• 23 Apr 09:00

# COMPGI14 - Machine Vision

This database contains 2017-18 versions of the syllabuses. For current versions please see here.

Code COMPGI14 (Also taught as COMPM054) MSc Successful completion of an appropriate Computer Science, Mathematics, or other Physical Science or Engineering undergraduate programme with sufficient mathematical and programming content, plus some familiarity with digital imaging and digital image processing. 1 Gabriel Brostow(100%) The course addresses algorithms for automated computer vision. It focuses on building mathematical models of images and objects and using these to perform inference. Students will learn how to use these models to automatically find, segment and track objects in scenes, perform face recognition and build three-dimensional models from images. To be able to understand and apply a series of probabilistic models of images and objects in machine vision systems. To understand the principles behind face recognition, segmentation, image parsing, super-resolution, object recognition, tracking and 3D model building.

# Content

Two-dimensional visual geometry: 2d transformation family. The homography. Estimating 2d transformations. Image panoramas.

Three dimensional image geometry: The projective camera. Camera calibration. Recovering pose to a plane.

More than one camera: The fundamental and essential matrices. Sparse stereo methods. Rectification. Building 3D models. Shape from sillhouette.

Vision at a single pixel: background subtraction and color segmentations problems. Parametric, non-parametric and semi-parametric techniques. Fitting models with hidden variables.

Connecting pixels: Dynamic programming for stereo vision. Markov random fields. MCMC methods. Graph cuts.

Texture: Texture synthesis, super-resolution and denoising, image inpainting. The epitome of an image.

Dense Object Recognition: Modelling covariances of pixel regions. Factor analysis and principle components analysis.

Sparse Object Recognition: Bag of words, latent dirilecht allocation, probabilistic latent semantic analysis.

Face Recognition: Probabilistic approaches to identity recognition. Face recognition in disparate viewing conditions.

Shape Analysis: Point distribution models, active shape models, active appearance models.

Tracking: The Kalman filter, the Condensation algorithm.

# Method of Instruction

Lectures, practical lab classes.

# Assessment

The course has the following assessment components:

• Written Examination (2.5 hours, 80%)
• Coursework Section (2 pieces, 20%)

To pass this course, students must:

• Obtain an overall pass mark of 50% for all sections combined.

The examination rubric is: