All data is dirty, some data is useful.
–cf. George Box
Welcome to the mid-point of the book. In something like the loose way in which a rock “concept album” tells an overarching story through its individual songs, this book is meant, to a certain degree, to follow the process a data scientist goes through from acquiring raw data to feeding suitable data into a machine learning model or data analysis. Up until this point, we have looked at how one goes about getting data into a program or analysis system (e.g. a notebook), and we touched on identifying data that has clearly “gone bad” at the level of individual data points in Chapter 4 , Anomaly Detection . In the chapters after this one, we will look at remediation of that messy and marked data that earlier chapters delivered in stages.
Now, however, is the time to look for ways in which your data may have problems, not in its individual details, but in its overall “shape” and character. In some cases, these problems will pertain to the general collection techniques used, and in particular to systematic bias that might be introduced during collection. In other cases, problems are not the fault of data collectors, but simply of units and scales, and correction can be quite mechanical and routine. At this point, we gradually ease into active interventions that do not simply detect dirt as we have done hitherto, but also go about cleaning it. One such cleanup might involve handling the inherent biases that cyclicities in data often create (often over time periods, but not exclusively).
In the last section of this chapter, we look at the idea of performing validation that is domain-specific and utilizes rules that are practical, beyond being simply numeric. Of course, every domain might have its own such rules, and an example in this chapter is meant to inspire thought, not provide a blueprint for your specific tasks. In fact, it can hardly be said often enough that everything within this book is meant to provide inspiration for ways of thinking about data science problems, and never merely recipes to copy directly to the task you have in front of you.
***
Before we get to the sections of this chapter, let us run our standard setup code.
from src.setup import *
%load_ext rpy2.ipython
%%R
library(gridExtra)
library(tidyverse)
Missing Data
Absence of evidence is not evidence of absence.
–Martin Rees
Concepts :
Aspects of missing data
Distribution of records in parameter space
Bias in missing data
The story of missing data forms a trilogy in this book. The prior chapter, Chapter 4 , Anomaly Detection , led with a section on missing data. In that case, our concern was to identify “missingness,” which can be marked in various ways by various datasets in various data formats. The next chapter, Chapter 6 , Value Imputation , is primarily about what we might do to fill missing values with reasonable guesses.
This chapter falls between the previous and the next one. We have already taken mechanical or statistical tests to identify some data as missing (or as unreliable enough that it is better to pretend it is missing). But we have not yet decided whether to keep or drop the observations to which those missing data points belong. For this section, we need to assess the significance of that missing data to our overall dataset.
When we have a record with missing data, we essentially have two choices about its disposition. On the one hand, we can discard that particular record. On the other hand, we can impute some value for the missing value, as will be discussed in Chapter 6 . Actually, in some sense there is a third option as well: we may decide that because of the amount or distribution of missing data in our dataset, the data is simply not usable for the purpose at hand. While, as data scientists, we never want to declare a task hopeless, as responsible researchers we need to consider the possibility that particular data simply cannot support any conclusions. Missing data is not the only thing that could lead us to this conclusion, but it is certainly one common fatal deficit.
If we wish to discard records—but also to a large extent if we wish to impute values—we need to think about whether what remains will be a fair representation of the parameter space of the data. Sample bias can exist not only in the overall composition of a dataset, but also more subtly in the distribution of missing values. Keep in mind that “missing” here might result from the processing in Chapter 4 , in which some values may have been marked missing because we determined they were unreliable, even if they were not per se absent in the raw data.
For example, I created a hypothetical dataset of persons with names, ages, genders, and favorite colors and flowers. The ages, genders, and names are modeled on the actual distribution of popular names over time reported by the United States Social Security Administration. I assigned favorite colors and flowers to the people for this illustration.
df = pd.read_parquet('data/usa_names.parq' )
df
Age Gender Name Favorite_Color Favorite_Flower
———————————————————————————————————————————————————————————————
0 48 F Lisa Yellow Daisy
1 62 F Karen Green Rose
2 26 M Michael Purple None
3 73 F Patricia Red Orchid
... ... ... ... ... ...
6338 11 M Jacob Red Lily
6339 20 M Jacob Green Rose
6340 72 M Robert Blue Lily
6341 64 F Debra Purple Rose
6342 rows × 5 columns
In general, this is an ordinary-looking dataset, with a moderately large collection of records. We can notice in the data frame summary that at least some data is missing. This is worth investigating more carefully.
with show_more_rows():
print(df.describe(include='all' ))
Age Gender Name Favorite_Color Favorite_Flower
count 6342.000000 6342 6342 5599 5574
unique NaN 2 69 6 5
top NaN F Michael Yellow Orchid
freq NaN 3190 535 965 1356
mean 42.458846 NaN NaN NaN NaN
std 27.312662 NaN NaN NaN NaN
min 2.000000 NaN NaN NaN NaN
25% 19.000000 NaN NaN NaN NaN
50% 39.000000 NaN NaN NaN NaN
75% 63.000000 NaN NaN NaN NaN
max 101.000000 NaN NaN NaN NaN
Using Pandas’ .describe()
method or similar summaries by other tools allows us to see that Age
, Gender
, and Name
have values for all 6,342 records. However, Favorite_Color
and Favorite_Flower
are missing for approximately 750 records each. In itself, missing data in 10-15% of the rows is quite likely not to be a huge problem. This statement assumes that missingness is not itself biased. Even if we need to discard those records altogether, that is a relatively small fraction of a relatively large dataset. Likewise, imputing values would probably not introduce too much bias, and other features could be utilized within those records. In the below section and in Chapter 6 , Value Imputation , in relation to undersampling and oversampling, we discuss the dangers of exclusion resulting in class imbalance.
While uniformly randomly missing data can be worked around relatively easily, data that is missing in a biased way can present a more significant problem. To figure out which category we are in with this dataset, let us compare those missing flower preferences to the ages of the people. Looking at every individual age up to 101 years old is hard to visualize; for this purpose, we will group people into 10-year age groups. The graph below uses a statistical graphing library called Seaborn , which is built on top of Matplotlib.
df[' Age Group' ] = df.Age//10 * 10
fig, ax = plt.subplots(figsize=(12 , 4.5 ))
sns.countplot(x="Age Group" , hue="Favorite_Flower" ,
ax=ax, palette='gray' , data=df)
ax.set_title("Distribution of flower preference by age" );
Figure 5.1: Distribution of flower preference by age
A few patterns jump out in this visualization. It appears that older people tend to have a strong preference for orchids, and young people a moderate preference for roses. This is perhaps a property of the data meriting analysis. More significantly for this section, there are few data points for favorite flower at all in the 20-30 age group. One might imagine several explanations, but the true answer would depend on problem and domain knowledge. For example, perhaps the data corresponding to these ages was not collected during a certain time period. Or perhaps people in that age group reported a different favorite flower but its name was lost in some prior inaccurate data validation/cleaning step.
If we look at the records with missing color preference, we see a similar pattern in relation to age. The drop in frequency of available values occurs instead in the 30-40 age group though.
fig, ax = plt.subplots(figsize=(12 , 4.5 ))
sns.countplot(x="Age Group" , hue="Favorite_Color" ,
ax=ax, palette='gray' , data=df)
ax.set_title("Distribution of color preference by age" );
Figure 5.2: Distribution of color preference by age
If we were to drop all records with missing data, we would wind up with nearly no representation of people in the entire 20-40 age range. This biased unavailability of data would be likely to weaken the analysis generally. The number of records would remain fairly large, but the parameter space, as mentioned, would have an empty (or at least much less densely occupied) region. Obviously, these statements depend both on the purpose of our data analysis and our assumptions about the underlying domain. If age is not an important aspect of the problem in general, our approach may not matter much. But if we think age is a significant independent variable, dropping this data would probably not be a workable approach.
This section, like many others, shows the kinds of exploration one should typically perform of a dataset. It does not provide one simple answer for the best remediation of bias in missing data. That decision will be greatly dependent upon the purpose for which the data is being used and also on background domain knowledge that may clarify the reasons for the data being missing. Remediation is inevitably a per-problem decision.
Let us turn to ways that bias might occur in relation to other features rather than simply globally in a dataset.
Biasing Trends
It is not the slumber of reason that engenders monsters, but vigilant and insomniac rationality.
–Gilles Deleuze
Concepts :
Collection bias versus trends in underlying domain
Perspective as source of bias
Artifact of collection methods
Visualization to identify bias
Variance by group
Externally identifying base rates
Benford’s law
At times, you may be able to detect sample bias within your data, and will need to make a domain area judgment about the significance of that bias. There are at least two kinds of sample bias that you should be on the lookout for. On the one hand, the distribution of observations may not match the distribution in the underlying domain. Quite likely, you will need to consult other data sources—or simply use your own domain area knowledge—to detect such a skew in the samples. On the other hand, the data themselves may reveal a bias by trends that exist between multiple variables. In this latter case, it is important to think about whether the detected “trend” could be a phenomenon you have detected in the data, or is a collection or curation artifact.
Understanding Bias
Bias is an important term in both statistics and human sciences, with a meaning that is strongly related, but that assumes a different valence across fields. In the most neutral statistical sense, bias is simply the fact, more commonly true than not, that a dataset does not accurately represent its underlying population of possible observations. This bare statement hides more nuance than is evident, even outside of observations about humans and politically laden matters. More often than not, neither we data scientists, who analyze data, nor the people or instruments that collected the raw data in the first place can provide an unambiguous delineation of exactly what belongs to the underlying population. In fact, the population is often somewhat circularly defined in terms of data collection techniques.
An old joke observes someone looking for their lost keys at night in the area under a street light. Asked why they do not also look elsewhere, they answer that it is because the visibility is better where they are looking. This is a children’s joke, not told particularly engagingly, but it also lays the pattern for most data collection of most datasets.
Observers make observations of what they can see (metaphorically, most are probably voltages in an instrument, or bits on a wire, rather than actual human eyes), and not what they cannot. Survivorship bias is a term for the cognitive error of assuming those observations we have available are representative of the underlying population.
It is easy not to be conscious of bias that exists in data, and probably that much easier when it indeed does concern human or social subjects and human observers bring in psychological and social biases. But it is humans, in the end, even if aided by instruments we set up, who make observations of everything else too. For example, the history of ethology (the study of animal behavior) is largely a history of scientists seeing the behaviors in animals that exist—or that they believe should exist—in the humans around them, that they impose by metaphor and blindness. If you make a survey of books in your local library to determine the range of human literature or music, you will discover the predominance of writers and musicians who use your local language and play your local musical style. Even in areas that seem most obviously not about humans, our vantage point may create a perspectival bias. For example, if we catalog the types of stars that exist in the universe, and the prevalence of different types, we are always observing those within our cosmological horizon, which not only expresses an interaction of space and time, but also may not uniformly describe the entire universe. Cosmologists know this, of course, but they know it as an inherent bias to their observations.
In most of this section, we will look at a version of the synthetic United States name/age data to detect both of these patterns. As in the last section, this data approximately accurately represents the frequency of different names across different age groups, based on Social Security Administration data. We can see that within the actual domain, the popularity of various names authentically changed over time. As in the last section, it is useful to aggregate people into coarser age groups for visualization.
Throughout this book I have attempted to avoid social bias in the datasets I select or create as examples. For the imagined people in the rows of the name tables, I added features like favorite color or flower, rather than more obviously ethnically or culturally marked features like eye color, favorite food, or musical preference. Even those invented features I use are not entirely independent of culture though, and perhaps my position in the social world leads me to choose different factor values than would someone located elsewhere.
Moreover, by choosing the top 5 most popular names in the United States each year, I impose a kind of majority bias: all are roughly Anglo names, and none, for example, are characteristically African-American, Latino, Chinese, or Polish, though such are all common outside of that top-5-by-year collation methodology.
names = pd.read_parquet('data/usa_names_states.parq' )
names['Age Group' ] = names.Age//10 * 10
names
Age Birth_Month Name Gender Home Age Group
———————————————————————————————————————————————————————————————————————
0 17 June Matthew M Hawaii 10
1 5 September Emma F West Virginia 0
2 4 January Liam M Alaska 0
3 96 March William M Arkansas 90
... ... ... ... ... ... ...
6338 29 August Jessica F Massachusetts 20
6339 51 April Michael M Wyoming 50
6340 29 May Christopher M North Carolina 20
6341 62 November James M Texas 60
6342 rows × 6 columns
The fields Birth_Month
and Home
are added to this dataset, and let us stipulate that we suspect they may indicate some bias in the observations. Before we look at that, let us take a look at a more-or-less expected trend. Note that this dataset was artificially constructed only based on the most popular male and female names for each birth year. A particular name may not be in this top 5 (per gender) for a particular year, or even a particular decade, but nonetheless, a certain number of people in the United States were probably given that name (and would be likely to show up in non-synthetic data).
fig, ax = plt.subplots(figsize=(12 , 4.5 ))
somenames = ['Michael' , 'James' , 'Mary' , 'Ashley' ]
popular = names[names.Name.isin(somenames)]
sns.countplot(x="Age Group" , hue="Name" ,
ax=ax, palette='gray' , data=popular)
ax.set_title("Distribution of name frequency by age" );
Figure 5.3: Distribution of name frequency by age
We can see trends in this data. Mary is a popular name among the older people in the dataset, but no longer shows up in the most popular names for younger people. Ashley is very popular among 20-40-year-olds, but we do not see it present outside that age group. James seems to have been used over most age ranges, although it fell out of the top-5 spot among 10-40-year-olds, resurging among children under 10. Michael, similarly, seems especially represented from 10-60 years of age.
The top-5 threshold used in the generation of the data has definitely created a few artifacts in the visualization, but a general pattern of some names becoming popular and others waning is exactly a phenomenon we would expect with a bare minimum of domain knowledge. Moreover, if we know only a little bit more about popular baby names in the United States, the specific distribution of names will seem plausible; both for the 4 shown and for the remaining 65 names that you can investigate within the dataset if you download it.
Detecting Bias
Let us apply a similar analysis to birth month as we did to name frequency. A minimum of domain knowledge will tell you that while there are small annual cyclicities in birth month, there should not be a general trend over ages. Even if some world-historical event had dramatically affected births in one particular month of one particular year, this should create little overall trend when we aggregate over decades of age.
fig, ax = plt.subplots(figsize=(12 , 4.5 ))
months = ['January' , 'February' , 'March' , 'April' ]
popular = names[names.Birth_Month.isin(months)]
sns.countplot(x="Age Group" , hue=" Birth_Month" ,
ax=ax, palette='gray' , data=popular)
ax.set_title("Distribution of birth month frequency by age" );
Figure 5.4: Distribution of birth month frequency by age
Contrary to our hope of excluding a biasing trend, we have discovered that—for unknown reasons—January births are dramatically underrepresented among the youngest people and dramatically overrepresented among the oldest people. This is overlain on an age trend of there being more young people, in general, but the pattern nonetheless appears strong. We have not looked at months beyond April, but of course we could in a similar fashion.
A certain amount of random fluctuation occurs in the dataset simply because of sampling issues. The fact that April is a somewhat more common birth month for 50-something people than for 40-something people in the dataset is quite likely meaningless since there are relatively few data points (on the order of 50) once we have cross-cut by both age and birth month. Distinguishing genuine data bias from randomness can require additional analysis (albeit, by construction, the January pattern jumps out strongly even in this simple visualization).
There are numerous ways we might analyze it, but looking for notable differences in the spread of one variable in relation to another can be a good hint. For example, we think we see an oddness in the pattern of January birth months, but is there a general irregularity in the distribution per age? We could attempt to analyze this using exact age, but that probably makes the distinction too fine-grained to have good subsample sizes. The decade of age is an appropriate resolution for this test. As always, think about your subject matter in making such judgments.
Since the number of people decreases with age, we need to find statistics that are not overly influenced by the raw numbers. In particular, we can count the number of records we have for each age group and birth month and see if those counts are notably divergent. Variance or standard deviation (of counts) will increase as the size of the age group increases. However, we can normalize that simply by dividing by the raw count within the age group of all months.
A little bit of Pandas magic gets us this. We want to group the data by age group, look at the birth month, and count the number of records that fall within each Age
⨯ Birth_Month
. We wish to look at this in a tabular way rather than with a hierarchical index. This operation arranges months in order of their occurrence in the data, but ordering by chronology is more friendly.
by_month = (names
.groupby('Age Group' )
.Birth_Month
.value_counts()
.unstack())
by_month = by_month[month_names]
by_month
Birth_Month January February March April May June July August
Age Group
——————————————————————————————————————————————————————————————————————
0 20 67 59 76 66 77 71 65
10 37 72 71 78 70 73 82 81
20 52 60 76 72 65 65 71 66
30 54 56 66 64 73 58 87 82
... ... ... ... ... ... ... ... ...
70 57 43 39 33 39 36 45 34
80 57 39 28 21 31 37 23 28
90 55 17 31 24 21 23 30 29
100 10 7 4 2 6 2 4 6
Birth_Month September October November December
Age Group
————————————————————————————————————————————————————
0 67 67 56 63
10 83 79 70 79
20 68 75 76 71
30 66 65 57 58
... ... ... ... ...
70 38 30 37 37
80 27 31 34 37
90 33 25 28 20
100 5 5 7 7
11 rows × 12 columns
That data grid remains a bit too much to immediately draw a conclusion about, so as described, let us look at the normalized variance across age groups.
with show_more_rows():
print(by_month.var(axis=1 ) / by_month.sum (axis=1 ))
Age Group
0 0.289808
10 0.172563
20 0.061524
30 0.138908
40 0.077120
50 0.059772
60 0.169321
70 0.104118
80 0.227215
90 0.284632
100 0.079604
dtype: float64
The over-100-years-old group shows a low normalized variance, but it is a small subset. Among the other age groups, the middle ages show a notably lower normalized variance across months than do the older or younger people. This difference is quite striking for those under 10 and those over 80 years old. We can reasonably conclude at this point that some kind of sample bias occurred in the collection of the birth month; specifically, there is a different bias in effect based on the age group of persons sampled. Whether or not this bias matters for the purpose at hand, the fact should be documented clearly in any work products of your analyses or models. In principle, some sampling technique that will be discussed in Chapter 6 , Value Imputation , might be relevant to adjust for this.
Comparison to Baselines
The setup of this synthetic dataset is a giveaway, of course. As well as introducing birth month, I also added Home
in the sense of state or territory of residence and/or birth. While there is no documented metadata that definitively clarifies the meaning of the column, let us take it as the state of current residence. If we had chosen to interpret it as birthplace, we might need to find historical data on populations at the times people of various ages were born; clearly that is possible, but the current assumption simplifies our task.
Let us take a look at the current population of the various US states. This will provide an external baseline relative to which we can look for sample bias in the dataset under consideration.
states = pd.read_fwf('data/state-population.fwf' )
states
State Population_2019 Population_2010 House_Seats
———————————————————————————————————————————————————————————————————————
0 California 39512223 37254523 53.0
1 Texas 28995881 25145561 36.0
2 Florida 21477737 18801310 27.0
3 New York 19453561 19378102 27.0
... ... ... ... ...
52 Guam 165718 159358 0.5
53 U.S. Virgin Isl 104914 106405 0.5
54 American Samoa 55641 55519 0.5
55 N. Mariana Isl 55194 53883 0.5
56 rows × 4 columns
As most readers will know, the range of population sizes across different US states and territories is quite large. In this particular dataset, representation of states in the House of Representatives is given as a whole number, but in order to indicate the special status of some entities that have non-voting representation, the special value of 0.5
is used (this is not germane to this section, just as a note).
Let us take a look at the distribution of home states of persons in the dataset. The step of sorting the index is used to assure that states are listed in alphabetical order, rather than by count or something else.
(names
.Home
.value_counts()
.sort_index()
.plot(kind=' bar' , figsize=(12 , 3 ),
title="Distribution of sample by home state" )
);
Figure 5.5: Distribution of sample by home state
There is clearly variation in the number of samples drawn from residents of each state. However, the largest state represented, California, has only about 3x the number of samples as the smallest. In comparison, a similar view of the underlying populations emphasizes the different distribution.
(states
.sort_values('State' )
[['State' , 'Population_2019' ]]
.set_index('State' )
.plot(kind='bar' , figsize=(12 , 3 ),
title="2019 Population of U.S. states and territories" )
);
Figure 5.6: 2019 population of United States states and territories
While California provides the most samples for this dataset, Californians are simultaneously the most underrepresented relative to the baseline population of the states. As a general pattern, smaller states tend to be overrepresented generally. We can, and probably should, think of this as selection bias based on the size of the various states. As before, unless we have accurate documentation or metadata that describes the collection and curation procedures, we cannot be sure of the cause of the imbalance. But a strong trend exists in this inverse relationship of population to relative sample frequency.
A note here is that sometimes sampling approaches deliberately introduce similar imbalances. If the actual samples were precisely balanced, with some fixed N collected per state, this would fairly clearly point to such a deliberate categorical sampling as opposed to a sampling based on an underlying rate. The pattern we actually have is less obvious than that. We might form a hypothesis that the sampling rate is based on some other underlying feature not directly present in this data.
For example, perhaps a fixed number of observations were made in each county of each state, and larger states tend to have more counties (this is not the actual underlying derivation, but thinking in this manner should be in your mind). Understanding data integrity issues resembles either a scientific process of experimentation and hypothesis, or perhaps even more so a murder mystery. Developing a reasonable theory of why the data is dirty is always a good first step in remediating it (or even in ignoring the issue as not pertinent to the actual problem at hand).
Benford’s Law
There is a curious fact about the distribution of digits in many observed numbers called Benford’s Law . For a large range of real-world datasets, we see leading 1 digits far more often than leading 2 s, which in turn occur far more commonly than leading 3 s, and so on. If you see this pattern, it probably does not reflect harmful bias; in fact, for many kinds of observations, if you fail to see it, that might itself reflect bias (or even fraud).
If a distribution precisely follows Benford’s law, it will specifically have digits distributed as:
However, this distribution is often only approximate for real-world data.
When data is distributed according to a power law or a scaling factor, it becomes relatively intuitive to understand what leading digits will be distributed in a “biased” way. However, much observational data that is not obviously scaling in nature still follows Benford’s law (at least approximately). Let us pick an example to check; I scraped and cleaned up formatting for the populations and areas of the most populous US cities.
cities = pd.read_fwf('data/us-cities.fwf' )
cities
NAME POP2019 AREA_KM2
0 New York City 8336817 780.9
1 Los Angeles 3979576 1213.9
2 Chicago 2693976 588.7
3 Houston 2320268 1651.1
... ... ... ...
313 Vacaville 100670 75.1
314 Clinton 100471 72.8
315 Bend 100421 85.7
316 Woodbridge 100145 60.3
317 rows × 3 columns
Let us first count the leading digits of populations.
pop_digits = cities.POP2019.astype(str).str[0 ].value_counts()
with show_more_rows():
print(pop_digits)
1 206
2 53
3 20
4 10
6 9
5 8
8 5
7 3
9 3
Name: POP2019, dtype: int64
Now we ask the same question of area in square kilometers.
area_digits = cities.AREA_KM2.astype(str).str[0 ].value_counts()
with show_more_rows():
print(area_digits)
1 118
2 47
3 31
4 23
9 21
8 21
7 20
6 20
5 16
Name: AREA_KM2, dtype: int64
Neither collection of data exactly matches the Benford’s law ideal distribution, but both show the general pattern of favoring leading digits in roughly ascending order.
Let us turn to evaluating the importance of the uneven distribution of categorical variables.
Class Imbalance
It seems to be correct to begin with the real and the concrete, with the real precondition, thus to begin [...] with the population. However, on closer examination this proves false. The population is an abstraction if I leave out, for example, the classes of which it is composed.
–Karl Marx
Concepts :
Predicting rare events
Imbalance in features versus in targets
Domain versus data integrity imbalance
Forensic analysis of sources of imbalance
Stipulating the direction of causality
The data you receive will have imbalanced classes, if it has categorical data at all. The several distinct values that a categorical variable may have are also sometimes called factor levels (“factor” is synonymous with “feature ” or “variable ,” as discussed in the Preface and Glossary ). Moreover, as will be discussed in Chapter 6 , Value Imputation in the section on Sampling , dividing a continuous variable into increments can often usefully form synthetic categories also. In principle, any variable might have a categorical aspect, depending on the purpose at hand. When these factor levels occur with notably different frequency, it may show selection bias or some other kind of bias; however, it very often simply represents the inherent nature of the data, and is an essential part of the observation.
A problem arises because many types of machine learning models have difficulty predicting rare events. Discussion of concretely rebalancing classes is deferred until the Chapter 6 discussion of undersampling and oversampling, but here we at least want to reflect on identifying class imbalance. Moreover, while many machine learning techniques are highly sensitive to class imbalance, others are more or less indifferent to it. Documentation of the characteristics of particular models, and their contrast with others, is outside the scope of this particular book.
In particular, though, the main difference between when class imbalance poses a difficulty versus when it is central to the predictive value of the data is precisely the difference between a target and the features. Or equivalently, the difference between a dependent variable and independent variables. When we think of a rare event that might cause difficulty for a model, we usually mean a rare target value, and only occasionally are we concerned about a rare feature. When we wish to use sampling to rebalance classes, it is almost always in relation to target class values.
We will work with a simple example. Two weeks of Apache server logs from my web server are provided as sample data. Such a log file has a number of features encoded in it, but one particular value in each request is the HTTP status code returned. If we imagine trying to model the behavior of my web server, quite likely we would wish to treat this status code as a target that might be predicted by the other (independent) variables. Of course, the log file itself does not impose any such purpose; it simply contains data on numerous features of each request (including response).
The status codes returned from the actual requests to my web server are extremely unbalanced, which is generally a good thing. I want most requests to result in 200 OK responses (or at least some 2xx code). When they do not, there is either a problem with the URLs that users have utilized or there is a problem with the web server itself. Perhaps the URLs were published in incorrect form, such as in links from other web pages; or perhaps deliberately wrong requests were used in attempts to hack my server. I never really want a status code outside of 2xx, but inevitably some arise. Let us look at their distribution:
%%bash
zcat data/gnosis/*.log.gz |
cut -d' ' -f9 |
sort |
uniq -c
10280 200
2 206
398 301
1680 304
181 403
901 404
9 500
The 200 status dominates here. The next highest occurrence is 304 Not Modified , which is actually fine as well. It simply indicates that a cached copy on a client remains current. Those 4xx and 5xx (and perhaps 301) status codes are generally undesirable events, and I may want to model the patterns that cause them. Let us remind ourselves what is inside an Apache access.log
file (the name varies by installation, as can the exact fields).
%%bash
zcat data/gnosis/20200330.log.gz | head -1 | fmt -w50
162.158.238.207 - - [30/Mar/2020:00:00:00 -0400]
"GET /TPiP/024.code HTTP/1.1" 200 75
There is a variety of data in this line, but notably it is easy to think of pretty much all of it as categorical. The IP address is a dotted quad , and the first (and often second) quad tends to be correlated with the organization or region where the address originates. Allocation of IPv4 addresses is more complex than we can detail here, but it may be that requests originating from a particular /8
or /16
origin tend to get non-200 responses. Likewise, the date—while unfortunately not encoded in I S O 8601 format—can be thought of as categorical fields for month, hour, minute, and so on.
Let us show a bit of Pandas code to read and massage these records into a data frame. The particular manipulations done are not the main purpose of this section, but gaining familiarity with some of these methods is worthwhile.
One thing to notice, however, is that I have decided that I am not really concerned with the pattern where, for example, my web server became erratic for a day. That has not occurred in this particular data, but if it had I would assume that was a one-off occurrence not subject to analysis. The separate cyclical elements of hour and minute might detect recurrent issues (which are discussed more in later sections of this chapter). Perhaps, for example, my web server gives many 404 responses around 3 a.m., and that would be a pattern/problem worth identifying.
def apache_log_to_df ( fname ):
cols = ['ip_address' , 'ident' , 'userid' , 'timestamp' ,
'tz' , 'request' , ' status' , 'size' ]
df = pd.read_csv(fname, sep=' ' , header=None , names=cols)
fmt = "[%d/%b/%Y:%H:%M:%S"
df['timestamp' ] = pd.to_datetime(df.timestamp, format =fmt)
df['tz' ] = df.tz.str [:3 ].astype(int )
df[['method' , 'resource' , 'protocol' ]] = (
df.request.str .split(' ' , expand=True ))
df[['quad1' , 'quad2' , 'quad3' , 'quad4' ]] = (
df.ip_address.str .split('.' , expand=True ))
df['hour' ] = df.timestamp.dt.hour
df['minute' ] = df.timestamp.dt.minute
df[['path' , 'page' ]] = (
df.resource.str .rsplit('/' , n=1 , expand=True ))
cols = ['hour' , 'minute' ,
'quad1' , 'quad2' , 'quad3' , 'quad4' ,
'method' , 'path' , 'page' , 'status' ]
return df[cols]
This function allows us to read all of the daily log files into a single Pandas DataFrame simply by mapping over the collection of file names and concatenating data frames. Everything except perhaps page
in the resulting data frame is reasonable to think of as a categorical variable.
reqs = pd.concat(map (apache_log_to_df,
glob('data/gnosis/*.log.gz' )))
reqs = reqs.reset_index().drop(' index' , axis=1 )
reqs.drop(['quad3' , 'quad4' ], axis=1 , inplace=True )
reqs
hour minute quad1 quad2 method path
0 0 0 162 158 GET /download/pywikipedia/cache
1 0 3 172 68 GET /TPiP
2 0 7 162 158 GET download/pywikipedia/archive
3 0 7 162 158 GET /juvenilia
... ... ... ... ... ... ...
13447 23 52 162 158 GET /download/gnosis/util
13448 23 52 172 69 GET
13449 23 52 162 158 GET /publish/resumes
13450 23 56 162 158 GET /download/pywikipedia/cache
page status
0 DuMont%20Television%20Network 200
1 053.code 200
2 ?C=N;O=A 200
3 History%20of%20Mathematics.pdf 200
... ... ...
13447 hashcash.py 200
13448 favicon.ico 304
13449 200
13450 Joan%20of%20Lancaster 200
13451 rows × 8 columns
Within my web server, I have relatively few directories where content lives, but relatively many different concrete pages within many of those directories. In fact, the path /download/pywikipedia/cache
is actually a robot that performs some formatting cleanup of Wikipedia pages that I had forgotten that I left running 15+ years ago. Given that it may be pointed to any Wikipedia page, there is effectively an infinite space of possible pages my server will reply to. There are also a small number of long path components because URL parameters are sometimes passed in to a few resources. Let us visualize the distribution of the other features in this dataset, with an eye to the places where class imbalance occurs.
fig, axes = plt.subplots(3 , 2 , figsize=(12 , 9 ))
factors = ['hour' , 'minute' , 'quad1' , 'quad2' , 'method' , 'status' ]
for col, ax in zip (factors, axes.flatten()):
if col == 'minute' :
data = (reqs[col] // 5 * 5 ).value_counts()
else :
data = reqs[col].value_counts()
data.plot(kind='bar' , ax=ax)
ax.set_title(f" {col} distibution" )
fig.tight_layout()
Figure 5.7: Distributions of different features
In these plots, we see some highly imbalanced classes and some mostly balanced ones. The hours show a minor imbalance, but with a fairly strong pattern of more requests around 21:00–24:00 in Atlantic Daylight Time. Why my hosted server is in that timezone is unclear to me, but this is around 6 p.m. US Pacific Time, so perhaps users in California and British Columbia tend to read my pages after work. The distribution of 5-minute increments within an hour is generally uniform, although the slight elevation of a few increments could possibly be more than random fluctuation.
The imbalance in the initial quads of IP address seems striking, and might initially suggest an important bias or error. However, after probing only slightly deeper, we can determine using online “whois” databases that (at the time of writing) both 162.158.0.0/16
and 172.69.0.0/16
are assigned to the CDN (content delivery network) that I use to proxy traffic. So the imbalance in these features has simply provided a clue that almost all requests are proxied through a known entity. In particular, it means that we are unlikely to be able to use these features usefully in any kind of predictive model. At most, we might perform feature engineering—as will be discussed in Chapter 7 , Feature Engineering —to create a derived feature such as is_proxied
.
The class imbalances that remain are in the HTTP method and in the status code returned. In neither case is it at all surprising that GET
and 200
dominate the respective features. This is what I expect, and even hope for, in the behavior of my web server and website. So nothing there suggests bias in the data collection; since all requests were logged, this is not a sample but rather a complete domain.
As a side note, the population is specifically delineated, and cannot necessarily be used to describe anything beyond those lines. These are all requests made to port 80
or port 443
for the web domain gnosis.cx
between March 29, 2020, and April 11, 2020; we can draw no conclusions about other web domains or other dates without further analysis or reasoning about how typical this data is of the web as a whole.
As data scientists, we are not necessarily constrained by temporal causality. For example, it is clear that in a literal and sequential way, the requesting IP address, possibly the userid
, maybe the time of the request, and definitely the URL of the request, both method and path, will cause a certain status code and number of bytes to be returned. In many cases (probably all of them on my simple, static website), the size is simply that of the underlying HTML page. But in concept, a server might do something different depending on the date and time, or the requester’s address. In any case, certain facts about the request exist a few milliseconds before the server decides on the appropriate status code and response size and logs all of that.
However, for an analysis, we might want to make predictions that exactly reverse causality. Perhaps we would like to treat the size of the response as an independent variable in our effort to predict the time of day. For example, it could be that large files are always requested around 7 p.m. rather than at other times. Our model might try to predict a cause from its effect—and that is perfectly legitimate in data science, as long as we are aware of it. In fact, we may only look for correlations, entirely ignoring for a particular task the potential hidden cause of multiple features. Data science is something different from other sciences; the endeavors are, hopefully, complementary.
***
In this section, we focused merely on recognizing, and to a limited extent analyzing, class imbalance. What it means for the actual task to which we wish to put this data is another matter. A significant distinction to keep in mind is that between independent and dependent variables. Generally, imbalance in a dependent variable will skew classification models in a more important way than imbalance in an independent variable. So, for example, if we wish to predict the likely status code that will be produced by a request based on other features of the request, we would be likely to use sampling techniques that will be discussed in Chapter 6 , Value Imputation , to balance the dataset synthetically.
On the other hand, class imbalance is not completely irrelevant in independent variables, at least not for all kinds of models. This very much depends on the kind of model. If we use something in the family of decision trees, for example, it makes little difference that HEAD requests are rare if we wish to detect the (hypothetical) fact that HEAD is strongly associated with 500 status codes. However, if we use a K-nearest neighbors family of algorithm, the actual distance in parameter space can be important. Neural networks fall somewhere in the middle in terms of sensitivity to class imbalance in independent variables. If we encode the HTTP method either as an ordinal value or using one-hot encoding, we may naïvely underweight that strong but rare feature. One-hot encoding is discussed in Chapter 7 , Feature Engineering . For an independent variable, we would not generally wish to oversample a rare factor level; but we might wish to artificially overweight it.
We also should think about the numeric ranges of data, which might reflect very different underlying units.
Normalization and Scaling
Measure with a micrometer. Mark with chalk. Cut with an axe.
–Rule for precision
Concepts :
The effect of numeric ranges in variables
Univariate and multivariate effects
Numeric forms of various scalers
Factor and sample weighting
The idea behind normalization of data is simply bringing all the features being utilized in a dataset into a comparable numeric range. When starkly different units are used for different features—that is, for dimensions of a parameter space—some machine learning models will disproportionately utilize those features which simply have a larger numeric range. Special cases of differently scaled numeric ranges occur when one feature has outliers that have not been removed, or when one feature is normally distributed but another feature is exponentially distributed.
This book generally steers away from showing machine learning examples or code. There are many wonderful libraries that address that 20% of your work, as a data scientist, that you will do after you have done the 80% that this book teaches you. However, to emphasize the motivation for normalization, we will create a very simple machine learning model on some overly neat data that illustrates an overwhelming benefit of scaling. For this example, a small amount of code in scikit-learn is used. Notably, however, the scaler classes in scikit-learn are extremely useful even if you do not wish to use that library for modeling. It is certainly reasonable—and perhaps even best practice within Python—to use scikit-learn even if you only ever perform normalization with it.
The synthetic dataset here has two features and one target; all are continuous variables.
unscaled = make_unscaled_features()
unscaled
Feature_1 Feature_2 Target
——————————————————————————————————————————
0 0.112999 19247.756104 11.407035
1 0.204178 23432.270613 20.000000
2 0.173678 19179.445753 17.336683
3 0.161411 17579.625264 16.633166
... ... ... ...
196 0.137692 20934.654450 13.316583
197 0.184393 18855.241195 18.241206
198 0.177846 19760.314890 17.839196
199 0.145229 20497.722353 14.371859
200 rows × 3 columns
At a glance, we can see that the Target
values are on the order of 15, while Feature_1
is on the order of 0.1 and Feature_2
is on the order of 20,000. The invented example does not assign any specific units for these measures, but there are many quantities you might measure whose units produce numeric values in those ranges. As an initial question, we might ask whether any of the features have a univariate correlation with the target. A machine learning model will find more than just this, but it is a useful first question.
unscaled.corr()
Feature_1 Feature_2 Target
—————————————————————————————————————————————
Feature_1 1.000000 -0.272963 0.992514
Feature_2 -0.272963 1.000000 -0.269406
Target 0.992514 -0.269406 1.000000
We see that Feature_1
has a very strong positive correlation with the Target
, and Feature_2
has a moderate negative correlation. So on the face of it, a model should have plenty to work with. Indeed, we can tell from the correlation matrix that linear models would do extremely well, with or without normalization; but that is the topic of a different book. This point can be made visually by plotting Target
against each feature.
plot_univariate_trends(unscaled)
Figure 5.8: Feature_1 and Feature_2 as functions of Target
Feature_1
has a visually obvious correlation; Feature_2
reveals at most a very weak one to a human eye.
Applying a Machine Learning Model
As promised, let us apply a machine learning model against this data, trying to predict the target based on the features. In ML, we conventionally use the names X
and y
for features and target, respectively. This follows the common pattern, from high school algebra, of naming an independent variable x
and a dependent variable y
. Since we generally have multiple features, a capital X
is used. While we cannot discuss the motivation in any depth, good practice in machine learning is to always reserve a portion of your training data for testing, so that you do not overfit your model. That is done with the function train_test_split()
.
from sklearn.model_selection import train_test_split
X = unscaled.drop('Target' , axis=1 )
y = unscaled['Target' ]
X_train, X_test, y_train, y_test = (
train_test_split(X, y, random_state=1 ))
For this example, we use a K-neighbors regressor to try to model our data. For many kinds of problems, this is a very effective algorithm, but it is also one that looks directly at distances in parameter space, and is hence very sensitive to scaling. If we naïvely apply this model to our raw data, the R-squared score is very low (other metrics would be similarly bad).
from sklearn.neighbors import KNeighborsRegressor
knn = KNeighborsRegressor()
knn.fit(X_train, y_train).score(X_test, y_test)
0.027756186064182953
A “perfect” R-squared score is 1.0. A very bad score is 0.0 (negative scores are also sometimes possible, and even worse in a sense). But for anything below 0.25 or so, we essentially reject the model.
By using, in this case, a min-max scaler, we achieve a far better metric score. The scaler we use here simply takes the minimum value of the raw feature, and shifts all values by that amount toward zero by subtraction, then divides all values by the shifted maximum value. The effect is to produce a range that is always [0, 1]
, for every feature. This synthetic feature does not have any physical meaning per se, as the original measure presumably did.
But by applying this scaler, all features are guaranteed to occupy the same numeric range (with the specific values distributed differently within their ranges). Let us apply this min-max scaling to our features before fitting the model again.
from sklearn.preprocessing import MinMaxScaler
X_new = MinMaxScaler().fit_transform(X)
X_train, X_test, y_train, y_test = (
train_test_split(X_new, y, random_state=1 ))
knn2 = KNeighborsRegressor()
knn2.fit(X_train, y_train).score(X_test, y_test)
0.9743878175626131
Notice that I did not bother to scale the target in the above code. There would be no harm in doing so for the model, but there is no benefit either since the target is not part of the parameter space of the features. Moreover, if we scaled the target, we would have to remember to unscale it correspondingly to get a meaningful number in the desired units.
Scaling Techniques
The scaling technique we used above utilized scikit-learn’s MinMaxScaler
. All of the scalers in scikit-learn use the same API, and are implemented in an efficient and correct manner. There is certainly a good argument for using those within Python, even if scikit-learn is not otherwise part of your overall modeling pipeline. However, it is not difficult to do the same scaling “by hand” using lower-level vectorized operations. For example, this would be simple in NumPy; here we show an example in R, and focus only on the algorithm. One nice detail of the scikit-learn API is that it knows to normalize column-by-column. In the comparison, we only do one column.
%%R -i X,X_new
py_raw_data <- X$Feature_1
py_scaled <- X_new[,1 ]
normalize <- function(x) {
floor <- min (x)
return ((x - floor) / (max (x) - floor))
}
r_scaled <- normalize(py_raw_data)
all .equal(py_scaled, r_scaled)
[1] TRUE
Notice that even for a straightforward operation like this, the different implementations, across libraries and languages, do not perform identical operations in an identical order. This allows some floating-point rounding differences to creep in. Comparing for strict equality of floating-point values is almost always the wrong thing to do; measurements have finite precision and operations introduce 1-ULP (unit in the last place) errors frequently. On the other hand, these slight numeric differences make no practical difference for actual models, only for equality checks.
%%R
print("A few 'equalities':" )
print(py_scaled[1 :5 ])
print(r_scaled[1 :5 ])
print("Exactly equal?" )
print((py_scaled == r_scaled)[1 :10 ])
print("Mean absolute difference:" )
print(mean(abs (py_scaled - r_scaled)))
[1] "A few 'equalities':"
[1] 0.1776148 1.0000000 0.7249096 0.6142706 0.8920478
[1] 0.1776148 1.0000000 0.7249096 0.6142706 0.8920478
[1] "Exactly equal?"
[1] TRUE FALSE FALSE FALSE FALSE TRUE FALSE TRUE TRUE TRUE
[1] "Mean absolute difference:"
[1] 6.130513e-17
Another very common scaling technique is called StandardScaler
in scikit-learn. It sets the mean of a feature to 0 and the standard deviation to 1. This scaling is particularly relevant when a variable is (very roughly) normally distributed. The name hints that this approach is usually the default scaler to choose (although probably it was derived from “standard deviation” when the name was chosen). Let us implement it to illustrate the simple transformation. Here we display the values from Feature_2
, which are around 20,000 in the raw data.
from sklearn.preprocessing import StandardScaler
X_new2 = StandardScaler().fit_transform(X)
plt.hist(X_new2[:, 1 ], bins=30 )
plt.title("Value distribution after StandardScaler" );
Figure 5.9: Feature_2 value distribution after the StandardScaler transformation
StandardScaler
uses more numeric operations than MinMaxScaler
, since it involves standard deviation, and that gives the calculation more opportunity for introducing numeric errors. The code in scikit-learn performs tricks to minimize this error better than the simple version we present, although again the magnitude is unlikely to be genuinely important. Let us manually reproduce the basic operation of StandardScaler.
%%R -i X,X_new2
py_raw_data <- X$Feature_2
py_scaled <- X_new2[, 2 ]
r_scaled = (py_raw_data - mean(py_raw_data)) /
sd(py_raw_data)
all .equal(py_scaled, r_scaled)
[1] "Mean relative difference: 0.002503133"
In this calculation, we do not pass the all.equal()
test. R characterizes the failure beyond only a boolean FALSE
. We can make the comparison with a bit more laxness by setting the tolerance parameter. Let us also verify the characteristics of the scaled data.
%%R
print("Mean from R scaling:" )
print(mean(r_scaled))
print("Standard deviation:" )
print(sd(r_scaled))
print("Almost equal with tolerance 0.005" )
all .equal(py_scaled, r_scaled, tolerance = 0.005 )
[1] "Mean from R scaling:"
[1] 6.591949e-17
[1] "Standard deviation:"
[1] 1
[1] "Almost equal with tolerance 0.005"
[1] TRUE
A number of variations are available for scaling through basic multiplication and subtraction operations. For example, rather than normalize on standard deviation, we could normalize using inter-quartile range (IQR). The scikit-learn class RobustScaler
does this, for example. To some degree, IQR—or generally quantile-based approaches—are more robust against outliers. However, the degree to which IQR range scaling normalizes is limited, and a stricter quantile approach can be more aggressive.
Let us replicate Feature_1
in the sample dataset we are presenting, but make just one value (out of 200) an extreme outlier. Recall that Feature_1
has values on the order of 0.1. We will introduce a single value of 100 into the variable. Arguably, this is an extreme-enough outlier that we should have removed it already, using the techniques discussed in Chapter 4 , Anomaly Detection , but for whatever reason we did not.
X['Feature_3' ] = X.Feature_1
X.loc[0 , 'Feature_3' ] = 100
When we attempt to utilize RobustScaler
, the transformed data still has one data point at an extreme value. In fact, that extreme is worse than the out-of-bounds value, 100, that we selected; moreover, the outlier is even farther out than under a StandardScaler
transformation. RobustScaler
is really only productive under a collection including a moderate number of moderate outliers (of the sort that might have escaped anomaly detection).
from sklearn.preprocessing import RobustScaler
X_new3 = RobustScaler().fit_transform(X)
plt.hist(X_new3[:, 2 ], bins=30 )
plt.title("Value distribution after RobustScaler" );
Figure 5.10: Feature_1 value distribution after RobustScaler
A stronger approach we can use is to rigorously scale values so that they fall exclusively within quantiles. In essence, this scales the data within each quantile range separately, and hence imposes both a reasonable distribution overall and strict bounds on values.
from sklearn.preprocessing import QuantileTransformer
deciles = QuantileTransformer(n_quantiles=10 )
X_new4 = deciles.fit_transform(X)
plt.hist(X_new4[:, 2 ], bins=30 )
plt.title("Value distribution after QuantileTransformer" );
Figure 5.11: Feature_1 value distribution after QuantileTransformer
Obviously, this transformed data is not completely uniform—it would have little value if there was not some variability beyond ordinal order—but it is bounded and reasonably evenly distributed across the range [0, 1]
. The single outlier point remains as a minor outlier from the main distribution, but is numerically not very distant.
In principle, even though the specific transformers in scikit-learn operate in a column-wise fashion, we might wish to apply a different scaling technique to each column or feature. As long as the particular transformation generates numeric ranges among the transformed values on roughly the same scale (i.e. usually of about distance one or two between maximum and minimum value, at least for the majority of data), all machine learning techniques that utilize distance in parameter space as part of their algorithm will be satisfied. Examples of such algorithms include linear models, support vector machines, and K-nearest neighbors. As was mentioned, algorithms in the family of decision trees simply do not care about specific distance in a dimension, and neural networks can perform a kind of scaling by allowing what we can informally call a “scaling layer ” that at least might act as a multiplier of each input feature (exactly what a trained network “decides” to use neurons and layers for is always somewhat opaque to our intentions or understanding).
Factor and Sample Weighting
There are times when you will wish to give a particular feature more significance than fair scaling across features allows. This is a slightly different issue than the one that is addressed by sampling in Chapter 6 , Value Imputation . In that later chapter, I discuss either undersampling or oversampling to produce more witnesses of minority target classes. That is certainly a possible approach to balancing classes within a feature rather than a target, but is not usually the best approach.
If nothing else, oversampling across two distinct unbalanced classes has the potential to explode the number of synthetic samples.
In the case of unbalanced feature classes, another approach is available. We can simply overweight minority classes rather than oversample them. Many machine learning models contain an explicit hyperparameter called something like sample_weight
(the scikit-learn spelling). Separately from the sample weights, however, these same model classes will also sometimes have something like class_weight
as a separate hyperparameter. The distinction here is exactly the one we have been making: sample weight allows you to overweight (or underweight) specific rows of input data, while class weight allows you to over/underweight specific target class values.
To add more nuance to this matter, we are not restricted to over/underweighting only to address class imbalance. We can, in fact, apply it for any reason we like. For example, we may know that certain measurements in our dataset are more reliable than others, and wish to overweight those. Or we may know that getting predictions right for samples with a certain characteristic is more important for task-specific reasons, even while not wishing entirely to discard those samples lacking that characteristic.
Let us return to the Apache log file example to illustrate all of these concerns. Recall that the processed data looks something like this:
reqs.sample(8 , random_state=72 ).drop('page' , axis=1 )
hour minute quad1 quad2 method
——————————————————————————————————————————————————
3347 0 4 172 69 GET
2729 9 43 172 69 GET
8102 4 16 172 69 GET
9347 0 48 162 158 GET
6323 21 30 162 158 GET
2352 0 35 162 158 GET
12728 9 0 162 158 GET
12235 19 3 172 69 GET
path status
————————————————————————————————————————————————————
3347 /publish/programming 200
2729 /TPiP 200
8102 /member/images 404
9347 /publish/images 304
6323 /download/pywikipedia/cache 200
2352 /download/gnosis/xml/pickle/test 200
12728 /download/relax 200
12235 /dede2 404
We noted that both method
and status
are highly imbalanced in pretty much the way we expect them to be in a working web server. The method data specifically has this imbalance that we saw plotted above, in Figure 5.7 . The hypothetical task we have in mind is to predict status codes based on the other features of the dataset (without actually issuing an HTTP request, which might change based on the current time, for example).
reqs.method.value_counts()
GET 13294
HEAD 109
POST 48
Name: method, dtype: int64
In other words, GET
requests are 122 times more common than HEAD
requests, and 277 times more common than POST
requests. We may be concerned that this limits our ability to make predictions on the rare class values for the method. Often our models will simply figure this out for us, but sometimes they will not. Moreover, although it is a frequently occurring path, we have decided that we need our model to be more sensitive to paths of /TPiP
and so will artificially overweight that by 5x as well. Notice that in this stipulation, the overweighting has nothing whatsoever to do with the underlying distribution of the feature, but rather is a domain requirement of the underlying purpose of our modeling.
Likewise, we are especially concerned about predicting 404 status codes (i.e. enhance the recall of this label), but are not necessarily interested in the overall balance of the target. Instead, we will weight all other outcomes as 1, but weight 404s as 10, for task purposes we have determined before performing modeling. Let us do all of that in code, in this case using a random forest model from scikit-learn. Should some row match both the overweighted path
and an underrepresented method
, the larger multiplier for the method
will take precedence.
tpip_rows = reqs[reqs.path == '/TPiP' ].index
head_rows = reqs[reqs.method == 'HEAD' ].index
post_rows = reqs[reqs.method == 'POST' ].index
reqs_weighted = reqs.copy()
reqs_weighted['weight' ] = 1
reqs_weighted.loc[tpip_rows, 'weight' ] = 5
reqs_weighted.loc[head_rows, 'weight' ] = 122
reqs_weighted.loc[post_rows, 'weight' ] = 277
reqs_weighted.drop('page' , axis=1 , inplace=True )
reqs_weighted.sample(4 , random_state=72 )
hour minute quad1 quad2 method path status
———————————————————————————————————————————————————————————————————————
3347 0 4 172 69 GET /publish/programming 200
2729 9 43 172 69 GET /TPiP 200
8102 4 16 172 69 GET /member/images 404
9347 0 48 162 158 GET /publish/images 304
weight
—————————————
3347 1
2729 5
8102 1
9347 1
These sample weights are stored on a per-row basis; in other words, we have 13,451 of them. For this example, most are simply weight 1, but they could all be distinct numbers, in concept. Configuring the weights we wish to use with the target is different. We could leverage the sample weight itself to choose rows with a certain target label; however, that approach is unnecessarily clunky and is not usually our preferred approach. Instead, we simply wish to create a small mapping from label to weight.
target_weight = {code:1 for code in reqs.status.unique()}
target_weight[404 ] = 10
target_weight
{200: 1, 304: 1, 403: 1, 404: 10, 301: 1, 500: 1, 206: 1}
Here we will create, fit, train, and score a scikit-learn model. The API will vary if you use some other library, but the concepts will remain the same. It only takes a line to perform a train/test split, as is good practice in real code. As a minor API detail, we need to encode our string categorical values for this model type, so we will use OrdinalEncoder
.
from sklearn.ensemble import RandomForestClassifier
from sklearn.preprocessing import OrdinalEncoder
rfc = RandomForestClassifier(class_weight=target_weight,
random_state=0 )
X = reqs_weighted[['hour' , 'minute' ,
'quad1' , 'quad2' ,
' method' , 'path' ]]
X = OrdinalEncoder().fit_transform(X)
y = reqs_weighted['status' ]
weight = reqs_weighted.weight
X_train, X_test, y_train, y_test, weights_train, _ = (
train_test_split(X, y, weight, random_state=1 ))
rfc.fit(X_train, y_train, sample_weight=weights_train)
rfc.score(X_test, y_test)
0.8183169788878977
As with R-squared used in the regression example, 1.0 represents perfect accuracy . Accuracy cannot be less than 0.0 though.
Without more context and analysis, I cannot say whether this model does well or poorly for the intended purpose. Quite possibly some other model class and/or some better-tuned weights would serve the hypothetical purpose better. The steps in trying those are straightforward, and mostly the same as the code shown.
We turn now to a difficult but important concept. Many times we wish to remove expected trends from data to reveal the exceptions to those trends.
Cyclicity and Autocorrelation
Do I contradict myself?
Very well then I contradict myself,
(I am large, I contain multitudes.)
–Walt Whitman
Concepts :
Detrending sequential data
Detected cycles versus a priori domain knowledge
Expected versus distinctive variability
Multiple cyclicities
Autocorrelation
There are times when you expect your data to have periodic behavior within it. In such cases—especially when multiple overlapping cyclicities exist within sequential data—the deviations from the cyclical patterns can be more informative than the raw values. Most frequently we see this in association with time series data, of course. To some degree, this concern falls under the purview of Chapter 7 , Feature Engineering , and indeed we return there to some of the same concerns, and even to the same dataset we discuss here.
As a first step, we would like to be able to recognize and analyze periodicities or cyclicities in our data. Some of these are intuitively obvious once we have some domain knowledge, but others lurk in the data themselves and not necessarily in our initial intuitions. For this section, I will utilize a dataset collected many years ago by my friend, and occasional co-author, Brad Huntting. For a period in the past, Brad collected temperatures in and outside his house in Colorado (USA), generally every 3 minutes. The data presented here covers a few days less than a year.
Rooms inside the house were regulated by thermostats; the outdoors naturally shows seasonal variation. Moreover, the data itself is imperfect. When we return to this data in Chapter 7 , Feature Engineering , we will look at gaps, recording errors, and other problems in the data collection. For the purpose of this section, a minor degree of data cleanup and value imputation was performed in the code that loads the dataset. See also Chapter 6 , Value Imputation , for additional discussion of imputation generally, with different examples.
First, let us read in the data using a Python function that loads a Pandas DataFrame. However, beyond the loading step, we will perform the analysis and visualization in R and its Tidyverse. Very similar capabilities exist in other libraries and languages, including Pandas. The underlying concepts are important here, not the specific APIs and languages used. Brad uses a web domain name of “glarp” so we use that same invented word for some variable names referring to this data about his house temperatures.
thermo = read_glarp()
start, end = thermo.timestamp.min (), thermo.timestamp.max ()
print("Start:" , start)
print(" End:" , end)
print(" Days:" , 1 + (end.date() - start.date()).days)
Start: 2003-07-25 16:04:00
End: 2004-07-16 15:28:00
Days: 358
Let us look at a few rows of the dataset to have a feeling for its nature. We can see that one row exists every 3 minutes during the interval of recording. For this section, the interval is completely regular at 3 minutes, and no missing values are present. Moreover, a few obvious recording errors in the raw data are cleaned up here with imputed values.
%%R -i thermo
glarp <- as .tibble(thermo)
glarp
# A tibble: 171,349 x 5
timestamp basement lab livingroom outside
<dttm> <dbl> <dbl> <dbl> <dbl>
1 2003-07-25 16:04:00 24 25.2 29.8 27.5
2 2003-07-25 16:07:00 24 25.2 29.8 27.3
3 2003-07-25 16:10:00 24 25.2 29.8 27.3
4 2003-07-25 16:13:00 24.1 25.2 29.8 27.4
5 2003-07-25 16:16:00 24.1 25.2 29.8 27.8
6 2003-07-25 16:19:00 24.1 25.2 29.8 27.5
7 2003-07-25 16:22:00 24.1 25.2 29.8 27.6
8 2003-07-25 16:25:00 24.1 25.2 29.8 27.6
9 2003-07-25 16:28:00 24.1 25.2 29.8 27.7
10 2003-07-25 16:31:00 24.1 25.2 29.8 27.6
# ... with 171,339 more rows
We can visualize this data as a first step to removing cyclicities with the goal of focusing on the ways in which individual measurements vary from expectations . These operations are also called “detrending ” the data. Let us look first at outside temperatures, plotting their pattern using ggplot2 .
%%R
ggplot(glarp, aes(x=timestamp, y=outside)) +
geom_line() + clean_theme +
ggtitle("Outside temperature over recording interval" )
Figure 5.12: Outside temperature over the recording interval
As is easy to guess, there is a general pattern of northern hemisphere temperatures being warmer in July than in January, with a great deal of jitter within the global trend. Even though only 1 year of data is available, we know from very basic domain knowledge to expect similar annual cycles for other years. In contrast, as we can also anticipate, indoor temperatures both fall within a narrower range and show less of a clear pattern.
%%R
ggplot(glarp, aes(x=timestamp, y=basement)) +
geom_line() + clean_theme +
ggtitle("Basement temperature over recording interval" )
Figure 5.13: Basement temperature over the recording interval
Overall, indoor temperatures in the basement are relatively narrowly bound between about 14°C and 23°C. Some points fall outside of this range, both some high summer temperatures indicating that the house had a heating system but no air conditioner, and some low winter temperatures in sharp spikes, perhaps reflecting periods when windows were opened. However, the outside lows reached about -20°C while these indoor lows are generally above 10°C. Something somewhat odd seems to have happened around September and October of 2003 as well; perhaps this reflects some change in the heating system during that period.
Domain Knowledge Trends
As a first task, let us think about outdoor temperatures that are presumably little affected by the house heating system. We would like to identify unexpectedly warm or unexpectedly cold measurements as inputs to our downstream model. For example, a temperature of 10°C might either be a surprisingly cold summer temperature or a surprisingly warm winter temperature, but in itself it is merely globally typical and does not carry very much information about the observation without additional context.
Given that yearly temperatures will continue to repeat from year to year, it might make sense to model this yearly pattern as a portion of a sine wave. However, in shape, it certainly resembles a parabola for this period from roughly the warmest day of 2003 until roughly the warmest day of 2004. Since we are merely detrending a year-scale pattern, not modeling the behavior, let us fit a second-order polynomial to the data, which will account for most of the variation that exists in the measurements.
%%R
year.model <- lm(outside ~ poly(timestamp, 2 ), data = glarp)
ggplot(glarp, aes(x=timestamp)) + clean_theme +
geom_line(aes(y = outside), color = "gray" ) +
geom_line(aes(y = predict(year.model)),
color = "darkred" , size = 2 ) +
ggtitle("Outside temperature versus polynomial fit" )
Figure 5.14: Fitting a polynomial curve to the outside temperature data
We can see in the plot that our annual detrending accounts for most of the data variation, so we can simply subtract the trend from the underlying points to get, as a first pass, the degree to which a measurement is unexpected. A new tibble named outside
will hold the data for this narrower focus.
%%R
outside <- glarp[, c("timestamp" , "outside" )] %>%
add_column(no_seasonal = glarp$outside - predict(year.model))
outside
# A tibble: 171,349 x 3
timestamp outside no_seasonal
<dttm> <dbl> <dbl>
1 2003-07-25 16:04:00 27.5 1.99
2 2003-07-25 16:07:00 27.3 1.79
3 2003-07-25 16:10:00 27.3 1.79
4 2003-07-25 16:13:00 27.4 1.89
5 2003-07-25 16:16:00 27.8 2.29
6 2003-07-25 16:19:00 27.5 1.99
7 2003-07-25 16:22:00 27.6 2.10
8 2003-07-25 16:25:00 27.6 2.10
9 2003-07-25 16:28:00 27.7 2.20
10 2003-07-25 16:31:00 27.6 2.07
# ... with 171,339 more rows
Visualizing the seasonally detrended temperatures, we see a remaining range from around -20°C to +20°C. This is somewhat less than the range of the raw temperatures, but only somewhat. Variability has decreased, but only modestly.
However, there is no obvious overall annual trend once we have performed this removal, and the synthetic value is centered at 0.
%%R
ggplot(outside, aes(x=timestamp)) +
geom_line(aes(y = no_seasonal)) + clean_theme +
ggtitle("Outside temperature with removed seasonal expectation" )
Figure 5.15: Outside temperature with seasonal expectation subtracted
The second obvious insight we might have into outdoor temperature cycles is that it is warmer during the day than at night. Given that there are 358 days of data, a polynomial will clearly not fit, but a trigonometric model is likely to fit to a better degree. We do not calculate a Fourier analysis here, but rather simply look for an expected daily cyclicity. Since we have observations every 3 minutes during each day, we wish to convert these 3,360 intervals into 2π radians for the regression to model. The model will simply consist of fitted sine and cosine terms, which can additively construct any sine-like curve on the specified periodicity.
%%R
x <- 1 :nrow(outside) * 2 *pi / (24 *60 /3 )
day_model <- lm(no_seasonal ~ sin(x) + cos(x),
data = outside)
print(day_model)
outside2 <- add_column(outside,
day_model = predict(day_model),
no_daily = outside$no_seasonal - day_model)
outside2
Call:
lm(formula = no_seasonal ~ sin(x) + cos(x), data = outside)
Coefficients:
(Intercept) sin(x) cos(x)
0.0002343 -0.5914551 3.6214463
# A tibble: 171,349 x 5
timestamp outside no_seasonal day_model no_daily
<dttm> <dbl> <dbl> <dbl> <dbl>
1 2003-07-25 16:04:00 27.5 1.99 3.61 -1.62
2 2003-07-25 16:07:00 27.3 1.79 3.60 -1.81
3 2003-07-25 16:10:00 27.3 1.79 3.60 -1.80
4 2003-07-25 16:13:00 27.4 1.89 3.59 -1.69
5 2003-07-25 16:16:00 27.8 2.29 3.58 -1.28
6 2003-07-25 16:19:00 27.5 1.99 3.56 -1.57
7 2003-07-25 16:22:00 27.6 2.10 3.55 -1.46
8 2003-07-25 16:25:00 27.6 2.10 3.54 -1.44
9 2003-07-25 16:28:00 27.7 2.20 3.53 -1.33
10 2003-07-25 16:31:00 27.6 2.07 3.51 -1.44
# ... with 171,339 more rows
It is difficult to tell from just the first few rows of the data frame, but the daily detrending is typically closer to zero than the seasonal detrending alone. The regression consists mostly of a cosine factor, but is shifted a bit by a smaller negative sine factor. The intercept is very close to zero, as we would expect from the seasonal detrending. If we visualize the three lines, we can get some sense; in order to show it better, only one week in early August of 2003 is shown. Other time periods have a similar pattern; all will be centered at zero because of the detrending.
%%R
week <- outside2[5000 :8360 ,]
p1 <- ggplot(week, aes(x = timestamp)) +
no_xlabel + ylim(-8 , +8 ) +
geom_line(aes(y = no_seasonal))
p2 <- ggplot(week, aes(x = timestamp)) +
no_xlabel + ylim(-8 , +8 ) +
geom_line(aes(y = day_model), color = "lightblue" , size = 3 )
p3 <- ggplot(week, aes(x = timestamp)) +
clean_theme + ylim(-8 , +8 ) +
geom_line(aes(y = no_daily), color = "darkred" )
grid.arrange(p1, p2, p3,
top = "Annual de-trended; daily regression; daily de-trended" )
Figure 5.16: Annual detrended data; daily regression; daily detrended
The thicker, smooth line is the daily model of temperature. In electronic versions of this book, it will appear as light blue. At the top is the more widely varying seasonally detrended data. At the bottom, the daily detrended data has mostly lower magnitudes (in red if your reading format allows it). The third subplot is simply the subtraction of the middle subplot from the top one.
Around August 7 are some oddly low values. These look sharp enough to suggest data problems, but perhaps a thunderstorm brought August temperatures that much lower during one afternoon. One thing we can note in the date range plotted is that even the daily detrended data shows a weak daily cycle, albeit with much more noise. This would indicate that other weeks of the year have less temperature fluctuation than this one; in fact, some weeks will show an anti-cyclic pattern with the detrended data being an approximate inverse of the regression line. Notably, even on this plot, it looks like August 8 was anti-cyclic, while August 5 and 6 have a remaining signal matching the sign of the regression, and the other days have a less clear correspondence. By anti-cyclic, we do not mean that, for example, a night was warmer than the days around it, but rather that there was less than the expected fluctuation, and hence detrending produces an inverted pattern.
That said, while we have not removed every possible element of more complex cyclic trends, the range of most values in the doubly detrended data is approximately 8°C, whereas it was approximately 50°C for the raw data. Our goal is not to remove the underlying variability altogether but rather to emphasize the more extreme magnitude measurements, which this has done.
Discovered Cycles
We have good a priori beliefs about what outdoor temperatures are likely to do. Summers are warmer than winters, and nights are colder than days. However, no similarly obvious assumption presents itself for indoor temperatures. We saw earlier a plot for temperatures in Brad’s basement. The data is interestingly noisy, but in particular we noticed that for about two summer months, the basement temperatures were pinned above about 21°C throughout the day and night. From this, we inferred that Brad’s house had a heating system but no cooling system, and therefore the indoor temperature approximately followed the higher outdoor ones. We wish here to analyze only the heating system and its artificially maintained temperature, rather than the seasonal trend. Let us limit the data to non-summer days (here named according to the pattern in the data rather than the official season dates).
%%R
not_summer <- filter (glarp,
timestamp >= as .Date("2003-08-15" ),
timestamp <= as .Date("2004-06-15" ))
ggplot(not_summer, aes(x=timestamp, y=basement)) +
geom_line() + clean_theme +
ggtitle("Basement temperature over non-summer days" )
Figure 5.17: Basement temperature over non-summer days
Within the somewhat narrowed period, nearly every day of measurements has temperatures both above and below around 18-20°C, so most likely the heating system was operating for a portion of each day in almost all of these non-summer days. The question we would like to analyze—and perhaps to detrend—is whether cyclic patterns exist in indoor temperature data, among the considerable noisiness that is clearly present in the raw data.
A technique called autocorrelation lends itself well to this analysis. Autocorrelation is a mathematical technique that identifies repeating patterns, such as the presence of a periodic signal mixed with noise or non-periodic variation. In Pandas, the Series method .autocorr()
looks for this. In R, the relevant function is called acf()
. Other libraries or programming languages have similar capabilities. Let us take a look at what we discover. Note that we do not wish blindly to look for autocorrelations if our domain knowledge tells us that only certain periodicities “make sense” within the subject matter.
Although our data frame contains a timeseries
column already, it is easier here simply to create one out of the basement
column we will work with. The actual dates corresponding to data points are irrelevant for the operation; only their spacing in time is of interest. In particular, we can impose a frequency matching the number of observations in a day to get a plot labeled intuitively by the number of days. The acf()
function generates a plot automatically, and returns an object with a number of values attached that you can utilize numerically. For the purpose of this section, the graph is sufficient.
%%R
per_day <- 24 *60 /3
basement.temps <- ts(not_summer$basement, frequency = per_day)
auto <- acf(basement.temps, lag.max = 10 *per_day)
Figure 5.18: Density distribution of similarities at different increments
As the autocorrelation name suggests, this shows the correlation of the single data series with itself at each possible offset. Trivially, the zero increment is 100% correlated with itself. Everything other than that tells us something specific about the cyclicities within this particular data. There are strong spikes at each integral number of days. We limited the analysis to 10 days forward here. These spikes let us see that the thermostat in the basement had a setting to regulate the temperature to different levels at different times of each day, but in a way that was largely the same between one day and each of the next ten after it.
The spikes in this data are sloped rather than sharp (they are, at least, continuous rather than stepped). Any given 3-minute interval tends to have a similar temperature to those nearby it, diminishing fairly quickly, but not instantaneously, as measurements occur farther away. This is what we would expect in a house with a thermostat-controlled heating system, of course. Other systems might be different; for example, if a light was on a timer to come on for exactly 3 minutes then go out, on some schedule, the measurement of light levels would be suddenly, rather than gradually, different between adjacent measurements.
The pattern in the autocorrelation provides more information than only the daily cycle, however. We see also a lower correlation at approximately half-day intervals. This is also easily understood by thinking about the domain and the technology that produced it. To save energy, Brad set his thermostat timer to come on in the mornings when he’d wake up, then go to a lower level while he was at the office, then again to go up in the early evening when he returned home. I happen to know this was an automated setting, but the same effect might, for example, have occurred if it was simply a human pattern of manually adjusting the thermostat up and down at those times (the signal would probably be less strong than with a mechanical timer, but likely present).
Rising above the daily cyclicity, there is also a somewhat higher spike in the autocorrelation at 7 days. This indicates that days of the week are correlated with the temperature setting of the thermostat. Most likely, either because of a timer setting or human habit and comfort, a different temperature was set on weekdays versus weekends, for example. This secondary pattern is less strong than the general 24-hour cyclicity, but about as strong as the half-day cyclicity; examining the autocorrelation spikes more carefully could reveal exactly what duration Brad was at his office versus coming home, typically. The offset of the secondary spikes from the 24-hour spikes is probably not at exactly 12 hours, but is at some increment less than the full 24 hours.
We will not do these operations in this section, but think about using the autocorrelation as a detrending regression, much as we did with the trigonometric regression. This would effectively have separate periodicities of 12 and 24 hours, and at 7 days. Clearly, the raw data shown has a lot of additional noise, but it would presumably be reduced by subtracting out these known patterns. Some very atypical values would stand out even more strongly among this detrended data, and potentially thereby have even stronger analytic significance.
Sometimes the data validation that we need to perform is simply highly specific to the domain in question. For that, we tend to need more custom approaches and code.
Bespoke Validation
Explanations exist; they have existed for all time; there is always a well-known solution to every human problem—neat, plausible, and wrong.
–H. L. Mencken
Concepts :
Leveraging domain knowledge beyond anomaly detection
Example: evaluating duplicated data
Validation as sanity check to further investigation
There are many times when domain knowledge informs the shape of data that is likely to be genuine versus data that is more likely to reflect some kind of recording or collation error. Even though general statistics on the data do not show anomalies, bias, imbalance, or other generic problems, we know something more about the domain or the specific problem that informs our expectations about “clean” data.
To illustrate, we might have an expectation that certain kinds of observations should occur with roughly a particular frequency compared to other observations; perhaps this would be specified further by the class values of a third categorical variable. For example, as background domain knowledge, we know that in the United States, family size is slightly less than 2 children, on average. If we had data that was meant to contain information about all the individual people in sampled households, we could use this as a guideline for the shape of the data. In fact, if we had auxiliary data on children per household by state, we might refine this reference expectation more when validating our data.
Obviously, we do not expect every household to have exactly 1.9 children in it. Given that humans come in integral units, we in fact could never have such a fractional number in any specific household at all. However, if we found that in our sampled households we averaged 0.5 children per household, or 4 children per household-with-children, we would have a strong indication that some kind of sample bias was occurring. Perhaps children are under- or overreported in the household data for individual households. Perhaps the selection of which households to sample biases the data toward those with children, or toward those without them. This scenario is largely similar to the issue addressed earlier in this chapter of comparisons to baselines. It adds only a minor wrinkle to the earlier examples in that we only identify households where we wish to validate our expectation of the number of children (i.e. under 18 years old) based on a shared address feature across several observations (that is, a household).
Collation Validation
Let us look at a completely different example that really cannot be formulated in terms of baseline expectations. In this section, we consider genomic data on ribosomal RNA (rRNA) that was downloaded from DNA Data Bank of Japan (DDBJ), specifically the 16S rRNA (Prokaryotes) in FASTA format dataset. You do not need to know anything about genomics or cellular biology for this example; we focus simply on the data formats used and an aggregation of records in this format.
Each sequence in this dataset contains a description of the organism in question and the nature of the sequence recorded. The FASTA format is widely used in genomics and is a simple textual format. Multiple entries in the line-oriented format can simply be concatenated in the same file or text. For example, a sequence entry might look like this:
FASTA
>AB000001_1|Sphingomonas sp.|16S ribosomal RNA
agctgctaatattagagccctatatatagagggggccctatactagagatatatctatca
gctaatattagagccctatatatagagggggccctatactagagatatatctatcaggct
attagagccctatatatagagggggccctatactagagatataagtcgacgatattagca
agccctatatatagagggggccctatactagagatatatctatcaggtgcacgatcgatc
cagctagctagc
The description published with this dataset indicates that each sequence contained is at least 300 base pairs, and the average length is 1,104 base pairs. There are 998,911 sequences contained as of this writing. Note that in DNA or RNA, every nucleobase uniquely determines which other base is paired in a double helix, so the format does not need to notate both. A variety of high-quality tools exist for working with genomic data; details of those are outside the scope of this book. However, as an example, let us use SeqKit to identify duplicated sequences. In this dataset, there are no pairs of sequences with the same name or ID, but quite a few contain the same base pairs. This is not an error, per se, since it reflects different observations. It may, however, be redundant data that is not useful for our analysis.
%%bash
cd data/prokaryotes
zcat 16S.fasta.gz |
seqkit rmdup --by-seq --ignore-case \
-o clean.fasta.gz \
-d duplicated.fasta.gz \
-D duplicated.detail.txt
[INFO] 159688 duplicated records removed
Around 15% of all the sequences are duplicates. In general, these are multiple IDs that pertain to the same organism. We can see such in a quick examination of the duplication report produced by seqkit
. As an exercise, you might think about how you would write a similar duplicate detection function in a general-purpose programming language; it is not particularly difficult, but SeqKit is certainly more optimized and better tested than would be a quick implementation you might produce yourself.
%%bash
cut -c-60 data/prokaryotes/duplicated.detail.txt | head
1384 JN175331_1|Lactobacillus, MN464257_1|Lactobacillus, MN4
1383 MN438326_1|Lactobacillus, MN438327_1|Lactobacillus, MN4
1330 AB100791_1|Lactococcus, AB100792_1|Lactococcus, AB10079
1004 CP014153_1|Bordetella, CP014153_2|Bordetella, CP014153_
934 MN439952_1|Lactobacillus, MN439953_1|Lactobacillus, MN43
912 CP003166_2|Staphylococcus, CP003166_3|Staphylococcus, CP
908 CP010838_1|Bordetella, CP010838_2|Bordetella, CP010838_3
793 MN434189_1|Enterococcus, MN434190_1|Enterococcus, MN4341
683 CP007266_3|Salmonella, CP007266_5|Salmonella, CP007266_6
609 MN440886_1|Leuconostoc, MN440887_1|Leuconostoc, MN440888
Horizontal transfer of rRNA between organisms is possible, but such an occurrence in the data might also represent a misclassification of an organism under examination. We can write some code to determine if such an event of multiple IDs for the same sequence are sometimes tagged as different bacteria (or perhaps archaea).
def matched_rna ( dupfile ):
"""Count of distinct organisms per sequence match
Return a mapping from line number in the duplicates
to Counters of occurrences of species names
"""
counts = dict ()
for line in open (dupfile):
line = line.rstrip()
_, match_line = line.split('\t' )
matches = match_line.split(', ' )
first_id = matches[0 ].split('|' )[0 ]
names = [match.split('|' )[1 ] for match in matches]
count = Counter(names)
counts[first_id] = count
return counts
It turns out that cataloging multiple organisms with apparently identical rRNA sequences is quite a common occurrence. But our analysis/validation may shed light on what is likely occurring with these duplicate records. Many lines in the duplication report show just one species with many observations. A significant minority show something else. Let us look at several examples.
dupfile = 'data/prokaryotes/duplicated.detail.txt'
counts = matched_rna(dupfile)
In some examples, different observations have differing levels of specificity, but are not per se different organisms.
print(counts[' CP004752_1' ])
print(counts['AB729796_1' ])
Counter({'Mannheimia': 246, 'Pasteurellaceae': 1})
Counter({'Microbacterium': 62, 'Microbacteriaceae': 17})
Mannheimia is a genus of the family Pasteurellaceae, and Microbacterium is a genus of the family Microbacteriaceae. Whether these “discrepancies” need to be remediated in cleanup is very problem-specific, however. For example, we may wish to use the more general families in order to group matching sequences together. On the other hand, the problem may demand as much specificity in identifying organisms as is available. You have to decide how to process or handle different levels of specificity in your domain ontology.
A similar issue occurs in another record, but with what appears to be an additional, straightforward data error.
counts['AB851397_1' ]
Counter({'Proteobacteria': 1, 'proteobacterium': 2, 'Phyllobacteriaceae': 8})
Phyllobacteriaceae is a family in the broad phylum Proteobacteria, so either way we are dealing with rather non-specific classification. But “proteobacterium” appears to be a non-standard way of spelling the Linnaean family, both in being singular and in lacking of capitalization of the name.
Looking at another record, we might judge the classification as an observational error, but it is obviously difficult to be certain without deeper domain knowledge.
counts['CP020753_6' ]
Counter({'Shigella': 11, 'Escherichia': 153})
Both Shigella and Escherichia belong to the family Enterobacteriaceae. The identical sequence is characterized as belonging to different genera here. Whether this indicates a misidentification of the underlying organism or a horizontal transfer of rRNA between these organisms is not clear from this data alone. However, in your data science tasks, this is the sort of decision you are required to make, probably in consultation with domain experts.
One more record we can look at is very strange relative to this dataset. It shows many duplicates, but that is not really the surprising aspect.
counts['FJ537133_1' ]
Counter({'Aster': 1,
"'Elaeis": 1,
"'Tilia": 1,
"'Prunus": 2,
"'Brassica": 3,
'Papaya': 1,
"'Phalaris": 1,
"'Eucalyptus": 1,
"'Melochia": 1,
'Chinaberry': 1,
"'Catharanthus": 4,
"'Sonchus": 1,
"'Sesamum": 1,
'Periwinkle': 1,
'Candidatus': 1})
In this case, we have a number of genera of flowering plants—that is, eukaryotes—mixed with a dataset that is documented to catalog rRNA in prokaryotes. There is also a spelling inconsistency in that many of the genera listed have a spurious single-quote character at the beginning of their name. Whether or not it is plausible for these different plants, mostly trees, to share rRNA is a domain knowledge question, but it seems likely that these data do not belong within our hypothetical analysis of prokaryotic rRNA at all.
The examination of duplicated sequences in this dataset of rRNA sequences points to a number of likely problems in the collection. It also hints at problems that may lurk elsewhere within the collection. For example, even where identical sequences are not named by different levels of cladistic phylogeny, these differing levels may conflate the classification of other sequences. Perhaps, for example, this calls out for normalization of the data to a common phyletic level (which is a significantly large project, but it might be required for a task). Either way, this cursory validation suggests a need to filter the dataset to address only a well-defined collection of genera or families of organisms.
Transcription Validation
We discussed above, in this section, the possibility that the collection of records (i.e. sequences) may have problems in their annotation or aggregation. Perhaps records are inconsistent with each other or in some way present conflicting information. The examples we identified point to possible avenues for removal or remediation. In this second part of the section, we want to look at possible identifiable errors in the individual records.
This hypothetical is presented simply as a data example, not per se motivated by deep knowledge of RNA sequencing techniques. This is commonly the perspective of data scientists who work with domain experts. For example, I do not know how many of the measurements in the dataset utilized RNA-Seq versus older hybridization-based microarrays.
But for this purpose, let us suppose that a relatively common error in the sequencing technique causes inaccurate repetitions of short fragments of RNA base pairs that are not present in the actual measured rRNA. On the other hand, we also do know that microsatellites and minisatellites do occur in rRNA as well (although telomeres do not), so the mere presence of repeated sequences does not prove that a data collection error occurred; it is merely suggestive.
The purpose of this example is simply to present the idea that something as custom as what we do below may be relevant to your data validation for your specific domain. What we will look for is all the places where relatively long subsequences are repeated within a particular sequence. Whether this is an error or an interesting phenomenon is a matter for domain expertise. By default in the code below we look for repeated subsequences of 45 base pairs, but provide a configuration option to change that length. If each nucleotide were simply randomly chosen, each particular pattern of length 45 would occur with probability of about 10–27 , and repetitions—even with “birthday paradox ” considerations—would essentially never occur. But genetic processes are not so random as that.
As a first step, let us create a short function that iterates over a FASTA file, producing a more descriptive namedtuple
for each sequence contained along with its metadata. Many libraries will do something similar, perhaps faster and more robustly than the code shown does, but the FASTA format is simple enough that such a function is simple to write.
Sequence = namedtuple("FASTA" , "recno ID name locus bp" )
def get_sequence ( fname ):
fasta = gzip.open (fname)
pat = re.compile (r'n+' )
sequence = []
recno = 0
for line in fasta:
line = line.decode('ASCII' ).strip()
if line.startswith('>' ):
bp = "" .join(sequence)
bp = re.sub(pat, '-' , bp)
if recno > 0 :
yield Sequence(recno, ID, name, locus, bp)
ID, name, locus = line[1 :].split('|' )
sequence = []
recno += 1
else :
sequence.append(line)
The get_sequence()
function allows us to iterate lazily over all the sequences contained in a single gzipped file. Given that the total data is 1.1 GiB , not reading it all at once is an advantage. Beyond assuming such files are gzipped, it also makes an assumption that headers are formatted in the manner of the DDBJ rather than according to a different convention or lacking headers. As I say, other tools are more robust. Let us try reading just one record to see how the function works:
fname = 'data/prokaryotes/16S.fasta.gz'
prokaryotes = get_sequence(fname)
rec = next (prokaryotes)
print(rec.recno, rec.ID, rec.name, rec.locus)
print(fill(rec.bp, width=60 ))
1 AB000106_1 Sphingomonas sp. 16S ribosomal RNA
ggaatctgcccttgggttcggaataacgtctggaaacggacgctaataccggatgatgac
gtaagtccaaagatttatcgcccagggatgagcccgcgtaggattagctagttggtgagg
taaaggctcaccaaggcgacgatccttagctggtctgagaggatgatcagccacactggg
actgagacacggcccagactcctacgggaggcagcagtagggaatattggacaatgggcg
aaagcctgatccagcaatgccgcgtgagtgatgaaggccttagggttgtaaagctctttt
acccgggatgataatgacagtaccgggagaataagccccggctaactccgtgccagcagc
cgcggtaatacggagggggctagcgttgttcggaattactgggcgtaaagcgcacgtagg
cggcgatttaagtcagaggtgaaagcccggggctcaaccccggaatagcctttgagactg
gattgcttgaatccgggagaggtgagtggaattccgagtgtagaggtgaaattcgtagat
attcggaagaacaccagtggcgaaggcggatcactggaccggcattgacgctgaggtgcg
aaagcgtggggagcaaacaggattagataccctggtagtccacgccgtaaacgatgataa
ctagctgctggggctcatggagtttcagtggcgcagctaacgcattaagttatccgcctg
gggagtacggtcgcaagattaaaactcaaaggaattgacgggggcctgcacaagcggtgg
agcatgtggtttaattcgaagcaacgcgcagaaccttaccaacgtttgacatccctagta
tggttaccagagatggtttccttcagttcggctggctaggtgacaggtgctgcatggctg
tcgtcagctcgtgtcgtgagatgttgggttaagtcccgcaacgagcgcaaccctcgcctt
tagttgccatcattcagttgggtactctaaaggaaccgccggtgataagccggaggaagg
tggggatgacgtcaagtcctcatggcccttacgcgttgggctacacacgtgctacaatgg
cgactacagtgggcagctatctcgcgagagtgcgctaatctccaaaagtcgtctcagttc
ggatcgttctctgcaactcgagagcgtgaaggcggaatcgctagtaatcgcggatcagca
tgccgcggtgaatacgtccccaggtcttgtacacaccgcccgtcacaccatgggagttgg
tttcacccgaaggcgctgcgctaactcgcaagagaggcaggcgaccacggtgggatcagc
gactgggtgagtcgtacaggtgc
In order to check each sequence/record for the subsequence duplication we are concerned about, another short function can help us. This Python code uses a Counter again, as did the matched_rna()
function earlier. It simply looks at every subsequence of a given length, many thereby overlapping, and returns only those counts that are greater than 1.
def find_dup_subseq ( bp, minlen= 45 ):
count = Counter()
for i in range (len (bp)-minlen):
count[bp[i:i+minlen]] += 1
return {seq: n for seq, n in count.items() if n > 1 }
Putting it together, let us look at only the first 2,800 records to see if any have the potential problem we are addressing. Given that the full dataset contains close to 1 million sequences, many more such duplicates occur. An initial range was only chosen by trial and error to find exactly two examples. Duplicate subsequences are comparatively infrequent, but not so rare as not to occur numerous times among a million sequences.
for seq in islice(get_sequence(fname), 2800 ):
dup = find_dup_subseq(seq.bp)
if dup:
print(seq.recno, seq.ID, seq.name)
pprint(dup)
2180 AB051695_1 Pseudomonas sp. LAB-16
{'gtcgagctagagtatggtagagggtggtggaatttcctgtgtagc': 2,
'tcgagctagagtatggtagagggtggtggaatttcctgtgtagcg': 2}
2534 AB062283_1 Acinetobacter sp. ST-550
{'aaaggcctaccaaggcgacgatctgtagcgggtctgagaggatga': 2,
'aaggcctaccaaggcgacgatctgtagcgggtctgagaggatgat': 2,
'accaaggcgacgatctgtagcgggtctgagaggatgatccgccac': 2,
'aggcctaccaaggcgacgatctgtagcgggtctgagaggatgatc': 2,
'ccaaggcgacgatctgtagcgggtctgagaggatgatccgccaca': 2,
'cctaccaaggcgacgatctgtagcgggtctgagaggatgatccgc': 2,
'ctaccaaggcgacgatctgtagcgggtctgagaggatgatccgcc': 2,
'gcctaccaaggcgacgatctgtagcgggtctgagaggatgatccg': 2,
'ggcctaccaaggcgacgatctgtagcgggtctgagaggatgatcc': 2,
'ggggtaaaggcctaccaaggcgacgatctgtagcgggtctgagag': 2,
'gggtaaaggcctaccaaggcgacgatctgtagcgggtctgagagg': 2,
'ggtaaaggcctaccaaggcgacgatctgtagcgggtctgagagga': 2,
'ggtggggtaaaggcctaccaaggcgacgatctgtagcgggtctga': 2,
'gtaaaggcctaccaaggcgacgatctgtagcgggtctgagaggat': 2,
'gtggggtaaaggcctaccaaggcgacgatctgtagcgggtctgag': 2,
'taaaggcctaccaaggcgacgatctgtagcgggtctgagaggatg': 2,
'taccaaggcgacgatctgtagcgggtctgagaggatgatccgcca': 2,
'tggggtaaaggcctaccaaggcgacgatctgtagcgggtctgaga': 2,
'tggtggggtaaaggcctaccaaggcgacgatctgtagcgggtctg': 2,
'ttggtggggtaaaggcctaccaaggcgacgatctgtagcgggtct': 2}
As before, this validation only points in the direction of asking domain- and problem-specific questions, and does not determine the correct action. Subsequence duplications may indicate errors in the sequencing process, but they might also reveal something relevant about the underlying domain, and genomic mechanisms. Collisions are far too unlikely to occur by mere chance, however.
Exercises
For the exercises of this chapter, we first ask you to perform a typical multi-step data cleanup using techniques you have learned. For the second exercise, you try to characterize sample bias in the provided dataset using analytic tools this book has addressed (or others of your choosing).
Data Characterization
For this exercise, you will need to perform a fairly complete set of data cleaning steps. The focus is on techniques discussed in this chapter, but concepts discussed in other chapters will be needed as well. Some of these tasks will require skills discussed in later chapters, so skip ahead briefly, as needed, to complete the tasks.
Here we return to the “Brad’s House” temperature data, but in its raw form. The raw data consists of four files, corresponding to the four thermometers that were present. These files may be found at:
https://www.gnosis.cx/cleaning/outside.gz
https://www.gnosis.cx/cleaning/basement.gz
https://www.gnosis.cx/cleaning/livingroom.gz
https://www.gnosis.cx/cleaning/lab.gz
The format of these data files is a simple but custom textual format. You may want to refer back to Chapter 1 , Tabular Formats , and to Chapter 3 , Repurposing Data Sources , for inspiration on parsing the format. Let us look at a few rows:
%%bash
zcat data/glarp/lab.gz | head -5
2003 07 26 19 28 25.200000
2003 07 26 19 31 25.200000
2003 07 26 19 34 25.300000
2003 07 26 19 37 25.300000
2003 07 26 19 40 25.400000
As you can see, the space-separated fields represent the components of a datetime, followed by a temperature reading. The format itself is consistent for all the files. However, the specific timestamps recorded in each file are not consistent. All four data files end on 2004-07-16T15:28:00
, and three of them begin on 2003-07-25T16:04:00
. Various and different timestamps are missing in each file. For comparison, we can recall that the full data frame we read with a utility function that performs some cleanup has 171,346 rows. In contrast, the line counts of the several data files are:
%%bash
for f in data/glarp/*.gz; do
echo -n "$f: "
zcat $f | wc -l
done
data/glarp/basement.gz: 169516
data/glarp/lab.gz: 168965
data/glarp/livingroom.gz: 169516
data/glarp/outside.gz: 169513
All of the tasks in this exercise are agnostic to the particular programming languages and libraries you decide to use. The overall goal will be to characterize each of the 685k data points as one of several conceptual categories that we present below.
Task 1 : Read all four data files into a common data frame. Moreover, we would like each record to be identified by a proper native timestamp rather than by separated components. You may wish to refer forward to Chapter 7 , Feature Engineering , which discusses date/time fields.
Task 2 : Fill in all missing data points with markers indicating they are explicitly missing. This will have two slightly different aspects. There are some implied timestamps that do not exist in any of the data files. Our goal is to have 3-minute increments over the entire duration of the data. In the second aspect, some timestamps are represented in some data files but not in others. You may wish to refer to the Missing Data section of this chapter and the same-named one in Chapter 4 , Anomaly Detection ; as well, the discussion of date/time fields in Chapter 7 is likely relevant.
Task 3 : Remove all regular trends and cycles from the data. The relevant techniques may vary between the different instruments. As we noted in the discussion in this chapter, three measurement series are of indoor temperatures regulated, at least in part, by a thermostat, and one is of outdoor temperatures. Whether or not the house in question had differences in thermostats or heating systems between rooms is left for readers to try to determine based on the data (at the very least though, heat circulation in any house is always imperfect and not uniform).
Note: As a step in performing detrending, it may be useful to temporarily impute missing data, as is discussed in Chapter 6 , Value Imputation .
Task 4 : Characterize every data point (timestamp and location) according to these categories:
A “regular” data point that falls within generally expected bounds.
An “interesting” data point that is likely to indicate relevant deviation from trends.
A “data error” that reflects an improbable value relative to expectations, and is more likely to be a recording or transcription error. Consider that a given value may be improbable based on its delta from nearby values and not exclusively because of absolute magnitude. Chapter 4 is likely to be relevant here.
A missing data point.
Task 5 : Describe any patterns you find in the distribution of characterized data points. Are there temporal trends or intervals that show most or all data characterized in a certain way? Does this vary by which of four instruments we look at?
Oversampled Polls
Polling companies often deliberately utilize oversampling (overselection) in their data collection. This is a somewhat different issue than the overweighting discussed in a topic of this chapter, or than the mechanical oversampling that will be addressed in Chapter 6 , Value Imputation . Rather, the idea here is that a particular class, or a value range, is known to be uncommon in the underlying population, and hence the overall parameter space is likely to be sparsely filled for that segment of the population. Alternately, the oversampled class may be common in the population but also represents a subpopulation about which the analytic purpose needs particularly high discernment.
The use of oversampling in data collection itself is not limited to human subjects surveyed by polling companies. There are times when it similarly makes sense for entirely unrelated subject domains, for example, the uncommon particles produced in cyclotrons or the uncommon plants in a studied forest. Responsible data collectors, such as the Pew Research Center that collected the data used in this exercise, will always explicitly document their oversampling methodology and expectations about the distribution of the underlying population. You can, in fact, read all of these details about the 2010 opinion survey we utilize at:
https://www.pewsocialtrends.org/2010/02/24/millennials-confident-connected-open-to-change/
However, to complete this exercise, we prefer you skip initially consulting that documentation. For the work here, pretend that you received this data without adequate accompanying documentation and metadata (just to be clear: Pew is meticulous here). Such is all too often the case in the real world of messy data. The raw data, with no systematic alteration to introduce bias or oversampling, is available by itself at:
https://www.gnosis.cx/cleaning/pew-survey.csv
Task 1 : Read in the data, and make a judgment about what ages were deliberately over- or undersampled, and to what degree. We may utilize this weighting in later synthetic sampling or weighting, but for now, simply add a new column called sampling_multiplier
to each observation of the dataset matching your belief.
For this purpose, treat 1x as the “neutral” term. So, for example, if you believe 40-year-old subjects were overselected by 5x, assign the multiplier 5.0. Symmetrically, if you believe 50-year-olds were systematically underselected by 2x, assign the multiplier 0.5. Keep in mind that humans in the United States in 2010 were not uniformly distributed by age.
Moreover, with a sample size of about 2,000 and 75 different possible ages, we expect some non-uniformity of subgroup sizes simply from randomness. Merely random variation from the neutral selection rate should still be coded as 1.0.
Task 2 : Some of the categorical fields seem to encode related but distinct binary values. For example, this question about technology is probably not ideally coded for data science goals:
pew = pd.read_csv('data/pew-survey.csv' )
list (pew.q23a.unique())
['New technology makes people closer to their friends and family',
'New technology makes people more isolated',
'(VOL) Both equally',
"(VOL) Don't know/Refused",
'(VOL) Neither equally']
Since the first two descriptions may either be mutually believed or neither believed by a given surveyed person, encoding each as a separate boolean value makes sense. How to handle a refusal to answer is an additional decision for you to make in this re-encoding. Determine which categorical values should better be encoded as multiple booleans, and modify the dataset accordingly. Explain and justify your decisions about each field.
Task 3 : Determine whether any other demographic fields than age were oversampled. While the names of the columns are largely cryptic, you can probably safely assume that a field with qualitative answers indicating degree of an opinion are dependent variables surveyed rather than demographic independent variables. For example:
list (pew.q1.unique())
['Very happy', 'Pretty happy', 'Not too happy', "(VOL) Don't know/Refused"]
You may need to consult outside data sources to make judgments for this task. For example, you should be able to find the rough population distribution of US timezones (in 2010) to compare to the dataset distribution.
list (pew.timezone.unique())
['Eastern', 'Central', 'Mountain', 'Pacific']
Task 4 : Some fields, such as q1
presented in Task 3 , are clearly ordinally encoded. While it is not directly possible to assign relative ratios for (Very happy:Pretty happy
) versus (Pretty happy:Not too happy
), the ranking of those three values is evident, and calling them ordinal 1, 2, and 3 is reasonable and helpful. You will, of course, also have to encode refusal to answer in some fashion. Re-encode all relevant fields to take advantage of this intuitive domain knowledge you have.
Denouement
Quality is never an accident. It is always the result of intelligent effort.
–John Ruskin
Topics covered in this chapter : Missing Data (revisited); Bias; Class Imbalance; Normalization; Scaling; Overweighting; Cyclicity; Bespoke Validation.
In this chapter, we focused on the problem of bias in data. Datasets rarely, if ever, completely represent a population; rather they skew and select from that population to form a certain kind of picture. Sometimes this bias is intentional and well-founded as a way of filling parameter spaces. Other times it simply reflects the distribution of quantities or classes in the underlying reality. In this case, it is both the inherent virtue of our data and a pitfall in our analysis. But at other times still, elements of the data collection, collation, transcription, or aggregation can introduce biases that are more subtle and may need to be remediated in some manner for our analyses and modeling of the data. Detecting bias is the first step toward addressing it.
Related to bias, but somewhat parallel as a concern, are cyclicities in data. Very often a particular series of data—when the data is ordered in some manner, often as a time series—has components of “signal” and “variation” that can be usefully separated. A signal is, in some sense, a kind of bias, in that it provides an expectation that at time T there is a higher probability the measurement will be close to M . Identifying the signals is often an important aspect of data analysis—they are often not a priori—but identifying the deviations from the signal also provides an additional channel of interesting information.
The prior chapter on anomaly detection provided hints about identifying data that is generically statistically unlikely within a collection of values. But very often we want to look at problems that are more domain-specific. We are often able to take advantage of expectations we have about patterns in clean data that might be violated by the data we actually have. These patterns might only be represented by custom code that algorithmically expresses these expectations but that cannot be formulated in terms of generic statistical tests.
In the next chapter, we turn to the important and subtle question of imputing data.