An Artificial Intelligence Curriculum

Like the software workshop if all you have is access to a phone or tablet it's possible to complete this course using Google colab (free) otherwise the course uses Python3 and provides Vagrant files and instructions to set up your own environment. I went with miniconda. All the assignments are handed out as jupyter notebooks, you can certainly do them in PyCharm too if you wanted or vim even. The lectures are through panopto and open to the public.

We're watching the first lecture named introduction. If you want to download these lectures, right-click, open inspector, click on <head id="HeadNode"> and expand the tree, scroll down to <meta property="og:video" content =" …"> and cut and paste the .mp4 address into another browser tab, you can now save the video the locally. There's also notes for this lecture.

This is a great description of statistics, from a book we will be able to complete soon:

Statistics is the branch of mathematical engineering which designs and analyses methods for drawing reliable inferences from imperfect data. The subject of most sciences is some aspect of the world around us, or within us. Psychology studies minds; geology studies the Earth’s composition and form; economics studies production, distribution and exchange; mycology studies mushrooms. Statistics does not study the world, but some of the ways we try to understand the world — some of the intellectual tools of the other sciences. Its utility comes indirectly, through helping those other sciences. This utility is very great, because all the sciences have to deal with imperfect data.

Data may be imperfect because we can only observe and record a small fraction of what is relevant; or because we can only observe indirect signs of what is truly relevant; or because, no matter how carefully we try, our data always contain an element of noise. Over the last two centuries, statistics has come to handle all such imperfections by modeling them as random processes, and probability has become so central to statistics that we introduce random events deliberately (as in sample surveys). Statistics, then, uses probability to model inference from data. We try to mathematically understand the properties of different procedures for drawing inferences: Under what conditions are they reliable? What sorts of errors do they make, and how often? What can they tell us when they work? What are signs that something has gone wrong? Like other branches of engineering statistics aims not just at understanding but also at improvement: we want to analyze data better: more reliably, with fewer and smaller errors, under broader conditions, faster, and with less mental effort. – Advanced Data Analysis From an Elementary Point of View by Cosma Shalizi

All the examples he talks about you can see the slides better in the lecture notes. The one example about thatched roofs turned out to be a bad indicator as one student mentions. Googling this I discover: "There are many structures in Kenya and Uganda that have thatched roofs, but are not households, such as kitchens and sheds. These buildings were artificially inflating the count of households with thatched roofs, making areas look poorer than they were."

We don't have the recommended background but you'll see later most of these requirements are given a crash course enough to finish the assignments. The rest of this lecture is just course logistics, the masters version of this course 15-688 has extra homework assignments, which are up to you if you want to try them.

Next lecture when he introduces Jupyter notebook, you can export the notes for this lecture as a notebook to experiment around with the regex library, they are fully interactive can run them yourself, change anything to see how corner cases are matched, go through the Python tutorial looking up anything you don't understand like what range does or list/dict comprehensions.

The regex poll done in class is explained in the notes:

r"\w+\s+science" 

"These rules can of course be combined with the rules to match potentially very complicated expressions. For instance, if we want to match the text “something science” where something is any alphanumeric character, and there can be any number of spaces of any kind between something and the word “science”, we could use the expression r"\w+\s+science".

Watching lecture 3.

Colab If you must it's possible to use Google Colab (python v 3.6) online for free click on File -> New Notebook and enter in a throwaway or regular google account, a new notebook should appear. Free version of Colab, the VM will shut down after some indeterminate amount of time being idle, which you then have to reset with Runtime -> Restart Runtime. You can back up everything to a Google drive account or Github. You can redefine all the heavily used key shortcuts in Colab so if you're stuck with just a tablet, then redefine Shift-Enter (run and move to new cell) and Ctrl-Enter (run cell) to whatever you want. You can enter shell commands with ! so !cd or !ls or !python –version to match up to the online python documentation.

Local environment There is a vagrant installation method here (scroll down to environment) but it likely won't install anymore and you'll have to manually change the box in the Vagrantfile to another ubuntu distro. If you're wondering what Vagrant does in this context, it's a pile of scripts to download and configure a virtual environment, starts up virtualbox, you minimize that window and from command line 'vagrant ssh' into the running VM, so you can start jupyter notebook which gives you a localhost IP, and then whatever regular browser you use can go to that address and run the notebook. You can also install all this with your regular OS though a vm is nice to keep environments seperate as we'll installing pip packages for the course. I took his advice in the lecture and installed Anaconda, actually Miniconda, which has a cheat sheet for it's package manager (Python is so complex now that it needs distros). One reason anaconda exists is because there are countless scientific libraries and that all require a specific environment of python to run so anaconda solves this problem, and in many research labs and bigcorps you need written permission to download and install new software from the various layers of corporate security officers so anaconda full install can give you everything up front. Other solutions exist like NixOS or Guix in order to run multiple different versions of the same software.

His shill of python growth based on the amount of stackoverflow questions could also mean the documentation is terrible or error messages so cryptic that everybody needs to consult stackoverflow. For our use in this course, which is hacking around with data, scripting it into various datastructures, visualization, and machine learning, Python is the obvious choice because of the libraries available like Facebook's Pytorch. If whatever prototype you come up with needs to be deployed in some other language there is a C++ API for Pytorch.

I assume you have a notebook open while he's going through the lab. Note the syntax of python is nearly identical to what we've been using in the other workshop (pyret, with is python + racket) except each function needs a return statement.

• Efficiency lists:
  • Accessing a list element O(1)
  • Appending O(1)
  • Inserting O(n) due to 'lists' being an array
  • If you forgot efficiency from CS019 see this
  • There's a somewhat accurate list of python builtins complexity

Note he uses a magic command for %%timeit.

• Efficiency dicts:
  • Value lookup O(1)
  • Insert O(1)
  • Delete O(1)
    • Worse time constant than lists
    • Use for more complex type than integers

Classes, methods and OOP in python are explained here and here, more here and finally using sets and dictionaries in classes but we won't be using any kind of complex OOP or engineering software in this course just scripting together libraries.

Let's do the first recitation. Download the Jupyter notebook for this recitation and untar it, open the .ipynb file in jupyter notebook and now you can run all the code.

If you're using Google Colab, look at this otherwise mount a google drive, save the homework .tar.gz file directly to your google drive, and use something like ZIP extractor to open it there. Other method is open a new notebook in colab and type the following, then File -> Open from drive and load the .ipnyb notbook and run all code blocks Runtime -> Run All

!wget http://www.datasciencecourse.org/notes/recitation_1/recitation_1.tar.gz
!tar -xvf recitation_1.tar.gz
!cp recitation_1.ipynb '/content/drive/My Drive' 

# note this can all be automated with python (pydrive) or google colab library

Run all the cells (Cell -> Run All). Recitation begins with notes about testing, in every homework assignment notebook it comes with a large amount of tests already written for us. The 'from' statement is of course importing a library. This recitation is self explanatory, notice what 'pprint(dict(response.headers))' did, returned the header in a dictionary with keys. Anytime you want try some examples yourself insert a code cell below what you want to manipulate.

They show that Python libraries can create encoding conflicts. Remember code points from cs019, Unicode/UTF-8 replaces ASCII, ISO 8859 and other encodings, and supports any written language characters. These encodings are all different ways to interpret raw bytes and represent textual data.

Regexp they want us to read a blog, it can be summarized as: break up your regexp into newlines so it's not a massive oneliner, use comments so you don't forget what you wrote, use a regexp tool like 'regex buddy' that allows you to paste in regexp and figure out what they do should you come across them in code, and use a real parser for parsing. The python documentation will explain metacharacters like *, ?, + which are repetition operators or ^ $. You can add more examples and run them in this recitation notebook.

A diversion into theoretical CS so you can understand regular languages and expressions as a finite automaton then all these Kleene star notations and repetition/assertion operators will make sense. You can understand DFAs even if you haven't taken set theory in the math workshop.

• Finite Automata 15-251 Great Theoretical Ideas in CS
  • In the beginning the slides are slightly out of order, match with these slides.

The accepting state in a regular expression is a matching state. The 5 tuple he describes, is similar to the definition of an algorithm in the first chapter of The Art of Computer Programming vol 1 by Knuth. Now you know how to do those exercises should you ever read that book.

Around 59:25 we begin regular operations, concatenation (multiplication), union and star.

• Example: Concatenation
  • \(L_1\) = {00,10}; \(L_2\) = {0,1} then \(L_1 \cdot L_2\) = {000, 001, 100, 101}
  • The dot notation is dropped in regex, abc is still multiplication
• Example: Star, the concatenation of i copies of L for i > 0
  • If L = {0,1} then \(L^{2}\) = {00, 01, 10, 11} (L x L concatenated) and \(L^{*}\) = {none, 0, 00, 0000, 01, 111, 01110 etc}
  • Select any finite number of strings from the language and concat them all together (including possibility of no strings selected, as empty concat empty gives empty)

Their example regular expression of 'x starts and ends with the same char, in the language L of {a,b} then \(L^{*}\) would be {a, b, aa, bb, aaa, bbb, ababa, etc}

a(a|b)*a | b(a|b)*b | a | b which translates to: a concatenated with any amount of a's or b's, and ends with a, OR b concatenated with any amount of a's or b's, ending with b OR a OR b

There is also order precedence: Repetition like ?, star (highest), concat, union (lowest) unless you use parenthesis to denote order. For example ab* is a(b*).

Some regex and their corresponding state diagrams:

• The automaton for "a?bc" (matches empty string as well)
• Kleene star matching example and it's corresponding automaton for [fr]*og
  • the DFA explains why [fr]*og matches "og" as well as "frog", * will also match empty, so this regex is any combination of f or r (ffffff, or rr), or nothing, concatenated with og
• The regex automaton for "[A-Z]+[aeiou]+[bd]?"
  • Two acceptance states, because [bd]? is none or b or d
• The automaton for "[abc]+[123]*|[def]*[456]+"
• The automaton for "([A-C][0-3][D-F])+"

Standard dbms crash course, more here if you're interested in learning some advanced sql like CTEs (common table expressions) where you just declare everything up front 'here's what I want' in a single statement and the dbms optimizes the query for you. Reminder you can load the notes for this lecture in jupyter notebook and test out all the Pandas functions as he introduces them.

This lecture is about making your own visualizations for data exploration much like how we wrote examples in CS019 in the software workshop to better understand the full domain of the problem. Some good advice in here about how not to visualize, like never using a pie chart. There's no code in this lecture.

None of this will make sense unless you've done a bit of linear algebra already, so let's get a crash course.