Visão Computacional

This is the homepage for the computer vision course at the undergraduate level being taught in 2018/2 at IPRJ/UERJ. This year will focus on programming 3D technology useful for robotics, motion capture and augmented reality applications such as Kinnect, Hololens, 3D scanning in Google streetview, and Glass.

General Information

• Instructor: prof. Ricardo Fabbri, Ph.D. Brown University
• Period: Semester 2018/1 (ending August 2018), for Computer Engineering students in their 10th semester
• Tuesdays and Fridays, 3:10pm-5:00pm, room 207
• Forum for file exchange and discussion: google groups: iprj-visao-2018@googlegroups.com
• Chat: IRC #labmacambira for random chat

Requisites

The student should know basic programming concepts and quickly learn languages on demand. This year's focus on 3D puts demands some C++ programming, which will be reviewed, but familiarity with C is required. Prior experience with linear algebra and vector calculus are highly recommended, and will also be reviewed as needed.

Software

This year will focus on practical C++ programming (whose performance and scalability are needed for the demands of 3D programming). Auxiliary languages will be used:

• Scripting languages such as Python, Scilab or Matlab for experimentation and prototyping small ideas
• Pd (pure data) will be used for real-time interactive apps (although the underlying code is C/C++)

Bibliografia

• Principal livro este ano (enfase 3D): An Invitation to 3D Vision, Yi Ma, Stefano Soatto, Jana Kosecka e Shankar Sastry
• Segundo livro principal (enfase 3D): Multiple View Geometry in Computer Vision, Hartley & Zisserman

Livros Auxiliares

• Auxiliar 1: Computer Vision, Richard Szeliski, cujo pdf se encontra on-line: http://szeliski.org/Book

• Auxiliar 2: Shape Classification and Analysis, 2nd. Ed., Luciano da Fontoura Costa & Roberto Marcondes Cesar Jr.

Links

3D Vision Courses

Finding a 3D vision course suitable for undergraduates is hard, just as the subject itself tends to be hard

• Super Cool 3D course by Frank Dellaert. This is the same type of course as ours, except that we focused on getting structure from motion to work for most problems.
• 3D Photography Course at Brown University by Gabriel Taubin. This vision course is similar to the present course, except it work later into the 3D vision pipeline, after we already have the 3D cameras and an initial reconstruction, how to get better reconstructions and photometry.

Other Vision & Related Courses

• Computer Vision research course at Brown Engineering, 2013 - ENGN 2560
• Image Understanding course at Brown Engineering (basic to intermediate level)
  • 2013 course http://mesh.brown.edu/engn1610
  • 2011 course http://vision.lems.brown.edu/engn161/fall2011
• Computer Vision course at Brown Computer Science (basic to intermediate) http://cs.brown.edu/courses/cs143
• Stochastic Processes course by prof. Fabbri
• Curso de Computacao Paralela do IPRJ: incluindo CUDA
• Curso de Álgebra Linear Numérica do IPRJ: muitos conceitos úteis para visao computacional e computação gráfica
• Curso de Computacao Grafica do IPRJ
• Curso de Teoria dos Padroes do IPRJ: aprendizagem de maquina, tecnicas estocasticas, vertente importante de Visao Computacional
• OpenCV, VXL, SIP: bibliotecas de visao computacional em C/C++ e Scilab, respectivamente

Provas

Tarefas

Labs

Download dos Labs

Todo material dos trabalhos (imagens, pdfs, etc) pode ser baixado e atualizado pelo Git [1]:

 git clone https://github.com/rfabbri/vision-course.git

Lab1: Processamento ponto a ponto

• Enunciado
• As imagens necessarias estao no repositorio Git[2]
• Data de entrega: quarta-feira 13/Nov/2013 ate a meia-noite. Atrasos serao aceitos porem somente com reducao na nota.

Instrucoes para Submissao

• A solucao deve ser digitada em um relatorio e entregue no formato pdf.
• Incluir tambem todo o codigo fonte e dados gerados
• Enviar um arquivo zipado com tudo (scripts scilab, relatorio, etc) por email, no formato:

<sobrenome>-<nome>-visao-computacional-lab<numero_lab>.zip

Projetos

3D Reconstruction for Robotics

Optional: Toy Piano

Build an interactive toy piano or toy keyboard where you have colored objects representing each letter of the alphabet, and the user would touch each object and the computer would react to the persons' touch. To make this easy and cheap, this could work with a webcam and color detection, and the person/baby could use a black glove/sock.

Criterio de Avaliacao

• Nota = 70% projetos e tarefas, 30% prova
• Bonus: top 2 projetos que atingirem nivel de excelencia ganharao +3 pontos na media