Unit 2.3 Extracting Information from Data, Pandas
2.3 Unit
- Pandas and DataFrames Notes
- Cleaning Data
- Extracting Info
- Create your own DataFrame
- Example of larger data set
- APIs are a Source for Writing Programs with Data
- Hacks
'''Pandas is used to gather data sets through its DataFrames implementation'''
import pandas as pd
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Pandas is a popular Python library that enables you to work with data more efficiently. One of the key features of Pandas is its ability to create dataframes, which are similar to tables in SQL and store data along with metadata. With Pandas, you can work with both data and metadata in a seamless manner, making it easier for you to manipulate and analyze large datasets.
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A great benefit of using Pandas is that it allows you to create your own custom dataframes in Python, providing you with the flexibility to tailor your data analysis needs to your specific project requirements. Additionally, Pandas provides a range of tools for cleaning and manipulating data. For instance, common issues that can lead to errors, such as missing or duplicate data, can be easily identified and addressed with the help of Pandas.
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In addition to cleaning data, Pandas also provides functionality for extracting information from dataframes. You can extract specific columns of data from a dataframe, and use the index to count the amount of datapoints in a given column. Moreover, you can use the "print df" function to display data related to the data in a referenced dataframe. Another way to filter data is through dataframe selection, which enables you to use logical operations like Demorgans law to select data that meets certain criteria.
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Another useful feature of Pandas is the ability to view the front or back of a dataset with the "head" and "tail" functions. The head function displays the first few rows of data, while the tail function displays the last few rows.
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Lastly, APIs can be a valuable source for writing programs with data. Pandas provides functionality to access and manipulate data from APIs, allowing you to integrate external data sources into your data analysis. In summary, Pandas is a powerful library that provides many tools and functions for working with data and metadata, making it a valuable asset for data analysis and manipulation.
df = pd.read_json('../_notebooks/grade.json')
print(df)
# What part of the data set needs to be cleaned?
# From PBL learning, what is a good time to clean data? Hint, remember Garbage in, Garbage out?
print(df[['GPA']])
print()
#try two columns and remove the index from print statement
print(df[['Student ID','GPA','Year in School']].to_string(index=False))
print(df.sort_values(by=['GPA']))
print()
#sort the values in reverse order
print(df.sort_values(by=['GPA'], ascending=False))
print(df[df.GPA > 3.00])
print(df[df.GPA == df.GPA.max()])
print()
print(df[df.GPA == df.GPA.min()])
import pandas as pd
#the data can be stored as a python dictionary
dict = {
"calories": [420, 380, 390],
"duration": [50, 40, 45]
}
#stores the data in a data frame
print("-------------Dict_to_DF------------------")
df = pd.DataFrame(dict)
print(df)
print("----------Dict_to_DF_labels--------------")
#or with the index argument, you can label rows.
df = pd.DataFrame(dict, index = ["day1", "day2", "day3"])
print(df)
print("-------Examine Selected Rows---------")
#use a list for multiple labels:
print(df.loc[["day1", "day3"]])
#refer to the row index:
print("--------Examine Single Row-----------")
print(df.loc["day1"])
print(df.info())
import pandas as pd
#read csv and sort 'Duration' largest to smallest
df = pd.read_csv('../_notebooks/data.csv').sort_values(by=['Duration'], ascending=False)
print("--Duration Top 10---------")
print(df.head(10))
print("--Duration Bottom 10------")
print(df.tail(10))
'''Pandas can be used to analyze data'''
import pandas as pd
import requests
def fetch():
'''Obtain data from an endpoint'''
url = "https://flask.nighthawkcodingsociety.com/api/covid/"
fetch = requests.get(url)
json = fetch.json()
# filter data for requirement
df = pd.DataFrame(json['countries_stat']) # filter endpoint for country stats
print(df.loc[0:5, 'country_name':'deaths']) # show row 0 through 5 and columns country_name through deaths
fetch()
Hacks
Early Seed award
- Add this Blog to you own Blogging site.
- Have all lecture files saved to your files directory before Tech Talk starts. Have data.csv open in vscode. Don't tell anyone. Show to Teacher.
AP Prep
- Add this Blog to you own Blogging site. In the Blog add notes and observations on each code cell.
- In blog add College Board practice problems for 2.3.
The next 4 weeks, Teachers want you to improve your understanding of data. Look at the blog and others on Unit 2. Your intention is to find some things to differentiate your individual College Board project.
- Create or Find your own dataset. The suggestion is to use a JSON file, integrating with your PBL project would be Fambulous.
When choosing a data set, think about the following:- Does it have a good sample size? - Is there bias in the data?
- Does the data set need to be cleaned?
- What is the purpose of the data set?
- ...
- Continue this Blog using Pandas extract info from that dataset (ex. max, min, mean, median, mode, etc.)
import pandas as pd
# Create a data table using pandas of top track times
data = {
'Name': ['Liav', 'Safin', 'Adi', 'Arnav', 'Taiyo'],
'Age': [17, 17, 17, 18, 16],
'Weight': [130, 130, 130, 130, 120],
'Height': [180, 165, 175, 160, 190],
'Event': [100, 200, 100, 3200, 1600],
'PR': [11.2, 23.4, 10.5, 618, 270]
}
df = pd.DataFrame(data)
# Display the dataset
print(df)
print('Etracker User Data:')
# Calculate some basic statistics
print('Age:')
age_stats = {'Max': df['Age'].max(),
'Min': df['Age'].min(),
'Mean': df['Age'].mean(),
'Median': df['Age'].median(),
'Mode': df['Age'].mode()[0]}
for stat, value in age_stats.items():
print(f'User {stat} age: {value}')
print('Weight:')
weight_stats = {'Max': df['Weight'].max(),
'Min': df['Weight'].min(),
'Mean': df['Weight'].mean(),
'Median': df['Weight'].median(),
'Mode': df['Weight'].mode()[0]}
for stat, value in weight_stats.items():
print(f'User {stat} Weight: {value}')
print('Height:')
height_stats = {'Max': df['Height'].max(),
'Min': df['Height'].min(),
'Mean': df['Height'].mean(),
'Median': df['Height'].median(),
'Mode': df['Height'].mode()[0]}
for stat, value in height_stats.items():
print(f'User {stat} Height: {value}')
print('Event:')
event_stats = {'Max': df['Event'].max(),
'Min': df['Event'].min(),
}
for stat, value in event_stats.items():
print(f'User {stat} Event: {value}')
Hack Helpers
Here is how Mort started on this assignment by asking ChatGPT ... Regarding Python Pandas, what are some data sets that would be good for learning Pandas?
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There are many data sets that are suitable for learning pandas, depending on your interests and the skills you want to develop. Here are some suggestions:- Titanic Dataset: This is a classic dataset for data analysis and machine learning, and is often used as an introduction to pandas. The dataset contains information about passengers on the Titanic, including their demographics, ticket class, and survival status.
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Iris Dataset: This is another classic dataset that is often used in machine learning and data analysis courses. The dataset contains information about iris flowers, including their sepal length, sepal width, petal length, and petal width.
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NBA Player Stats: This dataset contains information about NBA players, including their stats for various games, their positions, and their salaries. It is a great dataset for learning how to clean and manipulate data using pandas.
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Housing Prices Dataset: This dataset contains information about housing prices in a particular city or region, including variables such as the number of bedrooms, square footage, and price. It is a great dataset for learning how to manipulate and analyze numerical data using pandas.
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COVID-19 Dataset: This dataset contains information about the COVID-19 pandemic, including the number of cases, deaths, and recoveries in various countries and regions. It is a great dataset for learning how to manipulate and analyze time-series data using pandas.
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World Bank Dataset: This dataset contains information about economic indicators from various countries, such as GDP, population, and poverty rates. It is a great dataset for learning how to manipulate and analyze large datasets using pandas.
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These are just a few examples of the many datasets that are suitable for learning pandas. The best dataset for you will depend on your interests and the specific skills you want to develop.
Follow up question, "where can I find Titanic data set?"
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The Titanic dataset is a popular dataset for data analysis and machine learning, and it can be found on various websites and data repositories. Here are a few places where you can find the Titanic dataset:- Kaggle: The Titanic dataset is available on Kaggle, which is a popular platform for data scientists and machine learning enthusiasts. You can download the dataset from the Kaggle website after creating an account.
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UCI Machine Learning Repository: The Titanic dataset is also available on the UCI Machine Learning Repository, which is a collection of datasets that are commonly used for machine learning research. You can download the dataset from the UCI Machine Learning Repository website.
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Seaborn library: If you have the Seaborn library installed in your Python environment, you can load the Titanic dataset directly from the library using the following code:
import seaborn as sns titanic_data = sns.load_dataset('titanic')
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import seaborn as sns
# Load the titanic dataset
titanic_data = sns.load_dataset('titanic')
print("Titanic Data")
print(titanic_data.columns) # titanic data set
print(titanic_data[['survived','pclass', 'sex', 'age', 'sibsp', 'parch', 'class', 'fare', 'embark_town']]) # look at selected columns
Use Pandas to clean the data. Most analysis, like Machine Learning or even Pandas in general like data to be in standardized format. This is called 'Training' or 'Cleaning' data.
from sklearn.preprocessing import OneHotEncoder
td = titanic_data
td.drop(['alive', 'who', 'adult_male', 'class', 'embark_town', 'deck'], axis=1, inplace=True)
td.dropna(inplace=True)
td['sex'] = td['sex'].apply(lambda x: 1 if x == 'male' else 0)
td['alone'] = td['alone'].apply(lambda x: 1 if x == True else 0)
# Encode categorical variables
enc = OneHotEncoder(handle_unknown='ignore')
enc.fit(td[['embarked']])
onehot = enc.transform(td[['embarked']]).toarray()
cols = ['embarked_' + val for val in enc.categories_[0]]
td[cols] = pd.DataFrame(onehot)
td.drop(['embarked'], axis=1, inplace=True)
td.dropna(inplace=True)
print(td)
The result of 'Training' data is making it easier to analyze or make conclusions. In looking at the Titanic, as you clean you would probably want to make assumptions on likely chance of survival.
This would involve analyzing various factors (such as age, gender, class, etc.) that may have affected a person's chances of survival, and using that information to make predictions about whether an individual would have survived or not.
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Data description:- Survival - Survival (0 = No; 1 = Yes). Not included in test.csv file. - Pclass - Passenger Class (1 = 1st; 2 = 2nd; 3 = 3rd)
- Name - Name
- Sex - Sex
- Age - Age
- Sibsp - Number of Siblings/Spouses Aboard
- Parch - Number of Parents/Children Aboard
- Ticket - Ticket Number
- Fare - Passenger Fare
- Cabin - Cabin
- Embarked - Port of Embarkation (C = Cherbourg; Q = Queenstown; S = Southampton)
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Perished Mean/Average
print(titanic_data.query("survived == 0").mean())
- Survived Mean/Average
print(td.query("survived == 1").mean())
Survived Max and Min Stats
print(td.query("survived == 1").max())
print(td.query("survived == 1").min())
Machine Learning
From Tutorials Point%20is,a%20consistence%20interface%20in%20Python). Scikit-learn (Sklearn) is the most useful and robust library for machine learning in Python. It provides a selection of efficient tools for machine learning and statistical modeling including classification, regression, clustering and dimensionality reduction via a consistence interface in Python.> Description from ChatGPT. The Titanic dataset is a popular dataset for data analysis and machine learning. In the context of machine learning, accuracy refers to the percentage of correctly classified instances in a set of predictions. In this case, the testing data is a subset of the original Titanic dataset that the decision tree model has not seen during training......After training the decision tree model on the training data, we can evaluate its performance on the testing data by making predictions on the testing data and comparing them to the actual outcomes. The accuracy of the decision tree classifier on the testing data tells us how well the model generalizes to new data that it hasn't seen before......For example, if the accuracy of the decision tree classifier on the testing data is 0.8 (or 80%), this means that 80% of the predictions made by the model on the testing data were correct....Chance of survival could be done using various machine learning techniques, including decision trees, logistic regression, or support vector machines, among others.
- Code Below prepares data for further analysis and provides an Accuracy. IMO, you would insert a new passenger and predict survival. Datasets could be used on various factors like prediction if a player will hit a Home Run, or a Stock will go up or down.
- Decision Trees, prediction by a piecewise constant approximation. - Logistic Regression, the probabilities describing the possible outcomes.
from sklearn.model_selection import train_test_split
from sklearn.tree import DecisionTreeClassifier
from sklearn.linear_model import LogisticRegression
from sklearn.metrics import accuracy_score
# Split arrays or matrices into random train and test subsets.
X = td.drop('survived', axis=1)
y = td['survived']
X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.3, random_state=42)
# Train a decision tree classifier
dt = DecisionTreeClassifier()
dt.fit(X_train, y_train)
# Test the model
y_pred = dt.predict(X_test)
accuracy = accuracy_score(y_test, y_pred)
print('DecisionTreeClassifier Accuracy:', accuracy)
# Train a logistic regression model
logreg = LogisticRegression()
logreg.fit(X_train, y_train)
# Test the model
y_pred = logreg.predict(X_test)
accuracy = accuracy_score(y_test, y_pred)
print('LogisticRegression Accuracy:', accuracy)