Author: methylDragon
Contains a syntax reference for MATLAB!
I'll be adapting it from the ever amazing Derek Banas: https://www.youtube.com/watch?v=NSSTkkKRabI
- Systems
MATLAB stands for Matrix Laboratory. It's a very famous program used for working with matrices.
There are two main windows you'll really type into in MATLAB:
- The Command Window
- It's like a terminal! You can define variables here, call functions, and use it like a calculator
- The Editor
- You can write scripts here that you can use in the command window!
There's a third section known as the Workspace, where you can inspect your variables!
If you ever need to ask for help, either Google for it, or use the help function in the command window!
help <function>Be sure to ensure that all scripts you want to write are in MATLAB Path, in other words, that they are accessible and visible to MATLAB.
In the file explorer on the left, you may add folders and subfolders to your path by right clicking and selecting Add To Path. Alternatively, you may double click on a folder to focus it and add it to Path, since your Path also includes your current focused folder!
clc % Clear command window (does not clear variables)
clf % Clear figures
clear % Clear everything
clear all % Clear everything
clear <variable> % Clear single variableformat compact % Keeps output compact!Use CTRL-c to stop executing a particular command!
Precision is set to 15 digits by default. But you can configure that!
Click on New Script to start creating a new script!
% Single Comment
%{
multi
line
comment!
%}You can also use CTRL-r to comment and CTRL-t to uncomment!
Everything is a double by default in MATLAB.
a = 5 % a is now 5! Yay!Data Types:
- int8, int16, int32, int64
- char
- logical (Booleans)
- double
- single (Value without a decimal place)
- uint8
c1 = 'A'
class(c1) % Prints the class/type of the variable!
s1 = 'A string'
class(s1) % With single quotes, the class is 'char'
s2 = "A string"
class(s2) % With double quotes, the class is 'string'
5 > 2 % Logical 1
b1 = true % Logical 1To get the maximum number you can store, you can use these! The maximum and minimums differ depending on the number type. The example list I'm writing below is non-exhaustive.
% For ints
intmax('int8')
intmin('int8')
% For doubles
realmax
% For singles
realmax('single')I really shouldn't need to explain this... You can use MATLAB like a calculator, and the results can go into variables!
a = 1 + 2 + 3 + 4 + 5
5 + 5 % Add
5 - 5 % Subtract
5 * 5 % Multiply
5 / 5 % Divide
5 ^ 4 % Exponent
mod(5, 4) % Mod (get remainder)
% NOTE! MATLAB doesn't have increment and decrement operators. So you can't do stuff like a++, b--, etc.v2 = 8
v3 = int8(v2) % Like so!Just write the appropriate class identifier and use it like a function!
% Use this to display vectors and numbers!
disp(some_vector_variable)
% Use this to print strings!
fprintf("Hello world!")
% sprintf prints as a string
sprintf('5 + 4 = %d\n', 5 + 4)
% With the %d here, it transplants the next variable argument into the string!Using the ; suppresses the input printout after the user has entered the input!
Note:
"might not work in some versions of MATLAB as a string delineator. Use'in that case.
String Input
% String Input
% Notice the '' escapes the second quote
name = input('What''s your name : ', 's');
% Let's use this if statement to print the input out! (~ means not)
if ~isempty(name)
fprinf('Hello %s\n', name)
endVector Input
vInput = input('Enter a vector : ');
disp(vInput)help elfun for a whole list of math functions
randi([10, 20]) % Random int
abs(-1) % Returns 1
floor(2.45) % Returns 2
ceil(2.45) % Returns 3
round(2.45) % Returns 2
exp(1) % e^x
log(100) % Log base e (ln)
log10(100) % Log base 10
log2(100) % Log base 2
sqrt(100) % Square root
deg2rad(90)
rad2deg(3.14)> % More than
< % Less than
>= % More than or equal to
<= % Less than or equal to
== % Equal to
~= % Not equal to
|| % Or
&& % And
~ % NotIf block
if <condition>
<do something>
elseif <condition>
<do something else>
else
<do something entirely different>
end % REMEMBER TO END!!!Switch Statement
switch score
case 1
disp("Aw")
case 2
disp("Better")
case 3
disp("You get the point")
otherwise
disp("WHO NAMED IT OTHERWISE OMG")
end % REMEMBER TO ENDThey're one dimensional rows or columns!
THE INDEXING FOR MATLAB STARTS AT 1, NOT 0!!!!
% Row Vectors
vector_1 = [5 3 2 1] % Yep!
vector_2 [5, 3, 2, 1] % Both are valid ways!
% Column Vectors
vector_3 = [5; 3; 2; 1]
% Index into the vectors
vector_1(1) % 5
vector_1(end) % 1 (Last value)
vector([1 2 3]) % Get first, second, and third value in vector
% Get range
vector_1(1:3) % First to third
% Change at index
vector_1(1) = 6
% Transpose Vector
a = [1 2 3]
a' % This is now 1, 2, 3 as a column!Vector Operations
a = [2; 3; 4]
b = [1 2 3]
a * b
% 2 4 6
% 3 6 9
% 4 8 2vector_1 = [1 2 3 4 5]
length(vector_1)
sort(vector_1, 'descend')
% Create ranges
5 : 10 % Gives you [5 6 7 8 9 10]
2 : 2 : 10 % Gives you [2 4 6 8 10]
% Concatenate
a = [1 2 3]
b = [4 5 6]
[a b] % [1 2 3 4 5 6]
% Dot Product (Either...)
a * b' % Transpose as needed
dot(a, b) % Self explanatory
% Cross Product
cross(a, b) % Nice
% Linspace
linspace(1, 20, 4) % Generates 4 numbers equally spaced between 1 and 20
% Logspace
logspace(1, 3, 3) % Like linspace, but the spacing is logarithmicIt's MATLAB, not Vector lab.
matrix_a = [2 3 4; 4 6 8] % 2 rows, 3 columns (2x3)
length(matrix_a) % Gets you 3 (columns)
numel(matrix_a) % Number of values in matrix (6)
size(matrix_a) % Rows, then Columns (2 3)
% Generate random matrices!
randi([10, 20], 2)
% Index into matrices
a = [1 2 3; 4 5 6; 7 8 9]
a(1, 2) = 22 % Index into single value
a(1, :) = 25 % Change all row values
a(:, 2) % Change all column values
a(end, 1) % Last row
a(1, end) % Last column
% To delete a value, just literally put a semicolon at the end.
a(1, 2) = ;
% Multiply matrices
a * b
% Element-wise multiplication
a .* b % Take note of the period!
% Other matrix stuffffff
a - b
a + bThe list is not exhaustive!
Use the help command to find out how these work! They're overloaded functions.
eye()
ones()
zeros()
diag()sqrt(a) % Square root all values in matrix
sum(a) % Sum all columns
sum(a, 'all') % Sum all entries
prod(a) % Multiply all column values
cumsum(a, 'reverse') % Cumulative sum. First row stays the same, each row after is the sum of the preceding and current row (reverse makes it go in reverse)
cumsum(a) % Or if you don't want it reversed..
cumprod(a) % Cumulative product.
det() % Determinant
inv() % Inverseisequal(a, b) % Check for equality
a > 3 % Apply conditional to all entries
find(a > 24) % Gives you index of entries that fulfill the conditionfliplr(a) % Flip left to right
flipud(a) % Flip up down
rot90(a) % Rotate 90 degrees
rot90(a, 2) % Rotate 180 degrees
reshape(a, 2, 6) % Reshape into 2x6, it's like numpy!
repmat(a, 2, 1) % Duplicate matrix into new matrix. Eg. If original matrix was 3x3, doing repmat(a, 2, 1) makes it 6x3
repelem(m3, 2, 1) % Duplicates ELEMENTS, so in this case, each element is duplicated twice in terms of the rowFor loops! It's pretty Pythonic. It iterates through a range.
% Loop from 1 to 10 and print it
for i = 1:10
disp(i)
end % REMEMBER TO END
% MORE EXAMPLES
% Print every value in matrix
a = [1 2 3; 4 5 6]
for i = 1:2
for j = 1:3
disp(a(i, j))
end
end
% Print for undetermined length
b = [6 7 8]
for i = 1:length(b)
disp(b(i))
endi = 1 % You must create the variable first!
while i < 20
if(mod(i, 2)) == 0
disp(i)
i = i + 1; % Semicolon suppresses the print
continue
end % This end is for i
i = i + 1;
if i >= 10
break
end
endYou can store data of multiple types
cell_A = {'Hi', 35, [25 8 19]}
cell_B = cell(5) % Create the cell spaces first
cell_A{1} % Get first element
cell_A{3}(2) % Index further
cell_A{4} = 'Something else'
cell_A(4) = ; % Delete
for i = 1:length(cell_A)
disp(cell_A{i})
end
% You can cast character arrays into cell arrays too!
a = ['A', 'BB', 'CCC']
char_array = cellstr(a)Strings are vectors of characters!
str_1 = 'I am a string'
length(str_1)
% Index into a string
str_1(1)
str_1(3:4) % Slices
% Concatenation
str = strcat(str1, ' and now I''m longer!')
% Look for substring
strfind(str, 'a') % Returns indexes of all found substrings
% Replace string
strrep(str, 'longer', 'bigger')
% Split string
str_array = strsplit(str, ' ') % Splits at all spaces. Makes a string array
% Convert numbers to string
int2str(99)
num2str(3.14)
% Check for equality
strcmp(str1, str2)
% Check if is char
ischar('Rawr!11!!1')
% Check if a string is just made of letters
isletter('num 2') % Logical 0
isstrprop('word2', 'alpha')
% Check if string is made of alphanumeric characters
isstrprop('word2', 'alphanum') % Logical 1
% Sort
sort(str, 'descend')
% Delete whitespace (it's like .strip() in python)
strtrim(str)
% Lower and Uppercase conversion
lower(str)
upper(str)Custom data types! Think C++ structs! Or Python dictionaries/maps.
methyl_struct = struct('name', 'methylDragon', ... % the ... lets you skip down to the next line (:
'species', ' Dragon')
disp(methyl_struct.name) % methylDragon
% Add a new field!
methyl_struct.sound = 'Rawr'
% Delete a field
methyl_struct = rmfield(methyl_struct, 'sound')
% Check if field exists
isfield(methyl_struct, 'species')
% Get all field names
fieldnames(methyl_struct)
% Store structures in vectors!
a(1) = methyl_structTables are labelled rows of data in a table format
Get help table if you need help.
a = {'A'; 'B'; 'C'; 'D'};
b = [29; 42; 1; 2]
c = {'AA', 'BB', 'CC', 'DD'}
% Create a table!!! We'll specify a as the index now
test_table = table(a, b, c, 'RowName', a)
% You can do cool stuff with tables!
mean(test_table.b) % For example.. find the means
% Add new fields
test_table.d = [1; 2; 3]
% Pull specific entries
test_table({'A', 'B'}, :) % This defaults to using the RowName as indexer
% Pull specific entries, using another row
a(ismember(test_table.b, {29, 42},:)% Let's just make a random matrix first
rand_matrix = randi([10, 50], 8)
% Let's save and load some files!
save sampdata.dat rand_matrix -ascii
load sampdata.dat
disp sampdata
type sampdata.dat
% We can save variables in a file as well!
save params % Leaving no arguments saves all variables you have on hand
load params
who % Display it on the screen
a = 123
save -append params a % This appends to the normal variableIf you know Python you should know what this does already.
Eval executes strings as code!
toExecute = spritnf('total = %d + %d', 5, 4)
eval(toExecute) % Executes it as:
% total = 5 + 4You can pause in MATLAB too! Think of it like Arduino delay() or Python time.sleep()
pause(5) % Pause for 5 seconds
pause off % Disable pause
pause on % Enable pauseFunctions have to come at the end of your file!
Local and global variable rules still apply! Local variables defined in functions don't change outside of the function! Just take note!
% Function to calculate volume
% The return is defined by the name preceding the =
% The name of the function is the name following the =
% In this case, the return is 'vol' and the function name is 'cylinderVol'
function vol = cylinderVol(radius, height)
vol = pi radius^2 * height
end
% Let's try another one! This time a function with no arguments
function randNum = getRandomNum
randNum = randi([1, 100])
end
% Return more than one value
[coneV, cylVol] = getVols(10, 20) % I'll call the function here, and define it below
function [coneVol, cylinVol] = getVols(radius, height)
cylinVol = pi * radius^2 * height
coneVol = 1/3 * cylinVol
end
% Variable Number of Arguments
function sum = getSum(varargin)
sum = 0;
for k = 1:length(varargin)
sum = sum + varargin{k}(1);
end
end
% Return variable number of outputs
function [varargout] = getNumbers(howMany)
for k = 1:howMany
varargout{1}(k) = k;
end
endNo named functions! Think lambda in python
cubeVol = @ (l, w, h) l * w * h; % (input) output
a = cubeVol(2, 2, 2) % Gives you 8! Correct!Pass Function to another Function
Think decorators!
Source: https://www.youtube.com/watch?v=NSSTkkKRabI
mult3 = @ (x) x * 3;
sol = doMath(mult3, 4)
function sol = doMath(func, num)
sol = func(num);
endReturning Functions
Source: https://www.youtube.com/watch?v=NSSTkkKRabI
mult4 = doMath2(4);
sol2 = mult4(5)
function func = doMath2(num)
func = @(x) x * num;
endThey call themselves!
function val = factorial(num)
if num == 1
val = 1;
else
val = num * factorial(num - 1);
end
endStatic members are shared amongst all members of a class
classdef Shape
properties % Variables!!!
height
width
end
methods(Static)
function out = setGetNumShapes(data)
% Persistent values are shared by all objects also
persistent Var;
if isempty(Var)
Var = 0;
end
if nargin % Number of input arguments
Var = Var + data
end
out = Var;
end
end
methods
% Define a constructor
function obj = Shape(height, width)
obj.height = height
obj.width = width
obj.setGetNumShapes(1)
end
% Overloaded disp function
% If you don't know what overloading is, check my C++ tutorial. It basically overwrites the functionality of a pre-existing function if the argument number matches
function disp(obj)
fprintf('Height : %.2f / Width : %.2f\n', obj.height, obj.width)
end
function area = getArea(obj)
area = obj.height * obj.width;
end
% Overload Greater Than function
function tf = gt(obja, objb)
tf = obja.getArea > objb.getArea
end
end
endLet's try using it!
a1 = Shape(10, 20)
disp(a1)
Shape.setGetNumShapes
a1.getArea
a2 = Shape(5, 10)
disp(a2)
Shape.setGetNumShapes
a1 > a2classdef Trapezoid < Shape % Trapezoid inherits from Shape
properties
width2
end
methods
function obj = Trapezoid(height, width, width2)
obj@Shape(height,width) % The @ sign means you're taking it from the parent
% In this case we're using Shape's constructor!
obj.width2 = width2
end
function disp(obj)
fprint('Height : %.2f / Width : %.2f / Width2 : %.2f', obj.height, obj.width, obj.width2);
end
function area = getArea(obj)
area = (obj.height/2) * (obj.width + obj.width2);
end
end
endLet's try it out!
a3 = Trapezoid(10, 4, 6)
disp(a3)
a3.getAreaSource: https://www.youtube.com/watch?v=NSSTkkKRabI
help plot for help!
xVals = 1:5
yVals = [2 4 8 5 9]
yVals2 = [1 5 7 6 8]
figure(1)
plot(xVals, yVals, 'g+', 'LineWidth', 2)
hold on % Draw over what was plotted, keep plot settings
plot(xVals, yVals2, 'k*')
legend('yVals', 'yVals2')
grid on % Turn grid on
xlabel('Days')
ylabel('Money')
title('Money Made Today')
figure(2)
bar(xVals, yVals, 'r')
% Colors : blue(b), black(k), cyan(c), green(g),
% magenta(m), red(r), yellow(y), white(y)
% Plot Symbols : . o x + * s d v ^ < > p h
% Line Types : -, :, -., - -
% Set font weights and the like
% gca is the axis object, gcf is the figure object
set(gca, 'FontWeight', 'bold', 'FontSize', 20, 'color', 'white');
set(gcf, 'color', 'white')
clf % Delete all figuresy = A.*cos(2*pi .* t/T - 2*pi .* x/lambda + phi0);
plot3() % Use this instead of plot2!
% Example
t = 0: pi/50 : 10*pi;
plot3(sin(t), cos(t), t)
% Meshgrids
meshgrid()% Plot surfaces
cylinder()
sphere()
surf() % Plot a surface
isosurface() % For when plotting normal surfaces are too hard
contour() % Plot a contour map insteadquiver() % 2D
quiver3() % 3D
colorbar % Add a colorbar!gradient()
divergence()
curl()
del2() % Discrete laplacian . .
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