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Machine Learning Projects

  • Challenge: learn the foundations of machine learning
  • Actions:
    • concepts: linear regression, logistic regression, regularisation, neural networks, support vector machines, dimensionality reduction, principal component analysis, k-means clustering, anomaly detection, recommender systems, large scale machine learning
    • tools: Matlab / Octave
  • Results: https://www.coursera.org/account/accomplishments/certificate/WLHZZ6TPVVM2
  • Challenge: train a convolution neural network to clone driving behaviour using training sets recorded in realistic video games
  • Actions:
    • use the simulator to collect data of good driving behaviour
    • build a convolution neural network in Keras that predicts steering angles from images
    • train and validate the model with a training and validation set
    • test that the model successfully drives around track without leaving the road
  • Results: https://github.com/FlorinGh/SelfDrivingCar-ND-pr3-Behavioral-Cloning
  • Challenge: write a software pipeline to identify the lane boundaries in a video taken while driving on a motorway
  • Actions:
    • compute the camera calibration matrix and distortion coefficients given a set of chessboard images.
    • apply a distortion correction on the video frames and save a corrected video
    • use colour transforms and gradients to create a threshold binary image
    • apply a perspective transform to rectify binary image ("birds-eye view")
    • detect lane pixels and fit to find the lane boundary
    • determine the curvature of the lane and vehicle position with respect to centre of curvature
    • warp the detected lane boundaries back onto the original perspective
    • output visual display of the lane boundaries and numerical estimation of lane curvature and vehicle position.
  • Results: https://github.com/FlorinGh/SelfDrivingCar-ND-pr4-Advanced-Lane-Lines
  • Challenge: write a software pipeline to detect vehicles in a video taken while driving on a motorway
  • Actions:
    • extract features from images using HOG (histogram of oriented gradients)
    • separate the images in train/test and train an SVM (support vector machine) classifier
    • implement a sliding window search and classify each window as vehicle or non-vehicle
    • output a video with the detected vehicles positions drawn as bounding boxes
  • Results: https://github.com/FlorinGh/SelfDrivingCar-ND-pr5-Vehicle-Detection
  • Challenge: use computing capabilities of Python to solve the nonlinear coupled partial derivative equations that govern the dynamics of fluids, the Navier-Stokes equations
  • Actions:
    • creating implicit numerical schemes to solve ever increasing difficult components of the NS equations: linear convection, nonlinear convection, diffusion, Burgers' equation, Laplace equation, Poisson equation
    • applying the full final code on two classical problems: cavity flow and channel flow
  • Results: https://github.com/FlorinGh/12-steps-to-navier-stokes