In this project, you are required to extend a spline-based animation system to support multiple curve types, and implement a particle system simulation engine. After building a working system, you will use your (robust and powerful) program to produce a (compelling and arresting) animation.
The skeleton code provided is built on top of the same architecture as the Modeler, and is designed so that you can re-use your models. If you replace robotarm.cpp with a working model file from Project 2, you should be able to compile the program and play with the interface. As with the Modeler, this application has two windows: a viewer for the model, and a main window that allows you to manipulate the various model and camera parameters. If you click on the "Controls" tab in the main window, you will essentially get the Modeler interface, with sliders for controlling components of your character. The second mode, where you'll be spending most of your time, is the "Curves" mode. Curves mode is where you edit a time-varying curve for each model parameter by adding and moving control points. Selecting controls in the left-hand browser window brings up the corresponding curves in the graph on the right. Here, time is plotted on the x-axis, and the value of a given parameter is plotted on the y-axis. This graph display and interface is encapsulated in the GraphWidget class.
Here is a summary of the requirements for this project:
Some of these requirements are explained in greater detail below.
Bezier Curves
When we say "cubic beziers splined together with C0
continuity" it means that you'll need at least four control points
to make a single bezier curve. Adjacent Bezier curves share control
points so that the last control point of one Bezier curve will be the
first control point of another. In this way you can have two complete
Bezier curves with only 7 control points. Note: In the lecture slides, you were shown an adaptive recurrsive algorithm for creating bezier curves as well as a straight forward method that simply samples at a consistent rate. The adaptive Bezier curve generation is not required (but is a bell of extra credit). Feel free to sample the curve at a constant rate to fulfill the project requirments.
General Curves
It is possible to make parametric curves that "double back" on
themselves (x is not monotonically increasing as a function of t). It
must be possible to interpret the curves that your solution produces as
a function of time, so you'll have to think about and solve this case.
Two Distinct Forces
Create at least two distinct types of forces that act on your particle
system. The three most obvious distinct forces are gravity (f=mg),
viscous drag (f=-k_d*v), and Hooks spring law. Other interesting
possibilities include electromagnetic force, simulation of flocking
behavior, and buoyant force. If the forces you choose are complicated or
novel (or listed in the Bells and Whistles) you may earn extra credit
while simultaneously fulfilling this requirement.
Collision Detection & Response
Perform collision detection with your particles and at least one primitive
in your scene. A natural choice is the ground plane of your scene.
Your particles should bounce off of that primitive, and you should provide
a control for the restitution constant that determines how much the normal
component of the reflected velocity is attenuated.
To control the restitution, you can add a RangeProperty field to your ParticleSystem class, just like you did for your model class in Modeler. The difference is that you will add the field to your ParticleSystem class, then add it to your model's property list in your model's constructor. This way, you can easily access your field both from inside your ParticleSystem and inside your model!
#include "properties.h" to particleSystem.h, before class ParticleSystem. This lets you use sliders in ParticleSystem.
// in particleSystem.h
#include "properties.h" // you added this, right?
class ParticleSystem {
public:
RangeProperty restitution;
};
// in particleSystem.cpp
ParticleSystem::ParticleSystem() : restitution("Restitution", 0.0f, 2.0f, 1.0f, 0.1f) {
// ... constructor code
}
// in sample.cpp (or whatever file your model is in):
class MyModel : public Model {
ParticleSystem ps;
// ... other stuff ....
MyModel() : // ... constructor calls for your sliders, textures, shader, etc ...
{
// ... calls to properties.add() for each slider, checkbox, etc. ...
properties.add(&ps.restitution);
}
}
restitution.getValue().
After selecting a model parameters in the tree on the left, the parameter's corresponding animation curve is displayed in the graph. Each spline is evaluated as a simple piece-wise linear curve that linearly interpolates between control points. You can manipulate the curve as follows:
|
Command |
Action |
| LEFT MOUSE | Clicking anywhere in the graph creates a control point for the selected curve. Control points can be moved by clicking on them and dragging. |
| SHIFT LEFT MOUSE | Removes a control point |
| ALT LEFT MOUSE | Rubber-band selection of control points |
| RIGHT MOUSE | Zooms in X and Y dimensions |
| CTRL RIGHT MOUSE | Zooms into the rubber-banded space region |
| SHIFT RIGHT MOUSE | Pans the viewed region |
Note that each of the displayed curves has a different scale. Based on the maximum and minimum values for each parameter that you specified in your model file, the curve is drawn to "fit" into the graph. You'll also notice that the other curve types in the drop-down menu are not working. One part of your requirements (outlined below) is to implement these other curves.
At the bottom of the window is a simple set of VCR-style controls and a time slider that let you play, pause, and seek in your animation. The The Simulate checkbox relates to the particle system which is discussed below.
Camera motions can be edited in two ways:
The GraphWidget object owns a bunch of Curve objects. The Curve class is used to represent the time-varying splines associated with your model parameters. You don't need to worry about most of the existing code, which is used to handle the user interface. However, it is important that you understand the curve evaluation model. Each curve is represented by a vector of evaluated points.
mutable std::vector
mutable std::vector
The user of your program can manipulate the positions of the control points using the Graph Widget interface. Your code will compute the value of the curve at intervals in time, determining the shape of the curve. Given a set of control points, the system figures out what the evaluated points are.
This conversion process is handled by the CurveEvaluator member variable of each curve.
const CurveEvaluator* m_pceEvaluator;
In the skeleton, only the LinearCurveEvaluator has been implemented. Consequently, the curve drawn is composed of line segments directly connecting each control point. You should use the LinearCurveEvaluator as a model to implement the other required curve evaluators: Bezier and Catmull-Rom. B-Spline and C2-Interpolating curves can be added for extra credit.
For each curve type, you must write a new class that inherits from CurveEvaluator. Inside the class, you should implement the evaluateCurve function. This function takes the following parameters:
ptvCtrlPts--a collection of control points that you specify in the curve editor
ptvEvaluatedCurvePts--a collection of evaluated curve points that you return from the function calculated using the curve type's formulas
fAniLength--the maximum time that a curve is defined
bWrap--a flag indicating whether or not the curve should be wrapped (wrapping can be implemented for extra credit)
To add a new curve
type, you should look in the GraphWidget constructor and change the
following lines to use your new set of evaluator classes.
m_ppceCurveEvaluators[CURVE_TYPE_BSPLINE]
= new LinearCurveEvaluator();
m_ppceCurveEvaluators[CURVE_TYPE_BEZIER] = new LinearCurveEvaluator();
m_ppceCurveEvaluators[CURVE_TYPE_CATMULLROM] = new LinearCurveEvaluator();
For Bezier curves (and the splines based on them), it is sufficient to sample the curve at fixed intervals of time. The adaptive de Casteljau subdivision algorithm presented in class may be implemented for an extra bell.
Catmull-Rom curves should be endpoint interpolating. This can be done by doubling the endpoints.
You do not have to sort the control points or the evaluated curve points. This has been done for you. Note, however, that for an interpolating curve (Catmull-Rom), the fact that the control points are given to you sorted by x does not ensure that the curve itself will also monotonically increase in x. You should recognize and handle this case appropriately. One solution is to return only the evaluated points that are increasing monotonically in x.
Also, be aware that the evaluation function will linearly interpolate
between the evaluated points to ensure a continuous curve on the screen.
This is why you don't have to generate infinitely many evaluated points.
The skeleton code has a very high-level framework in place for running particle simulations that is based on Witkin's Particle System Dynamics. In this model, there are three major components:
You are responsible for coming up with a representation for particles and forces. The skeleton provides a very basic outline of a simulation engine, encapsulated by the ParticleSystem class. Currently, the header file (ParticleSystem.h) specifies an interface that must be supported in order for your particle system to interact correctly with the animator UI. Alternately, you can try to figure out how the UI works yourself by searching within the project files for all calls to the particle system's functions, and then re-organizing the code. This second option may provide you with more flexibility in doing some very ambitious particle systems with extra UI support. However, the framework seems general enough to support a wide range of particle systems. There is detailed documentation in the header file itself that indicates what each function you are required to write should do. Note that the ParticleSystem declaration is by no means complete. As mentioned above, you will have to figure out how you want to store and organize particles and forces, and as a result, you will need to add member variables and functions.
One of the functions you are required to implement is called computeForcesAndUpdateParticles:
virtual void computeForcesAndUpdateParticles(float t);
This function represents the meat of the simulation solver. Here you will compute the forces acting on each particle and update their positions and velocities based on these forces using Euler's method. As mentioned above, you are responsible for modeling particles and forces in some way that allows you to perform this update step at each frame.
One requirement of your particle system is to attach it to a node of your model other than the root. This requires that you think carefully about about how to represent the positions of your particles.
Suppose you want to attach a particle shower to your model's hand. When you apply the force of gravity to these particles, the direction of the force will always be along the negative Y axis of the world. If you mistakenly apply gravity along negative Y of the hand's coordinate space, you'll see some funky gravity that depends on the orientation of the hand (bad!). To solve this problem, we recommend that you attach a particle emitter to the model's hand, but store all the particles positions as coordinates in world space. This means that you'll need to calculate the world coordinates of the particle emitter every time a particle is spawned.
Please read the following pseudocode, which contains an in-depth discussion of using particles in your hierarchy.
The function getModelViewMatrix
is used in the file above. We are also providing the C implementation for
it:
Mat4f getModelViewMatrix()
{
GLfloat m[16];
glGetFloatv(GL_MODELVIEW_MATRIX, m);
Mat4f matMV(m[0], m[1], m[2], m[3],
m[4], m[5], m[6], m[7],
m[8], m[9], m[10], m[11],
m[12], m[13], m[14], m[15] );
return matMV.transpose(); // because the matrix GL
returns is column major
}
Animator obtains your model's particle system by calling the getParticleSystem() method of your Model subclass. If you don't override it, this method returns NULL (and Animator may crash as a result). So, to add your particle system, do the following:
protected: ParticleSystem ps;
public:
ParticleSystem* getParticleSystem() { return &ps; }
You will eventually use your program to produce an animated artifact for this project (after the project due date – see the top of the page for artifact due date). Under the File menu of the program, there is a Save Movie Frames option, that will let you specify a base filename for a set of movie frames. Each frame is saved as a png or jpg, with your base filename plus some digits that indicate the frame number. Use a program like Adobe Premiere (installed in the labs) to compress the frame into a video file. (See Quick Links for more detail.)
We may give extra credit to those that are exceptionally clever or aesthetically pleasing. Try to use the ideas discussed in the John Lasseter article. These include anticipation, follow-through, squash and stretch, and secondary motion.
Finally, plan for your animation to be 30 seconds long (60 seconds is the absolute maximum). You will find this is a very small amount of time, so consider this when planning your animation. We reserve the right to penalize artifacts that go over the time limit and/or clip the video for the purposes of voting. Refer to this guide for creating your final .avi file.
Then, you must turn in your completed artifact as a video through catalyst. DO NOT submit the artifact with your code and binary. The due dates are different!
See due dates/times at the top of this page. Do not be late!
Enhance the
required spline options. Some of these will require alterations to the user
interface, which involves learning Fluid and the UI framework. If you
want to access mouse events in the graph window, look at the handle
function in the GraphWidget class. Also, look at the Curve
class to see what control point manipulation functions are already
provided. These could be helpful, and will likely give you a better
understanding of how to modify or extend your program's behavior. A
maximum of 3 whistles will be given out in this category.
Let the user control the tension of the Catmull-Rom spline.
Implement
one of the standard subdivision curves (e.g., Lane-Riesenfeld or
Dyn-Levin-Gregory).
Add
options to the user interface to enforce C1 or C2
continuity between adjacent Bezier curve segments automatically. (It
should also be possible to override this feature in cases where you don't
want this type of continuity.)
Add
the ability to add a new control point to any curve type without changing
the curve at all.
The linear curve
code provided in the skeleton can be "wrapped," which means that the
curve has C0 continuity between the end of the animation and the beginning. As
a result, looping the animation does not result in abrupt jumps. You will be
given a whistle for each (nonlinear) curve that you wrap.
Render a mirror in
your scene. As you may already know, OpenGL has no built-in reflection
capabilities. You can simulate a mirror with the following steps: 1) Reflect
the world about the mirror's plane, 2) Draw the reflected world, 3) Pop the
reflection about the mirror plane from your matrix stack, 4) Draw your world as
normal. After completing these steps, you may discover that some of the
reflected geometry appears outside the surface of the mirror. For an
extra whistle you can clip the reflected image to the mirror's surface, you
need to use something called the stencil buffer. The stencil buffer is
similar to a Z buffer and is used to restrict drawing to certain portions of
the screen. See Scott Schaefer's
site for more information. In addition, the NeHe game development site has
a detailed tutorial
Modify your
particle system so that the particles' velocities gets initialized with the
velocity of the hierarchy component from which they are emitted. The particles
may still have their own inherent initial velocity. For example, if your model
is a helicopter with a cannon launching packages out if it, each package's
velocity will need to be initialized to the sum of the helicopter's velocity
and the velocity imparted by the cannon.
Particles rendered
as points or spheres may not look that realistic. You can achieve more
spectacular effects with a simple technique called billboarding. A
billboarded quad (aka "sprite") is a textured square that always
faces the camera. See the
sprites demo. For full credit, you should load a texture with
transparency (sample textures), and
turn on alpha blending (see this tutorial
for more information). Hint: When rotating your particles to face the
camera, it's helpful to know the camera's up and right vectors in
world-coordinates.
Use the
billboarded quads you implemented above to render the following effects.
Each of these effects is worth one whistle provided you have put in a whistle
worth of effort making the effect look good.
Fire (example) (You'll probably want to use
additive blending for your particles -glBlendFunc(GL_SRC_ALPHA,GL_ONE);)
Snow (Example)
Water
fountain (Example)
Fireworks
(Example)
Use environment
mapping to simulate a reflective material. This technique is particularly
effective at faking a metallic material or reflective, rippling water
surface. Note that OpenGL provides some very useful functions for
generating texture coordinates for spherical environment mapping. Part of
the challenge of this whistle is to find these functions and understand how
they work.
Add baking to your
particle system. For simulations that are expensive to process, some
systems allow you to cache the results of a simulation. This is called
"baking." After simulating once, the cached simulation can then
be played back without having to recompute the particle properties at each time
step. See this page for more information on how
to implement particle baking.
Implement a motion
blur effect (example). The easy
way to implement motion blur is using an accumulation
buffer - however, consumer grade graphics cards do not implement an
accumulation buffer. You'll need to simulate an accumulation buffer by
rendering individual frames to a texture, then combining those textures.
See this
tutorial for an example of rendering to a texture.
Euler's method is
a very simple technique for solving the system of differential equations that
defines particle motion. However, more powerful methods can be used to
get better, more accurate results. Implement your simulation engine using
a higher-order method such as the Runge-Kutta technique. ( Numerical Recipes,
Sections 16.0, 16.1) has a description of Runge-Kutta and pseudo-code.
Implement B-Spline. There is already an entry for it in the drop-down menu.
Implement
adaptive Bezier curve generation: Use a recursive, divide-and-conquer, de
Casteljau algorithm to produce Bézier curves, rather than just sampling
them at some arbitrary interval. You are required to provide some way to change
the flatness parameter and maximum recursion depth, with a keystroke or mouse
click. In addition, you should have some way of showing (a printf
statement is fine) the number of points generated for a curve to demonstrate
your adaptive algorithm at work.
To get an extra whistle, provide visual controls in the UI (i.e. sliders) to modify the flatness parameter and maximum recursion depth, and also display the number of points generated for each curve in the UI.
Extend the particle
system to handle springs. For example, a pony tail can be simulated with a
simple spring system where one spring endpoint is attached to the character's
head, while the others are floating in space. In the case of springs, the
force acting on the particle is calculated at every step, and it depends on the
distance between the two endpoints. For one more bell, implement
spring-based cloth. For 2 more bells, implement spring-based fur.
The fur must respond to collisions with other geometry and interact with at
least two forces like wind and gravity.
Allow for particles
to bounce off each other by detecting collisions when updating their positions
and velocities. Although it is difficult to make this very robust, your
system should behave reasonably.
Implement a
"general" subdivision curve, so the user can specify an arbitrary
averaging mask You will receive still more credit if you can generate,
display, and apply the evaluation masks as well. There's a site at
Caltech with a few interesting applets that may be useful.
Add
a lens flare. This effect has components both in screen space and world
space effect.
For full credit, your lens flare should have at least 5 flare
"drops", and the transparency of the drops should change depending on
how far the light source is from the center of the screen. You do not
have to handle the case where the light source is occluded by other geometry
(but this is worth an extra whistle).
Perform
collision detection with more complicated shapes. For complex scenes, you
can even use the accelerated ray tracer and ray casting to determine if a
collision is going to occur. Credit will vary with the complexity shapes
and the sophistication of the scheme used for collision detection.
If
you find something you don't like about the interface, or something you think
you could do better, change it! Any really good changes will be
incorporated into the next Animator. Credit varies with the quality of
the improvement.
After you are done with B-Spline, implementing a C2-Interpolating curve is straight-forward. You can look at pages 13 and 14 of this handout. There is already an entry for it in the drop-down menu.
Add flocking
behaviors to your particles to simulate creatures moving in flocks, herds, or
schools. A convincing way of doing this is called "boids"
(see here for a demo and for more
information). For full credit, use a model for your creatures that makes
it easy to see their direction and orientation (for example, the yellow/green
pyramids in the boids demo would be a minimum requirement). For up to one
more bell, make realistic creature model and have it move realistically
according to its motion path. For example, a bird model would flap its
wings when it rises, and hold it's wings outstretched when turning.
Add the ability to
edit Catmull-Rom curves using the two "inner" Bezier control points
as "handles" on the interpolated "outer" Catmull-Rom
control points. After the user tugs on handles, the curve may no longer be
Catmull-Rom. In other words, the user is really drawing a C1
continuous curve that starts off with the Catmull-Rom choice for the inner
Bezier points, but can then be edited by selecting and editing the
handles. The user should be allowed to drag the interpolated point in a
manner that causes the inner Bezier points to be dragged along. See
PowerPoint and Illustrator pencil-drawn curves for an example.
Implement picking of
a part in the model hierarchy. In other words, make it so that you can
click on a part of your model to select its animation curve. To recognize
which body part you're picking, you need to first render all body parts into a
hidden buffer using only an emissive color that corresponds to an object
ID. After modifying the mouse-ing UI to know about your new picking mode,
you'll figure out which body part the user has picked by reading out the ID
from your object ID buffer at the location where the mouse clicked. This
should then trigger the GraphWidget to select the appropriate curve for
editing. If you're thinking of doing either of the inverse kinematics
(IK) extensions below, this kind of interface would be required.
If you implemented
twist for your original model, the camera movement for your old modeler can
give some unexpected results. For example, twist your model 90
degrees. Now try to do rotations as normal. This effect is called
gimbal lock. Change the camera to use quaternions as a method for
avoiding the gimbal lock.
Implement projected textures.
Projected textures are used to simulate things like a slide projector,
spotlight illumination, or casting shadows onto arbitrary geometry. Check
out this demo and read details
of the effect at glBase,
and SGI.
An alternative way to
do animations is to transform an already existing animation by way of motion
warping (animations).
Extend the animator to support this type of motion editing.
We've talked about
rigid-body simulations in class. Incorporate this functionality into your
program, so that you can correctly simulate collisions and response between
rigid objects in your scene. You should be able to specify a set of
objects in your model to be included in the simulation, and the user should
have the ability to enable and disable the simulation either using the existing
"Simulate" button, or with a new button.
The hierarchical model that you created is controlled by forward kinematics; that is, the positions of the parts vary as a function of joint angles. More mathematically stated, the positions of the joints are computed as a function of the degrees of freedom (these DOFs are most often rotations). The problem is inverse kinematics is to determine the DOFs of a model to satisfy a set of positional constraints, subject to the DOF constraints of the model (a knee on a human model, for instance, should not bend backwards).
This is a significantly harder problem than forward kinematics. Aside from the complicated math involved, many inverse kinematics problems do unique solutions. Imagine a human model, with the feet constrained to the ground. Now we wish to place the hand, say, about five feet off the ground. We need to figure out the value of every joint angle in the body to achieve the desired pose. Clearly, there are an infinite number of solutions. Which one is "best"?
Now imagine that we wish to place the hand 15 feet off the ground. It's fairly unlikely that a realistic human model can do this with its feet still planted on the ground. But inverse kinematics must provide a good solution anyway. How is a good solution defined?
Your solver should be fully general and not rely on your specific model (although you can assume that the degrees of freedom are all rotational). Additionally, you should modify your user interface to allow interactive control of your model though the inverse kinematics solver. The solver should run quickly enough to respond to mouse movement.
If you're interested in implementing this, you will probably want to consult
the
Create a character whose physics can be controlled by moving a mouse or pressing keys on the keyboard. For example, moving the mouse up or down may make the knees bend or extend the knees (so your character can jump), while moving it the left or right could control the waist angle (so your character can lean forward or backward). Rather than have these controls change joint angles directly, as was done in the modeler project, the controls should create torques on the joints so that the character moves in very realistic ways. This monster bell requires components of the rigid body simulation extension above, but you will receive credit for both extensions as long as both are fully implemented.. For this extension, you will create a hierarchical character composed of several rigid bodies. Next, devise a way user interactively control your character.
This technique can produce some organic looking movements that are a lot of fun to control. For example, you could create a little Luxo Jr. that hops around and kicks a ball. Or, you could create a downhill skier that can jump over gaps and perform backflips (see the Ski Stunt example below).
SIGGRAPH paper - http://www.dgp.toronto.edu/~jflaszlo/papers/sig2000.pdf
Several movie examples - http://www.dgp.toronto.edu/~jflaszlo/interactive-control.html
Ski Stunt - a fun game that implements this monster bell - Information and Java applet demo - Complete Game (win32)
If you want, you can do it in 2D, like the examples shown in this paper (in
this case you will get full monster bell credit, but half credit for the rigid
body component).
