COMPSCI 682 Neural Networks: A Modern Introduction

In this assignment you will practice putting together a simple image classification pipeline, based on the k-Nearest Neighbor or the SVM/Softmax classifier. The goals of this assignment are as follows:

understand the basic Image Classification pipeline and the data-driven approach (train/predict stages)
understand the train/val/test splits and the use of validation data for hyperparameter tuning.
develop proficiency in writing efficient vectorized code with numpy
implement and apply a k-Nearest Neighbor (kNN) classifier
implement and apply a Multiclass Support Vector Machine (SVM) classifier
implement and apply a Softmax classifier
implement and apply a Two layer neural network classifier
understand the differences and tradeoffs between these classifiers
get a basic understanding of performance improvements from using higher-level representations than raw pixels (e.g. color histograms, Histogram of Gradient (HOG) features)

Setup

Get the code as a zip file here. As for the dependencies:

[Option 1] Use Anaconda: The preferred approach for installing all the assignment dependencies is to use Anaconda, which is a Python distribution that includes many of the most popular Python packages for science, math, engineering and data analysis. Once you install it you can skip all mentions of requirements and you’re ready to go directly to working on the assignment.

[Option 2] Manual install, virtual environment: If you’d like to (instead of Anaconda) go with a more manual and risky installation route you will likely want to create a virtual environment for the project. If you choose not to use a virtual environment, it is up to you to make sure that all dependencies for the code are installed globally on your machine. To set up a virtual environment, run the following:

cd assignment1
sudo pip install virtualenv      # This may already be installed
virtualenv .env                  # Create a virtual environment
source .env/bin/activate         # Activate the virtual environment
pip install -r requirements.txt  # Install dependencies
# Work on the assignment for a while ...
deactivate                       # Exit the virtual environment

Download data: Once you have the starter code, you will need to download the CIFAR-10 dataset. Run the following from the assignment1 directory:

cd datasets
./get_datasets.sh

Start Jupyter Notebook: After you have the CIFAR-10 data, you should start the Jupyter Notebook server from the assignment1 directory. If you are unfamiliar with Jupyter, you should read our Jupyter tutorial.

NOTE: If you are working in a virtual environment on OSX, you may encounter errors with matplotlib due to the issues described here. You can work around this issue by starting the Jupyter server using the start_jupyter_osx.sh script from the assignment1 directory; the script assumes that your virtual environment is named .env.

Submitting your work

To make sure everything is working properly, remember to do a clean run (“Kernel -> Restart & Run All”) after you finish work for each notebook and submit the final version with all the outputs. Once you are done working, zip all the code and notebooks in a single file and upload it to Moodle. On Linux or macOS you can run the provided collectSubmission.sh script from assignment1/ to produce a file assignment1.zip.

Q1: k-Nearest Neighbor classifier (20 points)

The Jupyter Notebook knn.ipynb will walk you through implementing the kNN classifier.

Q2: Training a Support Vector Machine (25 points)

The Jupyter Notebook svm.ipynb will walk you through implementing the SVM classifier.

Q3: Implement a Softmax classifier (20 points)

The Jupyter Notebook softmax.ipynb will walk you through implementing the Softmax classifier.

Q4: Two-Layer Neural Network (25 points)

The Jupyter Notebook two_layer_net.ipynb will walk you through the implementation of a two-layer neural network classifier.

Q5: Higher Level Representations: Image Features (10 points)

The Jupyter Notebook features.ipynb will walk you through this exercise, in which you will examine the improvements gained by using higher-level representations as opposed to using raw pixel values.

Q6: Cool Bonus: Do something extra! (+10 points)

Implement, investigate or analyze something extra surrounding the topics in this assignment, and using the code you developed. For example, is there some other interesting question we could have asked? Is there any insightful visualization you can plot? Or anything fun to look at? Or maybe you can experiment with a spin on the loss function? If you try out something cool we’ll give you up to 10 extra points and may feature your results in the lecture.