The list below is a (non-comprehensive) selection of what I believe should be taught first, in data science classes, based on 30 years of business experience. This is a follow up to my article Why logistic regression should be taught last.

I am not sure whether these topics below are even discussed in data camps or college classes. One of the issue is the way teachers are recruited. The recruitment process favors individuals famous for their academic achievements, or for their "star" status, and they tend to teach the same thing over and over, for decades. Successful professionals have little interest in becoming a teacher (as the saying goes: if you can't do it, you write about it, if you can't write about it, you teach it.)

It does not have to be that way. Plenty of qualified professionals, even though not being a star, would be perfect teachers and are not necessarily motivated by money. They come with tremendous experience gained in the trenches, and could be fantastic teachers, helping students deal with real data. And they do not need to be a data scientist, many engineers are entirely capable (and qualified) to provide great data science training.

Topics that should be taught very early on in a data science curriculum

I suggest the following:

On overview of how algorithms work

Different types of data and data issues (missing data, duplicated data, errors in data) together with exploring real-life sample data sets, and constructively criticizing them

How to identify useful metrics

Lifecycle of data science projects

Introduction to programming languages, and fundamental command line instructions (Unix commands: grep, sort, uniq, head, Unix pipes, and so on.)

Communicating results to non experts and understanding requests from decision makers (translating requests into action items for the data scientist)

Overview of popular techniques with pluses and minuses, and when to use them

Case studies

Being able to identify flawed studies

By contrast, here is a typical list of topics discussed first, in traditional data science classes:

Probability theory, random variables, maximum likelihood estimation

Linear regression, logistic regression, analysis of variance, general linear model

K-NN (nearest neighbors clustering), hierarchical clustering

Test of hypotheses, non-parametric statistics, Markov chains, time series

NLP, especially world clouds (applied to small sample Twitter data)

Collaborative filtering algorithms

Neural networks, decision trees, linear discriminant analysis, naive Bayes

There is nothing fundamentally wrong about these techniques (except the two last ones), but you are unlikely to use them in your career -- not the rudimentary version presented in the classroom anyway -- unless your are in a team of like-minded people all using the same old-fashioned black box tools. Indeed they should be taught, but maybe not at the beginning.

Topics that should also be included in a data science curriculum

The ones listed below should not be taught at the very beginning, but are very useful, and rarely included in standard curricula:

Model selection, tool (product) selection, algorithm selection

Rules of thumb

Best practices

Turning unstructured data into structured data (creating taxonomies, cataloging algorithms and automated tagging)

Blending multiple techniques to get the best of each of them, as described here

Measuring model performance (R-Squared is the worst metric, but usually the only one taught in the classroom)

Data augmentation (finding external data sets and features to get better predictive power, blending it with internal data)

Building your own home-made models and algorithms

The curse of big data (different from the curse of dimensionality) and how to discriminate between correlation and causation

How frequently data science implementations (for instance, look-up tables) should be updated

From designing a prototype to deployment in production mode: caveats

Monte-Carlo simulations (a simple alternative to computing confidence intervals and test statistical hypotheses, without even knowing what a random variable is.)

To find out more about these techniques, use our search box to find literature about the topic in question.

For related articles from the same author, click here or visit www.VincentGranville.com. Follow me on on LinkedIn.

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