Difference between revisions of "MATLAB:Logical Masks"

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==== Simplification ====
 
==== Simplification ====
You do not need to give each mask and function a name - rather, you can compute the masks and multiply them by their appropriate function segments, all in one function line.  For example, the <code>GPA</code> variable above could be calculated as:
+
You do not need to (and should not) give each mask and function a name - rather, you can compute the masks and multiply them by their appropriate function segments, all in one function line.  For example, the <code>GPA</code> variable above could be calculated as:
 
<source lang="matlab">
 
<source lang="matlab">
 
Grade=linspace(0, 100, 1000);
 
Grade=linspace(0, 100, 1000);

Latest revision as of 03:32, 10 February 2020

Introduction

Many times, you will see functions that are written in some kind of piecewise fashion. That is, depending upon that value of the input argument, the output argument may be calculated in one of several different ways. In these cases, you can use MATLAB's logical and relational arguments to create logical masks - matrices containing either 0's or 1's - to help determine the appropriate calculation to perform to determine the values in a matrix.

Important Note

The examples in Piecewise Constant and Non-constant Piecewise Functions use scripts and are not creating functions. To see how to create a function that employs logical masks, pay particular attention to Using Logical Masks in Functions and especially note that all the mask and function calculations are performed inside the function.

Piecewise Constant

Sometimes, piecewise functions are broken up into several regions, with each region being defined by a single constant. These are called piecewise constant functions and can be easily generated in MATLAB.

Example - GPA Calculation

Take for example GPA as a function of numerical grade (assume \(\pm\)do not exist for the moment...). The mathematical statement of GPA might be:

\( \mbox{GPA}(\mbox{Grade})=\left\{ \begin{array}{rl} \mbox{Grade}\geq 90~~~ & 4.0\\ 80\leq\mbox{Grade} ~\And~ \mbox{Grade}<90~~~ & 3.0\\ 70\leq\mbox{Grade} ~\And~ \mbox{Grade}<80~~~ & 2.0\\ 60\leq\mbox{Grade} ~\And~ \mbox{Grade}<70~~~ & 1.0\\ \mbox{Grade}<60~~~ & 0.0 \end{array} \right. \)

If you want to write this table as a function that can accept multiple inputs at once, you really should not use an if-tree (because if-trees can only run one program segment for the entire matrix) or a for loop (because for loops are slower and more complex for this particular situation). Instead, use MATLAB's ability to create logical masks. Look at the following code:

Grade=linspace(0, 100, 1000);
MaskForA = Grade>=90;

The variable MaskForA will be the same size of the Grade variable, and will contain only 0's and 1's -- 0 when the logical expression is false and 1 when it is true. Given that, you can use this in conjunction with the function for an "A" grade to start building the GPA variable:

Grade=linspace(0, 100, 1000);
MaskForA = Grade>=90;
FunctionForA = 4.0;
GPA = MaskForA.*FunctionForA;

At the end of this code, the GPA variable will contain a 4.0 wherever the logical mask MaskForA was a 1 and it will contain a 0.0 wherever the logical mask was a 0. All that is required is to extend this to the rest of the possible GPA's - the full code is in the section below, along with an image of the graph it will create. Note the use of the continuation ... to write the commands in the same visual way the function definition is written - this is not required, but does make the code easier to interpret. Also, the axes of the graph have been changed using the axis command so that the graph is not directly on top of the border of the plot. Without this change, the "A" portion of the graph would be hidden by the top edge of the figure boundary.

Code and Graph

Grade=linspace(0, 100, 1000);
MaskForA = Grade>=90;
FunctionForA = 4.0;
MaskForB = 80<=Grade & Grade<90;
FunctionForB = 3.0;
MaskForC = 70<=Grade & Grade<80;
FunctionForC = 2.0;
MaskForD = 60<=Grade & Grade<70;
FunctionForD = 1.0;
MaskForF = Grade<60;
FunctionForF = 0.0;
GPA = ...
     MaskForA.*FunctionForA + ... 
     MaskForB.*FunctionForB + ... 
     MaskForC.*FunctionForC + ... 
     MaskForD.*FunctionForD + ... 
     MaskForF.*FunctionForF;
plot(Grade, GPA)
axis([0 100 -1 5])
xlabel('Numerical Grade')
ylabel('GPA')
title('GPA vs. Grade for EGR 103L (mrg)')
print -deps GPAPlot

GPAPlot.png

For a further explanation, look at the following code (which involves fewer points which are not in any particular order):

ClassGrades=[95 70 68 38 94 84 92 87];
MaskForA = ClassGrades>=90;
FunctionForA = 4.0;
MaskForB = 80<=ClassGrades & ClassGrades<90;
FunctionForB = 3.0;
MaskForC = 70<=ClassGrades & ClassGrades<80;
FunctionForC = 2.0;
MaskForD = 60<=ClassGrades & ClassGrades<70;
FunctionForD = 1.0;
MaskForF = ClassGrades<60;
FunctionForF = 0.0;
GPA = ...
     MaskForA.*FunctionForA + ... 
     MaskForB.*FunctionForB + ... 
     MaskForC.*FunctionForC + ... 
     MaskForD.*FunctionForD + ... 
     MaskForF.*FunctionForF;

The masks now looks like:

MaskForA: [1  0  0  0  1  0  1  0]
MaskForB: [0  0  0  0  0  1  0  1]
MaskForC: [0  1  0  0  0  0  0  0]
MaskForD: [0  0  1  0  0  0  0  0]
MaskForF: [0  0  0  1  0  0  0  0]

and the product of each of the masks with each of the functions produces:

MaskForA.*FunctionForA: [4  0  0  0  4  0  4  0]
MaskForB.*FunctionForB: [0  0  0  0  0  3  0  3]
MaskForC.*FunctionForC: [0  2  0  0  0  0  0  0]
MaskForD.*FunctionForD: [0  0  1  0  0  0  0  0]
MaskForF.*FunctionForF: [0  0  0  0  0  0  0  0]

These five matrices are added together to give:

GPA: [4  2  1  0  4  3  4  3]

Simplification

You do not need to (and should not) give each mask and function a name - rather, you can compute the masks and multiply them by their appropriate function segments, all in one function line. For example, the GPA variable above could be calculated as:

Grade=linspace(0, 100, 1000);
GPA = ...
     (Grade>=90)            .* (4.0) + ...
     (80<=Grade & Grade<90) .* (3.0) + ...
     (70<=Grade & Grade<80) .* (2.0) + ...
     (60<=Grade & Grade<70) .* (1.0) + ...
     (Grade<60)             .* (0.0)

Just make sure each mask is surrounded by parenthesis, each function segment (in this case, a constant) is surrounded by parenthesis, and the appropriate masks and function segments are element multiplied.

Non-constant Piecewise Functions

Sometimes, piecewise functions are defined as following different formulas involving the independent variable over a range of inputs rather than being piece-wise constant.

Example 1 - Discrete Function

For example, the expression:

\( f(x)=\left\{ \begin{array}{rl} x<0 & 0\\ 0\leq x<5 & x\\ 5\leq x<10 & 5\\ x\geq 10 & 2x-15 \end{array} \right. \)

which, for integers -2:1:12 can be calculated and graphed:

Code and Graph

x = -2:12
Mask1 = x<0;
Function1 = 0;
Mask2 = (0<=x) & (x<5);
Function2 = x;
Mask3 = (5<=x) & (x<10);
Function3 = 5
Mask4 = x>=10;
Function4 = 2*x-15;
f = ...
     Mask1.*Function1 + ... 
     Mask2.*Function2 + ... 
     Mask3.*Function3 + ... 
     Mask4.*Function4;
stem(x, f)
axis([-3 13 -1 10])
xlabel('x')
ylabel('f(x)')
title('f(x) (NET ID)')
print -deps PFunction

PFunction.png

Several of these variables are presented below. Note that the spacing in this document is set to make it easier to see which elements in one variable are paired up with equivalent elements in another variable (for example, to determine the element-multiplication of Mask2 and Function2). Given the code above, the masks are:

Mask1: [  1   1   0   0   0   0   0   0   0   0   0   0   0   0   0]
Mask2: [  0   0   1   1   1   1   1   0   0   0   0   0   0   0   0]
Mask3: [  0   0   0   0   0   0   0   1   1   1   1   1   0   0   0]
Mask4: [  0   0   0   0   0   0   0   0   0   0   0   0   1   1   1]

Notice how the masks end up spanning the entire domain of \(x\) without overlapping. The functions - as calculated over the entire domain, are:

Function1: [0]
Function2: [ -2  -1   0   1   2   3   4   5   6   7   8   9  10  11  12]
Function3: [5]
Function4: [-19 -17 -15 -13 -11  -9  -7  -5  -3  -1   1   3   5   7   9]

The individual products of the masks and the functions give:

Mask1.*Function1: [  0   0   0   0   0   0   0   0   0   0   0   0   0   0   0]
Mask2.*Function2: [  0   0   0   1   2   3   4   0   0   0   0   0   0   0   0]
Mask3.*Function3: [  0   0   0   0   0   0   0   5   5   5   5   5   0   0   0]
Mask4.*Function4: [  0   0   0   0   0   0   0   0   0   0   0   0   5   7   9]

Finally, when these are all added together, none of the individual products interfere with each other, so:

f: [  0   0   0   1   2   3   4   5   5   5   5   5   5   7   9]

Simplification

Once again, the code above takes up far more space than it needs to in order to individually calculate each component part of the solution. In practice, the code would be:

x = -2:12
f = ...
   (x<0)         .* (0) + ...
   (0<=x & x<5)  .* (x) + ...
   (5<=x & x<10) .* (5) + ...
   (x>=10)       .* (2*x-15);
stem(x, f)
axis([-3 13 -1 10])
xlabel('x')
ylabel('f(x)')
title('f(x) (NET ID)')
print -deps PFunction


Example 2 - Acceleration Due To Gravity

The following example determines the acceleration due to gravity for a sphere a particular distance away from the center of a sphere of constant density \(\rho\) and radius R. The formula changes depending on whether you are inside the sphere's surface or not. That is:

\( \mbox{Gravity}(r)= \left\{ \begin{array}{lr} r<=R & \frac{4}{3}\pi G\rho r\\ r>R & \frac{4}{3}\pi G \rho\frac{R^3}{r^2} \end{array} \right. \)

You can use the same method as the example above, making sure to calculate the values of the function rather than simply using constants. The following code and graph demonstrate:

Code and Graph

G = 6.67e-11; rho = 5515; R = 6371e3;
Position=linspace(0, 2*R, 1000);
MaskForInside = Position<=R;
FunctionForInside = 4/3*pi*G*rho*Position;
MaskForOutside = Position>R;
FunctionForOutside = 4/3*pi*G*rho*R.^3./Position.^2;
Gravity = ...
     MaskForInside.*FunctionForInside + ... 
     MaskForOutside.*FunctionForOutside;
plot(Position, Gravity, 'k-');
xlabel('Position from Center of Earth (m)');
ylabel('Gravity (m/s^2)');
title('Gravity vs. Position for Earth (mrg)');
print -deps GravityPlot

GravityPlot.png

Note that this code will generate a warning since the first value of Position is 0 and the second function requires division by that variable. Still, this is just a warning, and MATLAB does produce the plot shown above, despite the warning.

Using Logical Masks in Functions

Any of these tasks can be done using inline functions or function files. For the gravity example, you could create a function - say, GravFun.m for this problem. Regarding simplifying the code, as mentioned above, make sure each mask is surrounded by parentheses, each function segment is surrounded by parentheses, and the appropriate masks and function segments are element multiplied. In that case, your function file and script file might be:

Function file, GravFun.m

function out = GravFun(r, rho, R)
G = 6.67e-11;
out = (r<=R) .* (4/3*pi*G*rho*r) + ...
      (r>R)  .* (4/3*pi*G*rho*R.^3./r.^2);

Script file, RunGravFun.m

rho = 5515; R = 6371e3;
Position=linspace(0, 2*R, 1000);
Gravity = GravFun(Position, rho, R);
plot(Position, Gravity, 'k-');
xlabel('Position from Center of Earth (m)');
ylabel('Gravity (m/s^2)');
title('Gravity vs. Position for Earth (mrg)');
print -deps GravityPlot2

You could also write an anonymous function in a script to compute the gravity:

rho = 5515; R = 6371e3; G = 6.67e-11;
Position=linspace(0, 2*R, 1000);
GravFun = @(r, rho, R) (r<=R) .* (4/3*pi*G*rho*r) + ...
                 (r>R)  .* (4/3*pi*G*rho*R.^3./r.^2);
Gravity = GravFun(Position, rho, R);
plot(Position, Gravity, 'k-');
xlabel('Position from Center of Earth (m)');
ylabel('Gravity (m/s^2)');
title('Gravity vs. Position for Earth (mrg)');
print -deps GravityPlot3

Note in this case the constants rho, R, and G need to be defined before the anonymous function is created.

Questions

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External Links

References