I'm making a Theremin-like app in Unity (C#).
I have horizontal Axis X, on which I can click (with a mouse or with a finger on a smartphone).
This X-axis determines the frequency, which will be played.
The user will specify the frequency range of the board (X-Axis), let's say from frequency 261.63 (note C4) to 523.25 (note C5).
I'll calculate x_position_ratio which is a number between 0 and 1 determining, where did the user click on the X-axis (0 being on the most left (note C4 in this example), 1 on the most right (note C5))
From this, I will calculate the frequency to play by equation
float freqRange = maxFreq - minFreq;
float frequency = (x_position_ratio * freqRange) + minFreq;
And then play the frequency. It works just fine.
If I draw the notes on the board (X-axis), we can see, that the higher is the frequency, the higher is the jump between the 2 notes.
// Drawing just note A4 to demonstrate the code
float a4 = 440.0f //frequency of note A4
float x_position = (a4 - minFreq) / freqRange;
loc_x_position indicating the position of the note on the X-axis between 0 to 1
output
Question:
I would like to make the jump, same, between 2 notes (Make it linear instead of exponential, if you understand what I mean). Found the equation on Wikipedia Piano_key_frequencies but it's for the keys. I want it to every frequency and I cannot figure out how to implement it in my 2 code examples I posted
I figured it out. Tried to plot it logarithmic to at least approximate the result.
I was inspired by this answer Plotting logarithmic graph
Turns out this solution worked
To draw notes on the x-axis I used this:
minFreq = Mathf.Log10(minFreq);
maxFreq = Mathf.Log10(maxFreq);
float freqRange = maxFreq - minFreq;
x_position = (Mathf.Log10(frequencyOfNoteToPlot) - minFreq) / freqRange;
and to calculate the frequency I just derived frequency from the equation for the x_position and ended up with this piece of code:
frequency = Mathf.Pow(10, x_position * freqRange + minFreq);
One thing I still don't get is, why it doesn't matter, which base of the logarithm I use. Is it because I'm always getting ratio (value between 0 to 1)?
I am practicing my programming skill using Unity3D. I have a grid set up that has coordinates in an x,y type of setup.
[0,0] to [10,10]
With all the numbers in between (I.E. 5,5 would be close to center of the map).
The thing that I am trying to do now is figure out a mathematical formula to calculate the coordinates my character can move. If the character is at position 5,5 and has a movement radius of 2 what is the most efficient way to return a list or an array of coordinates my character can move to? Every single grid square is its own object and have public variables for its X and Y so once I have the available results actually using them in the code isn't hard.
Here's what I'm trying so far (I'm ignoring the out of range possibility for right now, that's an easy fix):
for(int x = currentGridSquare.xCoord - myMovementRange;
x <= currentGridSquare.xCoord + myMovementRange; x++){
for(int y = currentGridSquare.yCoord - myMovementRange;
y <= currentGridSquare + myMovementRange; y++)
{
//Starting at 5,5 with a movement range of 2 should
//start this process at the value of 3,3 which
// is incorrect
}
}
I may be too tired to actually calculate a formula for this but I've been searching and haven't come across anything so if anyone's had experience with this and knows a quick way to do it I would be greatly appreciative.
Update: The values that I am expecting this to return would be coordinates. In this example starting at 5,5, the values I'd want back would be [3,5],[4,4],[4,5],[4,6],[3,5],[4,5],[5,5],[6,5],[4,6],[5,6],[6,6] and [5,7]
So I used formula Ben provided and came up with:
foreach(var gridSquare in allGridSquares)
{
if( (Mathf.Abs(myX - gridSquare.Xcoord) + (Mathf.Abs(myY - gridSquare.Ycoor) >= myMovementValue)
{
gridSquare.activate();
}
}
I know that if the grid starts getting bigger than the distance formula will be more complicated and I will update this later if that's the case but for the size of my grid this works wonderfully.
Few days ago I decided to start in 3D programming and came across perspective projection.
I use the following code to get the matrix:
public static Matrix3D ProjectionMatrix(double angle, double aspect, double near, double far)
{
double size = near * Math.Tan(MathUtils.DegreeToRadian(angle) / 2.0);
double left = -size, right = size, bottom = -size / aspect, top = size / aspect;
Matrix3D m = new Matrix3D(new double[,] {
{2*near/(right-left),0,(right + left)/(right - left),0},
{0,2*near/(top-bottom),(top+bottom)/(top-bottom),0},
{0,0,-(far+near)/(far-near),-(2 * far * near) / (far - near)},
{0,0,-1,0}
});
return m;
}
I use the following code for the camera:
Matrix3D Camera
{
get
{
Vector3D cameraZAxis = -this.LookDirection;
cameraZAxis.Normalize();
Vector3D cameraXAxis = Vector3D.CrossProduct(this.UpDirection, cameraZAxis);
cameraXAxis.Normalize();
Vector3D cameraYAxis = Vector3D.CrossProduct(cameraZAxis, cameraXAxis);
Vector3D cameraPosition = (Vector3D)this.Position;
double offsetX = -Vector3D.DotProduct(cameraXAxis, cameraPosition);
double offsetY = -Vector3D.DotProduct(cameraYAxis, cameraPosition);
double offsetZ = -Vector3D.DotProduct(cameraZAxis, cameraPosition);
return new Matrix3D(new double[,]{{cameraXAxis.X, cameraYAxis.X, cameraZAxis.X, 0},
{cameraXAxis.Y, cameraYAxis.Y, cameraZAxis.Y, 0},
{cameraXAxis.Z, cameraYAxis.Z, cameraZAxis.Z, 0},
{offsetX, offsetY, offsetZ, 1}});
}
}
However, I don't know how to get the Model or World Matrix, also is there anything wrong with the previous code?
A Matrix is used to transform an object from one "space" into another. Think of a Model which is a cube, the model center is 0,0,0 and each corner is at an extent of 5. Now to transform that into your world you would apply a Worldmatrix with the transformation to put these model coordinates into your world.
A translation for example which should "move" the model to 5, 5, 5. Now just think of adding this position to your model and all its points, and now these new coordinates are called "in world space". Now the model is, via your World matrix placed in the world at position 5,5,5 (your former model center resides now in your world at this position).
The view matrix is a little bit tricky to understand, but the easiest is to think of "We can't move a camera, so we move all ojects in the opposite direction so it looks like we moved the camera". This sounds difficult, but in fact its the same like transforming from model space to world space.
Now we transform from World space into view space. Finally, we need to get it on the screen. Obviously your screen is 2D and you still have a 3D scene, now you need a way to transform your 3D objects into your view space. This can be achieved with different kinds of projection. The two important ones are orthogonal projection and perspective projection. In fact this uses the Z component( which we don't have on a 2D surface like a screen) and the screen resolution to "project" our visible world into our screen space.
All this is easily accomplished using matrices. One for each transformation is a good start. To be fair, you don't need any of it, you could directly supply your data in screen space, but this wouldn't be practical. If you don't need a World matrix for example, which happens if your model is modeled so that it could be used directly, you would use an Matrix.Identity which, can roughly be interpreted as multiplying a number by 1 which gives you the same number. Also an Identity Matrix for the view is like having the camera placed in the world on 0,0,0 and looking down the Z axis (which axis heavly depends on the coordinate system you use)
To get the final matrix for a shader you usually pass all these matrices (or a combined one via multiplication) to your shader. If you use the fixed function pipeline there are usually methods to supply them. The projection is usually fixed, but could be changed to apply some visual effects like zooming a sniper rifle or a fisheye effect. The camera matrix of course is used to move and rotate the camera. And the world matrix is used to position your objects in the scene, move players, rotate doors etc.
Disclaimer: This is how i understood the whole thing for myself, so it is by no means a mathematical correct explanation, but maybe it is of any help for the OP.
To get a better understanding of the whole subject you can read this.
Let's say I have a data structure like the following:
Camera {
double x, y, z
/** ideally the camera angle is positioned to aim at the 0,0,0 point */
double angleX, angleY, angleZ;
}
SomePointIn3DSpace {
double x, y, z
}
ScreenData {
/** Convert from some point 3d space to 2d space, end up with x, y */
int x_screenPositionOfPt, y_screenPositionOfPt
double zFar = 100;
int width=640, height=480
}
...
Without screen clipping or much of anything else, how would I calculate the screen x,y position of some point given some 3d point in space. I want to project that 3d point onto the 2d screen.
Camera.x = 0
Camera.y = 10;
Camera.z = -10;
/** ideally, I want the camera to point at the ground at 3d space 0,0,0 */
Camera.angleX = ???;
Camera.angleY = ????
Camera.angleZ = ????;
SomePointIn3DSpace.x = 5;
SomePointIn3DSpace.y = 5;
SomePointIn3DSpace.z = 5;
ScreenData.x and y is the screen x position of the 3d point in space. How do I calculate those values?
I could possibly use the equations found here, but I don't understand how the screen width/height comes into play. Also, I don't understand in the wiki entry what is the viewer's position vers the camera position.
http://en.wikipedia.org/wiki/3D_projection
The 'way it's done' is to use homogenous transformations and coordinates. You take a point in space and:
Position it relative to the camera using the model matrix.
Project it either orthographically or in perspective using the projection matrix.
Apply the viewport trnasformation to place it on the screen.
This gets pretty vague, but I'll try and cover the important bits and leave some of it to you. I assume you understand the basics of matrix math :).
Homogenous Vectors, Points, Transformations
In 3D, a homogenous point would be a column matrix of the form [x, y, z, 1]. The final component is 'w', a scaling factor, which for vectors is 0: this has the effect that you can't translate vectors, which is mathematically correct. We won't go there, we're talking points.
Homogenous transformations are 4x4 matrices, used because they allow translation to be represented as a matrix multiplication, rather than an addition, which is nice and quick for your videocard. Also convenient because we can represent successive transformations by multiplying them together. We apply transformations to points by performing transformation * point.
There are 3 primary homogeneous transformations:
Translation,
Rotation, and
Scaling.
There are others, notably the 'look at' transformation, which are worth exploring. However, I just wanted to give a brief list and a few links. Successive application of moving, scaling and rotating applied to points is collectively the model transformation matrix, and places them in the scene, relative to the camera. It's important to realise what we're doing is akin to moving objects around the camera, not the other way around.
Orthographic and Perspective
To transform from world coordinates into screen coordinates, you would first use a projection matrix, which commonly, come in two flavors:
Orthographic, commonly used for 2D and CAD.
Perspective, good for games and 3D environments.
An orthographic projection matrix is constructed as follows:
Where parameters include:
Top: The Y coordinate of the top edge of visible space.
Bottom: The Y coordinate of the bottom edge of the visible space.
Left: The X coordinate of the left edge of the visible space.
Right: The X coordinate of the right edge of the visible space.
I think that's pretty simple. What you establish is an area of space that is going to appear on the screen, which you can clip against. It's simple here, because the area of space visible is a rectangle. Clipping in perspective is more complicated because the area which appears on screen or the viewing volume, is a frustrum.
If you're having a hard time with the wikipedia on perspective projection, Here's the code to build a suitable matrix, courtesy of geeks3D
void BuildPerspProjMat(float *m, float fov, float aspect,
float znear, float zfar)
{
float xymax = znear * tan(fov * PI_OVER_360);
float ymin = -xymax;
float xmin = -xymax;
float width = xymax - xmin;
float height = xymax - ymin;
float depth = zfar - znear;
float q = -(zfar + znear) / depth;
float qn = -2 * (zfar * znear) / depth;
float w = 2 * znear / width;
w = w / aspect;
float h = 2 * znear / height;
m[0] = w;
m[1] = 0;
m[2] = 0;
m[3] = 0;
m[4] = 0;
m[5] = h;
m[6] = 0;
m[7] = 0;
m[8] = 0;
m[9] = 0;
m[10] = q;
m[11] = -1;
m[12] = 0;
m[13] = 0;
m[14] = qn;
m[15] = 0;
}
Variables are:
fov: Field of view, pi/4 radians is a good value.
aspect: Ratio of height to width.
znear, zfar: used for clipping, I'll ignore these.
and the matrix generated is column major, indexed as follows in the above code:
0 4 8 12
1 5 9 13
2 6 10 14
3 7 11 15
Viewport Transformation, Screen Coordinates
Both of these transformations require another matrix matrix to put things in screen coordinates, called the viewport transformation. That's described here, I won't cover it (it's dead simple).
Thus, for a point p, we would:
Perform model transformation matrix * p, resulting in pm.
Perform projection matrix * pm, resulting in pp.
Clipping pp against the viewing volume.
Perform viewport transformation matrix * pp, resulting is ps: point on screen.
Summary
I hope that covers most of it. There are holes in the above and it's vague in places, post any questions below. This subject is usually worthy of a whole chapter in a textbook, I've done my best to distill the process, hopefully to your advantage!
I linked to this above, but I strongly suggest you read this, and download the binary. It's an excellent tool to further your understanding of theses transformations and how it gets points on the screen:
http://www.songho.ca/opengl/gl_transform.html
As far as actual work, you'll need to implement a 4x4 matrix class for homogeneous transformations as well as a homogeneous point class you can multiply against it to apply transformations (remember, [x, y, z, 1]). You'll need to generate the transformations as described above and in the links. It's not all that difficult once you understand the procedure. Best of luck :).
#BerlinBrown just as a general comment, you ought not to store your camera rotation as X,Y,Z angles, as this can lead to an ambiguity.
For instance, x=60degrees is the same as -300 degrees. When using x,y and z the number of ambiguous possibilities are very high.
Instead, try using two points in 3D space, x1,y1,z1 for camera location and x2,y2,z2 for camera "target". The angles can be backward computed to/from the location/target but in my opinion this is not recommended. Using a camera location/target allows you to construct a "LookAt" vector which is a unit vector in the direction of the camera (v'). From this you can also construct a LookAt matrix which is a 4x4 matrix used to project objects in 3D space to pixels in 2D space.
Please see this related question, where I discuss how to compute a vector R, which is in the plane orthogonal to the camera.
Given a vector of your camera to target, v = xi, yj, zk
Normalise the vector, v' = xi, yj, zk / sqrt(xi^2 + yj^2 + zk^2)
Let U = global world up vector u = 0, 0, 1
Then we can compute R = Horizontal Vector that is parallel to the camera's view direction R = v' ^ U,
where ^ is the cross product, given by
a ^ b = (a2b3 - a3b2)i + (a3b1 - a1b3)j + (a1b2 - a2b1)k
This will give you a vector that looks like this.
This could be of use for your question, as once you have the LookAt Vector v', the orthogonal vector R you can start to project from the point in 3D space onto the camera's plane.
Basically all these 3D manipulation problems boil down to transforming a point in world space to local space, where the local x,y,z axes are in orientation with the camera. Does that make sense? So if you have a point, Q=x,y,z and you know R and v' (camera axes) then you can project it to the "screen" using simple vector manipulations. The angles involved can be found out using the dot product operator on Vectors.
Following the wikipedia, first calculate "d":
http://upload.wikimedia.org/wikipedia/en/math/6/0/b/60b64ec331ba2493a2b93e8829e864b6.png
In order to do this, build up those matrices in your code. The mappings from your examples to their variables:
θ = Camera.angle*
a = SomePointIn3DSpace
c = Camera.x | y | z
Or, just do the equations separately without using matrices, your choice:
http://upload.wikimedia.org/wikipedia/en/math/1/c/8/1c89722619b756d05adb4ea38ee6f62b.png
Now we calculate "b", a 2D point:
http://upload.wikimedia.org/wikipedia/en/math/2/5/6/256a0e12b8e6cc7cd71fa9495c0c3668.png
In this case ex and ey are the viewer's position, I believe in most graphics systems half the screen size (0.5) is used to make (0, 0) the center of the screen by default, but you could use any value (play around). ez is where the field of view comes into play. That's the one thing you were missing. Choose a fov angle and calculate ez as:
ez = 1 / tan(fov / 2)
Finally, to get bx and by to actual pixels, you have to scale by a factor related to the screen size. For example, if b maps from (0, 0) to (1, 1) you could just scale x by 1920 and y by 1080 for a 1920 x 1080 display. That way any screen size will show the same thing. There are of course many other factors involved in an actual 3D graphics system but this is the basic version.
Converting points in 3D-space into a 2D point on a screen is simply made by using a matrix. Use a matrix to calculate the screen position of your point, this saves you a lot of work.
When working with cameras you should consider using a look-at-matrix and multiply the look at matrix with your projection matrix.
Assuming the camera is at (0, 0, 0) and pointed straight ahead, the equations would be:
ScreenData.x = SomePointIn3DSpace.x / SomePointIn3DSpace.z * constant;
ScreenData.y = SomePointIn3DSpace.y / SomePointIn3DSpace.z * constant;
where "constant" is some positive value. Setting it to the screen width in pixels usually gives good results. If you set it higher then the scene will look more "zoomed-in", and vice-versa.
If you want the camera to be at a different position or angle, then you will need to move and rotate the scene so that the camera is at (0, 0, 0) and pointed straight ahead, and then you can use the equations above.
You are basically computing the point of intersection between a line that goes through the camera and the 3D point, and a vertical plane that is floating a little bit in front of the camera.
You might be interested in just seeing how GLUT does it behind the scenes. All of these methods have similar documentation that shows the math that goes into them.
The three first lectures from UCSD might be very helful, and contain several illustrations on this topic, which as far as I can see is what you are really after.
Run it thru a ray tracer:
Ray Tracer in C# - Some of the objects he has will look familiar to you ;-)
And just for kicks a LINQ version.
I'm not sure what the greater purpose of your app is (you should tell us, it might spark better ideas), but while it is clear that projection and ray tracing are different problem sets, they have a ton of overlap.
If your app is just trying to draw the entire scene, this would be great.
Solving problem #1: Obscured points won't be projected.
Solution: Though I didn't see anything about opacity or transparency on the blog page, you could probably add these properties and code to process one ray that bounced off (as normal) and one that continued on (for the 'transparency').
Solving problem #2: Projecting a single pixel will require a costly full-image tracing of all pixels.
Obviously if you just want to draw the objects, use the ray tracer for what it's for! But if you want to look up thousands of pixels in the image, from random parts of random objects (why?), doing a full ray-trace for each request would be a huge performance dog.
Fortunately, with more tweaking of his code, you might be able to do one ray-tracing up front (with transparancy), and cache the results until the objects change.
If you're not familiar to ray tracing, read the blog entry - I think it explains how things really work backwards from each 2D pixel, to the objects, then the lights, which determines the pixel value.
You can add code so as intersections with objects are made, you are building lists indexed by intersected points of the objects, with the item being the current 2d pixel being traced.
Then when you want to project a point, go to that object's list, find the nearest point to the one you want to project, and look up the 2d pixel you care about. The math would be far more minimal than the equations in your articles. Unfortunately, using for example a dictionary of your object+point structure mapping to 2d pixels, I am not sure how to find the closest point on an object without running through the entire list of mapped points. Although that wouldn't be the slowest thing in the world and you could probably figure it out, I just don't have the time to think about it. Anyone?
good luck!
"Also, I don't understand in the wiki entry what is the viewer's position vers the camera position" ... I'm 99% sure this is the same thing.
You want to transform your scene with a matrix similar to OpenGL's gluLookAt and then calculate the projection using a projection matrix similar to OpenGL's gluPerspective.
You could try to just calculate the matrices and do the multiplication in software.
lets say i have two points A & B in my 3D Space
now i want to start calculate points from A to B in direction of B and i want to continue calculation farther from B on the same line.
How t do it ?
what i am actually working on is bullets from plane.
If I understood your question correctly, you should first get the direction vector by calculating
dir = B - A
and then you can continue the travel by
C = B + dir
Otherwise, please clarify your question, like for example what you mean by "calculate points from A to B", because mathematically there is an infinite amount of points between A and B.
Edit:
If you want to trace a bullet path you have two options:
1) You implement it as hitscan weapon like done in many FPS; any bullets fired will immediately hit where they were aimed. This can be best achieved by doing a raytrace via Ray.Intersects and is probably the simplest and least computationally intensive way to do it. Of course, it's also not terribly realistic.
2) You make the bullet a physical entity in your world and move it during your Update() call via a "normal" combination of current position vector and movement/velocity vector, doing a manual collision detection with any hittable surfaces and objects. The advantage of this is that you can implement proper physics like travel time, drop, friction, etc., however it is also orders of magnitude more difficult to implement in a robust way. If you want to go this way, I suggest using either a pre-made physics API (like Bullet, but I'm not sure if there's a version for XNA) or at least doing extensive Google research on the subject, so you can avoid the many pitfalls of collision detection with fast-moving objects.
its a try to implement a 2D technique in 3D, i calculate the following once
position = start;
dx = destination.X - start.X;
dy = destination.Y - start.Y;
dz = destination.Z - start.Z;
distance = (float)Math.Sqrt( dx * dx + dy * dy + dz * dz );
scale = 2f / distance;
then i go on calculating
position.X += dx * scale;
position.Y += dy * scale;
position.Z += dz * scale;
but the result is still is not working of 3D Space, i am getting result for only 2 Dimension, the third axis is not being changed