Using Pandas

Estimated time: 30 minutes

Overview

Questions

• How can I work with subsets of data in a pandas DataFrame?
• How can I run summary statistics and sort columns of a DataFrame?
• How can I save DataFrames to other file formats?

Objectives

• Select specific columns and rows from pandas DataFrames.
• Use pandas methods to calculate sums and means, and to display unique items.
• Sort DataFrame columns (pandas series).
• Save a DataFrame as a CSV or pickle file.

Pinpoint specific rows and columns in a DataFrame

---

If you don’t already have all of the CSV files loaded into a DataFrame, let’s do that now:

PYTHON

import glob
import pandas as pd

dfs = [] 

for csv in sorted(glob.glob('data/*.csv')):
    year = csv[5:9] 
    data = pd.read_csv(csv) 
    data['year'] = year 
    dfs.append(data)

df = pd.concat(dfs, ignore_index=True)

df.head(3)

	branch	address	city	zip code	january	february	march	april	may	june	july	august	september	october	november	december	ytd	year
0	Albany Park	5150 N. Kimball Ave.	Chicago	60625.0	8427	7023	9702	9344	8865	11650	11778	11306	10466	10997	10567	9934	120059	2011
1	Altgeld	13281 S. Corliss Ave.	Chicago	60827.0	1258	708	854	804	816	870	713	480	702	927	787	692	9611	2011
2	Archer Heights	5055 S. Archer Ave.	Chicago	60632.0	8104	6899	9329	9124	7472	8314	8116	9177	9033	9709	8809	7865	101951	2011

Use tail() to look at the end of the DataFrame

We’ve seen how to look at the first rows in your DataFrame using .head(). You can use .tail() to look at the final rows.

PYTHON

df.tail(3)

	branch	address	city	zip code	january	february	march	april	may	june	july	august	september	october	november	december	ytd	year
960	Brighton Park	4314 S. Archer Ave.	Chicago	60632.0	1394	1321	1327	1705	1609	1578	1609	1512	1425	1603	1579	1278	17940	2022
961	South Chicago	9055 S. Houston Ave.	Chicago	60617.0	496	528	739	775	587	804	720	883	681	697	799	615	8324	2022
962	Chicago Bee	3647 S. State St.	Chicago	60609.0	799	543	709	803	707	931	778	770	714	835	718	788	9095	2022

Slicing a DataFrame

We can use the same slicing syntax that we used for strings and lists to look at a specific range of rows in a DataFrame.

PYTHON

df[50:60] #look at rows 50 to 59

	branch	address	city	zip code	january	february	march	april	may	june	july	august	september	october	november	december	ytd	year
50	Near North	310 W. Division St.	Chicago	60610.0	11032	10021	12911	12621	12437	13988	13955	14729	13989	13355	13006	12194	154238	2011
51	North Austin	5724 W. North Ave.	Chicago	60639.0	2481	2045	2674	2832	2202	2694	3302	3225	3160	3074	2796	2272	32757	2011
52	North Pulaski	4300 W. North Ave.	Chicago	60639.0	3848	3176	4111	5066	3885	5105	5916	5512	5349	6386	5952	5372	59678	2011
53	Northtown	6435 N. California Ave.	Chicago	60645.0	10191	8314	11569	11577	10902	14202	15310	14152	11623	12266	12673	12227	145006	2011
54	Oriole Park	7454 W. Balmoral Ave.	Chicago	60656.0	11999	11206	13675	12755	10364	12781	12219	12066	10856	11324	10503	9878	139626	2011
55	Portage-Cragin	5108 W. Belmont Ave.	Chicago	60641.0	9185	7634	9760	10163	7995	9735	10617	11203	10188	11418	10718	9517	118133	2011
56	Pullman	11001 S. Indiana Ave.	Chicago	60628.0	1916	1206	1975	2176	2019	2347	2092	2426	2476	2611	2530	2033	25807	2011
57	Roden	6083 N. Northwest Highway	Chicago	60631.0	6336	5830	7513	6978	6180	8519	8985	7592	6628	7113	6999	6082	84755	2011
58	Rogers Park	6907 N. Clark St.	Chicago	60626.0	10537	9683	13812	13745	13368	18314	20367	19773	18419	18972	17255	16597	190842	2011
59	Roosevelt	1101 W. Taylor St.	Chicago	60607.0	6357	6171	8228	7683	7257	8545	8134	8289	7696	7598	7019	6665	89642	2011

Look at specific columns

To work specifically with one column of a DataFrame we can use a similar syntax, but refer to the name the column of interest.

PYTHON

df['year'] #look at the year column

OUTPUT

0      2011
1      2011
2      2011
3      2011
4      2011
       ...
958    2022
959    2022
960    2022
961    2022
962    2022
Name: year, Length: 963, dtype: object

We can add a second square bracket after a column name to refer to specific row indices, either on their own, or using slices to look at ranges.

PYTHON

print(f"first row: {df['year'][0]}") #use double quotes around your fstring if it contains single quotes
print('rows 100 to 102:') #add a new print statement to create a new line
print(df['year'][100:103])

OUTPUT

first row: 2011
rows 100 to 102:
100    2012
101    2012
102    2012
Name: year, dtype: object

Columns display differently in our notebook since a column is a different type of object than a full DataFrame.

PYTHON

type(df['year'])

OUTPUT

pandas.core.series.Series

Summary statistics on columns

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A pandas Series is a one-dimensional array, like a column in a spreadsheet, while a pandas DataFrame is a two-dimensional tabular data structure with labeled axes, similar to a spreadsheet. One of the advantages of pandas is that we can use built-in functions like max(), min(), mean(), and sum() to provide summary statistics across Series such as columns. Since it can be difficult to get a sense of the range of data in a large DataFrame by looking over the whole thing manually, these functions can help us understand our dataset quickly and ask specific questions.

If we wanted to know the range of years covered in this data, for example, we can look at the maximum and minimum values in the year column.

PYTHON

print(f"max year: {df['year'].max()}")
print(f"min year: {df['year'].min()}")

OUTPUT

max year: 2022
min year: 2011

Summarize columns that hold string objects

We might also want to quickly understand the range of values in columns that contain strings, the branch column, for example. We can look at a range of values, but it’s hard to tell how many different branches are present in the dataset this way.

PYTHON

df['branch']

OUTPUT

0         Albany Park
1             Altgeld
2      Archer Heights
3              Austin
4       Austin-Irving
            ...
958         Chinatown
959          Brainerd
960     Brighton Park
961     South Chicago
962       Chicago Bee
Name: branch, Length: 963, dtype: object

We can use the .unique() function to output an array (like a list) of all of the unique values in the branch column, and the .nunique() function to tell us how many unique values are present.

PYTHON

print(f"Number of unique branches: {df['branch'].nunique()}")
print(df['branch'].unique())

OUTPUT

Number of unique branches: 82
['Albany Park' 'Altgeld' 'Archer Heights' 'Austin' 'Austin-Irving'
 'Avalon' 'Back of the Yards' 'Beverly' 'Bezazian' 'Blackstone' 'Brainerd'
 'Brighton Park' 'Bucktown-Wicker Park' 'Budlong Woods' 'Canaryville'
 'Chicago Bee' 'Chicago Lawn' 'Chinatown' 'Clearing' 'Coleman'
 'Daley, Richard J. - Bridgeport' 'Daley, Richard M. - W Humboldt'
 'Douglass' 'Dunning' 'Edgebrook' 'Edgewater' 'Gage Park'
 'Galewood-Mont Clare' 'Garfield Ridge' 'Greater Grand Crossing' 'Hall'
 'Harold Washington Library Center' 'Hegewisch' 'Humboldt Park'
 'Independence' 'Jefferson Park' 'Jeffery Manor' 'Kelly' 'King'
 'Legler Regional' 'Lincoln Belmont' 'Lincoln Park' 'Little Village'
 'Logan Square' 'Lozano' 'Manning' 'Mayfair' 'McKinley Park' 'Merlo'
 'Mount Greenwood' 'Near North' 'North Austin' 'North Pulaski' 'Northtown'
 'Oriole Park' 'Portage-Cragin' 'Pullman' 'Roden' 'Rogers Park'
 'Roosevelt' 'Scottsdale' 'Sherman Park' 'South Chicago' 'South Shore'
 'Sulzer Regional' 'Thurgood Marshall' 'Toman' 'Uptown' 'Vodak-East Side'
 'Walker' 'Water Works' 'West Belmont' 'West Chicago Avenue'
 'West Englewood' 'West Lawn' 'West Pullman' 'West Town'
 'Whitney M. Young, Jr.' 'Woodson Regional' 'Wrightwood-Ashburn'
 'Little Italy' 'West Loop']

Use .groupby() to analyze subsets of data

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A reasonable question to ask of the library usage data might be to see which branch library has seen the most checkouts over this ten + year period. We can use .groupby() to create subsets of data based on the values in specific columns. For example, let’s group our data by branch name, and then look at the ytd column to see which branch has the highest usage. .groupby() takes a column name as its argument and then for each group we can sum the ytd columns using .sum().

PYTHON

df.groupby('branch')['ytd'].sum()

OUTPUT

branch
Albany Park              1024714
Altgeld                    68358
Archer Heights            803014
Austin                    200107
Austin-Irving            1359700
                          ...
West Pullman              295327
West Town                 922876
Whitney M. Young, Jr.     259680
Woodson Regional          823793
Wrightwood-Ashburn        302285
Name: ytd, Length: 82, dtype: int64

Sort pandas series using .sort_values()

The output for code above is another pandas series object. Let’s save the output to a new variable so we can then apply the .sort_values() method which allows us to view the branches with the most usage. The ascending parameter for .sort_values() takes True or False. We want to pass False so that we sort from the highest values down…

PYTHON

circ_by_branch = df.groupby('branch')['ytd'].sum()
circ_by_branch.sort_values(ascending=False).head(10)

OUTPUT

branch
Harold Washington Library Center    7498041
Sulzer Regional                     5089225
Lincoln Belmont                     1850964
Edgewater                           1668693
Logan Square                        1539816
Rogers Park                         1515964
Bucktown-Wicker Park                1456669
Lincoln Park                        1441173
Austin-Irving                       1359700
Bezazian                            1357922
Name: ytd, dtype: int64

Now we have a list of the branches with the highest number of uses across the whole dataset.

We can pass multiple columns to groupby() to subset the data even further and breakdown the highest usage per year and branch. To do that, we need to pass the column names as a list. We can also chain together many methods into a single line of code.

PYTHON

circ_by_year_branch = df.groupby(['year', 'branch'])['ytd'].sum().sort_values(ascending=False)
circ_by_year_branch.head(5)

OUTPUT

year  branch
2011  Harold Washington Library Center    966720
2012  Harold Washington Library Center    937649
2013  Harold Washington Library Center    821749
2014  Harold Washington Library Center    755189
2015  Harold Washington Library Center    694528
Name: ytd, dtype: int64

Use .iloc[] and .loc[] to select DataFrame locations.

---

You can point to specific locations in a DataFrame using two-dimensional numerical indexes with .iloc[].

PYTHON

# print values in the 1st and 2nd to last columns in the first row
# '\n' prints a linebreak
print(f"Branch: {df.iloc[0,0]} \nYTD circ: {df.iloc[0,-2]}")

OUTPUT

Branch: Albany Park
YTD circ: 120059

.loc[] uses the same structure but takes row (index) and column names instead of numerical indexes. Since our df rows don’t have index names we would still use the default numerical index.

PYTHON

# print the same values as above, using the column names
print(f"Branch: {df.loc[0,'branch']} \nYTD circ: {df.loc[0, 'ytd']}")

OUTPUT

Branch: Albany Park
YTD circ: 120059

Save DataFrames

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You might want to export the series of usage by year and branch that we just created so that you can share it with colleagues. Pandas includes a variety of methods that begin with .to_... that allow us to convert and export data in different ways. First, let’s save our series as a DataFrame so we can view the output in a better format in our Jupyter notebook.

PYTHON

circ_df = circ_by_year_branch.to_frame()
circ_df.head(5)

		ytd
year	branch
2011	Harold Washington Library Center	966720
2012	Harold Washington Library Center	937649
2013	Harold Washington Library Center	821749
2014	Harold Washington Library Center	755189
2015	Harold Washington Library Center	694528

Save to CSV

Next, let’s export the new DataFrame to a CSV file so we can share it with colleagues who love spreadsheets. The .to_csv() method expects a string that will be the name of the file as a parameter. Make sure to add the .csv filetype to your file name.

PYTHON

circ_df.to_csv('high_usage.csv')

You should now see, in the JupyterLab file explorer to the left, the new CSV file. If you don’t see it, you can hit the refresh icon (it looks like a spinning arrow) above the files pane. You can double-click on the CSV to preview the full spreadsheet in a new Jupyter tab.

Save pickle files

Working with your data in CSVs (especially via tools like Microsoft Excel) can introduce reproducibility issues. For example, you’ll sometimes encounter character encoding problems, where certain characters in your dataset will no longer display properly after editing them in a spreadsheet software like Excel, and re-importing them to a pandas DataFrame.

One way to avoid issues like this is to save Python objects as pickles. Technically speaking, the Python pickle module serializes and de-serializes a Python object’s structure. In practical terms, pickling allows you to store Python objects (like DataFrames, lists, etc.) efficiently and without losing or corrupting your data.

You can save a DataFrame to pickle by using the to_pickle() method and using the filetype of pkl.

PYTHON

circ_df.to_pickle('high_usage.pkl')

You can only “see” the data in a pickle file by reloading it into Python. This is a great way to save a DataFrame that you created in one JupyterLab session so that you can reload it later on, or share it with a colleague who’s familiar with Python.

PYTHON

new_df = pd.read_pickle('high_usage.pkl')
new_df.head()

Finally, let’s save our full concatenated DataFrame to a pickle file that we can use later on in the lesson. We’ll save it in the data/ directory alongside our other data files.

PYTHON

df.to_pickle('data/all_years.pkl')

Displaying rows and columns

How would you use slicing and column names to select the following subsets of rows and columns from the circulation DataFrame?

1. The city column.
2. Rows 10 to 20.
3. Rows 20 to 30 from the zip code column.

Show me the solution

PYTHON

#1
df['city']

#2
df[10:21]

#3 
df['zip code'][20:31]

Using loc()

How would you use loc() to select rows 20 to 30 from the zip code column (the same rows as the last example in the challenge above)?

Tip: slices use “non-inclusive” indexing – so require you to ask for df[10:21] to see row 20, but loc() uses inclusive indexing.

Show me the solution

PYTHON

df.loc[20:30, 'zip code']

Unique items

How would you display:

1. all of the unique zip codes in the dataset?
2. the number of unique zip codes in the dataset?

Show me the solution

PYTHON

#1
df['zip code'].unique()

#2
df['zip code'].nunique()

Summary statistics and groupby()

We can apply mean() to pandas series’ in the same way we used sum(), min(), and max() above. How would you display the following?

1. the mean number of ytd checkouts grouped by zip code?
2. the mean number of ytd checkouts grouped by zip code, and sorted from smallest to largest?

Show me the solution

PYTHON

#1
df.groupby('zip code')['ytd'].mean()

#2
df.groupby('zip code')['ytd'].mean().sort_values()

Key Points

• Use builtin methods .sum(), .mean(), unique(), and nunique() to explore summary statistics on the rows and colums in your DataFrame.
• Use .groupby() to work with subsets of your dataset.
• Sort pandas series with .sort_values().
• Use .loc() and .iloc() to pinpoint specific locations in Pandas DataFrames.
• Save DataFrames to CSV and pickle files using .to_csv() and .to_pickle().