Sampling and Empirical Distributions

An important part of data science consists of making conclusions based on the data in random samples. In order to correctly interpret their results, data scientists have to first understand exactly what random samples are.

In this chapter we will take a more careful look at sampling, with special attention to the properties of large random samples.

Let's start by drawing some samples. Our examples are based on the top_movies.csv data set.

top1 = Table.read_table(path_data + 'top_movies.csv')
top2 = top1.with_column('Row Index', np.arange(top1.num_rows))
top = top2.move_to_start('Row Index')

top.set_format(make_array(3, 4), NumberFormatter)

Row Index	Title	Studio	Gross	Gross (Adjusted)	Year
0	Star Wars: The Force Awakens	Buena Vista (Disney)	906,723,418	906,723,400	2015
1	Avatar	Fox	760,507,625	846,120,800	2009
2	Titanic	Paramount	658,672,302	1,178,627,900	1997
3	Jurassic World	Universal	652,270,625	687,728,000	2015
4	Marvel's The Avengers	Buena Vista (Disney)	623,357,910	668,866,600	2012
5	The Dark Knight	Warner Bros.	534,858,444	647,761,600	2008
6	Star Wars: Episode I - The Phantom Menace	Fox	474,544,677	785,715,000	1999
7	Star Wars	Fox	460,998,007	1,549,640,500	1977
8	Avengers: Age of Ultron	Buena Vista (Disney)	459,005,868	465,684,200	2015
9	The Dark Knight Rises	Warner Bros.	448,139,099	500,961,700	2012

... (190 rows omitted)

Sampling Rows of a Table

Each row of a data table represents an individual; in top, each individual is a movie. Sampling individuals can thus be achieved by sampling the rows of a table.

The contents of a row are the values of different variables measured on the same individual. So the contents of the sampled rows form samples of values of each of the variables.

Deterministic Samples

When you simply specify which elements of a set you want to choose, without any chances involved, you create a deterministic sample.

You have done this many times, for example by using take:

top.take(make_array(3, 18, 100))

Row Index	Title	Studio	Gross	Gross (Adjusted)	Year
3	Jurassic World	Universal	652,270,625	687,728,000	2015
18	Spider-Man	Sony	403,706,375	604,517,300	2002
100	Gone with the Wind	MGM	198,676,459	1,757,788,200	1939

You have also used where:

top.where('Title', are.containing('Harry Potter'))

Row Index	Title	Studio	Gross	Gross (Adjusted)	Year
22	Harry Potter and the Deathly Hallows Part 2	Warner Bros.	381,011,219	417,512,200	2011
43	Harry Potter and the Sorcerer's Stone	Warner Bros.	317,575,550	486,442,900	2001
54	Harry Potter and the Half-Blood Prince	Warner Bros.	301,959,197	352,098,800	2009
59	Harry Potter and the Order of the Phoenix	Warner Bros.	292,004,738	369,250,200	2007
62	Harry Potter and the Goblet of Fire	Warner Bros.	290,013,036	393,024,800	2005
69	Harry Potter and the Chamber of Secrets	Warner Bros.	261,988,482	390,768,100	2002
76	Harry Potter and the Prisoner of Azkaban	Warner Bros.	249,541,069	349,598,600	2004

While these are samples, they are not random samples. They don't involve chance.

Probability Samples

For describing random samples, some terminology will be helpful.

A population is the set of all elements from whom a sample will be drawn.

A probability sample is one for which it is possible to calculate, before the sample is drawn, the chance with which any subset of elements will enter the sample.

In a probability sample, all elements need not have the same chance of being chosen.

A Random Sampling Scheme

For example, suppose you choose two people from a population that consists of three people A, B, and C, according to the following scheme:

Person A is chosen with probability 1.
One of Persons B or C is chosen according to the toss of a coin: if the coin lands heads, you choose B, and if it lands tails you choose C.

This is a probability sample of size 2. Here are the chances of entry for all non-empty subsets:

A: 1 
B: 1/2
C: 1/2
AB: 1/2
AC: 1/2
BC: 0
ABC: 0

Person A has a higher chance of being selected than Persons B or C; indeed, Person A is certain to be selected. Since these differences are known and quantified, they can be taken into account when working with the sample.

A Systematic Sample

Imagine all the elements of the population listed in a sequence. One method of sampling starts by choosing a random position early in the list, and then evenly spaced positions after that. The sample consists of the elements in those positions. Such a sample is called a systematic sample.

Here we will choose a systematic sample of the rows of top. We will start by picking one of the first 10 rows at random, and then we will pick every 10th row after that.

"""Choose a random start among rows 0 through 9;
then take every 10th row."""

start = np.random.choice(np.arange(10))
top.take(np.arange(start, top.num_rows, 10))

Row Index	Title	Studio	Gross	Gross (Adjusted)	Year
2	Titanic	Paramount	658,672,302	1,178,627,900	1997
12	The Hunger Games: Catching Fire	Lionsgate	424,668,047	444,697,400	2013
22	Harry Potter and the Deathly Hallows Part 2	Warner Bros.	381,011,219	417,512,200	2011
32	American Sniper	Warner Bros.	350,126,372	374,796,000	2014
42	Iron Man	Paramount	318,412,101	385,808,100	2008
52	Skyfall	Sony	304,360,277	329,225,400	2012
62	Harry Potter and the Goblet of Fire	Warner Bros.	290,013,036	393,024,800	2005
72	Jaws	Universal	260,000,000	1,114,285,700	1975
82	Twister	Warner Bros.	241,721,524	475,786,700	1996
92	Ghost	Paramount	217,631,306	447,747,400	1990

... (10 rows omitted)

Run the cell a few times to see how the output varies.

This systematic sample is a probability sample. In this scheme, all rows have chance $1/10$ of being chosen. For example, Row 23 is chosen if and only if Row 3 is chosen, and the chance of that is $1/10$.

But not all subsets have the same chance of being chosen. Because the selected rows are evenly spaced, most subsets of rows have no chance of being chosen. The only subsets that are possible are those that consist of rows all separated by multiples of 10. Any of those subsets is selected with chance 1/10. Other subsets, like the subset containing the first 11 rows of the table, are selected with chance 0.

Random Samples Drawn With or Without Replacement

In this course, we will mostly deal with the two most straightforward methods of sampling.

The first is random sampling with replacement, which (as we have seen earlier) is the default behavior of np.random.choice when it samples from an array.

The other, called a "simple random sample", is a sample drawn at random without replacement. Sampled individuals are not replaced in the population before the next individual is drawn. This is the kind of sampling that happens when you deal a hand from a deck of cards, for example.

In this chapter, we will use simulation to study the behavior of large samples drawn at random with or without replacement.

Drawing a random sample requires care and precision. It is not haphazard, even though that is a colloquial meaning of the word "random". If you stand at a street corner and take as your sample the first ten people who pass by, you might think you're sampling at random because you didn't choose who walked by. But it's not a random sample – it's a sample of convenience. You didn't know ahead of time the probability of each person entering the sample; perhaps you hadn't even specified exactly who was in the population.