In the four years of my data science career, I have built more than 80% of classification models and just 15-20% of regression models. These ratios can be more or less generalized throughout the industry. The reason behind this bias towards classification models is that most analytical problems involve making decisions. In this article, we will talk about one such widely used machine learning **classification technique** called the k-nearest neighbors (KNN) algorithm. Our focus will primarily be on how the algorithm works on new data and how the input parameter affects the output/prediction.

**Note**: People who prefer to learn through videos can learn the same through our free course – K-Nearest Neighbors (KNN) Algorithm in Python and R. And if you are a complete beginner to Data Science and Machine Learning, check out our Certified BlackBelt program –

**Learning Objectives**

- Understand the working of KNN and how it operates in python and R.
- Get to know how to choose the right value of k for KNN
- Understand the difference between training error rate and validation error rate

- Introduction
- What is KNN (K-Nearest Neighbor) Algorithm?
- When Do We Use the KNN Algorithm?
- How Does the KNN Algorithm Work?
- How Do We Choose the Factor K?
- Breaking It Down – Pseudo Code of KNN
- Implementation in Python From Scratch
- Comparing Our Model With Scikit-learn
- Implementation of KNN in R
- Comparing Our KNN Predictor Function With “Class” Library
- Conclusion
- Frequently Asked Questions

The K-Nearest Neighbors (KNN) algorithm is a popular machine learning technique used for classification and regression tasks. It relies on the idea that similar data points tend to have similar labels or values.

During the training phase, the KNN algorithm stores the entire training dataset as a reference. When making predictions, it calculates the distance between the input data point and all the training examples, using a chosen distance metric such as Euclidean distance.

Next, the algorithm identifies the K nearest neighbors to the input data point based on their distances. In the case of classification, the algorithm assigns the most common class label among the K neighbors as the predicted label for the input data point. For regression, it calculates the average or weighted average of the target values of the K neighbors to predict the value for the input data point.

The KNN algorithm is straightforward and easy to understand, making it a popular choice in various domains. However, its performance can be affected by the choice of K and the distance metric, so careful parameter tuning is necessary for optimal results.

KNN Algorithm can be used for both classification and regression predictive problems. However, it is more widely used in classification problems in the industry. To evaluate any technique, we generally look at 3 important aspects:

1. Ease of interpreting output

2. Calculation time

3. Predictive Power

Let us take a few examples to place KNN in the scale :

KNN classifier fairs across all parameters of consideration. It is commonly used for its ease of interpretation and low calculation time.

Let’s take a simple case to understand this algorithm. Following is a spread of red circles (RC) and green squares (GS):

You intend to find out the class of the blue star (BS). BS can either be RC or GS and nothing else. The “K” in KNN algorithm is the nearest neighbor we wish to take the vote from. Let’s say K = 3. Hence, we will now make a circle with BS as the center just as big as to enclose only three data points on the plane. Refer to the following diagram for more details:

The three closest points to BS are all RC. Hence, with a good confidence level, we can say that the BS should belong to the class RC. Here, the choice became obvious as all three votes from the closest neighbor went to RC. The choice of the parameter K is very crucial in this algorithm. Next, we will understand the factors to be considered to conclude the best K.

First, let us try to understand the influence of the K-nearest neighbors (KNN) in the algorithm. If we consider the last example, keeping all 6 training observations constant, a given K value allows us to establish boundaries for each class. These decision boundaries effectively segregate, for instance, RC from GS. Similarly, let’s examine the impact of the value “K” on these class boundaries. The following illustrates the distinct boundaries that separate the two classes, each corresponding to different values of K.

If you watch carefully, you can see that the boundary becomes smoother with increasing value of K. With K increasing to infinity it finally becomes all blue or all red depending on the total majority. The training error rate and the validation error rate are two parameters we need to access different K-value. Following is the curve for the training error rate with a varying value of K :

As you can see, the error rate at K=1 is always zero for the training sample. This is because the closest point to any training data point is itself.Hence the prediction is always accurate with K=1. If validation error curve would have been similar, our choice of K would have been 1. Following is the validation error curve with varying value of K:

This makes the story more clear. At K=1, we were overfitting the boundaries. Hence, error rate initially decreases and reaches a minima. After the minima point, it then increase with increasing K. To get the optimal value of K, you can segregate the training and validation from the initial dataset. Now plot the validation error curve to get the optimal value of K. This value of K should be used for all predictions.

The above content can be understood more intuitively using our free course – K-Nearest Neighbors (KNN) Algorithm in Python and R

We can implement a KNN model by following the below steps:

- Load the data
- Initialise the value of k
- For getting the predicted class, iterate from 1 to total number of training data points
- Calculate the distance between test data and each row of training dataset. Here we will use Euclidean distance as our distance metric since it’s the most popular method. The other distance function or metrics that can be used are Manhattan distance, Minkowski distance, Chebyshev, cosine, etc. If there are categorical variables, hamming distance can be used.
- Sort the calculated distances in ascending order based on distance values
- Get top k rows from the sorted array
- Get the most frequent class of these rows
- Return the predicted class

We will be using the popular Iris dataset for building our KNN model. You can download it from here.

```
from sklearn.neighbors import KNeighborsClassifier
neigh = KNeighborsClassifier(n_neighbors=3)
neigh.fit(data.iloc[:,0:4], data['Name'])
# Predicted class
print(neigh.predict(test))
-> ['Iris-virginica']
# 3 nearest neighbors
print(neigh.kneighbors(test)[1])
-> [[141 139 120]]
```

We can see that both the models predicted the same class (‘Iris-virginica’) and the same nearest neighbors ( [141 139 120] ). Hence we can conclude that our model runs as expected.

**Step 1: Importing the data****Step 2: Checking the data and calculating the data summary**

**Output**

```
#Top observations present in the data
SepalLength SepalWidth PetalLength PetalWidth Name
1 5.1 3.5 1.4 0.2 Iris-setosa
2 4.9 3.0 1.4 0.2 Iris-setosa
3 4.7 3.2 1.3 0.2 Iris-setosa
4 4.6 3.1 1.5 0.2 Iris-setosa
5 5.0 3.6 1.4 0.2 Iris-setosa
6 5.4 3.9 1.7 0.4 Iris-setosa
#Check the dimensions of the data
[1] 150 5
#Summarise the data
SepalLength SepalWidth PetalLength PetalWidth Name
Min. :4.300 Min. :2.000 Min. :1.000 Min. :0.100 Iris-setosa :50
1st Qu.:5.100 1st Qu.:2.800 1st Qu.:1.600 1st Qu.:0.300 Iris-versicolor:50
Median :5.800 Median :3.000 Median :4.350 Median :1.300 Iris-virginica :50
Mean :5.843 Mean :3.054 Mean :3.759 Mean :1.199
3rd Qu.:6.400 3rd Qu.:3.300 3rd Qu.:5.100 3rd Qu.:1.800
Max. :7.900 Max. :4.400 Max. :6.900 Max. :2.500
```

**Step 3: Splitting the Data**

**Step 4: Calculating the Euclidean Distance**

**Step 5: Writing the function to predict kNN****Step 6: Calculating the label(Name) for K=1**

**Output**

```
For K=1
[1] "Iris-virginica"
```

**In the same way, you can compute for other values of K.**

**Output**

```
For K=1
[1] "Iris-virginica"
```

We can see that both models predicted the same class (‘Iris-virginica’).

The KNN algorithm is one of the simplest classification algorithms. Even with such simplicity, it can give highly competitive results. KNN algorithm can also be used for regression problems. The only difference from the discussed methodology will be using averages of nearest neighbors rather than voting from k-nearest neighbors. KNN can be coded in a single line on R. I am yet to explore how we can use the KNN algorithm on SAS.

**Key Takeaways**

- KNN classifier operates by finding the k nearest neighbors to a given data point, and it takes the majority vote to classify the data point.
- The value of k is crucial, and one needs to choose it wisely to prevent overfitting or underfitting the model.
- One can use cross-validation to select the optimal value of k for the k-NN algorithm, which helps improve its performance and prevent overfitting or underfitting. Cross-validation is also used to identify the outliers before applying the KNN algorithm.
- The above article provides implementations of KNN in Python and R, and it compares the result with scikit-learn and the “Class” library in R.

A. KNN classifier is a machine learning algorithm used for classification and regression problems. It works by finding the K nearest points in the training dataset and uses their class to predict the class or value of a new data point. It can handle complex data and is also easy to implement, which is why KNN has become a popular tool in the field of artificial intelligence.

A. KNN algorithm is most commonly used for:

1. Disease prediction – predicts the likelihood of a disease based on symptoms and the data available.

2. Handwriting recognition – recognizes the handwritten characters.

3. Image classification – recognizes images in computer vision.

A. K-nearest neighbors (KNN) are mainly used for classification and regression problems, while Artificial Neural Networks (ANN) are used for complex function approximation and pattern recognition problems. Moreover, ANN has a higher computational cost than KNN.

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Understanding Cost Function
Understanding Gradient Descent
Math Behind Gradient Descent
Assumptions of Linear Regression
Implement Linear Regression from Scratch
Train Linear Regression in Python
Implementing Linear Regression in R
Diagnosing Residual Plots in Linear Regression Models
Generalized Linear Models
Introduction to Logistic Regression
Odds Ratio
Implementing Logistic Regression from Scratch
Introduction to Scikit-learn in Python
Train Logistic Regression in python
Multiclass using Logistic Regression
How to use Multinomial and Ordinal Logistic Regression in R ?
Challenges with Linear Regression
Introduction to Regularisation
Implementing Regularisation
Ridge Regression
Lasso Regression

Introduction to Stacking
Implementing Stacking
Variants of Stacking
Implementing Variants of Stacking
Introduction to Blending
Bootstrap Sampling
Introduction to Random Sampling
Hyper-parameters of Random Forest
Implementing Random Forest
Out-of-Bag (OOB) Score in the Random Forest
IPL Team Win Prediction Project Using Machine Learning
Introduction to Boosting
Gradient Boosting Algorithm
Math behind GBM
Implementing GBM in python
Regularized Greedy Forests
Extreme Gradient Boosting
Implementing XGBM in python
Tuning Hyperparameters of XGBoost in Python
Implement XGBM in R/H2O
Adaptive Boosting
Implementing Adaptive Boosing
LightGBM
Implementing LightGBM in Python
Catboost
Implementing Catboost in Python

Introduction to Clustering
Applications of Clustering
Evaluation Metrics for Clustering
Understanding K-Means
Implementation of K-Means in Python
Implementation of K-Means in R
Choosing Right Value for K
Profiling Market Segments using K-Means Clustering
Hierarchical Clustering
Implementation of Hierarchial Clustering
DBSCAN
Defining Similarity between clusters
Build Better and Accurate Clusters with Gaussian Mixture Models

Introduction to Machine Learning Interpretability
Framework and Interpretable Models
model Agnostic Methods for Interpretability
Implementing Interpretable Model
Understanding SHAP
Out-of-Core ML
Introduction to Interpretable Machine Learning Models
Model Agnostic Methods for Interpretability
Game Theory & Shapley Values

Deploying Machine Learning Model using Streamlit
Deploying ML Models in Docker
Deploy Using Streamlit
Deploy on Heroku
Deploy Using Netlify
Introduction to Amazon Sagemaker
Setting up Amazon SageMaker
Using SageMaker Endpoint to Generate Inference
Deploy on Microsoft Azure Cloud
Introduction to Flask for Model
Deploying ML model using Flask

Useful article. Can you share similar article for randomforest ? What are limitations with data size for accuracy?

Harshal, We have already published many articles on random forest. Here is the link of the article on random forest on similar lines http://www.analyticsvidhya.com/blog/2014/06/introduction-random-forest-simplified/. You can also subscribe to analyticsvidhya to get access to weekly updates on such articles.

Good one please share the value of Red circle and green square

Saurabh, The first graph is for illustrating purposes. You can create a random dataset to check the algorithm.

I am currently doing part time MS in BI & Data Mining. I found this article is really helpful to understand in more detail and expecting to utilize in my upcoming project work. I need to know do you have any article on importance of Data quality in BI , Classification & Decision Tree.

Debashish, We have published many articles on CART models before. Here is a link which will give you a kick start http://www.analyticsvidhya.com/blog/2014/06/comparing-random-forest-simple-cart-model/.

Hello the article is very clear and precise. I would like some clarification on the single line "To get the optimal value of K, you can segregate the training and validation from the initial dataset.". Do you mean that we segregate those points on the border of the boundaries for validation and keep the remaining for training. This is not very clear to me. Can you please elaborate ? Thanks.

Saraswathi, Here is what I meant : Take the entire population, and randomly split it into two. Now on the training sample, score each validation observation with different k-values. The error curve will give you the best value of k. Hope it becomes clear now.

Nice tease: "KNN can be coded in a single line on R. " Can you give an example?

We will cover this piece in our coming articles. Stay tuned.

Hi, great post, thanks. I would like to add, that "low calculation time" is not true for the prediction phase with big, high dimensional datasets. But it's still a good choice in many applications.

Felix, You are probably right for cases where the distance between observations comparable in the large dataset. But in general population have natural clusters which makes the calculation faster. Let me know in case you disagree. Tavish

I am trying to figure out churn analysis, any suggestions where I am start looking? BTW following this website for 6-8 months now, you guys are doing an amazing job

That was very helpful. Thank you! Can you please share a concise article on neural nets and deep learning as well?

Thank you.

Very useful. it was very explanatory. Thanks for that. Can you please post about adabooster algorithm?

You'll find it here : https://www.analyticsvidhya.com/blog/2015/11/quick-introduction-boosting-algorithms-machine-learning/

Quality articles or reviews is the secret to invite the visitors to visit the website, that's what this web site is providing.

The world of DS would be so boring and exaggerated without you guys. Anything I study, I get a better perspective from this site. And you are so generous and grounded compared to idiots here in UK. God bless.

Excellent post, I appreciate your effort. :)

KNN is fast to train but the prediction speed grows exponentially with the data set size and his complexity rather than Random forest...

Nice article. Do you have anything which can focus more on l0,l1,l2 and l-infinity norms(distances) with respect to KNN?

It is a really nice and well explained article, I am a beginner in the field of data science and machine learning and I find these articles really helpful to learn and understand the algorithms. Thanks for publishing them. Can you suggest me some datasets where I can experiment and apply KNN.

Hi Soumya, You can use the Cancer dataset to practice kNN. Refer this link for the same.

How do we handle categorical features with kNN? Do we need to create dummies for them? Do you suggest any other distance method other than euclidean distance if we have more number of features? I feel we have to treat outliers as they may have impact on the distances, similarly missing values.. Please share your opinion.

Hi, Yes you can create dummies for categorical variables in kNN. Apart from Euclidean distance, there are other methods that can be used to find the distance such as Manhattan or Minkowski. For outliers adn missing value treatment, you can refer this article .

IMO limitation of KNN comes into play when dimensions increase because in higher dimensions, finding neighbors which are quite close to each other in all dimensions might be tough, hence so called neighbors might be really far apart from each other which defeats the purpose of the algorithm. Kindly share your thoughts/experiences.

Hi Aanish, Thank you for sharing your thoughts.

I found it "inspiring". Have spent last 4 months learning linear algebra, statistics, python. This learning list was culled from analyticsvidhya.com. Now just glimpsing through your article gives me the confidence to code knn from scratch. Thank you!

Hi Amlesh, Glad you found this useful!

Hi, Can you guide me how i can design that code for image data? i am waiting for your reply. Thank you

Hi, Thanks for the clean article really helped in understanding KNN. I am working on a project for predictive web user navigation. Something like system learns the repetitive user interactions(adjustable nGram value) depending upon predicting what user would do next, So that system can assist). Any pointers what graph Algos i should be considering? Thanks

That was very helpful. Thank you! How to make the same visualization as in the pictures in section "How do we choose the factor K" ?

Hi Max, For this, you will have to use a for loop. For each value of k, calculate the validation error and store in a separate list. Then plot these validation error values against k values.

Nice article. I think it would be better to explain some disadvantages of k-nearest algorithm.

[…] learning technique and algorithm that can be used for both regression and classification tasks. K-Nearest Neighbors examines the labels of a chosen number of data points surrounding a target data point, in order to […]

hello thanks for this article it is helpful. please can you share with the case where we have mutual k nearest neighbor

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