## What is Markowitz Portfolios Optimization (Efficient Frontier)?

The Efficient Frontier takes a portfolio of investments and optimizes the expected return in regards to the risk. That is to find the optimal return for a risk.

According to investopedia.org the return is based on the expected Compound Annual Growth Rate (CAGR) and risk metric is the standard deviation of the return.

But what does all that mean? We will learn that in this tutorial.

## Step 1: Get the time series of your stock portfolio

We will use the following portfolio of 4 stocks of Apple (AAPL), Microsoft (MSFT), IBM (IBM) and Nvidia (NVDA).

To get the time series we will use the Yahoo! Finance API through the Pandas-datareader.

We will look 5 years back.

```import pandas_datareader as pdr
import pandas as pd
import datetime as dt
from dateutil.relativedelta import relativedelta

years = 5
end_date = dt.datetime.now()
start_date = end_date - relativedelta(years=years)
close_price = pd.DataFrame()
tickers = ['AAPL','MSFT','IBM','NVDA']
for ticker in tickers:
tmp = pdr.get_data_yahoo(ticker, start_date, end_date)
close_price[ticker] = tmp['Close']

print(close_price)
```

Resulting in the following output (or the first few lines).

```                  AAPL        MSFT         IBM        NVDA
Date
2015-08-25  103.739998   40.470001  140.960007   20.280001
2015-08-26  109.690002   42.709999  146.699997   21.809999
2015-08-27  112.919998   43.900002  148.539993   22.629999
2015-08-28  113.290001   43.930000  147.979996   22.730000
2015-08-31  112.760002   43.520000  147.889999   22.480000
```

It will contain all the date time series for the last 5 years from current date.

## Step 2: Calculate the CAGR, returns, and covariance

To calculate the expected return, we use the Compound Average Growth Rate (CAGR) based on the last 5 years. The CAGR is used as investopedia suggest. An alternative that also is being used is the mean of the returns. The key thing is to have some common measure of the return.

The CAGR is calculated as follows.

CAGR = (end-price/start-price)^(1/years) – 1

We will also calculate the covariance as we will use that the calculate the variance of a weighted portfolio. Remember that the standard deviation is given by the following.

sigma = sqrt(variance)

A portfolio is a vector w with the balances of each stock. For example, given w = [0.2, 0.3, 0.4, 0.1], will say that we have 20% in the first stock, 30% in the second, 40% in the third, and 10% in the final stock. It all sums up to 100%.

Given a weight w of the portfolio, you can calculate the variance of the stocks by using the covariance matrix.

variance = w^T Cov w

Where Cov is the covariance matrix.

This results in the following pre-computations.

```returns = close_price/close_price.shift(1)
cagr = (close_price.iloc[-1]/close_price.iloc[0])**(1/years) - 1
cov = returns.cov()

print(cagr)
print(cov)
```

Where you can see the output here.

```# CACR:
AAPL    0.371509
MSFT    0.394859
IBM    -0.022686
NVDA    0.905011
dtype: float64

# Covariance
AAPL      MSFT       IBM      NVDA
AAPL  0.000340  0.000227  0.000152  0.000297
MSFT  0.000227  0.000303  0.000164  0.000306
IBM   0.000152  0.000164  0.000260  0.000210
NVDA  0.000297  0.000306  0.000210  0.000879
```

## Step 3: Plot the return and risk

This is where the power of computing comes into the picture. The idea is to just try a random portfolio and see how it rates with regards to expected return and risk.

It is that simple. Make a random weighted distribution of your portfolio and plot the point of expected return (based on our CAGR) and the risk based on the standard deviation calculated by the covariance.

```import matplotlib.pyplot as plt
import numpy as np

def random_weights(n):
k = np.random.rand(n)
return k / sum(k)

exp_return = []
sigma = []
for _ in range(20000):
w = random_weights(len(tickers))
exp_return.append(np.dot(w, cagr.T))
sigma.append(np.sqrt(np.dot(np.dot(w.T, cov), w)))

plt.plot(sigma, exp_return, 'ro', alpha=0.1)
plt.show()
```

We introduce a helper function random_weights, which returns a weighted portfolio. That is, it returns a vector with entries that sum up to one. This will give a way to distribute our portfolio of stocks.

Then we iterate 20.000 times (could be any value, just want to have enough to plot our graph), where we make a random weight w, then calculate the expected return by the dot-product of w and cagr-transposed. This is done by using NumPy’s dot-product function.

What a dot-product of np.dot(w, cagr.T) does is to take elements pairwise from w and cagr and multiply them and sum up. The transpose is only about the orientation of it to make it work.

The standard deviation (assigned to sigma) is calculated similar by the formula given in the last step: variance = w^T Cov w (which has dot-products between).

This results in the following graph.

This shows a graph which outlines a parabola. The optimal values lie along the upper half of the parabola line. Hence, given a risk, the optimal portfolio is one corresponding on the upper boarder of the filled parabola.

## Considerations

The Efficient Frontier gives you a way to balance your portfolio. The above code can by trial an error find such a portfolio, but it still leaves out some consideratoins.

How often should you re-balance? It has a cost to do that.

The theory behind has some assumptions that may not be a reality. As investopedia points out, it assumes that asset returns follow a normal distribution, but in reality returns can be more the 3 standard deviations away. Also, the theory builds upon that investors are rational in their investment, which is by most considered a flawed assumption, as more factors play into the investments.

## The full source code

Below here you find the full source code from the tutorial.

```import pandas_datareader as pdr
import datetime as dt
import pandas as pd
from dateutil.relativedelta import relativedelta
import matplotlib.pyplot as plt
import numpy as np

years = 5
end_date = dt.datetime.now()
start_date = end_date - relativedelta(years=years)
close_price = pd.DataFrame()
tickers = ['AAPL', 'MSFT', 'IBM', 'NVDA']
for ticker in tickers:
tmp = pdr.get_data_yahoo(ticker, start_date, end_date)
close_price[ticker] = tmp['Close']

returns = close_price / close_price.shift(1)
cagr = (close_price.iloc[-1] / close_price.iloc[0]) ** (1 / years) - 1
cov = returns.cov()

def random_weights(n):
k = np.random.rand(n)
return k / sum(k)

exp_return = []
sigma = []
for _ in range(20000):
w = random_weights(len(tickers))
exp_return.append(np.dot(w, cagr.T))
sigma.append(np.sqrt(np.dot(np.dot(w.T, cov), w)))

plt.plot(sigma, exp_return, 'ro', alpha=0.1)
plt.show()
```

## What will we cover in this tutorial?

A quick way to make a candlestick plot using the mplfinance library on financial data in Pandas DataFrames.

## The code

It is straight forward to achieve by using the new matplotlib finance API. The data can be collected by using Pandas-datareader with the open Yahoo! Finance API.

```import pandas_datareader as pdr
import datetime as dt
import mplfinance as mpf

df = pdr.get_data_yahoo("AAPL", dt.datetime(2020,6,1), dt.datetime.now())

mpf.plot(df, type='candle', style='charles',
title='Apple',
ylabel='Price',
ylabel_lower='Volume',
volume=True,
mav=(1,3,6))
```

The mav-argument is the Moving Averages, I have also included the 1, which is the actual price.

## What will we cover in this tutorial?

In this tutorial we will visualize the inflation on a map. This will be done by getting the inflation data directly from World Bank using the Pandas-datareader. This data will be joined with data from GeoPandas, which provides a world map we can use to create a Choropleth map.

## Step 1: Retrieve the inflation data from World Bank

The Pandas-datareader has an interface to get data from World Bank. To find interesting data from World Bank you should explore data.worldbank.org, which contains various interesting indicators.

When you find one, like the Inflation, consumer prices (annual %), we will use, you can see that you can download it in CSV, XML, or excel. But we are not old fashioned, hence, we will use the direct API to get fresh data every time we run our program.

To use the API, we need the indicator, which you will find in the url. In this case.

```https://data.worldbank.org/indicator/FP.CPI.TOTL.ZG
```

Hence we have it FP.CPI.TOTL.ZG.

Using the Pandas-datareader API you can get the data by running the following piece of code.

```from pandas_datareader import wb

print(data)
```

If you inspect the output, you will see it is structured a bit inconvenient.

```                                                         FP.CPI.TOTL.ZG
country                                            year
Arab World                                         2019        1.336016
Caribbean small states                             2019             NaN
Central Europe and the Baltics                     2019        2.664561
Early-demographic dividend                         2019        3.030587
East Asia & Pacific                                2019        1.773102
East Asia & Pacific (excluding high income)        2019        2.779172
East Asia & Pacific (IDA & IBRD countries)         2019        2.779172
```

It has two indexes.

We want to reset index 1 (the year) and, which will make year to a column. Then for convenience we should rename the columns.

```from pandas_datareader import wb

data = data.reset_index(1)
data.columns = ['year', 'inflation']
print(data)
```

Resulting in the following.

```                                                    year  inflation
country
Arab World                                          2019   1.336016
Caribbean small states                              2019        NaN
Central Europe and the Baltics                      2019   2.664561
Early-demographic dividend                          2019   3.030587
East Asia & Pacific                                 2019   1.773102
East Asia & Pacific (excluding high income)         2019   2.779172
East Asia & Pacific (IDA & IBRD countries)          2019   2.779172
```

## Step 2: Retrieve the world map data

The world map data is available from GeoPandas. At first glance everything is easy.

```import geopandas

map = map[map['name'] != 'Antarctica']
print(map)
```

Where I excluded Antarctica for visual purposes. Inspecting some of the output.

```        pop_est                continent                      name iso_a3   gdp_md_est                                           geometry
0        920938                  Oceania                      Fiji    FJI      8374.00  MULTIPOLYGON (((180.00000 -16.06713, 180.00000...
1      53950935                   Africa                  Tanzania    TZA    150600.00  POLYGON ((33.90371 -0.95000, 34.07262 -1.05982...
2        603253                   Africa                 W. Sahara    ESH       906.50  POLYGON ((-8.66559 27.65643, -8.66512 27.58948...
3      35623680            North America                    Canada    CAN   1674000.00  MULTIPOLYGON (((-122.84000 49.00000, -122.9742...
4     326625791            North America  United States of America    USA  18560000.00  MULTIPOLYGON (((-122.84000 49.00000, -120.0000...
5      18556698                     Asia                Kazakhstan    KAZ    460700.00  POLYGON ((87.35997 49.21498, 86.59878 48.54918...
6      29748859                     Asia                Uzbekistan    UZB    202300.00  POLYGON ((55.96819 41.30864, 55.92892 44.99586...
```

It seems to be a good match to join the data on the name column.

To make it easy, we can make the name column index.

```import geopandas

map = map[map['name'] != 'Antarctica']
map = map.set_index('name')
```

## Step 3: Joining the datasets

This is the fun part of Data Science. Why? I am glad you asked. Well, it was an irony. The challenge will be apparent in a moment. There are various ways to deal with it, but in this tutorial we will use a simplistic approach.

Let us do the join.

```from pandas_datareader import wb
import geopandas

pd.set_option('display.width', 3000)
pd.set_option('display.max_columns', 300)
pd.set_option('display.max_rows', 500)

map = map[map['name'] != 'Antarctica']
map = map.set_index('name')

data = data.reset_index(1)
data.columns = ['year', 'inflation']

map = map.join(data, how='outer')
print(map)
```

Where I use an outer join, to get all the “challenges” visible.

```Russia                                              1.422575e+08                   Europe    RUS   3745000.00  MULTIPOLYGON (((178.72530 71.09880, 180.00000 ...   NaN        NaN
Russian Federation                                           NaN                      NaN    NaN          NaN                                               None  2019   4.470367
...
United States                                                NaN                      NaN    NaN          NaN                                               None  2019   1.812210
United States of America                            3.266258e+08            North America    USA  18560000.00  MULTIPOLYGON (((-122.84000 49.00000, -120.0000...   NaN        NaN
```

Where I only took two snippets. The key thing is here, that the data from GeoPandas, containing the map, and data from World Bank, containing the inflation rates we want to color the map with, are not joined.

Hence, we need to join United States together with United States of America. And Russia with Russian Federation.

We would use a location service, which maps counties to country codes. Hence, mapping each data sets country names to country codes (note that GeoPandas already has 3 letter country codes, but some are missing, like Norway and more). This approach still can have some missing pieces, as some country names are not known by the mapping.

Another approach is to look find all the data not mapped and rename them in one of the datasets. This can take some time, but I did most of them in the following.

```from pandas_datareader import wb
import geopandas

map = map[map['name'] != 'Antarctica']
map = map.set_index('name')
index_change = {
'United States of America': 'United States',
'Yemen': 'Yemen, Rep.',
'Venezuela': 'Venezuela, RB',
'Syria': 'Syrian Arab Republic',
'Solomon Is.': 'Solomon Islands',
'Russia': 'Russian Federation',
'Iran': 'Iran, Islamic Rep.',
'Gambia': 'Gambia, The',
'Kyrgyzstan': 'Kyrgyz Republic',
'Mauritania': 'Mauritius',
'Egypt': 'Egypt, Arab Rep.'
}
map = map.rename(index=index_change)

data = data.reset_index(1)
data.columns = ['year', 'inflation']

map = map.join(data, how='outer')
```

## Step 4: Making a Choropleth map based on our dataset

The simple plot of the data will not be very insightful. But let’s try that first.

```map.plot('inflation')
plt.title("Inflation 2019")
plt.show()
```

Resulting in the following.

A good way to get inspiration is to check out the documentation with examples.

Where you see a cool color map with scheme=’quantiles’. Let’s try that.

```map.plot('inflation', cmap='OrRd', scheme='quantiles')
plt.title("Inflation 2019")
plt.show()
```

Resulting in the following.

Adding grey tone to countries not mapped, adding a legend, setting the size. Then we are done. The full source code is here.

```from pandas_datareader import wb
import geopandas
import pandas as pd
import matplotlib.pyplot as plt

map = map[map['name'] != 'Antarctica']
map = map.set_index('name')
index_change = {
'United States of America': 'United States',
'Yemen': 'Yemen, Rep.',
'Venezuela': 'Venezuela, RB',
'Syria': 'Syrian Arab Republic',
'Solomon Is.': 'Solomon Islands',
'Russia': 'Russian Federation',
'Iran': 'Iran, Islamic Rep.',
'Gambia': 'Gambia, The',
'Kyrgyzstan': 'Kyrgyz Republic',
'Mauritania': 'Mauritius',
'Egypt': 'Egypt, Arab Rep.'
}
map = map.rename(index=index_change)

data = data.reset_index(1)
data.columns = ['year', 'inflation']

map = map.join(data, how='outer')

map.plot('inflation', cmap='OrRd', scheme='quantiles', missing_kwds={"color": "lightgrey"}, legend=True, figsize=(14,5))
plt.title("Inflation 2019")
plt.show()
```

Resulting in the following output.

## What will we cover in this tutorial?

Introduction to the Pandas-Datareader, which is an invaluable way to get data from many sources, including the World Bank.

In this tutorial we will cover how to get the data from GDP per capita yearly data from countries and plot them.

## Step 1: Get to know World Bank as a data source

The World Bank was founded in 1944 to make loans to low-income countries, with the purpose to decrease poverty in the world (see wikipedia.org for further history).

What you might not know, World Bank has an amazing sets of data that you can either browse on their webpage or get access to directly in Python using the Pandas-Datareader.

We will take a look at how to extract the NY.GDP.PCAP.KD indicator.

The what?

I know. The GDP per capita (constant 2010 US\$), as it states on the webpage.

On that page you can get the GDP per capita for each country in the world back to 1960.

That is what we are going to do.

## Step 2: Get the data

Reading the Pandas-datareaders World Bank documentation you fall over the following function.

`pandas_datareader.wb.download`(country=Noneindicator=Nonestart=2003end=2005freq=Noneerrors=’warn’**kwargs)

Where you can set the country (or countries) and indicator your want:

• country (string or list of strings.) – `all` downloads data for all countries 2 or 3 character ISO country codes select individual countries (e.g.“US“,“CA“) or (e.g.“USA“,“CAN“). The codes can be mixed.The two ISO lists of countries, provided by wikipedia, are hardcoded into pandas as of 11/10/2014.
• indicator (string or list of strings) – taken from the `id` field in `WDIsearch()`

Luckily we already have our indicator from Step 1 (NY.GDP.PCAP.KD). Then we just need to find some countries of interest.

Let’s take United States, France, Great Britain, Denmark and Norway.

```from pandas_datareader import wb

dat = wb.download(indicator='NY.GDP.PCAP.KD', country=['US', 'FR', 'GB', 'DK', 'NO'], start=1960, end=2019)

print(dat)
```

Resulting in the following output.

```                    NY.GDP.PCAP.KD
country       year
Denmark       2019    65147.427182
2018    63915.468361
2017    62733.019808
2016    61877.976481
2015    60402.129248
...                            ...
United States 1964    19824.587845
1963    18999.888387
1962    18462.935998
1961    17671.150187
1960    17562.592084

[300 rows x 1 columns]
```

## Step 3: Visualize the data on a graph

We need to restructure the data in order to make a nice graph.

This can be done with unstack.

```from pandas_datareader import wb
import matplotlib.pyplot as plt

dat = wb.download(indicator='NY.GDP.PCAP.KD', country=['US', 'FR', 'GB', 'DK', 'NO'], start=1960, end=2019)

print(dat.unstack())
```

Which result in this output.

```               NY.GDP.PCAP.KD                ...
year                     1960          1961  ...          2018          2019
country                                      ...
Denmark          20537.549556  21695.609308  ...  63915.468361  65147.427182
France           12743.925100  13203.320855  ...  43720.026351  44317.392315
Norway           23167.441740  24426.011426  ...  92119.522964  92556.321645
United Kingdom   13934.029831  14198.673562  ...  43324.049759  43688.437455
United States    17562.592084  17671.150187  ...  54795.450086  55809.007792
```

If we transpose this and remove the double index frames that will come, then it should be good to make a plot with.

```from pandas_datareader import wb
import matplotlib.pyplot as plt

dat = wb.download(indicator='NY.GDP.PCAP.KD', country=['US', 'FR', 'GB', 'DK', 'NO'], start=1960, end=2019)

print(dat.unstack().T.reset_index(0))

dat.unstack().T.reset_index(0).plot()
plt.title('GDP per capita')
plt.show()
```

Giving this output, where you can see what the Transpose (T) does.

```country         level_0       Denmark  ...  United Kingdom  United States
year                                   ...
1960     NY.GDP.PCAP.KD  20537.549556  ...    13934.029831   17562.592084
1961     NY.GDP.PCAP.KD  21695.609308  ...    14198.673562   17671.150187
1962     NY.GDP.PCAP.KD  22747.292463  ...    14233.959944   18462.935998
1963     NY.GDP.PCAP.KD  22712.577808  ...    14816.480305   18999.888387
1964     NY.GDP.PCAP.KD  24620.461432  ...    15535.026991   19824.587845
1965     NY.GDP.PCAP.KD  25542.173921  ...    15766.195724   20831.299767
1966     NY.GDP.PCAP.KD  26032.378816  ...    15926.169851   21930.591173
1967     NY.GDP.PCAP.KD  27256.322071  ...    16282.026160   22235.415708
```

Giving the following output.

Continue the exploration in the following tutorial.

## What will we cover in this tutorial?

We will continue our journey to explore a big dataset of 145,000+ respondents to a RIASEC test. If you want to explore the full journey, we recommend you read this tutorial first.

In this tutorial we will find some data points that are not correct and a potential way to deal with it.

## Step 1: Explore the family sizes from the respondents

In the first tutorial we looked at how the respondent were distributed around the world. Surprisingly, most countries were represented.

In this we will explore the dataset further. The dataset is available here.

```import pandas as pd

# Only to get a broader summary
pd.set_option('display.max_rows', 300)
pd.set_option('display.max_columns', 30)
pd.set_option('display.width', 1000)

data = pd.read_csv('riasec.csv', delimiter='\t', low_memory=False)
print(data)
```

Which will output the following.

```        R1  R2  R3  R4  R5  R6  R7  R8  I1  I2  I3  I4  I5  I6  I7  ...  gender  engnat  age  hand  religion  orientation  race  voted  married  familysize  uniqueNetworkLocation  country  source                major  Unnamed: 93
0        3   4   3   1   1   4   1   3   5   5   4   3   4   5   4  ...       1       1   14     1         7            1     1      2        1           1                      1       US       2                  NaN          NaN
1        1   1   2   4   1   2   2   1   5   5   5   4   4   4   4  ...       1       1   29     1         7            3     4      1        2           3                      1       US       1              Nursing          NaN
2        2   1   1   1   1   1   1   1   4   1   1   1   1   1   1  ...       2       1   23     1         7            1     4      2        1           1                      1       US       1                  NaN          NaN
3        3   1   1   2   2   2   2   2   4   1   2   4   3   2   3  ...       2       2   17     1         0            1     1      2        1           1                      1       CN       0                  NaN          NaN
4        4   1   1   2   1   1   1   2   5   5   5   3   5   5   5  ...       2       2   18     1         4            3     1      2        1           4                      1       PH       0            education          NaN
```

If you use the slider, I got curious about how family sizes vary around the world. This dataset is obviously not representing any conclusive data on it, but it could be interesting to see if there is any connection to where you are located in the world and family size.

## Step 2: Explore the distribution of family sizes

What often happens in dataset is there might be inaccurate data.

To get a feeling of the data in the column familysize, you can explore it by running this.

```import pandas as pd

data = pd.read_csv('riasec.csv', delimiter='\t', low_memory=False)

print(data['familysize'].describe())
print(pd.cut(data['familysize'], bins=[0,1,2,3,4,5,6,7,10,100, 1000000000]).value_counts())
```

Resulting in the following from the describe output.

```count    1.458280e+05
mean     1.255801e+05
std      1.612271e+07
min      0.000000e+00
25%      2.000000e+00
50%      3.000000e+00
75%      3.000000e+00
max      2.147484e+09
Name: familysize, dtype: float64
```

Where the mean value of family size is 125,580. Well, maybe we don’t count family size the same way, but something is wrong there.

Grouping the data into bins (by using the cut function combined with value_count) you get this output.

```(1, 2]               51664
(2, 3]               38653
(3, 4]               18729
(0, 1]               15901
(4, 5]                8265
(5, 6]                3932
(6, 7]                1928
(7, 10]               1904
(10, 100]              520
(100, 1000000000]       23
Name: familysize, dtype: int64
```

Which indicates 23 families of size greater than 100. Let’s just investigate the sizes in that bucket.

```print(data[data['familysize'] > 100]['familysize'])
```

Giving us this output.

```1212      2147483647
3114      2147483647
5770      2147483647
8524             104
9701             103
21255     2147483647
24003            999
26247     2147483647
27782     2147483647
31451           9999
39294           9045
39298          84579
49033            900
54592            232
58773     2147483647
74745      999999999
78643            123
92457            999
95916            908
102680           666
109429           989
111488       9234785
120489          5000
120505     123456789
122580          5000
137141           394
139226          3425
140377           934
142870    2147483647
145686           377
145706           666
Name: familysize, dtype: int64
```

The integer 2147483647 is interesting as it is the maximum 32-bit positive integer. I think it is safe to say that most family sizes given above 100 are not realistic.

## Step 3: Clean the data

You need to make a decision on these data points that seem to skew your data in a wrong way.

Say, you just decide to visualize it without any adjustment, it would give a misrepresentative picture.

It seems like Iceland has a tradition for big families.

Let’s investigate that.

```print(data[data['country'] == 'IS']['familysize'])
```

Interestingly it give only one line that does not seem correct.

```74745     999999999
```

But as there are only a few respondents the average is the highest.

To clean the data fully, we can make the decision that family sizes above 10 are not correct. I know, that might be set a bit low and you can choose to do something different.

Cleaning the data is simple.

```data = data[data['familysize'] < 10]
```

Magic right? You simply write a conditional that will be vectorized down and only keep those rows of data that fulfill this condition.

## Step 4: Visualize the data

We will use geopandas, matplotlib and pycountry to visualize it. The process is similar to the one in previous tutorial where you can find more details.

```import geopandas
import pandas as pd
import matplotlib.pyplot as plt
import pycountry

# Helper function to map country names to alpha_3 representation - though some are not known by library
def lookup_country_code(country):
try:
return pycountry.countries.lookup(country).alpha_3
except LookupError:
return country

data = pd.read_csv('riasec.csv', delimiter='\t', low_memory=False)

data['alpha3'] = data.apply(lambda row: lookup_country_code(row['country']), axis=1)
data = data[data['familysize'] < 10]

country_mean = data.groupby(['alpha3']).mean()

map = world.merge(country_mean, how='left', left_on=['iso_a3'], right_on=['alpha3'])
map.plot('familysize', figsize=(12,4), legend=True)
plt.show()
```

Resulting in the following output.

Looks like there is a one-child policy in China? Again, do not make any conclusions on this data as it is very narrow of this aspect.

Read the next part here:

## What will we cover in this tutorial

We will explore a dataset with the Holland Code (RIASEC) Test, which is a test that should predict careers and vocational choices by rating questions.

In this part of the exploration, we first focus on loading the data and visualizing where the respondents come from. The dataset contains more than 145,000 responses.

## Step 1: First glance at the data

Let us first try to see what the data contains.

Reading the codebook (the file with the dataset) you see it contains ratings of questions of the 6 categories RIASEC. Then there are 3 elapsed times for the test.

There is a ratings of The Ten Item Personality Inventory. Then a self assessment whether they know 16 words. Finally, a list if metadata on them, like where the respondent network was located (which is a indicator on where the respondent was located in most cases).

Other metadata can be seen explained here.

```education			"How much education have you completed?", 1=Less than high school, 2=High school, 3=University degree, 4=Graduate degree
urban				"What type of area did you live when you were a child?", 1=Rural (country side), 2=Suburban, 3=Urban (town, city)
gender				"What is your gender?", 1=Male, 2=Female, 3=Other
engnat				"Is English your native language?", 1=Yes, 2=No
age					"How many years old are you?"
hand				"What hand do you use to write with?", 1=Right, 2=Left, 3=Both
religion			"What is your religion?", 1=Agnostic, 2=Atheist, 3=Buddhist, 4=Christian (Catholic), 5=Christian (Mormon), 6=Christian (Protestant), 7=Christian (Other), 8=Hindu, 9=Jewish, 10=Muslim, 11=Sikh, 12=Other
orientation			"What is your sexual orientation?", 1=Heterosexual, 2=Bisexual, 3=Homosexual, 4=Asexual, 5=Other
race				"What is your race?", 1=Asian, 2=Arab, 3=Black, 4=Indigenous Australian / Native American / White, 5=Other (There was a coding error in the survey, and three different options were given the same value)
voted				"Have you voted in a national election in the past year?", 1=Yes, 2=No
married				"What is your marital status?", 1=Never married, 2=Currently married, 3=Previously married
familysize			"Including you, how many children did your mother have?"
major				"If you attended a university, what was your major (e.g. "psychology", "English", "civil engineering")?"

These values were also calculated for technical information:

uniqueNetworkLocation	1 if the record is the only one from its network location in the dataset, 2 if there are more than one record. There can be more than one record from the same network if for example that network is shared by a school etc, or it may be because of test retakes
country	The country of the network the user connected from
source	1=from Google, 2=from an internal link on the website, 0=from any other website or could not be determined
```

## Step 2: Loading the data into a DataFrame (Pandas)

First step would be to load the data into a DataFrame. If you are new to Pandas DataFrame, we can recommend this tutorial.

```import pandas as pd

pd.set_option('display.max_rows', 300)
pd.set_option('display.max_columns', 10)
pd.set_option('display.width', 150)

data = pd.read_csv('riasec.csv', delimiter='\t', low_memory=False)

print(data)
```

The pd.set_option are only to help get are more rich output, compared to a very small and narrow summary. The actual loading of the data is done by pd.read_csv(…).

Notice that we have renamed the csv file to riasec.csv. As it is a tab-spaced csv, we need to parse that as an argument if it is not using the default comma.

The output from the above code is.

```        R1  R2  R3  R4  R5  ...  uniqueNetworkLocation  country  source                major  Unnamed: 93
0        3   4   3   1   1  ...                      1       US       2                  NaN          NaN
1        1   1   2   4   1  ...                      1       US       1              Nursing          NaN
2        2   1   1   1   1  ...                      1       US       1                  NaN          NaN
3        3   1   1   2   2  ...                      1       CN       0                  NaN          NaN
4        4   1   1   2   1  ...                      1       PH       0            education          NaN
...     ..  ..  ..  ..  ..  ...                    ...      ...     ...                  ...          ...
145823   2   1   1   1   1  ...                      1       US       1        Communication          NaN
145824   1   1   1   1   1  ...                      1       US       1              Biology          NaN
145825   1   1   1   1   1  ...                      1       US       2                  NaN          NaN
145826   3   4   4   5   2  ...                      2       US       0                  yes          NaN
145827   2   4   1   4   2  ...                      1       US       1  Information systems          NaN
```

Interestingly, the dataset contains an unnamed last column with no data. That is because it ends each line with a tab (\t) before new line (\n).

We could clean that up, but as we are only interested in the country counts, we will ignore it in this tutorial.

## Step 3: Count the occurrences of each country

As said, we are only interested in this first tutorial on this dataset to get an idea of where the respondents come from in the world.

The data is located in the ‘country’ column of the DataFrame data.

To group the data, you can use groupby(), which will return af DataFrameGroupBy object. If you apply a size() on that object, it will return a Series with sizes of each group.

```print(data.groupby(['country']).size())
```

Where the first few lines are.

```country
AE        507
AF          8
AG          7
AL        116
AM         10
```

Hence, for each country we will have a count of how many respondents came from that country.

## Step 4: Understand the map data we want to merge it with

To visualize the data, we need some way to have a map.

Here the GeoPandas comes in handy. It contains a nice low-res map of the world you can use.

Let’s just explore that.

```import geopandas
import matplotlib.pyplot as plt

world.plot()
plt.show()
```

Which will make the following map.

This is too easy to be true. No, not really. This is the reality of Python.

We want to merge the data from out world map above with the data of counts for each country.

We need to see how to merge it. To do that let us look at the data from world.

```world = geopandas.read_file(geopandas.datasets.get_path("naturalearth_lowres"))
print(world)
```

Where the first few lines are.

```        pop_est                continent                      name iso_a3   gdp_md_est                                           geometry
0        920938                  Oceania                      Fiji    FJI      8374.00  MULTIPOLYGON (((180.00000 -16.06713, 180.00000...
1      53950935                   Africa                  Tanzania    TZA    150600.00  POLYGON ((33.90371 -0.95000, 34.07262 -1.05982...
2        603253                   Africa                 W. Sahara    ESH       906.50  POLYGON ((-8.66559 27.65643, -8.66512 27.58948...
3      35623680            North America                    Canada    CAN   1674000.00  MULTIPOLYGON (((-122.84000 49.00000, -122.9742...
4     326625791            North America  United States of America    USA  18560000.00  MULTIPOLYGON (((-122.84000 49.00000, -120.0000...
```

First problem arises here. In the other dataset we have 2 letter country codes, in this one they use 3 letter country codes.

## Step 5: Solving the merging problem

Luckily we can use a library called PyCountry.

Let’s add this 3 letter country code to our first dataset by using a lambda function. A lambda? New to lambda function, we recommend you read the this tutorial.

```import pandas as pd
import pycountry

# Helper function to map country names to alpha_3 representation - though some are not known by library
def lookup_country_code(country):
try:
return pycountry.countries.lookup(country).alpha_3
except LookupError:
return country

data = pd.read_csv('riasec.csv', delimiter='\t', low_memory=False)

data['alpha3'] = data.apply(lambda row: lookup_country_code(row['country']), axis=1)
```

Basically, we add a new column to the dataset and call it ‘alpha3’ with the three letter country code. We use the function apply, which takes the lambda function that actually calls the function outside, which calls the library.

The reason to so, is that sometimes the pycountry.contries calls makes a lookup exception. We want our program to be robust to that.

Now the data contains a row with the countries in 3 letters like world.

We can now merge the data together. Remember that the data we want to merge needs to be adjusted to be counting on ‘alpha3’ and also we want to convert it to a DataFrame (as size() returns a Series).

```import geopandas
import pandas as pd
import pycountry

# Helper function to map country names to alpha_3 representation - though some are not known by library
def lookup_country_code(country):
try:
return pycountry.countries.lookup(country).alpha_3
except LookupError:
return country

data = pd.read_csv('riasec.csv', delimiter='\t', low_memory=False)
data['alpha3'] = data.apply(lambda row: lookup_country_code(row['country']), axis=1)

country_count = data.groupby(['alpha3']).size().to_frame()
country_count.columns = ['count']

map = world.merge(country_count, how='left', left_on=['iso_a3'], right_on=['alpha3'])
print(map)
```

The first few lines are given below.

```        pop_est                continent                      name iso_a3   gdp_md_est                                           geometry    count  \
0        920938                  Oceania                      Fiji    FJI      8374.00  MULTIPOLYGON (((180.00000 -16.06713, 180.00000...     12.0
1      53950935                   Africa                  Tanzania    TZA    150600.00  POLYGON ((33.90371 -0.95000, 34.07262 -1.05982...      9.0
2        603253                   Africa                 W. Sahara    ESH       906.50  POLYGON ((-8.66559 27.65643, -8.66512 27.58948...      NaN
3      35623680            North America                    Canada    CAN   1674000.00  MULTIPOLYGON (((-122.84000 49.00000, -122.9742...   7256.0
4     326625791            North America  United States of America    USA  18560000.00  MULTIPOLYGON (((-122.84000 49.00000, -120.0000...  80579.0
5      18556698                     Asia                Kazakhstan    KAZ    460700.00  POLYGON ((87.35997 49.21498, 86.59878 48.54918...     46.0
```

Notice, that some countries do not have a count. Those a countries with no respondent.

## Step 6: Ready to plot a world map

Now to the hard part, right?

Making a colorful map indicating the number of respondents in a given country.

```import geopandas
import pandas as pd
import matplotlib.pyplot as plt
import pycountry
import numpy as np

# Helper function to map country names to alpha_3 representation - though some are not known by library
def lookup_country_code(country):
try:
return pycountry.countries.lookup(country).alpha_3
except LookupError:
return country

data = pd.read_csv('riasec.csv', delimiter='\t', low_memory=False)
data['alpha3'] = data.apply(lambda row: lookup_country_code(row['country']), axis=1)

country_count = data.groupby(['alpha3']).size().to_frame()
country_count.columns = ['count']

map = world.merge(country_count, how='left', left_on=['iso_a3'], right_on=['alpha3'])
map.plot('count', figsize=(10,3), legend=True)
plt.show()
```

It is easy. Just call plot(…) with the first argument to be the column to use. I also change the default figsize, you can play around with that. Finally I add the legend.

Not really satisfying. The problem is that all counties, but USA, have almost identical colors. Looking at the data, you will see that it is because that there are so many respondents in USA that the countries are in the bottom of the scale.

What to do? Use a log-scale.

You can actually do that directly in your DataFrame. By using a NumPy library we can calculate a logarithmic scale.

See the magic.

```import geopandas
import pandas as pd
import matplotlib.pyplot as plt
import pycountry
import numpy as np

# Helper function to map country names to alpha_3 representation - though some are not known by library
def lookup_country_code(country):
try:
return pycountry.countries.lookup(country).alpha_3
except LookupError:
return country

data = pd.read_csv('riasec.csv', delimiter='\t', low_memory=False)
data['alpha3'] = data.apply(lambda row: lookup_country_code(row['country']), axis=1)

country_count = data.groupby(['alpha3']).size().to_frame()
country_count.columns = ['count']
country_count['log_count'] = np.log(country_count['count'])

map = world.merge(country_count, how='left', left_on=['iso_a3'], right_on=['alpha3'])
map.plot('log_count', figsize=(10,3), legend=True)
plt.show()
```

Where the new magic is to add the log_count and using np.log(country_count[‘count’]).

Also notice that the plot is now done on ‘log_count’.

Now you see more of a variety in the countries respondents. Note that the “white” countries did not have any respondent.

Read the next exploration of the dataset here.

## Background

According to wikipedia, the Sexual Compulsivity Scale (SCS) is a psychometric measure of high libido, hypersexuality, and sexual addiction. While it does not say anything about the score itself, it is based on people rating 10 questions from 1 to 4.

The questions are the following.

```Q1. My sexual appetite has gotten in the way of my relationships.
Q2. My sexual thoughts and behaviors are causing problems in my life.
Q3. My desires to have sex have disrupted my daily life.
Q4. I sometimes fail to meet my commitments and responsibilities because of my sexual behaviors.
Q5. I sometimes get so horny I could lose control.
Q6. I find myself thinking about sex while at work.
Q7. I feel that sexual thoughts and feelings are stronger than I am.
Q8. I have to struggle to control my sexual thoughts and behavior.
Q9. I think about sex more than I would like to.
Q10. It has been difficult for me to find sex partners who desire having sex as much as I want to.
```

The questions are rated as follows (1=Not at all like me, 2=Slightly like me, 3=Mainly like me, 4=Very much like me).

A dataset of more than 3300+ responses can be found here, which includes the individual rating of each questions, the total score (the sum of ratings), age and gender.

## Step 1: First inspection of the data.

The first question that pops into my mind is how men and women rate themselves differently. How can we efficiently figure that out?

Welcome to NumPy. It has a built-in csv reader that does all the hard work in the genfromtxt function.

```import numpy as np

data = np.genfromtxt('scs.csv', delimiter=',', dtype='int')

# Skip first row as it has description
data = data[1:]

men = data[data[:,11] == 1]
women = data[data[:,11] == 2]

print("Men average", men.mean(axis=0))
print("Women average", women.mean(axis=0))
```

Dividing into men and women is easy with NumPy, as you can make a vectorized conditional inside the dataset. Men are coded with 1 and women with 2 in column 11 (the 12th column). Finally, a call to mean will do the rest.

```Men average [ 2.30544662  2.2453159   2.23485839  1.92636166  2.17124183  3.06448802
2.19346405  2.28496732  2.43660131  2.54204793 23.40479303  1.
32.54074074]
Women average [ 2.30959164  2.18993352  2.19088319  1.95916429  2.38746439  3.13010446
2.18518519  2.2991453   2.4985755   2.43969611 23.58974359  2.
27.52611586]
```

Interestingly, according to this dataset (which should be accounted for accuracy, where 21% of answers were not used) women are scoring slighter higher SCS than men.

Men rate highest on the following question:

```Q6. I find myself thinking about sex while at work.
```

While women rate highest on this question.

```Q6. I find myself thinking about sex while at work.
```

The same. Also the lowest is the same for both genders.

```Q4. I sometimes fail to meet my commitments and responsibilities because of my sexual behaviors.
```

## Step 2: Visualize age vs score

I would guess that the SCS score decreases with age. Let’s see if that is the case.

Again, NumPy can do the magic easily. That is prepare the data. To visualize it we use matplotlib, which is a comprehensive library for creating static, animated, and interactive visualizations in Python.

```import numpy as np
import matplotlib.pyplot as plt

data = np.genfromtxt('scs.csv', delimiter=',', dtype='int')

# Skip first row as it has description
data = data[1:]

score = data[:,10]
age = data[:,12]
age[age > 100] = 0

plt.scatter(age, score, alpha=0.05)
plt.show()
```

Resulting in this plot.

It actually does not look like any correlation. Remember, there are more young people responding to the survey.

Let’s ask NumPy what it thinks about correlation here? Luckily we can do that by calling the corrcoef function, which calculates the Pearson product-moment correlation coefficients.

```print("Correlation of age and SCS score:", np.corrcoef(age, score))
```

Resulting in this output.

```Correlation of age and SCS score:
[[1.         0.01046882]
[0.01046882 1.        ]]
```

Saying no correlation, as 0.0 – 0.3 is a small correlation, hence, 0.01046882 is close to none. Does that mean the the SCS score does not correlate with age? That our SCS score is static through life?

I do not think we can conclude that based on this small dataset.

## Step 3: Bar plot the distribution of scores

It also looked like in the graph we plotted that there was a close to even distribution of scores.

Let’s try to see that. Here we need to sum participants by group. NumPy falls a bit short here. But let’s keep the good mood and use plain old Python lists.

```import numpy as np
import matplotlib.pyplot as plt

data = np.genfromtxt('scs.csv', delimiter=',', dtype='int')

# Skip first row as it has description
data = data[1:]

scores = []
numbers = []
for i in range(10, 41):
numbers.append(i)
scores.append(data[data[:, 10] == i].shape[0])

plt.bar(numbers, scores)
plt.show()
```

Resulting in this bar plot.

We knew that the average score was around 23, which could give a potential evenly distribution. But it seems to be a little lower in the far high end of SCS score.

For another great tutorial on NumPy check this one out, or learn some differences between NumPy and Pandas.

## What will you learn in this tutorial?

• Where to find interesting data contained in CSV files.
• How to extract a map to plot the data on.
• Use Python to easily plot the data from the CSV file no the map.

## Step 1: Collect the data in CSV format

You can find various interesting data in CSV format on data.world that you can play around with in Python.

In this tutorial we will focus on Shooting Incidents in NYPD from the last year. You can find the data on data.world.

Looking at the data you see that each incident has latitude and longitude coordinates.

```{'INCIDENT_KEY': '184659172', 'OCCUR_DATE': '06/30/2018 12:00:00 AM', 'OCCUR_TIME': '23:41:00', 'BORO': 'BROOKLYN', 'PRECINCT': '75', 'JURISDICTION_CODE': '0', 'LOCATION_DESC': 'PVT HOUSE                     ', 'STATISTICAL_MURDER_FLAG': 'false', 'PERP_AGE_GROUP': '', 'PERP_SEX': '', 'PERP_RACE': '', 'VIC_AGE_GROUP': '25-44', 'VIC_SEX': 'M', 'VIC_RACE': 'BLACK', 'X_COORD_CD': '1020263', 'Y_COORD_CD': '184219', 'Latitude': '40.672250312', 'Longitude': '-73.870176252'}
```

That means we can plot on a map. Let us try to do that.

## Step 2: Export a map to plot the data

We want to plot all the shooting incidents on a map. You can use OpenStreetMap to get an image of a map.

We want a map of New York, which you can find by locating it on OpenStreetMap or pressing the link.

You should press the blue Download in the low right corner of the picture.

Also, remember to get the coordinates of the image in the left side bar, we will need them for the plot.

```map_box = [-74.4461, -73.5123, 40.4166, 41.0359]
```

## Step 3: Writing the Python code that adds data to the map

Importing data from a CVS file is easy and can be done through the standard library csv. Making plot on a graph can be done in matplotlib. If you do not have it installed already, you can do that by typing the following in a command line (or see here).

```pip install matplotlib
```

First you need to transform the CVS data of the longitude and latitude to floats.

```import csv

# The name of the input file might need to be adjusted, or the location needs to be added if it is not located in the same folder as this file.
csv_file = open('nypd-shooting-incident-data-year-to-date-1.csv')
longitude = []
latitude = []
for row in csv_reader:
longitude.append(float(row['Longitude']))
latitude.append(float(row['Latitude']))
```

Now you have two lists (longitude and latitude), which contains the coordinates to plot.

Then for the actual plotting into the image.

```import matplotlib.pyplot as plt

# The boundaries of the image map
map_box = [-74.4461, -73.5123, 40.4166, 41.0359]

# The name of the image of the New York map might be different.

fig, ax = plt.subplots()
ax.scatter(longitude, latitude)
ax.set_ylim(map_box[2], map_box[3])
ax.set_xlim(map_box[0], map_box[1])
ax.imshow(map_img, extent=map_box, alpha=0.9)

plt.show()
```

This will result in the following beautiful map of New York, which highlights where the shooting in the last year has occurred.

Now that is awesome. If you want to learn more, this and more is covered in my online course. Check it out.

You can also read about how to plot the mood of tweets on a leaflet map.

## What will we cover in this article?

• What is Machine Learning and how it can help you?
• How does Machine Learning work?
• A first example of Linear Regression in Python

## Step 1: How can Machine Learning help you?

Machine Learning is a hot topic these days and it is easy to get confused when people talk about it. But what is Machine Learning and how can it you?

I found the following explanation quite good.

In the classical computing model every thing is programmed into the algorithms. This has the limitation that all decision logic need to be understood before usage. And if things change, we need to modify the program.

With the modern computing model (Machine Learning) this paradigm is changes. We feed the algorithms with data, and based on that data, we do the decisions in the program.

While this can seem abstract, this is a big change in thinking programming. Machine Learning has helped computers to have solutions to problems like:

• Improved search engine results.
• Voice recognition.
• Number plate recognition.
• Categorisation of pictures.
• …and the list goes on.

## Step 2: How does Machine Learning work?

I’m glad you asked. I was wondering about that myself.

On a high level you can divide Machine Learning into two phases.

• Phase 1: Learning
• Phase 2: Prediction

The Learning phase is divided into steps.

It all starts with a training set (training data). This data set should represent the type of data that the Machine Learn model should be used to predict from in Phase 2 (predction).

The pre-processing step is about cleaning up data. While the Machine Learning is awesome, it cannot figure out what good data looks like. You need to do the cleaning as well as transforming data into a desired format.

Then for the magic, the learning step. There are three main paradigms in machine learning.

• Supervised: where you tell the algorithm what categories each data item is in. Each data item from the training set is tagged with the right answer.
• Unsupervised: is when the learning algorithm is not told what to do with it and it should make the structure itself.
• Reinforcement: teaches the machine to think for itself based on past action rewards.

Finally, the testing is done to see if the model is good. The training data was divided into a test set and training set. The test set is used to see if the model can predict from it. If not, a new model might be necessary.

After that the Prediction Phase begins.

When the model has been created it will be used to predict based on it from new data.

## Step 3: For our first example of Linear Regression in Python

### Installing the libraries

Linear regression is a linear approach to modelling the relationship between a scalar response to one or more variables. In the case we try to model, we will do it for one single variable. Said in another way, we want map points on a graph to a line (y = a*x + b).

To do that, we need to import various libraries.

```# Importing matplotlib to make a plot
import matplotlib.pyplot as plt
# work with number as array
import numpy as np
# we want to use linear_model (that uses datasets)
from sklearn import linear_model
```

The matplotlib library is used to make a plot, but is a comprehensive library for creating static, animated, and interactive visualizations in Python. If you do not have it installed you can do that by typing in the following command in a terminal.

```pip install matplotlib
```

The numpy is a powerful library to calculate with N-dimensional arrays. If needed, you can install it by typing the following command in a terminal.

```pip install numpy
```

Finally, you need the linear_model from the sklearn library, which you can install by typing the following command in a terminal.

```pip install scikit-learn
```

### Training data set

This simple example will let you make a linear regression of an input of the following data set.

```# data set
prices = [245, 312, 279, 308, 199, 409, 200, 400, 230]
size = [50, 60, 35, 55, 30, 65, 30, 75, 25]
```

Here some items are sold, but each item has a size. The first item was sold for 245 (\$) and had a size of 50 (something). The next item was sold to 312 (\$) and had a size of 60 (something).

The sizes needs to be reshaped before we model it.

```# Importing matplotlib and numpy and sklearn
import matplotlib.pyplot as plt
# work with number as array
import numpy as np
# we want to use linear_model (that uses datasets)
from sklearn import linear_model

# data set
prices = [245, 312, 279, 308, 199, 409, 200, 400, 230]
size = [50, 60, 35, 55, 30, 65, 30, 75, 25]

# reshape the input for regression ( second argument how many items
size2 = np.array(size).reshape((-1, 1))
print(size2)
```

Which results in the following output.

```[[50]
[60]
[35]
[55]
[30]
[65]
[30]
[75]
[25]]
```

Hence, the reshape((-1, 1)) transforms it from a row to a single array.

Then for the linear regression.

```# Importing matplotlib and numpy and sklearn
import matplotlib.pyplot as plt
# work with number as array
import numpy as np
# we want to use linear_model (that uses datasets)
from sklearn import linear_model

# data set
prices = [245, 312, 279, 308, 199, 409, 200, 400, 230]
size = [50, 60, 35, 55, 30, 65, 30, 75, 25]

# reshape the input for regression ( second argument how many items
size2 = np.array(size).reshape((-1, 1))
print(size2)

regr = linear_model.LinearRegression()
regr.fit(size2, prices)
print("Coefficients", regr.coef_)
print("intercepts", regr.intercept_)
```

Which prints out the coefficient (a) and the intercept (b) of a formula y = a*x + b.

Now you can predict future prices, when given a size.

```# How to predict
size_new = 60
price = size_new * regr.coef_ + regr.intercept_
print(price)
print(regr.predict([[size_new]]))
```

Where you both can compute it directly (2nd line) or use the regression model (4th line).

Finally, you can plot the linear regression as a graph.

```# Importing matplotlib and numpy and sklearn
import matplotlib.pyplot as plt
# work with number as array
import numpy as np
# we want to use linear_model (that uses datasets)
from sklearn import linear_model

# data set
prices = [245, 312, 279, 308, 199, 409, 200, 400, 230]
size = [50, 60, 35, 55, 30, 65, 30, 75, 25]

# reshape the input for regression ( second argument how many items
size2 = np.array(size).reshape((-1, 1))
print(size2)

regr = linear_model.LinearRegression()
regr.fit(size2, prices)

# Here we plot the graph
x = np.array(range(20, 100))
y = eval('regr.coef_*x + regr.intercept_')
plt.plot(x, y)
plt.scatter(size, prices, color='black')
plt.ylabel('prices')
plt.xlabel('size')
plt.show()
```

Which results in the following graph.

## Conclusion

This is obviously a simple example of linear regression, as it only has one variable. This simple example shows you how to setup the environment in Python and how to make a simple plot.