Linear Regression is a key data science tool for predicting continuous outcomes. This guide explains its principles, uses, and how to implement it in Python with real data. It covers simple and multiple linear regression, highlighting their importance, limitations, and practical examples.

In this article, we will explore what linear regression is, focusing on simple linear regression and its significance in linear regression statistics. We’ll also discuss the linear regression model and its applications in machine learning, providing a comprehensive explanation of linear regression in machine learning.

- Understand the principles and applications of linear regression.
- Differentiate between simple and multiple linear regression.
- Learn how to implement Simple linear regression in Python.
- Grasp the concept of gradient descent and its use in optimizing linear regression.
- Explore evaluation metrics for assessing regression models.
- Recognize the assumptions and potential pitfalls, such as overfitting and multicollinearity, in linear regression.

*This article was published as a part of the **Data Science Blogathon**.*

- What is Linear Regression?
- Simple Linear Regression
- What is the Best Fit Line?
- Cost Function for Linear Regression
- Gradient Descent for Linear Regression
- Why Linear Regression is Important?
- Evaluation Metrics for Linear Regression
- Assumptions of Linear Regression
- Hypothesis in Linear Regression
- Multiple Linear Regression
- Considerations of Multiple Linear Regression
- Multicollinearity
- Overfitting and Underfitting in Linear Regression
- Bias Variance Tradeoff
- Overfitting
- Underfitting
- Hands-on Coding: Linear Regression Model
- Conclusion
- Frequently Asked Questions

Linear regression predicts the relationship between two variables by assuming they have a straight-line connection. It finds the best line that minimizes the differences between predicted and actual values. Used in fields like economics and finance, it helps analyze and forecast data trends. Linear **regression** can also involve several variables (multiple linear regression) or be adapted for yes/no questions (logistic regression).

In a simple linear regression, there is one independent variable and one dependent variable. The model estimates the slope and intercept of the line of best fit, which represents the relationship between the variables. The slope represents the change in the dependent variable for each unit change in the independent variable, while the intercept represents the predicted value of the dependent variable when the independent variable is zero.

Linear regression is a quiet and the simplest statistical regression technique used for predictive analysis in machine learning. It shows the linear relationship between the independent(predictor) variable i.e. X-axis and the dependent (output) variable i.e. Y-axis, called linear regression. If there is a single input variable X (independent variable), such linear regression is ** simple linear regression**.

The graph above presents the linear relationship between the output(y) and predictor(X) variables. The blue line is referred to as the best-fit straight line. Based on the given data points, we attempt to plot a line that fits the points the best.

To calculate best-fit line linear regression uses a traditional slope-intercept form which is given below,

**Y i = β 0 + β 1 X i **

where Y i = Dependent variable, **β 0 ** = constant/Intercept, **β 1 ** = Slope/Intercept, **X i ** = Independent variable.

This algorithm explains the linear relationship between the dependent(output) variable y and the independent(predictor) variable X using a straight line Y= B 0 + B 1 X.

But how does the regression find out which is the best-fit line?

The goal of the linear regression algorithm is to get the **best values for B 0 and B 1** to find the best-fit line. The best-fit line is a line that has the least error which means the error between predicted values and actual values should be minimum.

But how the linear regression finds out which is the best fit line?

The goal of the linear regression algorithm is to get the **best values for B _{0} and B_{1}** to find the best fit line. The best fit line is a line that has the least error which means the error between predicted values and actual values should be minimum.

In regression, the difference between the observed value of the dependent variable(**y i **) and the predicted value(**predicted**) is called the residuals.

**ε i = ** **y predicted ** – **y i**

**where y predicted = B 0 + B 1 X i**

In simple terms, the best-fit line is a line that best fits the given scatter plot. Mathematically, you obtain the best-fit line by minimizing the Residual Sum of Squares (RSS).

The **cost function** helps to work out the optimal values for B 0 and B 1 , which provides the best-fit line for the data points.

In Linear Regression, generally **Mean Squared Error (MSE)** cost function is used, which is the average squared error that occurred between the **y predicted **and **y i**.

We calculate MSE using the simple linear equation y=mx+b:

Using the MSE function, we’ll update the values of B 0 and B 1 such that the MSE value settles at the minima. These parameters can be determined using the gradient descent method such that the value for the cost function is minimum.

Gradient Descent is one of the optimization algorithms that optimize the cost function (objective function) to reach the optimal minimal solution. To find the optimum solution, we need to reduce the cost function (MSE) for all data points. This is done by updating the values of the slope coefficient (B1) and the constant coefficient (B0) iteratively until we get an optimal solution for the linear function.

A regression model optimizes the gradient descent algorithm to update the coefficients of the line by reducing the cost function by randomly selecting coefficient values and then iteratively updating the coefficient values to reach the minimum cost function.

Let’s take an example to understand this. Imagine a U-shaped pit. You are standing at the uppermost point in the pit, and your motive is to reach the bottom of the pit. Suppose there is a treasure at the bottom of the pit, and you can only take a discrete number of steps to reach the bottom. If you opted to take one step at a time, you would get to the bottom of the pit in the end but, this would take a longer time. If you decide to take larger steps each time, you may achieve the bottom sooner but, there’s a probability that you could overshoot the bottom of the pit and not even near the bottom. In the gradient descent algorithm, the number of steps you’re taking can be considered as the **learning rate**, and this decides how fast the algorithm **converges** to the minima.

To update B 0 and B 1, we take gradients from the cost function. To find these gradients, we take partial derivatives for B 0 and B 1.

We need to minimize the cost function J. One of the ways to achieve this is to apply the batch gradient descent algorithm. In batch gradient descent, the values are updated in each iteration. (The last two equations show the updating of values)

The partial derivates are the gradients, and they are used to update the values of B 0 and B 1. Alpha is the learning rate.

Linear regression is important for a few reasons:

**Simplicity and interpretability:**It’s a relatively easy concept to understand and apply. The resulting simple linear regression model is a straightforward equation that shows how one variable affects another. This makes it easier to explain and trust the results compared to more complex models.**Prediction:**Linear regression allows you to predict future values based on existing data. For instance, you can use it to predict sales based on marketing spend or house prices based on square footage.**Foundation for other techniques:**It serves as a building block for many other data science and machine learning methods. Even complex algorithms often rely on linear regression as a starting point or for comparison purposes.**Widespread applicability:**Linear regression can be used in various fields, from finance and economics to science and social sciences. It’s a versatile tool for uncovering relationships between variables in many real-world scenarios.

In essence, linear regression provides a solid foundation for understanding data and making predictions. It’s a cornerstone technique that paves the way for more advanced data analysis methods.

The strength of any linear regression model can be assessed using various evaluation metrics. These evaluation metrics usually provide a measure of how well the observed outputs are being generated by the model.

The most used metrics are,

- Coefficient of Determination or R-squared (R2)
- Root Mean Squared Error (RSME) and Residual Standard Error (RSE)

R-squared is a number that explains the amount of variation that is explained/captured by the developed model. It always ranges between 0 & 1 . Overall, the higher the value of R-squared, the better the model fits the data.

Mathematically it can be represented as,

** R ^{2} = 1 – ( RSS/TSS ) **

**Residual sum of Squares (RSS)**is defined as the sum of squares of the residual for each data point in the plot/data. It is the measure of the difference between the expected and the actual observed output.

**Total Sum of Squares (TSS)**is defined as the sum of errors of the data points from the mean of the response variable. Mathematically TSS is,

where y hat is the mean of the sample data points.

The significance of R-squared is shown by the following figures,

The Root Mean Squared Error is the square root of the variance of the residuals. It specifies the absolute fit of the model to the data i.e. how close the observed data points are to the predicted values. Mathematically it can be represented as,

To make this estimate unbiased, one has to divide the sum of the squared residuals by the **degrees of freedom** rather than the total number of data points in the model. This term is then called the **Residual Standard Error(RSE)**. Mathematically it can be represented as,

R-squared is a better measure than RSME. Because the value of Root Mean Squared Error depends on the units of the variables (i.e. it is not a normalized measure), it can change with the change in the unit of the variables.

Regression is a parametric approach, which means that it makes assumptions about the data for analysis. For successful regression analysis, it’s essential to validate the following assumptions.

**Linearity of residuals**: There needs to be a linear relationship between the dependent variable and independent variable(s).

**Independence of residuals:**The error terms should not be dependent on one another (like in time-series data wherein the next value is dependent on the previous one). There should be no correlation between the residual terms. The absence of this phenomenon is known as**Autocorrelation.**

There should not be any visible patterns in the error terms.

**Normal distribution of residuals:**The mean of residuals should follow a normal distribution with a mean equal to zero or close to zero. This is done to check whether the selected line is the line of best fit or not. If the error terms are non-normally distributed, suggests that there are a few unusual data points that must be studied closely to make a better model.

**4. The equal variance of residuals:** The error terms must have constant variance. This phenomenon is known as **Homoscedasticity**. The presence of non-constant variance in the error terms is referred to as **Heteroscedasticity**. Generally, non-constant variance arises in the presence of *outliers or extreme leverage values*.

Once you have fitted a straight line on the data, you need to ask, “**Is this straight line a significant fit for the data?**” Or “I**s the** **beta coefficient explain the variance in the data plotted?” **And here comes the idea of **hypothesis testing** on the beta coefficient. The Null and Alternate hypotheses in this case are:

H 0 : B 1 = 0

H A : B 1 **≠** 0

To test this hypothesis we use a **t-test, **test statistics for the beta coefficient is given by,

Some other parameters to assess a model are:

**t statistic:**It is used to determine the p-value and hence, helps in determining whether the coefficient is significant or not**F statistic**: It is used to assess whether the overall model fit is significant or not. Generally, the higher the value of the F-statistic, the more significant a model turns out to be.

Multiple linear regression is a technique to understand the relationship between a *single *dependent variable and *multiple *independent variables.

The formulation for multiple linear regression is also similar to simple linear regression with

the small change that instead of having one beta variable, you will now have betas for all the variables used. The formula is given as:

Y = B_{0} + B_{1}X_{1} + B_{2}X_{2} + … + B_{p}X_{p} + **ε**

All four assumptions made for Simple Linear Regression still hold for Multiple Linear Regression along with a few new additional assumptions.

**Overfitting**: When more and more variables are added to a model, the model may become far too complex and usually ends up memorizing all the data points in the training set. This phenomenon is known as the overfitting of a model. This usually leads to high training accuracy and very low test accuracy.**Multicollinearity**: It is the phenomenon where a model with several independent variables, may have some variables interrelated.**Feature Selection:**With more variables present, selecting the optimal set of predictors from the pool of given features (many of which might be redundant) becomes an important task for building a relevant and better model.

As multicollinearity makes it difficult to find out which variable is contributing towards the prediction of the response variable, it leads one to conclude incorrectly, the effects of a variable on the target variable. Though it does not affect the precision of the model predictions, it is essential to properly detect and deal with the multicollinearity present in the model, as random removal of any of these correlated variables from the model causes the coefficient values to swing wildly and even change signs.

Multicollinearity can be detected using the following methods.

**Pairwise Correlations:**Checking the pairwise correlations between different pairs of independent variables can throw useful insights into detecting multicollinearity.**Variance Inflation Factor (VIF):**Pairwise correlations may not always be useful as it is possible that just one variable might not be able to completely explain some other variable but some of the variables combined could be ready to do this. Thus, to check these sorts of relations between variables, one can use VIF. VIF explains the relationship of one independent variable with all the other independent variables. VIF is given by,

where *i* refers to the* i*^{th} variable which is being represented as a linear combination of the rest of the independent variables.

The common heuristic followed for the VIF values is if VIF > 10 then the value is high and it should be dropped. And if the VIF=5 then it may be valid but should be inspected first. If VIF < 5, then it is considered a good VIF value.

There have always been situations where a model performs well on training data but not on the test data. While training models on a dataset, overfitting, and underfitting are the most common problems faced by people.

Before understanding overfitting and underfitting one must know about bias and variance.

Bias is a measure to determine how accurate a model’s predictions are likely to be on future unseen data. Complex models, assuming there is enough training data available, can make accurate model predictions. Whereas the models that are too naive, are very likely to perform badly concerning model predictions. Simply, Bias is errors made by training data.

Generally, linear algorithms have a high bias which makes them fast to learn and easier to understand but in general, are less flexible. Implying lower predictive performance on complex problems that fail to meet the expected outcomes.

Variance is the sensitivity of the model towards training data, that is it quantifies how much the model will react when input data is changed.

Ideally, the model shouldn’t change too much from one training dataset to the next training data, which means that the algorithm is good at picking out the hidden underlying patterns between the inputs and the output variables.

Ideally, a model should have lower variance which means that the model doesn’t change drastically after changing the training data(it is generalizable). Having higher variance will make a model change drastically even on a small change in the training dataset.

Let’s understand what a bias-variance tradeoff is.

In the pursuit of optimal performance, a supervised machine learning algorithm seeks to strike a balance between low bias and low variance for increased robustness.

In the realm of machine learning, there exists an inherent relationship between bias and variance, characterized by an inverse correlation.

- Increased bias leads to reduced variance.
- Conversely, heightened variance results in diminished bias.

Finding an equilibrium between bias and variance is crucial, and algorithms must navigate this trade-off for optimal outcomes.

In practice, calculating precise bias and variance error terms is challenging due to the unknown nature of the underlying target function.

Now, let’s delve into the nuances of overfitting and underfitting.

When a model learns every pattern and noise in the data to such an extent that it affects the performance of the model on the unseen future dataset, it is referred to as ** overfitting**. The model fits the data so well that it interprets noise as patterns in the data.

When a model has low bias and higher variance it ends up memorizing the data and causing overfitting. Overfitting causes the model to become specific rather than generic. This usually leads to high training accuracy and very low test accuracy.

Detecting overfitting is useful, but it doesn’t solve the actual problem. There are several ways to prevent overfitting, which are stated below:

- Cross-validation
- If the training data is too small to train add more relevant and clean data.
- If the training data is too large, do some feature selection and remove unnecessary features.
- Regularization

Underfitting is not often discussed as often as overfitting is discussed. When the model fails to learn from the training dataset and is also not able to generalize the test dataset, is referred to as ** underfitting**. This type of problem can be very easily detected by the performance metrics.

When a model has high bias and low variance it ends up not generalizing the data and causing underfitting. It is unable to find the hidden underlying patterns in the data. This usually leads to low training accuracy and very low test accuracy. The ways to prevent underfitting are stated below,

- Increase the model complexity
- Increase the number of features in the training data
- Remove noise from the data.

This is the section where you’ll find out how to perform the regression in Python. We will use *Advertising sales channel prediction data. You can access the data **here**.*

TV | Radio | Newspaper | Sales |

230.1 | 37.8 | 69.2 | 22.1 |

44.5 | 39.3 | 45.1 | 10.4 |

17.2 | 45.9 | 69.3 | 12.0 |

151.5 | 41.3 | 58.5 | 16.5 |

180.8 | 10.8 | 58.4 | 17.9 |

8.7 | 48.9 | 75.0 | 7.2 |

57.5 | 32.8 | 23.5 | 11.8 |

**‘Sales’ **is the target variable that needs to be predicted. Now, based on this data, our objective is to create a predictive model, that predicts sales based on the money spent on different platforms for marketing.

Let us straightaway get right down to some hands-on coding to get this prediction done. Please don’t feel overlooked if you do not have experience with Python. The best way to learn is to get your hands dirty by solving a problem – like the one we are doing.

The first step is to fire up your Jupyter notebook and load all the prerequisite libraries in your Jupyter notebook. Here are the important libraries that we will be needing for this linear regression.

**NumPy**(to perform certain mathematical operations)**pandas**(to storethe data in a pandas DataFrames)**matplotlib.pyplot**(you will use matplotlib to plot the data)

In order to load these, just start with these few lines of codes in your first cell:

```
#Importing all the necessary libraries
import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
# Supress Warnings
import warnings
warnings.filterwarnings('ignore')
```

The last line of code helps in suppressing the unnecessary warnings.

Let us now import data into a DataFrame. A DataFrame is a data type in Python. The simplest way to understand it would be that it stores all your data in tabular format.

```
#Read the given CSV file, and view some sample records
advertising = pd.read_csv( "advertising.csv" )
advertising.head()
```

Let us plot the scatter plot for target variable vs. predictor variables in a single plot to get the intuition. Also, plotting a heatmap for all the variables,

```
#Importing seaborn library for visualizations
import seaborn as sns
```

```
#to plot all the scatterplots in a single plot
sns.pairplot(advertising, x_vars=[ 'TV', ' Newspaper.,'Radio' ], y_vars = 'Sales', size = 4, kind = 'scatter' )
plt.show()
```

```
#To plot heatmap to find out correlations
sns.heamap( advertising.corr(), cmap = 'YlGnBl', annot = True )
plt.show()
```

From the scatterplot and the heatmap, we can observe that ‘Sales’ and ‘TV’ have a higher correlation as compared to others because it shows a linear pattern in the scatterplot as well as giving 0.9 correlation.

You can go ahead and play with the visualizations and can find out interesting insights from the data.

Here, as the TV and Sales have a higher correlation we will perform the simple linear regression for these variables.

We can use sklearn or statsmodels to apply linear regression. So we will go ahead with **statmodels**.

We first assign the feature variable, `TV`, during this case, to the variable `X` and the response variable, `Sales`, to the variable `y`.

```
X = advertising[ 'TV' ]
y = advertising[ 'Sales' ]
```

And after assigning the variables you need to split our variable into training and testing sets. You’ll perform this by importing `train_test_split`

from the `sklearn.model_selection`

library. It is usually a good practice to keep 70% of the data in your train dataset and the rest 30% in your test dataset.

```
from sklearn.model_selection import train_test_split
X_train, X_test, y_train, y_test = train_test_split( X, y, train_size = 0.7, test_size = 0.3, random_state = 100 )
```

In this way, you can split the data into train and test sets.

One can check the shapes of train and test sets with the following code,

```
print( X_train.shape )
print( X_test.shape )
print( y_train.shape )
print( y_test.shape )
```

importing statmodels library to perform linear regression

`import statsmodels.api as sm`

By default, the `statsmodels`

library fits a line on the dataset which passes through the origin. But in order to have an intercept, you need to manually use the `add_constant`

attribute of `statsmodels`

. And once you’ve added the constant to your `X_train`

dataset, you can go ahead and fit a regression line using the `OLS`

(Ordinary Least Squares) the attribute of `statsmodels`

as shown below,

```
# Add a constant to get an intercept
X_train_sm = sm.add_constant(X_train)
# Fit the resgression line using 'OLS'
lr = sm.OLS(y_train, X_train_sm).fit()
```

One can see the values of betas using the following code,

```
# Print the parameters,i.e. intercept and slope of the regression line obtained
lr.params
```

Here, 6.948 is the intercept, and 0.0545 is a slope for the variable TV.

Now, let’s see the evaluation metrics for this linear regression operation. You can simply view the summary using the following code,

```
#Performing a summary operation lists out all different parameters of the regression line fitted
print(lr.summary())
```

As you can see, this code gives you a brief summary of the linear regression. Here are some key statistics from the summary:

- The
**coefficient**for TV is 0.054, with a very low p-value. The coefficient is statistically significant. So the association is not purely by chance. **R – squared**is 0.816 Meaning that 81.6% of the variance in `Sales` is explained by `TV`. This is a decent R-squared value.**F-statistics**has a very low p-value(practically low). Meaning that the model fit is statistically significant, and the explained variance isn’t purely by chance.

Now that you have simply fitted a regression line on your train dataset, it is time to make some predictions on the test data. For this, you first need to add a constant to the `X_test`

data like you did for `X_train`

and then you can simply go on and predict the y values corresponding to `X_test`

using the `predict`

the attribute of the fitted regression line.

```
# Add a constant to X_test
X_test_sm = sm.add_constant(X_test)
# Predict the y values corresponding to X_test_sm
y_pred = lr.predict(X_test_sm)
```

You can see the predicted values with the following code,

y_pred.head()

To check how well the values are predicted on the test data we will check some evaluation metrics using sklearn library.

```
#Imporitng libraries
from sklearn.metrics import mean_squared_error
from sklearn.metrics import r2_score
```

```
#RMSE value
print( "RMSE: ",np.sqrt( mean_squared_error( y_test, y_pred ) )
#R-squared value
print( "R-squared: ",r2_score( y_test, y_pred ) )
```

We are getting a decent score for both train and test sets.

Apart from `statsmodels`, there is another package namely `sklearn` that can be used to perform linear regression. We will use the `linear_model` library from `sklearn` to build the model. Since we have already performed a train-test split, we don’t need to do it again.

There’s one small step that we need to add, though. When there’s only a single feature, we need to add an additional column in order for the linear regression fit to be performed successfully. Code is given below,

```
X_train_lm = X_train_lm.values.reshape(-1,1)
X_test_lm = X_test_lm.values.reshape(-1,1)
```

One can check the change in the shape of the above data frames.

```
print(X_train_lm.shape)
print(X_train_lm.shape)
```

To fit the model, write the below code,

```
from sklearn.linear_model import LinearRegression
#Representing LinearRegression as lr (creating LinearRegression object)
lr = LinearRegression()
#Fit the model using lr.fit()
lr.fit( X_train_lm , y_train_lm )
```

You can get the intercept and slope values with sklearn using the following code,

```
#get intercept
print( lr.intercept_ )
#get slope
print( lr.coef_ )
```

This is how we can perform the simple linear regression.

This is how we can perform the simple linear regression.

In conclusion, Linear Regression is a cornerstone in data science, providing a robust framework for predicting continuous outcomes. As we unravel its intricacies and applications, it becomes evident that Linear Regression Statistics is a versatile tool with widespread implications. This article is a comprehensive guide from its role in modeling relationships to real-world implementations in Python.

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Hope you find this overview of linear regression informative and gain a clearer understanding of simple linear regression, its applications in machine learning, and the essential concepts behind linear regression statistics.

- Linear regression predicts relationships between variables by fitting a line that minimizes prediction errors.
- Simple linear regression involves one predictor and one outcome variable, while multiple linear regression includes several predictors.
- The cost function, often minimized using gradient descent, determines the best-fit line in linear regression.
- Evaluation metrics like R-squared and RMSE measure the model’s performance and fit.
- Assumptions such as linearity, independence, normal distribution, and constant variance of residuals are crucial for valid regression analysis.
- Proper feature selection and validation techniques help mitigate overfitting and multicollinearity in regression models.

**The media shown in this article are not owned by Analytics Vidhya and are used at the Author’s discretion.**

A. Linear regression has two main parameters: slope (weight) and intercept. The slope represents the change in the dependent variable for a unit change in the independent variable. The intercept is the value of the dependent variable when the independent variable is zero. The goal is to find the best-fitting line that minimizes the difference between predicted and actual values.

A. The formula for a linear regression equation is:

y = mx + b

Where y is the dependent variable, x is the independent variable, m is the slope (weight), and b is the intercept. It represents the best-fitting straight line describing the relationship between the variables by minimizing squared differences between actual and predicted values.

A. Linear regression is used in statistics, economics, finance, and more to analyze relationships between variables. For instance, I was predicting stock prices in finance or studying the impact of advertising on sales in marketing. A basic example involves predicting weight based on height, where a linear equation is used to estimate weight from height data.

A. A basic linear regression example involves predicting a person’s weight based on height. In this scenario, height is the independent variable, while weight is the dependent variable. The relationship between height and weight is modeled using a simple linear equation, where the weight is estimated as a function of the height.

A. Linear regression predicts the relationship between variables by fitting a straight line that minimizes the differences between predicted and actual values. It analyzes and forecasts data trends.

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