing accuracy — in some cases that can lead to your validation loss being lower than your training loss.

Secondly, keep in mind that regularization methods such as dropout are not applied at validation/testing time.

As Aurélien shows in Figure 2, factoring in regularization to validation loss (ex., applying dropout during validation/testing time) can make your training/validation loss curves look more similar.

Reason #2: Training loss is measured during each epoch while validation loss is measured after each epoch

Figure 3: Reason #2 for validation loss sometimes being less than training loss has to do with when the measurement is taken (image source).

The second reason you may see validation loss lower than training loss is due to how the loss value are measured and reported:

1. Training loss is measured during each epoch
2. While validation loss is measured after each epoch

Your training loss is continually reported over the course of an entire epoch; however, validation metrics are computed over the validation set only once the current training epoch is completed.

This implies, that on average, training losses are measured half an epoch earlier.

If you shift the training losses half an epoch to the left you’ll see that the gaps between the training and losses values are much smaller.

For an example of this behavior in action, read the following section.

Implementing our training script

We’ll be implementing a simple Python script to train a small VGG-like network (called MiniVGGNet) on the Fashion MNIST dataset. During training, we’ll save our training and validation losses to disk. We’ll then create a separate Python script to compare both the unshifted and shifted loss plots.

Let’s get started by implementing the training script:

# import the necessary packages
from pyimagesearch.minivggnet import MiniVGGNet
from sklearn.metrics import classification_report
from tensorflow.keras.optimizers import SGD
from tensorflow.keras.datasets import fashion_mnist
from tensorflow.keras.utils import to_categorical
import argparse
import pickle

# construct the argument parser and parse the arguments
ap = argparse.ArgumentParser()
ap.add_argument("-i", "--history", required=True,
	help="path to output training history file")
args = vars(ap.parse_args())

Lines 2-8 import our required packages, modules, classes, and functions. Namely, we import

MiniVGGNet

fashion_mnist

pickle

The command line argument,

--history

.pickle

We then initialize a few hyperparameters, namely our number of epochs to train for, initial learning rate, and batch size:

# initialize the number of epochs to train for, base learning rate,
# and batch size
NUM_EPOCHS = 25
INIT_LR = 1e-2
BS = 32

We then proceed to load and preprocess our Fashion MNIST data:

# grab the Fashion MNIST dataset (if this is your first time running
# this the dataset will be automatically downloaded)
print("[INFO] loading Fashion MNIST...")
((trainX, trainY), (testX, testY)) = fashion_mnist.load_data()

# we are using "channels last" ordering, so the design matrix shape
# should be: num_samples x rows x columns x depth
trainX = trainX.reshape((trainX.shape[0], 28, 28, 1))
testX = testX.reshape((testX.shape[0], 28, 28, 1))

# scale data to the range of [0, 1]
trainX = trainX.astype("float32") / 255.0
testX = testX.astype("float32") / 255.0

# one-hot encode the training and testing labels
trainY = to_categorical(trainY, 10)
testY = to_categorical(testY, 10)

# initialize the label names
labelNames = ["top", "trouser", "pullover", "dress", "coat",
	"sandal", "shirt", "sneaker", "bag", "ankle boot"]

Lines 25-34 load and preprocess the training/validation data.

Lines 37 and 38 binarize our class labels, while Lines 41 and 42 list out the human-readable class label names for classification report purposes later.

From here we have everything we need to compile and train our MiniVGGNet model on the Fashion MNIST data:

# initialize the optimizer and model
print("[INFO] compiling model...")
opt = SGD(lr=INIT_LR, momentum=0.9, decay=INIT_LR / NUM_EPOCHS)
model = MiniVGGNet.build(width=28, height=28, depth=1, classes=10)
model.compile(loss="categorical_crossentropy", optimizer=opt,
	metrics=["accuracy"])

# train the network
print("[INFO] training model...")
H = model.fit(trainX, trainY,
	validation_data=(testX, testY),
	 batch_size=BS, epochs=NUM_EPOCHS)

Lines 46-49 initialize and compile the

MiniVGGNet

Lines 53-55 then fit/train the

model

From here we will evaluate our

model

# make predictions on the test set and show a nicely formatted
# classification report
preds = model.predict(testX)
print("[INFO] evaluating network...")
print(classification_report(testY.argmax(axis=1), preds.argmax(axis=1),
	target_names=labelNames))

# serialize the training history to disk
print("[INFO] serializing training history...")
f = open(args["history"], "wb")
f.write(pickle.dumps(H.history))
f.close()

Lines 59-62 make predictions on the test set and print a classification report to the terminal.

Lines 66-68 serialize our training accuracy/loss history to a

.pickle

Go ahead and use the “Downloads” section of this tutorial to download the source code.

From there, open up a terminal and execute the following command:

$ python fashion_mnist.py --history training.pickle
[INFO] loading Fashion MNIST...
[INFO] compiling model...
[INFO] training model...
Train on 60000 samples, validate on 10000 samples   
Epoch 1/25
60000/60000 [==============================] - 200s 3ms/sample - loss: 0.5433 - accuracy: 0.8181 - val_loss: 0.3281 - val_accuracy: 0.8815
Epoch 2/25
60000/60000 [==============================] - 194s 3ms/sample - loss: 0.3396 - accuracy: 0.8780 - val_loss: 0.2726 - val_accuracy: 0.9006
Epoch 3/25
60000/60000 [==============================] - 193s 3ms/sample - loss: 0.2941 - accuracy: 0.8943 - val_loss: 0.2722 - val_accuracy: 0.8970
Epoch 4/25
60000/60000 [==============================] - 193s 3ms/sample - loss: 0.2717 - accuracy: 0.9017 - val_loss: 0.2334 - val_accuracy: 0.9144
Epoch 5/25
60000/60000 [==============================] - 194s 3ms/sample - loss: 0.2534 - accuracy: 0.9086 - val_loss: 0.2245 - val_accuracy: 0.9194
...
Epoch 21/25
60000/60000 [==============================] - 195s 3ms/sample - loss: 0.1797 - accuracy: 0.9340 - val_loss: 0.1879 - val_accuracy: 0.9324
Epoch 22/25
60000/60000 [==============================] - 194s 3ms/sample - loss: 0.1814 - accuracy: 0.9342 - val_loss: 0.1901 - val_accuracy: 0.9313
Epoch 23/25
60000/60000 [==============================] - 193s 3ms/sample - loss: 0.1766 - accuracy: 0.9351 - val_loss: 0.1866 - val_accuracy: 0.9320
Epoch 24/25
60000/60000 [==============================] - 193s 3ms/sample - loss: 0.1770 - accuracy: 0.9347 - val_loss: 0.1845 - val_accuracy: 0.9337
Epoch 25/25
60000/60000 [==============================] - 194s 3ms/sample - loss: 0.1734 - accuracy: 0.9372 - val_loss: 0.1871 - val_accuracy: 0.9312
[INFO] evaluating network...
              precision    recall  f1-score   support

         top       0.87      0.91      0.89      1000
     trouser       1.00      0.99      0.99      1000
    pullover       0.91      0.91      0.91      1000
       dress       0.93      0.93      0.93      1000
        coat       0.87      0.93      0.90      1000
      sandal       0.98      0.98      0.98      1000
       shirt       0.83      0.74      0.78      1000
     sneaker       0.95      0.98      0.97      1000
         bag       0.99      0.99      0.99      1000
  ankle boot       0.99      0.95      0.97      1000

    accuracy                           0.93     10000
   macro avg       0.93      0.93      0.93     10000
weighted avg       0.93      0.93      0.93     10000

[INFO] serializing training history...

Checking the contents of your working directory you should have a file named

training.pickle

$ ls *.pickle
training.pickle

In the next section we’ll learn how to plot these values and shift our training information a half epoch to the left, thereby making our training/validation loss curves look more similar.

Shifting our training loss values

Our

plot_shift.py

fashion_mnist.py

Open up the

plot_shift.py

# import the necessary packages
import matplotlib.pyplot as plt
import numpy as np
import argparse
import pickle

# construct the argument parser and parse the arguments
ap = argparse.ArgumentParser()
ap.add_argument("-i", "--input", required=True,
	help="path to input training history file")
args = vars(ap.parse_args())

Lines 2-5 import

matplotlib

argparse

pickle

Lines 8-11 parse the

--input

.pickle

Let’s go ahead load our data and initialize our plot figure:

# load the training history
H = pickle.loads(open(args["input"], "rb").read())

# determine the total number of epochs used for training, then
# initialize the figure
epochs = np.arange(0, len(H["loss"]))
plt.style.use("ggplot")
(fig, axs) = plt.subplots(2, 1)

Line 14 loads our serialized training history 

.pickle

--input

Line 18 makes space for our x-axis which spans from zero to the number of

epochs

Lines 19 and 20 set up our plot figure to be two stacked plots in the same image:

• The top plot will contain loss curves as-is.
• The bottom plot, on the other hand, will include a shift for the training loss (but not for the validation loss). The training loss will be shifted half an epoch to the left just as in Aurélien’s tweet. We’ll then be able to observe if the plots line up more closely.

Let’s generate our top plot:

# plot the *unshifted* training and validation loss
plt.style.use("ggplot")
axs[0].plot(epochs, H["loss"], label="train_loss")
axs[0].plot(epochs, H["val_loss"], label="val_loss")
axs[0].set_title("Unshifted Loss Plot")
axs[0].set_xlabel("Epoch #")
axs[0].set_ylabel("Loss")
axs[0].legend()

And then draw our bottom plot:

# plot the *shifted* training and validation loss
axs[1].plot(epochs - 0.5, H["loss"], label="train_loss")
axs[1].plot(epochs, H["val_loss"], label="val_loss")
axs[1].set_title("Shifted Loss Plot")
axs[1].set_xlabel("Epoch #")
axs[1].set_ylabel("Loss")
axs[1].legend()

# show the plots
plt.tight_layout()
plt.show()

Notice on Line 32 that the training loss is shifted

0.5

Let’s now analyze our training/validation plots.

Open up a terminal and execute the following command:

$ python plot_shift.py --input training.pickle

Figure 4: Shifting the training loss plot 1/2 epoch to the left yields more similar plots. Clearly the time of measurement answers the question, “Why is my validation loss lower than training loss?”.

As you can observe, shifting the training loss values a half epoch to the left (bottom) makes the training/validation curves much more similar versus the unshifted (top) plot.

Reason #3: The validation set may be easier than the training set (or there may be leaks)

Figure 5: Consider how your validation set was acquired/generated. Common mistakes could lead to validation loss being less than training loss. (image source)

The final most common reason for validation loss being lower than your training loss is due to the data distribution itself.

Consider how your validation set was acquired:

• Can you guarantee that the validation set was sampled from the same distribution as the training set?
• Are you certain that the validation examples are just as challenging as your training images?
• Can you assure there was no “data leakage” (i.e., training samples getting accidentally mixed in with validation/testing samples)?
• Are you confident your code created the training, validation, and testing splits properly?

Every single deep learning practitioner has made the above mistakes at least once in their career.

Yes, it is embarrassing when it happens — but that’s the point — it does happen, so take the time now to investigate your code.

BONUS: Are you training hard enough?

Figure 6: If you are wondering why your validation loss is lower than your training loss, perhaps you aren’t “training hard enough”.

One aspect that Aurélien didn’t touch on in his tweets is the concept of “training hard enough”.

When training a deep neural network, our biggest concern is nearly always overfitting — and in order to combat overfitting, we introduce regularization techniques (discussed in Reason #1 above). We apply regularization in the form of:

• Dropout
• L2 weight decay
• Reducing model capacity (i.e., a more shallow model)

We also tend to be a bit more conservative with our learning rate to ensure our model doesn’t overshoot areas of lower loss in the loss landscape.

That’s all fine and good, but sometimes we end up over-regularizing our models.

If you go through all three reasons for validation loss being lower than training loss detailed above, you may have over-regularized your model. Start to relax your regularization constraints by:

• Lowering your L2 weight decay strength.
• Reducing the amount of dropout you’re applying.
• Increasing your model capacity (i.e., make it deeper).

You should also try training with a larger learning rate as you may have become too conservative with it.

Do you have unanswered deep learning questions?

You can train your first neural network in minutes…with just a few lines of Python.

But if you are just getting started, you may have questions such as today’s: “Why is my validation loss lower than training loss?”

Similar questions can stump you for weeks — maybe months. You might find yourself searching online for answers only to be disappointed in the explanations. Or maybe you posted your burning question to Stack Overflow or Quora and you are still hearing crickets.

It doesn’t have to be like that.

What you need is a comprehensive book to jumpstart your education. Discover and study deep learning the right way in my book: Deep Learning for Computer Vision with Python.

Inside the book, you’ll find self-study tutorials and end-to-end projects on topics like:

• Convolutional Neural Networks
• Object Detection via Faster R-CNNs and SSDs
• Generative Adversarial Networks (GANs)
• Emotion/Facial Expression Recognition
• Best practices, tips, and rules of thumb
• …and much more!

Using the knowledge gained by reading this book you’ll finally be able to bring deep learning to your own projects.

What’s more is that you’ll learn the “art” of training neural networks, answering questions such as:

1. Which deep learning CNN architecture is right for my task at hand?
2. How can I spot underfitting and overfitting either after or during training?
3. What is the most effective way to set my initial learning rate and to use a learning rate decay scheduler to improve accuracy?
4. Which deep learning optimizer is the best one for the job and how do I evaluate new, state-of-the-art optimizers as they are published?
5. How do I apply regularization techniques effectively ensuring that I am not over-regularizing my model?

You’ll find the answers to all of these questions inside my deep learning book.

Customers of mine attest that this is the best deep learning education you’ll find online — inside the book you’ll find:

• Super practical walkthroughs that present solutions to actual, real-world image classification, object detection, and segmentation problems.
• Hands-on tutorials (with lots of code) that not only show you the algorithms behind deep learning for computer vision but their implementations as well.
• A no-nonsense teaching style that is guaranteed to help you master deep learning for image understanding and visual recognition.

So why wait?

The cost of fumbling around the internet looking for answers to your questions only to find sub-par resources is costing you time that you can’t get back. The value you receive by reading my book is far, far greater than the price you pay and will ensure you receive a positive return on your investment of time and finances, I guarantee that.

To learn more about the book, and grab the table of contents + free sample chapters, just click here!

Summary

Today’s tutorial was heavily inspired by the following tweet thread from author, Aurélien Geron.

Inside the thread, Aurélien expertly and concisely explained the three reasons your validation loss may be lower than your training loss when training a deep neural network:

1. Reason #1: Regularization is applied during training, but not during validation/testing. If you add in the regularization loss during validation/testing, your loss values and curves will look more similar.
2. Reason #2: Training loss is measured during each epoch while validation loss is measured after each epoch. On average, the training loss is measured 1/2 an epoch earlier. If you shift your training loss curve a half epoch to the left, your losses will align a bit better.
3. Reason #3: Your validation set may be easier than your training set or there is a leak in your data/bug in your code. Make sure your validation set is reasonably large and is sampled from the same distribution (and difficulty) as your training set.
4. BONUS: You may be over-regularizing your model. Try reducing your regularization constraints, including increasing your model capacity (i.e., making it deeper with more parameters), reducing dropout, reducing L2 weight decay strength, etc.

Hopefully, this helps clear up any confusion on why your validation loss may be lower than your training loss!

It was certainly a head-scratcher for me when I first started studying machine learning and neural networks and it took me until mid-college to understand exactly why that happens — and none of the explanations back then were as clear and concise as Aurélien’s.

I hope you enjoyed today’s tutorial!

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

Downloads:

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

Email address:

Website

The post Why is my validation loss lower than my training loss? appeared first on PyImageSearch.

Continue Reading…

Collapse

Read More

Ray Could Write

Statistics Be

What has happened down here is the winds have changed

Spin

The Paper of My Enemy Has Been Retracted

Imaginary gardens with real data

A parable regarding changing standards on the presentation of statistical evidence

Laplace Calling

Thanks to W. B. Yeats, Young Tiger, Randy Newman, W. H. Auden, Clive James, Marianne Moore, Dr. Seuss, and the Clash for doing all the hard work on these.

Continue Reading…

Collapse

Read More

Also: Activation maps for deep learning models in a few lines of code; The 4 Quadrants of Data Science Skills and 7 Principles for Creating a Viral Data Visualization; OpenAI Tried to Train AI Agents to Play Hide-And-Seek but Instead They Were Shocked by What They Learned; 10 Great Python Resources for Aspiring Data Scientists

Continue Reading…

Collapse

Read More

Density estimation is estimating the probability density function of the population from the sample. This post examines and compares a number of approaches to density estimation.

Continue Reading…

Collapse

Read More

FiveThirtyEight has been predicting NBA games for a few years now, based on a variant of Elo ratings, which in turn have roots in ranking chess players. But for this season, they have a new metric to predict with called RAPTOR, or Robust Algorithm (using) Player Tracking (and) On/Off Ratings:

NBA teams highly value floor spacing, defense and shot creation, and they place relatively little value on traditional big-man skills. RAPTOR likewise values these things — not because we made any deliberate attempt to design the system that way but because the importance of those skills emerges naturally from the data. RAPTOR thinks ball-dominant players such as James Harden and Steph Curry are phenomenally good. It highly values two-way wings such as Kawhi Leonard and Paul George. It can have a love-hate relationship with centers, who are sometimes overvalued in other statistical systems. But it appreciates modern centers such as Nikola Jokić and Joel Embiid, as well as defensive stalwarts like Rudy Gobert.

I’ve mostly ignored sports-related predictions ever since the Golden State Warriors lost in the 2016 finals. There was a high probability that they would win it all, but they did not. That’s when I realized the predictions would only lead to a neutral confirmation or severe disappointment, but never happiness.

I’m sure this new metric will be different.

Tags: basketball, FiveThirtyEight

Continue Reading…

Collapse

Read More

Overfitting is one of the most critical challenges in deep neural networks, and there are various types of regularization methods to improve generalization performance. Injecting noises to hidden units during training, e.g., dropout, is known as a successful regularizer, but it is still not clear enough why such training techniques work well in practice and how we can maximize their benefit in the presence of two conflicting objectives—optimizing to true data distribution and preventing overfitting by regularization. This paper addresses the above issues by 1) interpreting that the conventional training methods with regularization by noise injection optimize the lower bound of the true objective and 2) proposing a technique to achieve a tighter lower bound using multiple noise samples per training example in a stochastic gradient descent iteration. We demonstrate the effectiveness of our idea in several computer vision applications. Regularizing Deep Neural Networks by Noise: Its Interpretation and Optimization

Continue Reading…

Collapse

Read More

Technically speaking, there is no need to evaluate the variable importance and to perform the variable selection in the training of a GRNN. It’s also been a consensus that the neural network is a black-box model and it is not an easy task to assess the variable importance in a neural network. However, from the practical prospect, it is helpful to understand the individual contribution of each predictor to the overall goodness-of-fit of a GRNN. For instance, the variable importance can help us make up a beautiful business story to decorate our model. In addition, dropping variables with trivial contributions also helps us come up with a more parsimonious model as well as improve the computational efficiency.

In the YAGeR project (https://github.com/statcompute/yager), two functions have been added with the purpose to assess the variable importance in a GRNN. While the grnn.x_imp() function (https://github.com/statcompute/yager/blob/master/code/grnn.x_imp.R) will provide the importance assessment of a single variable, the grnn.imp() function (https://github.com/statcompute/yager/blob/master/code/grnn.imp.R) can give us a full picture of the variable importance for all variables in the GRNN. The returned value “imp1” is calculated as the decrease in AUC with all values for the variable of interest equal to its mean and the “imp2” is calculated as the decrease in AUC with the variable of interest dropped completely. The variable with a higher value of the decrease in AUC is deemed more important.

Below is an example demonstrating how to assess the variable importance in a GRNN. As shown in the output, there are three variables making no contribution to AUC statistic. It is also noted that dropping three unimportant variables in the GRNN can actually increase AUC in the hold-out sample. What’s more, marginal effects of variables remaining in the GRNN make more sense now with all showing nice monotonic relationships, in particular “tot_open_tr”.

Continue Reading…

Collapse

Read More

• Transfer Learning with Dynamic Distribution Adaptation
• Conformal Prediction based Spectral Clustering
• Learning to Generate Questions with Adaptive Copying Neural Networks
• Measure Contribution of Participants in Federated Learning
• K-BERT: Enabling Language Representation with Knowledge Graph
• AdaFair: Cumulative Fairness Adaptive Boosting
• K-TanH: Hardware Efficient Activations For Deep Learning
• Multi Sense Embeddings from Topic Models
• !MDP Playground: Meta-Features in Reinforcement Learning
• Span-based Joint Entity and Relation Extraction with Transformer Pre-training
• Global Optimal Path-Based Clustering Algorithm
• Character-Centric Storytelling
• sktime: A Unified Interface for Machine Learning with Time Series
• Generating Black-Box Adversarial Examples for Text Classifiers Using a Deep Reinforced Model
• Ludwig: a type-based declarative deep learning toolbox
• Do NLP Models Know Numbers? Probing Numeracy in Embeddings
• BLOCCS: Block Sparse Canonical Correlation Analysis With Application To Interpretable Omics Integration
• ProtoGAN: Towards Few Shot Learning for Action Recognition
• Sparse Canonical Correlation Analysis via Concave Minimization
• Interpretable Principal Components Analysis for Multilevel Multivariate Functional Data, with Application to EEG Experiments
• Heterogeneity-Aware Asynchronous Decentralized Training
• Megatron-LM: Training Multi-Billion Parameter Language Models Using GPU Model Parallelism
• Adversarial Attacks and Defenses in Images, Graphs and Text: A Review
• Relaxed Softmax for learning from Positive and Unlabeled data
• A Distributed Fair Machine Learning Framework with Private Demographic Data Protection
• Ensemble Knowledge Distillation for Learning Improved and Efficient Networks
• Inference on the change point with the jump size near the boundary of the region of detectability in high dimensional time series models
• Gated Recurrent Units Learning for Optimal Deployment of Visible Light Communications Enabled UAVs
• The rank of a complex unit gain graph in terms of the matching number
• Object Reachability via Swaps under Strict and Weak Preferences
• A Joint Learning and Communications Framework for Federated Learning over Wireless Networks
• HAD-GAN: A Human-perception Auxiliary Defense GAN model to Defend Adversarial Examples
• Variable selection with false discovery rate control in deep neural networks
• Object-Centric Stereo Matching for 3D Object Detection
• Specific bounds for a probabilistically interpretable solution of the Poisson equation for general state-space Markov chains with queueing applications
• Nonnegative Canonical Polyadic Decomposition with Rank Deficient Factors
• A Data-Center FPGA Acceleration Platform for Convolutional Neural Networks
• Is That a Chair? Imagining Affordances Using Simulations of an Articulated Human Body
• Bridging the Gap between Pre-Training and Fine-Tuning for End-to-End Speech Translation
• On the Physical Interpretation of Proper Orthogonal Decomposition and Dynamic Mode Decomposition for Liquid Injection
• Multi-FAN: Multi-Spectral Mosaic Super-Resolution Via Multi-Scale Feature Aggregation Network
• Learned-SBL: A Deep Learning Architecture for Sparse Signal Recovery
• Stacking Models for Nearly Optimal Link Prediction in Complex Networks
• Design Theory and Some Non-simple Forbidden Configurations
• Exploring Scholarly Data by Semantic Query on Knowledge Graph Embedding Space
• Radiopathomics: Integration of radiographic and histologic characteristics for prognostication in glioblastoma
• Inverse Visual Question Answering with Multi-Level Attentions
• Grounding learning of modifier dynamics: An application to color naming
• A Hybrid Deep Learning Approach for Diagnosis of the Erythemato-Squamous Disease
• Communication-Efficient Distributed Learning via Lazily Aggregated Quantized Gradients
• Real-time Multi-target Path Prediction and Planning for Autonomous Driving aided by FCN
• Learning Explicit and Implicit Structures for Targeted Sentiment Analysis
• ASSED — A Framework for Identifying Physical Events through Adaptive Social Sensor Data Filtering
• Simple yet Effective Bridge Reasoning for Open-Domain Multi-Hop Question Answering
• Multi-step Entity-centric Information Retrieval for Multi-Hop Question Answering
• A Convergence Proof of Projected Fast Iterative Soft-thresholding Algorithm for Parallel Magnetic Resonance Imaging
• Integration and Simulation of Bivariate Projective-Cauchy Distributions within Arbitrary Polygonal Domains
• Improving the Learning of Multi-column Convolutional Neural Network for Crowd Counting
• On the nonexistence of pseudo-generalized quadrangles
• Alleviating Feature Confusion for Generative Zero-shot Learning
• Coherence Statistics of Structured Random Ensembles and Support Detection Bounds for OMP
• Cycle-consistent Conditional Adversarial Transfer Networks
• Quantum algorithm for finding the negative curvature direction in non-convex optimization
• Deep End-to-End Alignment and Refinement for Time-of-Flight RGB-D Module
• Refined $α$-Divergence Variational Inference via Rejection Sampling
• A Demonstration of Implication Logic Based on Volatile (Diffusive) Memristors
• Towards Efficient and Secure Delivery of Data for Deep Learning with Privacy-Preserving
• Communication-Efficient Weighted Sampling and Quantile Summary for GBDT
• Ergodic Spectral Efficiency of Massive MIMO with Correlated Rician Channel and MRC Detection based on LS and MMSE Channel Estimation
• Thanks for Nothing: Predicting Zero-Valued Activations with Lightweight Convolutional Neural Networks
• The Impact of Technologies in Political Campaigns
• DP-4-coloring of planar graphs with some restrictions on cycles
• Proceedings 35th International Conference on Logic Programming (Technical Communications)
• A heuristic use of dynamic programming to upperbound treewidth
• Social Network Analysis of Corruption Structures: Adjacency Matrices Supporting the Visualization and Quantification of Layeredness
• Multiple Birds with One Stone: Beating $1/2$ for EFX and GMMS via Envy Cycle Elimination
• Reachability Games with Relaxed Energy Constraints
• MetalGAN: a Cluster-based Adaptive Training for Few-Shot Adversarial Colorization
• Resource-Aware Automata and Games for Optimal Synthesis
• Controllable Length Control Neural Encoder-Decoder via Reinforcement Learning
• Specification and Optimal Reactive Synthesis of Run-time Enforcement Shields
• Novel Rigorous Multimode Equivalent Network Formulation for Boxed Planar Circuits with Arbitrarily Shaped Metallizations
• Persistence B-Spline Grids: Stable Vector Representation of Persistence Diagrams Based on Data Fitting
• Strong convergence order for slow-fast McKean-Vlasov stochastic differential equations
• Progressive Fusion for Unsupervised Binocular Depth Estimation using Cycled Networks
• Model-Based Real-Time Motion Tracking using Dynamical Inverse Kinematics
• Efficient Transfer Bayesian Optimization with Auxiliary Information
• Spatio-Semantic ConvNet-Based Visual Place Recognition
• Network-Aware Container Scheduling in Multi-Tenant Data Center
• Dynamics of balanced parentheses, lexicographic series and Dyck polynomials
• Probability distribution of the boundary local time of reflected Brownian motion in Euclidean domains
• Synchronous Maneuver Searching and Trajectory Planning for Autonomous Vehicles in Dynamic Traffic Environments
• Multilevel Sequential Importance Sampling for Rare Event Estimation
• Fiber Nonlinearity Mitigation via the Parzen Window Classifier for Dispersion Managed and Unmanaged Links
• Characterizing and Predicting Repeat Food Consumption Behavior for Just-in-Time Interventions
• Learning to Find Hydrological Corrections
• A goodness-of-fit test for the functional linear model with functional response
• Prediction of rare feature combinations in population synthesis: Application of deep generative modelling
• Competing growth processes with random growth rates and random birth times
• Network entity characterization and attack prediction
• Multi-Task Learning for Automotive Foggy Scene Understanding via Domain Adaptation to an Illumination-Invariant Representation
• Compositional uncertainty in deep Gaussian processes
• OpenReq Issue Link Map: A Tool to Visualize Issue Links in Jira
• Efficient, Fair and QoS-Aware Policies for Wirelessly Powered Communication Networks
• Task-Aware Monocular Depth Estimation for 3D Object Detection
• Using Latent Codes for Class Imbalance Problem in Unsupervised Domain Adaptation
• Multi-robot persistent surveillance with connectivity constraints
• re-OBJ: Jointly Learning the Foreground and Background for Object Instance Re-identification
• Variational Bayesian Context-aware Representation for Grocery Recommendation
• A Review of Tracking, Prediction and Decision Making Methods for Autonomous Driving
• LMI-based robust stability and stabilization analysis of fractional-order interval systems with time-varying delay
• An open-source, distributed workflow for band mapping data in multidimensional photoemission spectroscopy
• Geometric and spectral properties of directed graphs under a lower Ricci curvature bound
• Low-Dimensional Dynamics for Higher Order Harmonic Globally Coupled Phase Oscillator Ensemble
• Efficient and Robust Estimation of Linear Regression with Normal Errors
• DS-PASS: Detail-Sensitive Panoramic Annular Semantic Segmentation through SwaftNet for Surrounding Sensing
• Deep Point-wise Prediction for Action Temporal Proposal
• Building Change Detection for Remote Sensing Images Using a Dual Task Constrained Deep Siamese Convolutional Network Model
• Parallel Concatenation of Non-Binary Linear Random Fountain Codes with Maximum Distance Separable Codes
• An Image Based Visual Servo Approach with Deep Learning for Robotic Manipulation
• SocialNLP EmotionX 2019 Challenge Overview: Predicting Emotions in Spoken Dialogues and Chats
• $\mathrm{RCD}(K,N)$ spaces and the geometry of multi-particle Schrödinger semigroups
• Course Concept Expansion in MOOCs with External Knowledge and Interactive Game
• ICDAR 2019 Competition on Large-scale Street View Text with Partial Labeling — RRC-LSVT
• Control of criticality and computation in spiking neuromorphic networks with plasticity
• Adversarial Feature Training for Generalizable Robotic Visuomotor Control
• Hamiltonian regularisation of shallow water equations with uneven bottom
• Autonomous Energy Management system achieving piezoelectric energy harvesting in Wireless Sensors
• Defending against Machine Learning based Inference Attacks via Adversarial Examples: Opportunities and Challenges
• Sampling, Marcinkiewicz-Zygmund Inequalities, Approximation, and Quadrature Rules
• Impact of novel aggregation methods for flexible, time-sensitive EHR prediction without variable selection or cleaning
• A machine vision meta-algorithm for automated recognition of underwater objects using sidescan sonar imagery
• Single-shot 3D shape reconstruction using deep convolutional neural networks
• A pseudo-spectra based characterisation of the robust strong H-infinity norm of time-delay systems with real-valued and structured uncertainties
• Preprocessing and Cutting Planes with Conflict Graphs
• First-order sensitivity of the optimal value in a Markov decision model with respect to deviations in the transition probability function
• To Learn or Not to Learn: Deep Learning Assisted Wireless Modem Design
• A condition for scattered linearized polynomials involving Dickson matrices
• Extreme Value Based Estimation of Critical Single Event Failure Probability
• Chinese Street View Text: Large-scale Chinese Text Reading with Partially Supervised Learning
• Learn to Segment Organs with a Few Bounding Boxes
• DeepDriveMD: Deep-Learning Driven Adaptive Molecular Simulations for Protein Folding
• Learning Deformable Point Set Registration with Regularized Dynamic Graph CNNs for Large Lung Motion in COPD Patients
• Toward Understanding Crowd Mobility in Smart Cities through the Internet of Things
• A curvature notion for planar graphs stable under planar duality
• Weak Edge Identification Nets for Ocean Front Detection
• AdaptIS: Adaptive Instance Selection Network
• Shared Control Between Pilots and Autopilots: Illustration of a Cyber-Physical Human System
• Two-Sample Test Based on Classification Probability
• Dynamic causal modelling of phase-amplitude interactions
• Multimodal Multitask Representation Learning for Pathology Biobank Metadata Prediction
• Convergence of the random Abelian sandpile
• Adaptive Leader-Following Consensus for Multiple Euler-Lagrange Systems with an Uncertain Leader System
• Dynamic coloring for Bipartite and General Graphs
• Learning to Search for MIMO Detection
• Steady-State Optimal Frequency Control for Lossy Power Grids with Distributed Communication
• Markov Processes with Jumps on Manifolds and Lie Groups
• Minimax Confidence Intervals for the Sliced Wasserstein Distance
• Time scale design for network resilience
• Mitigating Network Noise on Dragonfly Networks through Application-Aware Routing
• Flag-transitive block designs and unitary groups
• Walling up Backdoors in Intrusion Detection Systems
• TruPercept: Trust Modelling for Autonomous Vehicle Cooperative Perception from Synthetic Data
• Two Computational Models for Analyzing Political Attention in Social Media
• Visualizing Movement Control Optimization Landscapes
• Learning to Manipulate Object Collections Using Grounded State Representations
• Multi-mapping Image-to-Image Translation via Learning Disentanglement
• Fractional matching preclusion number of graphs
• PixelHop: A Successive Subspace Learning (SSL) Method for Object Classification
• Estimating Glycemic Impact of Cooking Recipes via Online Crowdsourcing and Machine Learning
• A Note on Explicit Milstein-Type Scheme for Stochastic Differential Equation with Markovian Switching
• On Explicit Tamed Milstein-type scheme for Stochastic Differential Equation with Markovian Switching
• Distributional conformal prediction
• Vehicle routing by learning from historical solutions
• On the Optimality of the Greedy Policy for Battery Limited Energy Harvesting Communications
• Fast Search with Poor OCR
• SNR Enhancement in Brillouin Microspectroscopy using Spectrum Reconstruction
• Graph Nets for Partial Charge Prediction
• Generative Dialog Policy for Task-oriented Dialog Systems
• Pointer-based Fusion of Bilingual Lexicons into Neural Machine Translation
• Algorithm for Training Neural Networks on Resistive Device Arrays
• \lowercase{hm-toolbox}: Matlab software for HODLR and HSS matrices
• Learning to Deceive with Attention-Based Explanations
• On a sufficient condition for infinite horizon optimal control problems
• Safety-Critical Adaptive Control with Nonlinear Reference Model Systems
• Adaptive and Dynamically Constrained Process Noise Estimation for Orbit Determination
• Distributed Function Minimization in Apache Spark
• Ranking metrics on non-shuffled traffic
• Say Anything: Automatic Semantic Infelicity Detection in L2 English Indefinite Pronouns
• A Forensic Qualitative Analysis of Contributions to Wikipedia from Anonymity Seeking Users
• Sums of random polynomials with independent roots
• An Approximate Version of the Strong Nine Dragon Tree Conjecture
• Semantic Relatedness Based Re-ranker for Text Spotting
• Various Characterizations of Throttling Numbers
• On $m$-ovoids of Symplectic Polar Spaces
• An Internal Learning Approach to Video Inpainting
• A new scalable algorithm for computational optimal control under uncertainty
• Approximation of SDEs — a stochastic sewing approach
• Two-scale coupling for preconditioned Hamiltonian Monte Carlo in infinite dimensions
• Deep Learning based Precoding for the MIMO Gaussian Wiretap Channel
• On clique immersions in line graphs
• On sets with small sumset and m-sum-free sets in Z/pZ
• Towards Object Detection from Motion
• On an inverse Robin spectral problem
• Achieving Phase Coherency and Gain Stability in Active Antenna Arrays for Sub-6 GHz FDD and TDD FD-MIMO: Challenges and Solutions
• Leyenda: An Adaptive, Hybrid Sorting Algorithm for Large Scale Data with Limited Memory
• Distributed Leader Following of an Active Leader in Formation for Heterogeneous Multi-Agent Systems
• A Survey of Rate-optimal Power Domain NOMA Schemes for Enabling Technologies of Future Wireless Networks
• A Note on a Simple and Practical Randomized Response Framework for Eliciting Sensitive Dichotomous & Quantitative Information
• BSDAR: Beam Search Decoding with Attention Reward in Neural Keyphrase Generation
• Strategic Formation and Reliability of Supply Chain Networks
• Rotational Uniqueness Conditions Under Oblique Factor Correlation Metric
• Cardiac MRI Image Segmentation for Left Ventricle and Right Ventricle using Deep Learning
• Optimizing Through Learned Errors for Accurate Sports Field Registration
• Robust statistical modeling of monthly rainfall: The minimum density power divergence approach
• Masking Salient Object Detection, a Mask Region-based Convolutional Neural Network Analysis for Segmentation of Salient Objects
• Revealing the Importance of Semantic Retrieval for Machine Reading at Scale
• Masked-RPCA: Sparse and Low-rank Decomposition Under Overlaying Model and Application to Moving Object Detection
• A scalable noisy speech dataset and online subjective test framework
• Higher-order interactions in complex networks of phase oscillators promote abrupt synchronization switching
• Learn to Estimate Labels Uncertainty for Quality Assurance
• Construction of sequences with high Nonlinear Complexity from the Hermitian Function Field
• Simultaneous Identification and Control Using Active Signal Injection for Series Hybrid Electric Vehicles based on Dynamic Programming
• Deterministic algorithms for the Lovasz Local Lemma: simpler, more general, and more parallel
• Surface alignment disorder and pseudo-Casimir forces in smectic-A liquid crystalline films
• Properties of Laplacian Pyramids for Extension and Denoising
• Extractive Summarization of Long Documents by Combining Global and Local Context
• DOVER: A Method for Combining Diarization Outputs
• Worst-case complexity bounds of directional direct-search methods for multiobjective derivative-free optimization

Continue Reading…

Collapse

Read More

Transfer Learning with Dynamic Distribution Adaptation

Conformal Prediction based Spectral Clustering

Learning to Generate Questions with Adaptive Copying Neural Networks

Measure Contribution of Participants in Federated Learning

K-BERT: Enabling Language Representation with Knowledge Graph

AdaFair: Cumulative Fairness Adaptive Boosting

K-TanH: Hardware Efficient Activations For Deep Learning

We propose K-TanH, a novel, highly accurate, hardware efficient approximation of popular activation function Tanh for Deep Learning. K-TanH consists of a sequence of parameterized bit/integer operations, such as, masking, shift and add/subtract (no floating point operation needed) where parameters are stored in a very small look-up table. The design of K-TanH is flexible enough to deal with multiple numerical formats, such as, FP32 and BFloat16. High quality approximations to other activation functions, e.g., Swish and GELU, can be derived from K-TanH. We provide RTL design for K-TanH to demonstrate its area/power/performance efficacy. It is more accurate than existing piecewise approximations for Tanh. For example, K-TanH achieves speed up and reduction in maximum approximation error over software implementation of Hard TanH. Experimental results for low-precision BFloat16 training of language translation model GNMT on WMT16 data sets with approximate Tanh and Sigmoid obtained via K-TanH achieve similar accuracy and convergence as training with exact Tanh and Sigmoid.

Multi Sense Embeddings from Topic Models

!MDP Playground: Meta-Features in Reinforcement Learning

Span-based Joint Entity and Relation Extraction with Transformer Pre-training

Global Optimal Path-Based Clustering Algorithm

Character-Centric Storytelling

sktime: A Unified Interface for Machine Learning with Time Series

Generating Black-Box Adversarial Examples for Text Classifiers Using a Deep Reinforced Model

Ludwig: a type-based declarative deep learning toolbox

Do NLP Models Know Numbers? Probing Numeracy in Embeddings

BLOCCS: Block Sparse Canonical Correlation Analysis With Application To Interpretable Omics Integration

ProtoGAN: Towards Few Shot Learning for Action Recognition

Sparse Canonical Correlation Analysis via Concave Minimization

Interpretable Principal Components Analysis for Multilevel Multivariate Functional Data, with Application to EEG Experiments

Many studies collect functional data from multiple subjects that have both multilevel and multivariate structures. An example of such data comes from popular neuroscience experiments where participants’ brain activity is recorded using modalities such as EEG and summarized as power within multiple time-varying frequency bands within multiple electrodes, or brain regions. Summarizing the joint variation across multiple frequency bands for both whole-brain variability between subjects, as well as location-variation within subjects, can help to explain neural reactions to stimuli. This article introduces a novel approach to conducting interpretable principal components analysis on multilevel multivariate functional data that decomposes total variation into subject-level and replicate-within-subject-level (i.e. electrode-level) variation, and provides interpretable components that can be both sparse among variates (e.g. frequency bands) and have localized support over time within each frequency band. The sparsity and localization of components is achieved by solving an innovative rank-one based convex optimization problem with block Frobenius and matrix -norm based penalties. The method is used to analyze data from a study to better understand reactions to emotional information in individuals with histories of trauma and the symptom of dissociation, revealing new neurophysiological insights into how subject- and electrode-level brain activity are associated with these phenomena.

Heterogeneity-Aware Asynchronous Decentralized Training

Megatron-LM: Training Multi-Billion Parameter Language Models Using GPU Model Parallelism

Adversarial Attacks and Defenses in Images, Graphs and Text: A Review

Relaxed Softmax for learning from Positive and Unlabeled data

A Distributed Fair Machine Learning Framework with Private Demographic Data Protection

Ensemble Knowledge Distillation for Learning Improved and Efficient Networks

Inference on the change point with the jump size near the boundary of the region of detectability in high dimensional time series models

Continue Reading…

Collapse

Read More

“Moving data doesn’t come for free.” Adrian Colyer ( May 25, 2017 )

Continue Reading…

Collapse

Read More

Phase Plane Analysis of One- And Two-Dimensional Autonomous ODE Systems (phaseR)
Performs a qualitative analysis of one- and two-dimensional autonomous ordinary differential equation systems, using phase plane methods. Programs are available to identify and classify equilibrium points, plot the direction field, and plot trajectories for multiple initial conditions. In the one-dimensional case, a program is also available to plot the phase portrait. Whilst in the two-dimensional case, programs are additionally available to plot nullclines and stable/unstable manifolds of saddle points. Many example systems are provided for the user. For further details can be found in Grayling (2014) <doi:10.32614/RJ-2014-023>.

Distributions for Ecological Models in ‘nimble’ (nimbleEcology)
Common ecological distributions for ‘nimble’ models in the form of nimbleFunction objects. Includes Cormack-Jolly-Seber, occupancy, dynamic occupancy, hidden Markov, and dynamic hidden Markov models. (Jolly (1965) <doi:10.2307/2333826>, Seber (1965) <10.2307/2333827>, Turek et al. (2016) <doi:10.1007/s10651-016-0353-z>).

Bayesian Estimation of Bivariate Volatility Model (BayesBEKK)
The Multivariate Generalized Autoregressive Conditional Heteroskedasticity (MGARCH) models are used for modelling the volatile multivariate data sets. In this package a variant of MGARCH called BEKK (Baba, Engle, Kraft, Kroner) proposed by Engle and Kroner (1995) <http://…/3532933> has been used to estimate the bivariate time series data using Bayesian technique.

Data Transformation or Simulation with Empirical Covariance Matrix (simTargetCov)
Transforms or simulates data with a target empirical covariance matrix supplied by the user. The method to obtain the data with the target empirical covariance matrix is described in Section 5.1 of Christidis, Van Aelst and Zamar (2019) <arXiv:1812.05678>.

Graphical and Numerical Checks for Mode-Finding Routines (optimCheck)
Tools for checking that the output of an optimization algorithm is indeed at a local mode of the objective function. This is accomplished graphically by calculating all one-dimensional ‘projection plots’ of the objective function, i.e., varying each input variable one at a time with all other elements of the potential solution being fixed. The numerical values in these plots can be readily extracted for the purpose of automated and systematic unit-testing of optimization routines.

Continue Reading…

Collapse

Read More

Doing away with such handouts is devilishly difficult

Continue Reading…

Collapse

Read More

See which parties British voters plan to support

Continue Reading…

Collapse

Read More

I was recently making some arrangements for the 2020 eclipse in South America, which of course got me thinking of the day we were lucky enough to have a path of totality come to us.

We have a weather station that records local temperature every 5 minutes, so after the eclipse I was able to plot the temperature change over the eclipse as we experienced it at our house. Here is an example of a basic plot I made at the time.

Looking at this now with new eyes, I see it might be nice replace the gray rectangle with one that goes from light to dark to light as the eclipse progresses to totality and then back. I’ll show how I tackled making a gradient color background in this post.

library(ggplot2) # 3.2.1
library(dplyr) # 0.8.3

head(temp)

# # A tibble: 6 x 2
#   datetime            tempf
#                 
# 1 2017-08-21 06:00:00  54.9
# 2 2017-08-21 06:05:00  54.9
# 3 2017-08-21 06:10:00  54.9
# 4 2017-08-21 06:15:00  54.9
# 5 2017-08-21 06:20:00  54.9
# 6 2017-08-21 06:25:00  54.8

eclipse = data.frame(start = as.POSIXct("2017-08-21 09:05:10"),
                     end = as.POSIXct("2017-08-21 11:37:19") )

totality = data.frame(start = as.POSIXct("2017-08-21 10:16:55"),
                      end = as.POSIXct("2017-08-21 10:18:52") )

plottemp = filter(temp, between(datetime, 
                                as.POSIXct("2017-08-21 09:00:00"),
                                as.POSIXct("2017-08-21 12:00:00") ) )

ggplot(plottemp) +
     geom_line( aes(datetime, tempf), size = 1 ) +
     scale_x_datetime( date_breaks = "15 min",
                       date_labels = "%H:%M",
                       expand = c(0, 0) ) +
     coord_cartesian(xlim = c(eclipse$start, eclipse$end) ) +
     labs(y = expression( Temperature~(degree*F) ),
          x = NULL,
          title = "Temperature during 2017-08-21 solar eclipse",
          subtitle = expression(italic("Sapsucker Farm, 09:05:10 - 11:37:19 PDT") ),
          caption = "Eclipse: 2 hours 32 minutes 9 seconds\nTotality: 1 minute 57 seconds"
     ) +
     scale_y_continuous(sec.axis = sec_axis(~ (. - 32) * 5 / 9 , 
                                            name =  expression( Temperature~(degree*C)),
                                            breaks = seq(16, 24, by = 1)) ) +
     theme_bw(base_size = 14) +
     theme(panel.grid = element_blank() ) 

color_dat = data.frame(time = seq(eclipse$start, eclipse$end, by = "1 sec") )

color_dat = mutate(color_dat,
                   color = 0,
                   color = replace(color, 
                                   time < totality$start, 
                                   seq(100, 0, length.out = sum(time < totality$start) ) ),
                   color = replace(color, 
                                   time > totality$end, 
                                   seq(0, 100, length.out = sum(time > totality$end) ) ) )

g1 = ggplot(plottemp) +
     geom_segment(data = color_dat,
                  aes(x = time, xend = time,
                      y = -Inf, yend = Inf, color = color),
                  show.legend = FALSE) +
     geom_line( aes(datetime, tempf), size = 1 ) +
     scale_x_datetime( date_breaks = "15 min",
                       date_labels = "%H:%M",
                       expand = c(0, 0) ) +
     coord_cartesian(xlim = c(eclipse$start, eclipse$end) ) +
     labs(y = expression( Temperature~(degree*F) ),
          x = NULL,
          title = "Temperature during 2017-08-21 solar eclipse",
          subtitle = expression(italic("Sapsucker Farm, 09:05:10 - 11:37:19 PDT") ),
          caption = "Eclipse: 2 hours 32 minutes 9 seconds\nTotality: 1 minute 57 seconds"
     ) +
     scale_y_continuous(sec.axis = sec_axis(~ (. - 32) * 5 / 9 , 
                                            name =  expression( Temperature~(degree*C)),
                                            breaks = seq(16, 24, by = 1)) ) +
     theme_bw(base_size = 14) +
     theme(panel.grid = element_blank() ) 

g1

g1 + scale_color_gradient(low = gray.colors(1, 0.25),
                          high = gray.colors(1, 1) )

g2 = ggplot(temp) +
     geom_segment(data = color_dat,
                  aes(x = time, xend = time,
                      y = -Inf, yend = Inf, color = color),
                  show.legend = FALSE) +
     geom_line( aes(datetime, tempf), size = 1 ) +
     scale_x_datetime( date_breaks = "1 hour",
                       date_labels = "%H:%M",
                       expand = c(0, 0) ) +
     labs(y = expression( Temperature~(degree*F) ),
          x = NULL,
          title = "Temperature during 2017-08-21 solar eclipse",
          subtitle = expression(italic("Sapsucker Farm, Dallas, OR, USA") ),
          caption = "Eclipse: 2 hours 32 minutes 9 seconds\nTotality: 1 minute 57 seconds"
     ) +
     scale_y_continuous(sec.axis = sec_axis(~ (. - 32) * 5 / 9 , 
                                            name =  expression( Temperature~(degree*C)),
                                            breaks = seq(12, 24, by = 2)) ) +
     scale_color_gradient(low = gray.colors(1, .25),
                          high = gray.colors(1, 1) ) +
     theme_bw(base_size = 14) +
     theme(panel.grid.major.x = element_blank(),
           panel.grid.minor = element_blank() ) 

g2

g2 = g2 + 
     annotate("text", x = as.POSIXct("2017-08-21 08:00"),
              y = 74, 
              label = "Partial eclipse begins\n09:05:10 PDT",
              color = "grey24") +
     annotate("text", x = as.POSIXct("2017-08-21 09:00"),
              y = 57, 
              label = "Totality begins\n10:16:55 PDT",
              color = "grey24")
g2

arrows = data.frame(x1 = as.POSIXct( c("2017-08-21 08:35",
                                      "2017-08-21 09:34") ),
                    x2 = c(eclipse$start, totality$start),
                    y1 = c(74, 57.5),
                    y2 = c(72.5, 60) )

g2 +
     geom_curve(data = arrows,
                aes(x = x1, xend = x2,
                    y = y1, yend = y2),
                arrow = arrow(length = unit(0.075, "inches"),
                              type = "closed"),
                curvature = 0.25)

library(ggplot2) # 3.2.1
library(dplyr) # 0.8.3

head(temp)
eclipse = data.frame(start = as.POSIXct("2017-08-21 09:05:10"),
                     end = as.POSIXct("2017-08-21 11:37:19") )

totality = data.frame(start = as.POSIXct("2017-08-21 10:16:55"),
                      end = as.POSIXct("2017-08-21 10:18:52") )

plottemp = filter(temp, between(datetime, 
                                as.POSIXct("2017-08-21 09:00:00"),
                                as.POSIXct("2017-08-21 12:00:00") ) )
ggplot(plottemp) +
     geom_line( aes(datetime, tempf), size = 1 ) +
     scale_x_datetime( date_breaks = "15 min",
                       date_labels = "%H:%M",
                       expand = c(0, 0) ) +
     coord_cartesian(xlim = c(eclipse$start, eclipse$end) ) +
     labs(y = expression( Temperature~(degree*F) ),
          x = NULL,
          title = "Temperature during 2017-08-21 solar eclipse",
          subtitle = expression(italic("Sapsucker Farm, 09:05:10 - 11:37:19 PDT") ),
          caption = "Eclipse: 2 hours 32 minutes 9 seconds\nTotality: 1 minute 57 seconds"
     ) +
     scale_y_continuous(sec.axis = sec_axis(~ (. - 32) * 5 / 9 , 
                                            name =  expression( Temperature~(degree*C)),
                                            breaks = seq(16, 24, by = 1)) ) +
     theme_bw(base_size = 14) +
     theme(panel.grid = element_blank() ) 
color_dat = data.frame(time = seq(eclipse$start, eclipse$end, by = "1 sec") )
color_dat = mutate(color_dat,
                   color = 0,
                   color = replace(color, 
                                   time < totality$start, 
                                   seq(100, 0, length.out = sum(time < totality$start) ) ),
                   color = replace(color, 
                                   time > totality$end, 
                                   seq(0, 100, length.out = sum(time > totality$end) ) ) )
g1 = ggplot(plottemp) +
     geom_segment(data = color_dat,
                  aes(x = time, xend = time,
                      y = -Inf, yend = Inf, color = color),
                  show.legend = FALSE) +
     geom_line( aes(datetime, tempf), size = 1 ) +
     scale_x_datetime( date_breaks = "15 min",
                       date_labels = "%H:%M",
                       expand = c(0, 0) ) +
     coord_cartesian(xlim = c(eclipse$start, eclipse$end) ) +
     labs(y = expression( Temperature~(degree*F) ),
          x = NULL,
          title = "Temperature during 2017-08-21 solar eclipse",
          subtitle = expression(italic("Sapsucker Farm, 09:05:10 - 11:37:19 PDT") ),
          caption = "Eclipse: 2 hours 32 minutes 9 seconds\nTotality: 1 minute 57 seconds"
     ) +
     scale_y_continuous(sec.axis = sec_axis(~ (. - 32) * 5 / 9 , 
                                            name =  expression( Temperature~(degree*C)),
                                            breaks = seq(16, 24, by = 1)) ) +
     theme_bw(base_size = 14) +
     theme(panel.grid = element_blank() ) 

g1

g1 + scale_color_gradient(low = gray.colors(1, 0.25),
                          high = gray.colors(1, 1) )
g2 = ggplot(temp) +
     geom_segment(data = color_dat,
                  aes(x = time, xend = time,
                      y = -Inf, yend = Inf, color = color),
                  show.legend = FALSE) +
     geom_line( aes(datetime, tempf), size = 1 ) +
     scale_x_datetime( date_breaks = "1 hour",
                       date_labels = "%H:%M",
                       expand = c(0, 0) ) +
     labs(y = expression( Temperature~(degree*F) ),
          x = NULL,
          title = "Temperature during 2017-08-21 solar eclipse",
          subtitle = expression(italic("Sapsucker Farm, Dallas, OR, USA") ),
          caption = "Eclipse: 2 hours 32 minutes 9 seconds\nTotality: 1 minute 57 seconds"
     ) +
     scale_y_continuous(sec.axis = sec_axis(~ (. - 32) * 5 / 9 , 
                                            name =  expression( Temperature~(degree*C)),
                                            breaks = seq(12, 24, by = 2)) ) +
     scale_color_gradient(low = gray.colors(1, .25),
                          high = gray.colors(1, 1) ) +
     theme_bw(base_size = 14) +
     theme(panel.grid.major.x = element_blank(),
           panel.grid.minor = element_blank() ) 

g2
g2 = g2 + 
     annotate("text", x = as.POSIXct("2017-08-21 08:00"),
              y = 74, 
              label = "Partial eclipse begins\n09:05:10 PDT",
              color = "grey24") +
     annotate("text", x = as.POSIXct("2017-08-21 09:00"),
              y = 57, 
              label = "Totality begins\n10:16:55 PDT",
              color = "grey24")
g2

arrows = data.frame(x1 = as.POSIXct( c("2017-08-21 08:35",
                                      "2017-08-21 09:34") ),
                    x2 = c(eclipse$start, totality$start),
                    y1 = c(74, 57.5),
                    y2 = c(72.5, 60) )
g2 +
     geom_curve(data = arrows,
                aes(x = x1, xend = x2,
                    y = y1, yend = y2),
                arrow = arrow(length = unit(0.075, "inches"),
                              type = "closed"),
                curvature = 0.25)

Continue Reading…

Collapse

Read More

Scanning all new published packages on PyPI I know that the quality is often quite bad. I try to filter out the worst ones and list here the ones which might be worth a look, being followed or inspire you in some way.

• GN
A hierachical community detection algorithm by Girvan Newman. A Girvan Newman step is defined as a couple of successive edge removes such that a new community occurs.

• meditorch
A PyTorch package for biomedical image processing

• metriculous
Very unstable library containing utilities to measure and visualize statistical properties of machine learning models.

• podworld
2D partially observable dynamic world for RL experiments. PodWorld is (https://gym.openai.com ) environment for (http://…/the-book-2nd.html ) experimentations. PodWorld is specifically designed to be partially observable and dynamic (hence abbreviation P.O.D.). We emphasize these two attributes to force agents learn spatial as well as temporal representations that must go beyond simple memorization. In addition, all entities in PodWorld must obey laws of physics allowing for long tail of emergent observations that may not appear in games designed with arbitrary hand crafted rules for human entertainment. PodWorld is designed to be highly customizable as well as hackable with fairly simple and minimal code base. PodWorld is designed to be fast (>500 FPS on usual laptops) without needing GPU and run cross platform in headless mode or with render.

• sensplit
Splits a dataset (in Pandas dataframe format) to train/test sets.

• simple-gpu-scheduler
A simple scheduler for running commands on multiple GPUs. A simple scheduler to run your commands on individual GPUs. Following the (https://…/KISS_principle ), this script simply accepts commands via `stdin` and executes them on a specific GPU by setting the `CUDA_VISIBLE_DEVICES` variable.

• simple-s3
Simple S3 uploads

• sparkle-hypothesis
Use the power of hypothesis property based testing in PySpark tests. Data heavy tests benefit from Hypothesis to generate your data and desinging your tests. Sparkle-hypothesis makes it easy to use Hypothesis strategies to generate dataframes.

• sstk
A systematic strategy toolkit.

• TeaML
Automated Modeling in Financial Domain. TeaML is a simple and design friendly automatic modeling learning framework. It can automatically model from beginning to end, and in the end, it will also help you output a model report about the model.

Continue Reading…

Collapse

Read More

Introduction:

On August 2, 2016 then Trump campaign manager, Paul Manafort, gave polling data to Konstantin Kalimnik a Russian widely assumed to be a spy. Before then Manafort ordered his protege, Rick Gates, to share polling data with Kilmnik. Gates periodically did so starting April or May. The Mueller Report stated it did not know why Manafort was insistent on giving this information or whether the Russian’s used it to further Trump’s cause (p. 130 see here for my summary of Mueller Report V1).

One theory says that Manafort wanted to show the good work he was doing to Kilimnik’s boss, a Russian Oligarch named Deripiskia, whom Manafort owed money to. A more sinister hypothesis is that Manafort knew that the information would be valuable in the hands of Russian’s trying to interfere with the election.

This post will analyze whether the Russians used the polling data irrespective of Manafort’s intent. I looked at Russian Facebook Ads uncovered by House Intelligence Committee and tried to identify any changes in messaging after August 2nd. I conclude with a guess on what the polling data was shared.

Russian Facebook Data:

The House Intelligence Committee released  thousands of Russian Advertisements by the Internet Research Agency. There have been several analysis on these advertisements that discuss they’re effectiveness and one good one is by Spangher et al. However, I couldn’t find any that showed topics of advertisements over time.

I focused the analysis to data in 2016 which includes periods of Manafort coming into the position of campaign manager and the election itself in november. Overall there 1858 facebook Ads captured in this dataset. Below is a time series plot of number of Advertisements per day for 2016.

There are periods of high activity in May / June and in October right before the election.

Change After August 2nd?

Each advertisement has metadata and text associated with it including: date, text, target population, etc. To see if there were any changes through time and in particular august 2nd I tried some topic modeling and text clustering to see if there were any natural changes. I couldn’t find any changes or trends using an unsupervised approach.

Instead I built a predictive model with the response being a binary variable; before  / after august 2nd and explanatory variables as text features from each ad (over 1200 words). I then performed variable importance on these words to see which were most predictive. Below I plotted the number of adverts with the important words divided by numer of advertisements for a particular day to get a normalized percentage.

The blue line is when Manafort made contact with Kilimnik initially and the red line is the august 2nd meeting. There does appear to be large increases in the words associated with African American civil rights topics after 8/2. Specifically these words were not in the advertisements texts themselves but were in the ‘people who liked’ description. That is, if you liked ‘Martin Luther King’ on your profile then a particular ad would target you.

Another way to look at this information is to see the proportion of these words used before and after 8/2.

The above plot shows the number of times a word appeared before and after 8/2 and the P(date>8/2) | word). For instance the word 1954, signifying the beginning of civil rights, occured 4 times before and 376 times after 8/2 which means that just under 99% of times it appears happen after that. This suggests there was a change in the IRA advertisements where they focused more on targeting people that were interested African American civil rights issues.

Conclusions / Discussions

I’m guessing that the contents of the polling data would be something related to African Americans and how those that have an interest in civil rights movement are more susceptible to negative ads.

Do I think the evidence presented here is that strong enough to believe the Russians used polling data? Meh, not really. For few reasons:

• All words found here were used a few times before the 8/2
• Gates gave information on a continuous basis. If Russians used this data I assume they would incorporate it accordingly and there would not be a discrete change at 8/2
• I only did this for one date. Perhaps if I did this analysis for an arbitrary dates then I would find other words that were associated with other dates

I’m not saying that they didn’t use the polling data but I don’t think the evidence here is strong enough to say that they did. At a minimum I think that the IRA and Russians adapted Ads to target different populations at different points in time. This shows they are sophisticated and probably learn from previous results. 

Code

Continue Reading…

Collapse

Read More

Policy Learning based on Completely Behavior Cloning (PLCBC)
Direct policy search is one of the most important algorithm of reinforcement learning. However, learning from scratch needs a large amount of experience data and can be easily prone to poor local optima. In addition to that, a partially trained policy tends to perform dangerous action to agent and environment. In order to overcome these challenges, this paper proposed a policy initialization algorithm called Policy Learning based on Completely Behavior Cloning (PLCBC). PLCBC first transforms the Model Predictive Control (MPC) controller into a piecewise affine (PWA) function using multi-parametric programming, and uses a neural network to express this function. By this way, PLCBC can completely clone the MPC controller without any performance loss, and is totally training-free. The experiments show that this initialization strategy can help agent learn at the high reward state region, and converge faster and better. …

PredRNN++
We present PredRNN++, an improved recurrent network for video predictive learning. In pursuit of a greater spatiotemporal modeling capability, our approach increases the transition depth between adjacent states by leveraging a novel recurrent unit, which is named Causal LSTM for re-organizing the spatial and temporal memories in a cascaded mechanism. However, there is still a dilemma in video predictive learning: increasingly deep-in-time models have been designed for capturing complex variations, while introducing more difficulties in the gradient back-propagation. To alleviate this undesirable effect, we propose a Gradient Highway architecture, which provides alternative shorter routes for gradient flows from outputs back to long-range inputs. This architecture works seamlessly with causal LSTMs, enabling PredRNN++ to capture short-term and long-term dependencies adaptively. We assess our model on both synthetic and real video datasets, showing its ability to ease the vanishing gradient problem and yield state-of-the-art prediction results even in a difficult objects occlusion scenario. …

ReSIFT
This paper presents a full-reference image quality estimator based on SIFT descriptor matching over reliability-weighted feature maps. Reliability assignment includes a smoothing operation, a transformation to perceptual color domain, a local normalization stage, and a spectral residual computation with global normalization. The proposed method ReSIFT is tested on the LIVE and the LIVE Multiply Distorted databases and compared with 11 state-of-the-art full-reference quality estimators. In terms of the Pearson and the Spearman correlation, ReSIFT is the best performing quality estimator in the overall databases. Moreover, ReSIFT is the best performing quality estimator in at least one distortion group in compression, noise, and blur category. …

Feature Generation by Convolutional Neural Network (FGCNN)
Click-Through Rate prediction is an important task in recommender systems, which aims to estimate the probability of a user to click on a given item. Recently, many deep models have been proposed to learn low-order and high-order feature interactions from original features. However, since useful interactions are always sparse, it is difficult for DNN to learn them effectively under a large number of parameters. In real scenarios, artificial features are able to improve the performance of deep models (such as Wide & Deep Learning), but feature engineering is expensive and requires domain knowledge, making it impractical in different scenarios. Therefore, it is necessary to augment feature space automatically. In this paper, We propose a novel Feature Generation by Convolutional Neural Network (FGCNN) model with two components: Feature Generation and Deep Classifier. Feature Generation leverages the strength of CNN to generate local patterns and recombine them to generate new features. Deep Classifier adopts the structure of IPNN to learn interactions from the augmented feature space. Experimental results on three large-scale datasets show that FGCNN significantly outperforms nine state-of-the-art models. Moreover, when applying some state-of-the-art models as Deep Classifier, better performance is always achieved, showing the great compatibility of our FGCNN model. This work explores a novel direction for CTR predictions: it is quite useful to reduce the learning difficulties of DNN by automatically identifying important features. …

Continue Reading…

Collapse

Read More

Last week’s post just happened to use MCMCglmm as an example of an R package that can get confused by tibble-style data frames. To make that example, I simulated some pedigree and trait data. Just for fun, let’s look at the simulation code, and use MCMCglmm and AnimalINLA to get heritability estimates.

First, here is some AlphaSimR code that creates a small random mating population, and collects trait and pedigree:

library(AlphaSimR)

## Founder population
FOUNDERPOP <- runMacs(nInd = 100,
                      nChr = 20,
                      inbred = FALSE,
                      species = "GENERIC")

## Simulation parameters 
SIMPARAM <- SimParam$new(FOUNDERPOP)
SIMPARAM$addTraitA(nQtlPerChr = 100,
                   mean = 100,
                   var = 10)
SIMPARAM$setGender("yes_sys")
SIMPARAM$setVarE(h2 = 0.3)
 
## Random mating for 9 more generations
generations <- vector(mode = "list", length = 10) 
generations[[1]] <- newPop(FOUNDERPOP,
                           simParam = SIMPARAM)


for (gen in 2:10) {

    generations[[gen]] <- randCross(generations[[gen - 1]],
                                    nCrosses = 10,
                                    nProgeny = 10,
                                    simParam = SIMPARAM)

}

## Put them all together
combined <- Reduce(c, generations)


## Extract phentoypes
pheno <- data.frame(animal = combined@id,
                    pheno = combined@pheno[,1])

## Extract pedigree
ped <- data.frame(id = combined@id,
                  dam = combined@mother,
                  sire =combined@father)
ped$dam[ped$dam == 0] <- NA
ped$sire[ped$sire == 0] <- NA

## Write out the files
write.csv(pheno,
          file = "sim_pheno.csv",
          row.names = FALSE,
          quote = FALSE)

write.csv(ped,
          file = "sim_ped.csv",
          row.names = FALSE,
          quote = FALSE)

In turn, we:

1. Set up a founder population with a AlphaSimR’s generic livestock-like population history, and 20 chromosomes.
2. Choose simulation parameters: we have an organism with separate sexes, a quantitative trait with an additive polygenic architecture, and we want an environmental variance to give us a heritability of 0.3.
3. We store away the founders as the first generation, then run a loop to give us nine additional generations of random mating.
4. Combine the resulting generations into one population.
5. Extract phenotypes and pedigree into their own data frames.
6. Optionally, save the latter data frames to files (for the last post).

Now that we have some data, we can fit a quantitative genetic pedigree model (”animal model”) to estimate genetic parameters. We’re going to try two methods to fit it: Markov Chain Monte Carlo and (the unfortunately named) Integrated Nested Laplace Approximation. MCMC explores the posterior distribution by sampling; I’m not sure where I heard it described as ”exploring a mountain by random teleportation”. INLA makes approximations to the posterior that can be integrated numerically; I guess it’s more like building a sculpture of the mountain.

First, a Gaussian animal model in MCMCglmm:

library(MCMCglmm)

## Gamma priors for variances
prior_gamma <- list(R = list(V = 1, nu = 1),
                    G = list(G1 = list(V = 1, nu = 1)))
    
## Fit the model
model_mcmc  <- MCMCglmm(scaled ~ 1,
                        random = ~ animal,
                        family = "gaussian",
                        prior = prior_gamma,
                        pedigree = ped,
                        data = pheno,
                        nitt = 100000,
                        burnin = 10000,
                        thin = 10)

## Calculate heritability for heritability from variance components
h2_mcmc_object  <- model_mcmc$VCV[, "animal"] /
    (model_mcmc$VCV[, "animal"] + model_mcmc$VCV[, "units"])
 
## Summarise results from that posterior
h2_mcmc  <- data.frame(mean = mean(h2_mcmc_object),
                       lower = quantile(h2_mcmc_object, 0.025),
                       upper = quantile(h2_mcmc_object, 0.975),
                       method = "MCMC",
                       stringsAsFactors = FALSE)

And here is a similar animal model in AnimalINLA:

library(AnimalINLA)

## Format pedigree to AnimalINLA's tastes
ped_inla <- ped
ped_inla$id  <- as.numeric(ped_inla$id)
ped_inla$dam  <- as.numeric(ped_inla$dam)
ped_inla$dam[is.na(ped_inla$dam)] <- 0
ped_inla$sire  <- as.numeric(ped_inla$sire)
ped_inla$sire[is.na(ped_inla$sire)] <- 0
    
## Turn to relationship matrix
A_inv <- compute.Ainverse(ped_inla)
    
## Fit the model
model_inla  <- animal.inla(response = scaled,
                           genetic = "animal",
                           Ainverse = A_inv,
                           type.data = "gaussian",
                           data = pheno,
                           verbose = TRUE)

## Pull out summaries from the model object
summary_inla  <- summary(model_inla)

## Summarise results
h2_inla  <- data.frame(mean = summary_inla$summary.hyperparam["Heritability", "mean"],
                       lower = summary_inla$summary.hyperparam["Heritability", "0.025quant"],
                       upper = summary_inla$summary.hyperparam["Heritability", "0.975quant"],
                       method = "INLA",
                       stringsAsFactors = FALSE)

If we wrap this all in a loop, we can see how the estimation methods do on replicate data (full script on GitHub). Here are estimates and intervals from ten replicates (black dots show the actual heritability in the first generation):

As you can see, the MCMC and INLA estimates agree pretty well and mostly hit the mark. In the one replicate dataset where they falter, they falter together.

Continue Reading…

Collapse

Read More

Often data you’re working with has abstract column names, such as (x1, x2, x3…). Typically, the first step I take when renaming columns with r is opening my web browser. 

For some reason no matter the amount of times doing this it’s just one of those things. (Hoping that writing about it will change that)

The dataset cars is data from the 1920s on “Speed and Stopping Distances of Cars”. There is only 2 columns shown below.

colnames(datasets::cars)
[1] "speed" "dist" 

If we wanted to rename the column “dist” to make it easier to know what the data is/means we can do so in a few different ways.

Using dplyr:

cars %>% 
  rename("Stopping Distance (ft)" = dist) %>% 
  colnames()

[1] "speed"             "Stopping Distance"

cars %>%
  rename("Stopping Distance (ft)" = dist, "Speed (mph)" = speed) %>%
  colnames()

[1] "Speed (mph)"            "Stopping Distance (ft)"

Using Base r:

colnames(cars)[2] <-"Stopping Distance (ft)"

[1] "speed"                  "Stopping Distance (ft)"

colnames(cars)[1:2] <-c("Speed (mph)","Stopping Distance (ft)")

[1] "Speed (mph)"            "Stopping Distance (ft)"

Using GREP:

colnames(cars)[grep("dist", colnames(cars))] <-"Stopping Distance (ft)"

"speed"                  "Stopping Distance (ft)"

Continue Reading…

Collapse

Read More

Time series-Introduction

Feature Selection Techniques

Improving Quantum Computation with Classical Machine Learning

A Comprehensive Guide to Machine Learning

Bias and Algorithmic Fairness

5 Fundamental AI Principles

Building Data Pipelines using R

Combining Automatically Factor Levels With Trees

Ethics and Security in Data Science

3 Advanced Python Functions for Data Scientists

Interpreting Machine Learning Model

Facebook Has Been Quietly Open Sourcing Some Amazing Deep Learning Capabilities for PyTorch

PyTorch 1.3 adds mobile, privacy, quantization, and named tensors

Feature Extraction Techniques

AI – Fear, uncertainty, and hope

Introducing PyText

Using Agile Methodologies in Data Science

Machine Learning Project 17 – Compare Classification Algorithms

Continue Reading…

Collapse

Read More

A coauthor writes:

I really like the paper [we are writing] as it is. My only criticism of it perhaps would be that we present this great new method and discuss all of its merits, but we do not really discuss when it fails / what its downsides are. Are there any cases where the traditional analyses or some other analysis are more appropriate? Should we say that in the main body of the paper?

Good point! I’m gonna add a section to the paper called Failure Modes or something like that, to explore where our method makes things worse.

And, no, this is not the same as the traditional “Threats to Validity” section. The Threats to Validity section, like the Robustness Checks, are typically a joke in that the purpose is usually not to explore potential problems but rather to rule out potential objections.

Now, don’t get me wrong, I love our recommended method and so does my coauthor. It’s actually hard for us to think of examples where our approach would be worse than what people were diong before. But I’ll think about it. I agree we should write something about failure modes.

I love my collaborators. They’re just great.

Continue Reading…

Collapse

Read More

Scanning all new published packages on PyPI I know that the quality is often quite bad. I try to filter out the worst ones and list here the ones which might be worth a look, being followed or inspire you in some way.

• spacy-transformers
spaCy pipelines for pre-trained BERT and other transformers

• stackerpy
Model Stacking for scikit-learn models for Machine Learning (including blending)

• tabnet
Tensorflow 2.0 implementation of TabNet of any configuration. A Tensorflow 2.0 port for the paper (https://…/1908.07442 ), whose original codebase is available at https://…/tabnet.

• TeaML
Automated Modeling in Financial Domain. TeaML is a simple and design friendly automatic modeling learning framework.

• traintorch
Package for live visualization of metrics during training of a machine learning model

• trax
Trax

• VoicePy
A Python Library to interface with Alexa, Dialogflow, and Google Actions.

• aiPool
Framework for Advanced Statistics and Data Sciences

• cprior
Fast Bayesian A/B and multivariate testing

• elasticdl
A Kubernetes-native Deep Learning Framework

Continue Reading…

Collapse

Read More

This weekend I decided to create my first R package… it’s here!

https://github.com/NicoleRadziwill/easyMTS

Although I’ve been using R for 15 years, developing a package has been the one thing slightly out of reach for me. Now that I’ve been through the process once, with a package that’s not completely done (but at least has a firm foundation, and is usable to some degree), I can give you some advice:

• Make sure you know R Markdown before you begin.
• Some experience with Git and Github will be useful. Lots of experience will be very, very useful.
• Write the functions that will go into your package into a file that you can source into another R program and use. If your programs work when you run the code this way, you will have averted many problems early.

The process I used to make this happen was:

• I refactored ~250 lines of code into 15 lines of code and 12 functions. I stored the functions here: https://github.com/NicoleRadziwill/R-Functions/blob/master/MTSpak.R
• I followed this process:
  • https://qualityandinnovation.com/2019/10/13/my-first-r-package-part-1/
  • https://qualityandinnovation.com/2019/10/13/my-first-r-package-part-2/
  • https://qualityandinnovation.com/2019/10/13/my-first-r-package-part-3/
• I created an example that will become a vignette soon: https://qualityandinnovation.com/2019/10/13/easymts-r-package-quick-solver-for-mahalanobis-taguchi-system-mts-problems/

I hope you enjoy following along with my process, and that it helps you write packages too. If I can do it, so can you!

The post easyMTS: My First R Package (Story, and Results) appeared first on Quality and Innovation.

Continue Reading…

Collapse

Read More

A new R package in development. Please cite if you use it.

The post easyMTS R Package: Quick Solver for Mahalanobis-Taguchi System (MTS) appeared first on Quality and Innovation.

Continue Reading…

Collapse

Read More