2020MT2_Spirograph_alison - OpenProcessing

mySketch
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// SPIROGRAPH
// http://en.wikipedia.org/wiki/Spirograph
// also (for inspiration):
// http://ensign.editme.com/t43dances
//
// this p5 sketch uses simple transformations to create a
// Spirograph-like effect with interlocking circles (called sines).  
// press the spacebar to switch between tracing and
// showing the underlying geometry.
//
// your tasks:
// (1) tweak the code to change the simulation so that it draws something you like.
// hint: you can change the underlying system, the way it gets traced when you hit the space bar,
// or both.  try to change *both*.  :)
// (2) use p5.sound or tone.js to make the simulation MAKE SOUND.
// hint: the websites for p5.sound and tone.js have lots of examples.
// try and adapt them.
// another hint: javascript isn't super efficient with a large amount of audio playing at once.
// see if there's a simple way to get an effective sound, or limit the number of shapes
// you're working with.
​
var NUMSINES = 12; // how many of these things can we do at once?
var sines = new Array(NUMSINES); // an array to hold all the current angles
var rad; // an initial radius value for the central sine
var i; // a counter variable
​
// play with these to get a sense of what's going on:
var fund = 0.03; // the speed of the central sine
var ratio = 0.01; // what multiplier for speed is each additional sine?
var alpha = 100; // how opaque is the tracing system
​
var trace = false; // are we tracing?
​
var osc;
​
function setup()
{
  createCanvas(windowWidth, windowHeight);
​
  rad = height/4; // compute radius for central circle
  background(255); // clear the screen
​
  for (i = 0; i<sines.length; i++)
  {
    sines[i] = PI; // start EVERYBODY facing NORTH
  }
}
  osc = new p5.Oscillator(); 
  osc.setType('triangle'); 
  osc.amp(0.3);
​
function draw()
{
  if (!trace) {
    background(255); // clear screen if showing geometry
    stroke(0, 255); // black pen
    noFill(); // don't fill
  } 
​
  // MAIN ACTION
  push(); // start a transformation matrix
  translate(width/2, height/2); // move to middle of screen
​
  for (i = 0; i<sines.length; i++) // go through all the sines
  {
    var erad = 0.7; // radius for small "point" within circle... this is the 'pen' when tracing
    // setup for tracing
    if (trace) {
      stroke(random(145), random(26), 255*(float(i)/sines.length), alpha); 
      strokeWeight(random(20));
      fill(random(169), 0, random(105), alpha/2); 
      erad = 1.2*(1.2-float(i)/sines.length); // pen width will be related to which sine
    }
    var radius = rad/(i+1); // radius for circle itself
    rotate(sines[i]*1); // rotate circle
    if (!trace) {
      strokeWeight(random(2,7));
      stroke(random(34),random(98),random(178),90);
      ellipse(0, 0, radius*2.4, radius*2); // if we're simulating, draw the sine
      osc.stop();}
    push(); // go up one level
    translate(0, radius); // move to sine edge
    if (!trace) ellipse(0, 0, 6, 5); // draw a little circle
    if (trace) {
      rect(0, 0, erad*2.5, erad); // draw with erad if tracing
      osc.start();}
    pop(); // go down one level
    translate(0, radius); // move into position for next sine
    sines[i] = (sines[i]+(fund*random(0.6,1.4)+(fund*i*ratio)))%TWO_PI; // update angle based on fundamental
  }
  
  pop(); // pop down final transformation
  
}
​
function keyReleased()
{
  if (key==' ') {
    trace = !trace; 
    background(255);
  }
}
​
function keyTyped(){
  if (key==='!'){
    var r = random(225);
    var g = random(167);
    var b = random(86);
    var al = random(90, 120);
    background(r,g,b,al);
  }
​
}