CSCI 363 Vision--Fall 2016
Exam 2 Review
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Topics for Exam 2:
This sheet is intended to help you prepare for the second midterm in this course. The exam will
cover all readings and lectures up through Friday, November 4, "Biological Motion Processing". While you
are expected to know the material presented prior to the first exam, this exam will focus on the
material covered subsequent to the first exam. The exam
will be closed book and closed note, but you will be allowed to bring one 8.5 x 11 inch sheet
of paper with your own notes on it (one side only) to use as a reference during the exam.
The following list of topics should help you study for the exam.
1. Spatial Frequency
Spatial frequency components of an image
Fourier Series
Fourier Transform
2D frequency spectra of sinewaves, plaids and checkerboards
Psychophysics
Contrast Sensitivity function
Frequency Adapatation
Spatial Frequency channels
Frequency spectrum of a Gaussian
Band-pass filtering--relationship to smoothing at different scales
V1 cells and Spatial Frequency
Gabor filters and their Fourier transforms
V1 cells as Gabor filters
Spatial Frequency columns
V1 simple vs. complex cells--AC/DC responses
V1 cells response to temporal frequency
Relationship of speed, temporal frequency and spatial frequency
Non-linearities of neurons
2. Binocular stereo
Geometric Basis of stereo vision
Crossed and uncrossed disparity
The correspondence problem
Random dot stereograms (what they are and why they are a problem for stereo algorithms)
Constraints for solving the correspondence problem:
Smoothness
Uniqueness
Similarity
Epipolar
The Marr-Poggio algorithm
The Marr-Poggio-Grimson algorithm
Biology of Stereo vision
Constraints used by human visual system
Use of zero crossings by human visual system
Types of neurons tuned to disparity:
Near
Far
Tuned Excitatory
Tuned Inhibitory
3. Motion Detection
Models of motion detection: Correlation, Reichardt, Gradient
The Gradient Constraint equation
The aperture problem
Intersection of constraints technique for computing motion
Measuring velocity along a contour
The smoothness constraint
Motion Energy Filters
Motion as orientation in space-time
Spatio-temporal filters
Gabor filter in space-time
Motion Energy filters from Quadrature pairs
Motion Opponency
Velocity extraction
Motion Energy for 2D filters
Velocity as a plane in spatio-temporal frequency space
Motion Illusions
Rotating spirals
Barberpole illusion
Reversed Phi illusion
Fluted square wave (square wave minus fundamental frequency component)
Computing perpendicular velocities using the Gradient method.
Combining multiple measurements using error minimization
Biological Motion Processing
Dorsal and Ventral streams in extra-striate cortex
Motion processing in V1
Motion processling in MT
Responses to gratings and plaids (component vs. pattern motion)
Speed and direction selectivity
Motion opponency
Inhibitory surround in MT cells
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Constance Royden--croyden@holycross.edu
Computer Science 363--Computational Vision
Last Modified: November 4, 2016
Page Expires: November 4, 2017