Matrix
A matrix (pl. matricies) is a list of numbers, generally who have a relationship between them, that are ordered in a type of mathematical array. A matrix, m, may be written as either |m|, [m], or sometimes even (m) in mathematics, where m is a placeholder for the numbers in the matrix.
Any matrix examples below will use the |m| notation for simplicity.
Reading a Matrix
A matrix is ordered in rows and colums, which are counted by increasing i and j respectively. One can think of a matrix as a 2-dimensional array where each object in the 1st dimension holds an array of numbers in that row.
An entry at i=2 and j=3 is noted by either M[2,3] or m2,3. These numbers are important for some modifications involving these matricies.
Demystifying Matricies in GraalScript
If you have ever tested any of the matrix functions built into GraalScript, you may be lost as to where the return value comes from. Well, luckily there are some adept enough with math to understand these functions. These are their findings.
matrixcreate()
Let v be a vector and a consisting of a vector and a scalar.
Usage
strMatrix = matrixcreate(v,a); |
Where v describes the translation (postition) and 'a' describes the rotation (rotation axis and angle).
Return Value
Returns a matrix array of length 7 (this will be explained later).
Example
temp.matrix = matrixcreate({1,1,1},{1,7,1,1});
// This will return 1,1,1,0.140028,0.980196058,0.140028,7.14595223 |
The Math Behind the Function
The first three numbers of the return value should be rather familiar. It is the vector you passed to the function. The other four seem to come out of nowhere. However, there is a method to this madness. The first of these three are merely a property of angles. Because of the Dot Product of vectors, we are able to calculate the cosine of the angle between two vectors. Well, we have actually created a new vector in this code!
As defined in Vectors, we know that there are three unit vectors that lay on the x, y, and z axes. These vectors have been given the letters i, j, and k, respectively. The first value defined in the "rotation" is multiplied to i, the second to j, and so forth, and this makes a new vector. However, this still does not tell us why we have these numbers returned to us.
From the definition of the dot product, we know that
cos(θ) = u•v/(|u||v|)
The first three numbers returned to us are the cosine of the angles between the new vector (in this case, <1,7,1>) and each of our unit vectors. For example:
cos(α) = <1,7,1>•<1,0,0>/(|<1,7,1>||<1,0,0>|) = 1/√51 = 0.1400280084 cos(β) = <1,7,1>•<0,1,0>/(|<1,7,1>||<0,1,0>|) = 7/√51 = 0.9801960588 cos(γ) = <1,7,1>•<0,0,1>/(|<1,7,1>||<0,0,1>|) = 1/√51 = 0.1400280084
There is an evident difference between the values given here and the return value. A computer cannot calculate cosine on its own. It merely uses a method of estimation.
cos(α)2 + cos(β)2 + cos(γ)2 = 1 (1)
(1) The returned values are accurate within ±10-5
So far, we have 6 of 7 figured out. The last is the simplest of them all. Plugging the new vector into vectorlen() or using √(x2 + y2 + z2) returns it's magnitude. This, multiplied by the fourth number of the second parameter, is the last of the returned values (and as far as anyone can tell the vector passed to the function has no bearing on the return value).
Matricies in Mathematics
There are several matrix-specific operations in mathematics that are helpful in calculations of objects in space.
Matrix Addition and Subtraction
These operations are generally between two equal-sized matricies. This is a rather simple operation. however, we can assume that the matricies can zero-fill until they are of equal size. If we have two matricies, m and n, the sum of these two is merely mi,j±ni,j for each i and j where 0 ≤ i < # of rows and 0 ≤ j < # of columns.
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Matrix Multiplication
In mathematics, two matricies can be multiplied together to create a third matrix. There is only one rule to multiplying matricies. That is that the number of columns of the first must be equal to the number of rows of the second. A matrix that is a high and b wide can multiply with another matrix that is b high and c wide, but not the reverse. Their products will be a matrix with height a and width c.
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3x3 | 3x1 | 3x1 |
The above example could be used to simply describe the equations of three planes and find the point at which three planes in three dimensions meet (three planes meet at exactly one point, two planes meet at a unique line).