(Excercise01 "Introductions”)
(Excercise04 "Position based Dynamics”)
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* Attend lessons. All lessons attended is +0 points. Four and more lectures missed you missed the course Fx.
 
* Attend lessons. All lessons attended is +0 points. Four and more lectures missed you missed the course Fx.
* Solve all homework problems (mandatory each one >=30%, 50 points)
+
* Solve all homework problems (mandatory each one >=30%, 60 points)
 
* Pass written Final term exam (mandatory each one >=30%, 30 points), no retakes. Realtime problem solution in Wolfram Mathematica or Wolfram Alpha.
 
* Pass written Final term exam (mandatory each one >=30%, 30 points), no retakes. Realtime problem solution in Wolfram Mathematica or Wolfram Alpha.
 
* Pass oral/written exam: (optional, +0 .. +20 points) If you feel you are better, convince me ! You can get +20 points max.
 
* Pass oral/written exam: (optional, +0 .. +20 points) If you feel you are better, convince me ! You can get +20 points max.
 
* Summary
 
* Summary
 
** Attendance = +0 or -100 (or Fx)
 
** Attendance = +0 or -100 (or Fx)
** Homework = +50..+12 or 12..0 (or Fx)
+
** Homework = +60..+18 or 12..0 (or Fx)
** Excercises = +20..0  
+
** Excercises = +10..0  
** Final term = +30..0  
+
** Final term = (better than Fx) +30..0  
 
** Optional oral exam = +20..0
 
** Optional oral exam = +20..0
  
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** Fx = 0-59
 
** Fx = 0-59
  
* '''[https://docs.google.com/spreadsheets/d/1e8DObml_p0mjpxVnVCIlRQV70payv3HNi_ajUGONrNw/edit?usp=sharing RESULTS]'''
+
* '''[https://docs.google.com/spreadsheets/d/1JS_ICQv73QpPuyiZ_l7D0E-eKWJG4ToYl_H4xDE_GTw/edit?usp=sharing RESULTS]'''
 +
* In case of online lecture connect to MS Teams [https://teams.microsoft.com/l/team/19%3a09e9527680ca40ef8a336492c5749111%40thread.tacv2/conversations?groupId=54138d27-ced4-46a6-99cc-cb7510664011&tenantId=ce31478d-6e7a-4ce7-8670-a5b9d51884f9 Teams] Teams code: 1himkdt
  
 
=== Oral / Written Examination ===
 
=== Oral / Written Examination ===
Riadok 157: Riadok 158:
 
* Demos / tools / libs
 
* Demos / tools / libs
 
* Lecture notes: [[media:ca15_lesson07.pdf|lesson07.pdf]]
 
* Lecture notes: [[media:ca15_lesson07.pdf|lesson07.pdf]]
* Štátnicová téma (Lesson 5,6,7): S4 Detekcie kolízie, nutná a postačujúca podmienka kedy nie sú dve telesá v rovine, broad phase (hierachycká mriežka), mid phase (hierarchie obálok, Voronoiove oblasti v kolízii, vysvetlujte na príklade kolízie gula x kapsula, dekompozícia telesa na konvexné časti), narrow phase (Minkowskeho priestor a blízkosť konvexných telies).
+
* Štátnicová téma (Lesson 5,6,7): S4 Detekcie kolízie, nutná a postačujúca podmienka kedy nie sú dve telesá v kolízii, broad phase (hierachycká mriežka), mid phase (hierarchie obálok, Voronoiove oblasti v kolízii, vysvetlujte na príklade kolízie gula x kapsula, dekompozícia telesa na konvexné časti), narrow phase (Minkowskeho priestor a blízkosť konvexných telies).
  
  
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*On every seminar we will focus on the selected problems from lessons. We will use the numerical methods to solve specific problems.
 
*On every seminar we will focus on the selected problems from lessons. We will use the numerical methods to solve specific problems.
  
 
+
<!--
 
=== Excercise00 "Key Framing” ===
 
=== Excercise00 "Key Framing” ===
 
* '''[https://www.youtube.com/watch?v=CFFhgutjZQk Blender demo]'''
 
* '''[https://www.youtube.com/watch?v=CFFhgutjZQk Blender demo]'''
Riadok 217: Riadok 218:
 
** rigging https://www.youtube.com/watch?v=mJwWTKt12ak
 
** rigging https://www.youtube.com/watch?v=mJwWTKt12ak
 
** motion capture database https://sites.google.com/a/cgspeed.com/cgspeed/motion-capture/daz-friendly-release
 
** motion capture database https://sites.google.com/a/cgspeed.com/cgspeed/motion-capture/daz-friendly-release
 
+
-->
  
 
=== Excercise01 "Introductions” ===
 
=== Excercise01 "Introductions” ===
 
* Vectors
 
* Vectors
 +
** https://reference.wolfram.com/language/tutorial/Lists.html#2534
 
* Matrices
 
* Matrices
 
* Linear interpolation
 
* Linear interpolation
 
 
<!--*WOLFRAM DEVELOPMENT PLATFORM [https://develop.open.wolframcloud.com/app/]-->
 
<!--*WOLFRAM DEVELOPMENT PLATFORM [https://develop.open.wolframcloud.com/app/]-->
*https://reference.wolfram.com/language/tutorial/Lists.html#2534
+
*WOLFRAM NOTEBOOK [https://www.wolfram.com/notebooks/]
 +
* https://www.wolfram.com/language/fast-introduction-for-programmers/en/interactive-usage/
  
 
*resources:
 
*resources:
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* Assigment
 
* Assigment
**[[media:uloha1A.pdf|uloha1A.pdf]] (deadline see Attendance table)
+
**[[media:uloha1B.pdf|uloha1.pdf]] (deadline see Attendance table)
***HINT: If SLERP does not work, use linear interpolation.
+
  
 
* Euler angles
 
* Euler angles
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***http://www.academia.edu/4095904/Quaternion_calculus_as_a_basic_tool_in_computer_graphics
 
***http://www.academia.edu/4095904/Quaternion_calculus_as_a_basic_tool_in_computer_graphics
 
***https://www.youtube.com/watch?v=d4EgbgTm0Bg
 
***https://www.youtube.com/watch?v=d4EgbgTm0Bg
 +
***https://reference.wolfram.com/language/Quaternions/tutorial/Quaternions.html
  
 
=== Excercise03 "Differential Equations” ===
 
=== Excercise03 "Differential Equations” ===
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***http://terpconnect.umd.edu/~petersd/246/matlabode.html
 
***http://terpconnect.umd.edu/~petersd/246/matlabode.html
 
***https://computing.llnl.gov/casc/nsde/pubs/u113855.pdf
 
***https://computing.llnl.gov/casc/nsde/pubs/u113855.pdf
* Wolfram Mathematica http://mathworld.wolfram.com/
+
* Wolfram Mathematica https://reference.wolfram.com/language/ref/NDSolve.html
 
* FreeMat http://freemat.sourceforge.net/index.html
 
* FreeMat http://freemat.sourceforge.net/index.html
 
* Matlab tutorial http://www.tutorialspoint.com/matlab/index.htm
 
* Matlab tutorial http://www.tutorialspoint.com/matlab/index.htm
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**resources
 
**resources
 
***[[media:Position based Dynamics.pdf|Position based Dynamics.pdf]]
 
***[[media:Position based Dynamics.pdf|Position based Dynamics.pdf]]
 +
***https://www.cs.toronto.edu/~jacobson/seminar/mueller-et-al-2007.pdf
 
<!--
 
<!--
 
* Assigment
 
* Assigment

Verzia zo dňa a času 14:20, 3. november 2021

Ca10 lesson01.png

Physical based Animations and Mathematical Modelling (Course Materials)

This lecture ...

  • Will focus on simulating natural phenomena
  • Will show you what are current topics
  • Will improve your skills in
    • Newtonian physics
    • Computational geometry
    • Algorithms and data structures
  • Hopefully will not be boring
  • List of Open Source Physics Engines

Student Animation Projects

What you Need to Pass

  • Attend lessons. All lessons attended is +0 points. Four and more lectures missed you missed the course Fx.
  • Solve all homework problems (mandatory each one >=30%, 60 points)
  • Pass written Final term exam (mandatory each one >=30%, 30 points), no retakes. Realtime problem solution in Wolfram Mathematica or Wolfram Alpha.
  • Pass oral/written exam: (optional, +0 .. +20 points) If you feel you are better, convince me ! You can get +20 points max.
  • Summary
    • Attendance = +0 or -100 (or Fx)
    • Homework = +60..+18 or 12..0 (or Fx)
    • Excercises = +10..0
    • Final term = (better than Fx) +30..0
    • Optional oral exam = +20..0
  • Grades
    • A = 92-100
    • B = 84-91
    • C = 76-83
    • D = 68-75
    • E = 60-67
    • Fx = 0-59
  • RESULTS
  • In case of online lecture connect to MS Teams Teams Teams code: 1himkdt

Oral / Written Examination

To the oral examination, all the above requirements must be SATISFACTORILY completed. Moodle



Lesson01 "Introduction to Computer Animation"

Ca10 lesson01.png

  • Introduction to Computer Animation
  • Common animation techniques
  • Cutting edge tools and packages
  • Gurus and the State of the Art
  • Lecture schedule
  • "Terms and conditions" of this lecture
  • Lecture notes: lesson01.pdf


Lesson02 "Basic methods in Computer Animation"

Ca10 lesson02.png

  • Problem definition and motivations
  • Key-framing and parameter interpolation
  • Quternions, orientation
  • Skeleton and skinning animation
  • Forward and inverse kinematics
  • Procedural techniques
  • (Motion capture)
  • Lecture notes: lesson02.pdf
  • Štátnicová téma: S1 Animácie pohybu a orientácie, interpolačný spline na animáciu pohybu, splinu podľa dĺžky krivky, quaternion a orientácia, interpolácie dvoch a viacerých quaternionov.


Lesson03 "Particle Systems"

Ca10 lesson03.png

  • Newton dynamics of particles
  • Ordinary differential equation (ODE) solver
  • Particle - obstacle collision detection
  • Practical design of particle system
  • Demos / tools / libs
  • Lecture notes: lesson03.pdf
  • Štátnicová téma: S2 Numerické riešenie diferenciálnych rovníc, Eulerova metóda, MidPoint metóda, Runge-Kuta metóda, podmienka stability na voľbu časového kroku, sily odozvy (response forces).


Lesson04 "Soft bodies, Cloths and hair”

Ca10 lesson11.png

  • Problem definition and motivations
  • Modeling solids with stress and strain
  • Extending Mass-spring model for cloth and ropes
  • Massive (self) collision and resolution for cloths
  • Mesh-less deformations
  • Modeling solids with infinitely stiff springs
  • Demos / tools / libs
  • Lecture notes: lesson04.pdf
  • Štátnicová téma (Lesson 3,4): S3 Časticové systémy, rovnice pohybu prvého rádu, integračné metódy na výpočet rýchlosti a pozície, stavový vektor systému, vonkajšie sily, obmedzujúce podmienky – constraints, sily odozvy, kolízie častica - rovina.


Lesson05 "Broad Phase Collision Detection"

Ca10 lesson04.png

  • Problem definition and motivations
  • Hierarchical grids and spatial hashing
  • Sweep and prune and radix sort
  • Pair management – a practical guide
  • Demos / tools / libs
  • Lecture notes: lesson05.pdf


Lesson "All Saints' Day (no lesson)"

Ca10 lesson07.png

  • No lesson


Lesson06 "Mid Phase Collision Detection"

Ca10 lesson05.png

  • Problem definition and motivations
  • Generic Bounding Volume Hierarchy (BVH)
  • Tandem BVH traversal
  • Proximity evaluation of primitive geometries
    • External Voronoi regions
    • Sphere x Capsule x Box x triangle collisions
  • Approximate convex decomposition
  • Lecture notes: lesson06.pdf


Lesson07 "Narrow Phase Collision Detection"

Ca10 lesson06.png

  • Problem definition and motivations
  • Proximity queries for convex objects (Minkowski space)
  • GJK based algorithms (GJK, EPA, ISA-GJK)
  • Voronoi-Clip (V-Clip) Algorithm
  • Signed Distance Maps for collision detection
  • Demos / tools / libs
  • Lecture notes: lesson07.pdf
  • Štátnicová téma (Lesson 5,6,7): S4 Detekcie kolízie, nutná a postačujúca podmienka kedy nie sú dve telesá v kolízii, broad phase (hierachycká mriežka), mid phase (hierarchie obálok, Voronoiove oblasti v kolízii, vysvetlujte na príklade kolízie gula x kapsula, dekompozícia telesa na konvexné časti), narrow phase (Minkowskeho priestor a blízkosť konvexných telies).


Lesson08 "Rigid body Dynamics”

Ca10 lesson08.png

  • Problem definition and motivations
  • Dynamics of rigid bodies
  • The equation of unconstrained motion (ODE)
  • User and time control
  • Mass properties of polyhedral objects
  • Demos / tools / libs
  • Lecture notes: lesson08.pdf
  • Štátnicová téma (Lesson 9): S5 Dynamika tuhých telies, definícia problému, rovnice pohybu (4 ODE), rýchlosť, zrýchlenie, uhľová rýchlosť a uhľové zrýchlenie, matica hybnosti (matica inercie).


Lesson09 "Rigid body Collisions and Joints”

Ca10 lesson09.png

  • Problem definition and motivations
  • Simplified collision model
  • Impulse based collision equation
  • Friction-less collision resolution
  • Algebraic collision resolution for Coulomb friction
  • Linear and angular joint formulations
  • Demos / tools / libs
  • Lecture notes:lesson09.pdf


Lesson10 "Fluid, Fire and Smoke”

Ca10 lesson10.png

  • Problem definition and motivations
  • Navier-Stokes equations for fluid dynamics
  • Grid based MAC method
  • Particle based SPH method
  • Neighbor search for coupled particles
  • Modeling smoke and fire with fluid
  • Demos / tools / libs
  • Lecture notes: lesson10.pdf


Lesson11 "Final term"

Ca10 lesson12.png

  • Don't panic - just few simple questions


Lesson12 "Animation Show"

  • Show your animation to your colleagues

EXCERCISES

  • Your presence at the seminar is optional.
  • On every seminar we will focus on the selected problems from lessons. We will use the numerical methods to solve specific problems.


Excercise01 "Introductions”

Excercise02 "Quaternion Interpolation”

  • Assigment

Excercise03 "Differential Equations”

Excercise04 "Position based Dynamics”

Excercise05 "Particles”

Excercise06 "STAR reports”

Excercise07 "Separating Axis Theorem”

Excercise08 "Rigid body Dynamics”

RESOURCES