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So far, I've done research into the design by Armin Hoffman (rubber band design). The objective is to create a grid of circles which can be selected to change from white to black and connect these circles in a natural fluid shape that avoids white circles but never traps them. I've been using Codecademy to learn the basics while copying and studying examples on the p5.js website and additionally following The Coding Train on Youtube (specifically: 7.4 mouse interaction and 7.6 clicking on objects).
Check #MauriceMeilleur on Twitter between Feb 2021 and Aug 2021
Also: https://discourse.processing.org/t/shape-generator-help-armin-hofmanns-rubber-band-shape-generator/33190
Every time I try to make a matrix or array of x and y values stored and to be used in the for loop within the draw/setup functions, it becomes invalid and it doesn't show the shapes I would like.
I know I'm missing info.
This is my latest trial:
class boundingBox {
createBox() {
stroke(0);
strokeWeight(3);
fill(255, 255, 255, 255);
rect(100, 100, 700, 700);
}
}
function Bubble(x, y, x1, y1, x2, y2, x3, y3) {
// creating a distinction from x/y private and x/y public
this.x = x;
this.y = y;
this.x1 = x1;
this.y1 = y1;
this.x2 = x2;
this.y2 = y2;
this.x3 = x3;
this.y3 = y3;
//this.x = x = [225,350,475,600];
//this.y = y = [225,350,475,600];
// creating color public for later use
this.col = color(255);
// this expression works to make a public function within a private function
this.display = function() {
stroke(0);
fill(this.col);
// creating the ability to display the circles within the parameters set
//ellipse(this.x, this.y, 48,48);
// in theory this should loop through the x array position values against all the y values in it's array creating multiple circles
for (i = 0; i < 4; i++) {
ellipse(this.x /*[i]*/ , this.y, 100, 100);
ellipse(this.x1, this.y1, 100, 100);
ellipse(this.x2, this.y2, 100, 100);
ellipse(this.x3, this.y3, 100, 100);
}
}
//this.move = function() {
// //making the circles change position and act like they are moving within air
// this.x = this.x + random(-0.5, 0.5);
// this.y = this.y + random(-0.5, 0.5);
// this.x1 = this.x1 + random(-0.5, 0.5);
// this.y1 = this.y1 + random(-0.5, 0.5);
// //this.x = this.x + random(1, 0.5);
// //this.y = this.y + random(1, 0.5);
//}
// again expression to make function but this time implementing a clicking function
this.clicked = function() {
// calculating the distance from the circle center to help fill it with color and nothing else
var d = dist(mouseX, mouseY, this.x, this.y)
// diameter of the circle
if (d < 50) {
this.col = color(0, 0, 0)
}
}
//joinBubbles(bubbles); {
// bubbles.forEach(element => {
// let dis = dist(this.x, this.y, element.x, element.y);
// stroke(200, 200, 200, 127);
// line(this.x, this.y, element.x, element.y);
// });
//}
//}
//class lines {
// constructor(){
// this.x4 = x4;
// this.y4 = y4;
// this.x5 = x5;
// this.y5 = y5;
// }
// this.displayLine = function(){
// stroke(0)
// }
}
let bubbles = [];
let boxii = [];
function setup() {
createCanvas(1536, 1250);
for (let i = 0; i < 1; i++) {
boxii.push(new boundingBox());
}
for (let i = 200; i < 860; i += 165) {
//var x = random (width);
var x = 200;
var y = i;
bubbles.push(new Bubble(x, y /*x1,y1*/ ));
}
for (let i = 200; i < 860; i += 165) {
//var x = random (width);
var x1 = 375;
var y1 = i;
bubbles.push(new Bubble(x1, y1 /*x1,y1*/ ));
}
for (let i = 200; i < 860; i += 165) {
//var x = random (width);
var x2 = 550;
var y2 = i;
bubbles.push(new Bubble(x2, y2 /*x1,y1*/ ));
}
for (let i = 200; i < 860; i += 165) {
//var x = random (width);
var x3 = 700;
var y3 = i;
bubbles.push(new Bubble(x3, y3 /*x1,y1*/ ));
}
//for (let i = 0; i < 1; i++) {
//var x1 = 400;
//var y1 = 200;
//bubbles.push(new Bubble(x1,y1));
//}
//for (let i = 200; i < 1000; i+=200){
//var x2 = 200;
//var y2 = i;
//bubbles.push(new Bubble(x2,y2));
//}
}
function mousePressed() {
// checking where the mouse presses so that clicking outside the circle does nothing
for (let i = 0; i < bubbles.length; i++) {
//for (let i = 0; i < 4; i++) {
// using this function on all the circles and again using .this to bring properties from /bubble
bubbles[i].clicked();
}
}
function draw() {
background(140);
for (let i = 0; i < 1; i++) {
boxii[i].createBox();
}
for (let i = 0; i < bubbles.length; i++) {
//bubbles[i].move();
bubbles[i].display();
}
if (mousePressed) {
for (let i = 0; i < bubbles.length; i++) {
bubbles[i].display(fill(0))
}
}
}
<script src="https://cdnjs.cloudflare.com/ajax/libs/p5.js/1.4.1/p5.js"></script>
I have created an element called Particle. Single animation of this element also works. But as soon as I try to run multiple animations, only one animation gets performed. I think the problem is the requestAnimationFrame (this.animate.bind(this))-call, but I don't know how to change it to accept multiple animations at once. Any ideas on how to fix this?
Code:
//gloabl vars
let particels = [];
let numberParticels = 120;
let canvas;
let ctx;
let title;
let mesaureTitle;
let boundRadius;
let animations;
window.onload = function () {
this.init();
for(let i = 0; i < numberParticels; i++){
particels[i].update();
particels[i].draw();
particels[i].animate(0);
}
}
function init(){
canvas = document.getElementById("c");
ctx = canvas.getContext("2d");
title = document.getElementById("title");
mesaureTitle = title.getBoundingClientRect();
bound = {
x: mesaureTitle.x,
y: mesaureTitle.y,
width: mesaureTitle.width,
height: mesaureTitle.height,
};
canvas.width = window.innerWidth;
canvas.height = window.innerHeight;
for(let i = 0; i < numberParticels; i++){
let x = Math.floor(Math.random() * window.innerWidth);
let y = Math.floor(Math.random() * window.innerHeight);
let size = Math.floor(Math.random() * 25) + 3;
let weight = Math.floor(Math.random() * 11) + 2;
particels.push(new Particel(x, y, size, weight));
}
}
class Particel {
constructor (x,y,size, weight) {
this.x = x;
this.y = y;
this.size = size;
this.directionX = 0.15332;
this.resetWeight = weight;
this.weight = weight;
this.lastTime = 0;
this.interval = 1000/60;
this.timer = 0;
}
update(){
this.weight += 0.02;
this.y = this.y + this.weight;
this.x += this.directionX;
//check for collision with textField
if (this.x < bound.x + bound.width
&& this.x + this.size > bound.x &&
this.y < bound.y + bound.height &&
this.y + this.size > bound.y) {
this.y -= 3;
this.weight *= -0.3;
}
}
draw(){
if(this.y > canvas.height){
this.y = 0 - this.size;
this.weight = this.resetWeight;
//create random start point
this.x = Math.floor(Math.random() * canvas.width);
}
ctx.fillStyle = "rgb(0, 180, 97)";
ctx.beginPath();
ctx.arc(this.x, this.y, this.size, 0, Math.PI * 2);
ctx.closePath();
ctx.fill();
}
animate(timeStamp){
const deltaTime = timeStamp - this.lastTime;
this.lastTime = timeStamp;
if(this.timer > this.interval){
ctx.clearRect(0,0, canvas.width, canvas.height);
this.update();
this.draw();
this.timer = 0;
}else {
this.timer += deltaTime;
}
ctx.fillStyle = "rgba(0, 0, 0, 0.3)";
requestAnimationFrame(this.animate.bind(this));
}
}
The major problem is clearing the canvas inside the animate method of each particle. So if you draw multiple particles, each particle update call clears the canvas, overwriting previous particle data, which only leaves the last particle visible.
You could try removing the
ctx.clearRect(0,0, canvas.width, canvas.height);
line from where it is and create a createAnimationFrame call back in init to clear the canvas before amimating particles:
function init() {
// ....
requestAnimationFrame( ()=> ctx.clearRect(0,0, canvas.width, canvas.height));
// existing for loop:
for(let i = 0; i < numberParticels; i++){
// ... .
}
However this creates (one plus the number of particles) requests for an animation frame. A better solution would be to remove requesting animation frames from the Particel class and create a single requestAnimationFrame callback which goes through the particels array and calls a class method to redraw each particle on the canvas with updated position.
Also the code generates an error in strict mode that bound has not been declared. I suggest declaring it globally rather than relying on sloppy mode JavaScript creating it as a window property for you.
I'm currently using a canvas animation as the background of my new portfolio page. It works wonderfully until there's more content than can be displayed on a single page, but once you scroll down you'll find the canvas stops at the dimensions of the initial page display even though it's supposed to be the same size as the body element.
I apologize if this is a question that has been answered but I've been looking for a solution all morning and I'm coming up with nothing. Any help you can give is greatly appreciated.
My deployed page can be found here, and below is the JS.
Javascript:
var canvas,
ctx,
circ,
nodes,
mouse,
SENSITIVITY,
SIBLINGS_LIMIT,
DENSITY,
NODES_QTY,
ANCHOR_LENGTH,
MOUSE_RADIUS;
// how close next node must be to activate connection (in px)
// shorter distance == better connection (line width)
SENSITIVITY = 100;
// note that siblings limit is not 'accurate' as the node can actually have more connections than this value that's because the node accepts sibling nodes with no regard to their current connections this is acceptable because potential fix would not result in significant visual difference
// more siblings == bigger node
SIBLINGS_LIMIT = 10;
// default node margin
DENSITY = 50;
// total number of nodes used (incremented after creation)
NODES_QTY = 0;
// avoid nodes spreading
ANCHOR_LENGTH = 20;
// highlight radius
MOUSE_RADIUS = 200;
circ = 2 * Math.PI;
nodes = [];
canvas = document.querySelector("canvas");
resizeWindow();
mouse = {
x: canvas.width / 2,
y: canvas.height / 2
};
ctx = canvas.getContext("2d");
if (!ctx) {
alert("Ooops! Your browser does not support canvas :'(");
}
function Node(x, y) {
this.anchorX = x;
this.anchorY = y;
this.x = Math.random() * (x - (x - ANCHOR_LENGTH)) + (x - ANCHOR_LENGTH);
this.y = Math.random() * (y - (y - ANCHOR_LENGTH)) + (y - ANCHOR_LENGTH);
this.vx = Math.random() * 2 - 1;
this.vy = Math.random() * 2 - 1;
this.energy = Math.random() * 100;
this.radius = Math.random();
this.siblings = [];
this.brightness = 0;
}
Node.prototype.drawNode = function() {
var color = "rgba(216, 48, 168, " + this.brightness + ")";
ctx.beginPath();
ctx.arc(
this.x,
this.y,
2 * this.radius + (2 * this.siblings.length) / SIBLINGS_LIMIT,
0,
circ
);
ctx.fillStyle = color;
ctx.fill();
};
Node.prototype.drawConnections = function() {
for (var i = 0; i < this.siblings.length; i++) {
var color = "rgba(24, 168, 216, " + this.brightness + ")";
ctx.beginPath();
ctx.moveTo(this.x, this.y);
ctx.lineTo(this.siblings[i].x, this.siblings[i].y);
ctx.lineWidth = 1 - calcDistance(this, this.siblings[i]) / SENSITIVITY;
ctx.strokeStyle = color;
ctx.stroke();
}
};
Node.prototype.moveNode = function() {
this.enbergy -= 2;
if (this.energy < 1) {
this.energy = Math.random() * 100;
if (this.x - this.anchorX < -ANCHOR_LENGTH) {
this.vx = Math.random() * 2;
} else if (this.x - this.anchorX > ANCHOR_LENGTH) {
this.vx = Math.random() * -2;
} else {
this.vx = Math.random() * 4 - 2;
}
if (this.y - this.anchorY < -ANCHOR_LENGTH) {
this.vy = Math.random() * 2;
} else if (this.y - this.anchorY > ANCHOR_LENGTH) {
this.vy = Math.random() * -2;
} else {
this.vy = Math.random() * 4 - 2;
}
}
this.x += (this.vx * this.energy) / 100;
this.y += (this.vy * this.energy) / 100;
};
function initNodes() {
ctx.clearRect(0, 0, canvas.width, canvas.height);
nodes = [];
for (var i = DENSITY; i < canvas.width; i += DENSITY) {
for (var j = DENSITY; j < canvas.height; j += DENSITY) {
nodes.push(new Node(i, j));
NODES_QTY++;
}
}
}
function calcDistance(node1, node2) {
return Math.sqrt(
Math.pow(node1.x - node2.x, 2) + Math.pow(node1.y - node2.y, 2)
);
}
function findSiblings() {
var node1, node2, distance;
for (var i = 0; i < NODES_QTY; i++) {
node1 = nodes[i];
node1.siblings = [];
for (var j = 0; j < NODES_QTY; j++) {
node2 = nodes[j];
if (node1 !== node2) {
distance = calcDistance(node1, node2);
if (distance < SENSITIVITY) {
if (node1.siblings.length < SIBLINGS_LIMIT) {
node1.siblings.push(node2);
} else {
var node_sibling_distance = 0;
var max_distance = 0;
var s;
for (var k = 0; k < SIBLINGS_LIMIT; k++) {
node_sibling_distance = calcDistance(node1, node1.siblings[k]);
if (node_sibling_distance > max_distance) {
max_distance = node_sibling_distance;
s = k;
}
}
if (distance < max_distance) {
node1.siblings.splice(s, 1);
node1.siblings.push(node2);
}
}
}
}
}
}
}
function redrawScene() {
resizeWindow();
ctx.clearRect(0, 0, canvas.width, canvas.height);
findSiblings();
var i, node, distance;
for (i = 0; i < NODES_QTY; i++) {
node = nodes[i];
distance = calcDistance(
{
x: mouse.x,
y: mouse.y
},
node
);
if (distance < MOUSE_RADIUS) {
node.brightness = 1 - distance / MOUSE_RADIUS;
} else {
node.brightness = 0;
}
}
for (i = 0; i < NODES_QTY; i++) {
node = nodes[i];
if (node.brightness) {
node.drawNode();
node.drawConnections();
}
node.moveNode();
}
requestAnimationFrame(redrawScene);
}
function initHandlers() {
document.addEventListener("resize", resizeWindow, false);
canvas.addEventListener("mousemove", mousemoveHandler, false);
}
function resizeWindow() {
canvas.width = window.innerWidth;
canvas.height = window.innerHeight;
}
function mousemoveHandler(e) {
mouse.x = e.clientX;
mouse.y = e.clientY;
}
initHandlers();
initNodes();
redrawScene();
})();
Set the canvas width property to document.body.scrollHeight, that's the full height of the document
Set the canvas height property to document.body.clientWidth, that's the full width of the document minus the scroll bar.
Change the height style of the canvas to fit-content or remove it. height: 100% will make it as high as the viewport.
I'm trying to create a hyperdrive effect, like from Star Wars, where the stars have a motion trail. I've gotten as far as creating the motion trail on a single circle, it still looks like the trail is going down in the y direction and not forwards or positive in the z direction.
Also, how could I do this with (many) randomly placed circles as if they were stars?
My code is on jsfiddle (https://jsfiddle.net/5m7x5zxu/) and below:
var canvas = document.querySelector("canvas");
var context = canvas.getContext("2d");
var xPos = 180;
var yPos = 100;
var motionTrailLength = 16;
var positions = [];
function storeLastPosition(xPos, yPos) {
// push an item
positions.push({
x: xPos,
y: yPos
});
//get rid of first item
if (positions.length > motionTrailLength) {
positions.pop();
}
}
function update() {
context.clearRect(0, 0, canvas.width, canvas.height);
for (var i = positions.length-1; i > 0; i--) {
var ratio = (i - 1) / positions.length;
drawCircle(positions[i].x, positions[i].y, ratio);
}
drawCircle(xPos, yPos, "source");
var k=2;
storeLastPosition(xPos, yPos);
// update position
if (yPos > 125) {
positions.pop();
}
else{
yPos += k*1.1;
}
requestAnimationFrame(update);
}
update();
function drawCircle(x, y, r) {
if (r == "source") {
r = 1;
} else {
r*=1.1;
}
context.beginPath();
context.arc(x, y, 3, 0, 2 * Math.PI, true);
context.fillStyle = "rgba(255, 255, 255, " + parseFloat(1-r) + ")";
context.fill();
}
Canvas feedback and particles.
This type of FX can be done many ways.
You could just use a particle systems and draw stars (as lines) moving away from a central point, as the speed increase you increase the line length. When at low speed the line becomes a circle if you set ctx.lineWidth > 1 and ctx.lineCap = "round"
To add to the FX you can use render feedback as I think you have done by rendering the canvas over its self. If you render it slightly larger you get a zoom FX. If you use ctx.globalCompositeOperation = "lighter" you can increase the stars intensity as you speed up to make up for the overall loss of brightness as stars move faster.
Example
I got carried away so you will have to sift through the code to find what you need.
The particle system uses the Point object and a special array called bubbleArray to stop GC hits from janking the animation.
You can use just an ordinary array if you want. The particles are independent of the bubble array. When they have moved outside the screen they are move to a pool and used again when a new particle is needed. The update function moves them and the draw Function draws them I guess LOL
The function loop is the main loop and adds and draws particles (I have set the particle count to 400 but should handle many more)
The hyper drive is operated via the mouse button. Press for on, let go for off. (It will distort the text if it's being displayed)
The canvas feedback is set via that hyperSpeed variable, the math is a little complex. The sCurce function just limits the value to 0,1 in this case to stop alpha from going over or under 1,0. The hyperZero is just the sCurve return for 1 which is the hyper drives slowest speed.
I have pushed the feedback very close to the limit. In the first few lines of the loop function you can set the top speed if(mouse.button){ if(hyperSpeed < 1.75){ Over this value 1.75 and you will start to get bad FX, at about 2 the whole screen will just go white (I think that was where)
Just play with it and if you have questions ask in the comments.
const ctx = canvas.getContext("2d");
// very simple mouse
const mouse = {x : 0, y : 0, button : false}
function mouseEvents(e){
mouse.x = e.pageX;
mouse.y = e.pageY;
mouse.button = e.type === "mousedown" ? true : e.type === "mouseup" ? false : mouse.button;
}
["down","up","move"].forEach(name => document.addEventListener("mouse"+name,mouseEvents));
// High performance array pool using buubleArray to separate pool objects and active object.
// This is designed to eliminate GC hits involved with particle systems and
// objects that have short lifetimes but used often.
// Warning this code is not well tested.
const bubbleArray = () => {
const items = [];
var count = 0;
return {
clear(){ // warning this dereferences all locally held references and can incur Big GC hit. Use it wisely.
this.items.length = 0;
count = 0;
},
update() {
var head, tail;
head = tail = 0;
while(head < count){
if(items[head].update() === false) {head += 1 }
else{
if(tail < head){
const temp = items[head];
items[head] = items[tail];
items[tail] = temp;
}
head += 1;
tail += 1;
}
}
return count = tail;
},
createCallFunction(name, earlyExit = false){
name = name.split(" ")[0];
const keys = Object.keys(this);
if(Object.keys(this).indexOf(name) > -1){ throw new Error(`Can not create function name '${name}' as it already exists.`) }
if(!/\W/g.test(name)){
let func;
if(earlyExit){
func = `var items = this.items; var count = this.getCount(); var i = 0;\nwhile(i < count){ if (items[i++].${name}() === true) { break } }`;
}else{
func = `var items = this.items; var count = this.getCount(); var i = 0;\nwhile(i < count){ items[i++].${name}() }`;
}
!this.items && (this.items = items);
this[name] = new Function(func);
}else{ throw new Error(`Function name '${name}' contains illegal characters. Use alpha numeric characters.`) }
},
callEach(name){var i = 0; while(i < count){ if (items[i++][name]() === true) { break } } },
each(cb) { var i = 0; while(i < count){ if (cb(items[i], i++) === true) { break } } },
next() { if (count < items.length) { return items[count ++] } },
add(item) {
if(count === items.length){
items.push(item);
count ++;
}else{
items.push(items[count]);
items[count++] = item;
}
return item;
},
getCount() { return count },
}
}
// Helpers rand float, randI random Int
// doFor iterator
// sCurve curve input -Infinity to Infinity out -1 to 1
// randHSLA creates random colour
// CImage, CImageCtx create image and image with context attached
const randI = (min, max = min + (min = 0)) => (Math.random() * (max - min) + min) | 0;
const rand = (min = 1, max = min + (min = 0)) => Math.random() * (max - min) + min;
const doFor = (count, cb) => { var i = 0; while (i < count && cb(i++) !== true); }; // the ; after while loop is important don't remove
const sCurve = (v,p) => (2 / (1 + Math.pow(p,-v))) -1;
const randHSLA = (h, h1, s = 100, s1 = 100, l = 50, l1 = 50, a = 1, a1 = 1) => { return `hsla(${randI(h,h1) % 360},${randI(s,s1)}%,${randI(l,l1)}%,${rand(a,a1)})` }
const CImage = (w = 128, h = w) => (c = document.createElement("canvas"),c.width = w,c.height = h, c);
const CImageCtx = (w = 128, h = w) => (c = CImage(w,h), c.ctx = c.getContext("2d"), c);
// create image to hold text
var textImage = CImageCtx(1024, 1024);
var c = textImage.ctx;
c.fillStyle = "#FF0";
c.font = "64px arial black";
c.textAlign = "center";
c.textBaseline = "middle";
const text = "HYPER,SPEED FX,VII,,Battle of Jank,,Hold the mouse,button to increase,speed.".split(",");
text.forEach((line,i) => { c.fillText(line,512,i * 68 + 68) });
const maxLines = text.length * 68 + 68;
function starWarIntro(image,x1,y1,x2,y2,pos){
var iw = image.width;
var ih = image.height;
var hh = (x2 - x1) / (y2 - y1); // Slope of left edge
var w2 = iw / 2; // half width
var z1 = w2 - x1; // Distance (z) to first line
var z2 = (z1 / (w2 - x2)) * z1 - z1; // distance (z) between first and last line
var sk,t3,t3a,z3a,lines, z3, dd = 0, a = 0, as = 2 / (y2 - y1);
for (var y = y1; y < y2 && dd < maxLines; y++) { // for each line
t3 = ((y - y1) * hh) + x1; // get scan line top left edge
t3a = (((y+1) - y1) * hh) + x1; // get scan line bottom left edge
z3 = (z1 / (w2 - t3)) * z1; // get Z distance to top of this line
z3a = (z1 / (w2 - t3a)) * z1; // get Z distance to bottom of this line
dd = ((z3 - z1) / z2) * ih; // get y bitmap coord
a += as;
ctx.globalAlpha = a < 1 ? a : 1;
dd += pos; // kludge for this answer to make text move
// does not move text correctly
lines = ((z3a - z1) / z2) * ih-dd; // get number of lines to copy
ctx.drawImage(image, 0, dd , iw, lines, t3, y, w - t3 * 2, 1.5);
}
}
// canvas settings
var w = canvas.width;
var h = canvas.height;
var cw = w / 2; // center
var ch = h / 2;
// diagonal distance used to set point alpha (see point update)
var diag = Math.sqrt(w * w + h * h);
// If window size is changed this is called to resize the canvas
// It is not called via the resize event as that can fire to often and
// debounce makes it feel sluggish so is called from main loop.
function resizeCanvas(){
points.clear();
canvas.width = innerWidth;
canvas.height = innerHeight;
w = canvas.width;
h = canvas.height;
cw = w / 2; // center
ch = h / 2;
diag = Math.sqrt(w * w + h * h);
}
// create array of points
const points = bubbleArray();
// create optimised draw function itterator
points.createCallFunction("draw",false);
// spawns a new star
function spawnPoint(pos){
var p = points.next();
p = points.add(new Point())
if (p === undefined) { p = points.add(new Point()) }
p.reset(pos);
}
// point object represents a single star
function Point(pos){ // this function is duplicated as reset
if(pos){
this.x = pos.x;
this.y = pos.y;
this.dead = false;
}else{
this.x = 0;
this.y = 0;
this.dead = true;
}
this.alpha = 0;
var x = this.x - cw;
var y = this.y - ch;
this.dir = Math.atan2(y,x);
this.distStart = Math.sqrt(x * x + y * y);
this.speed = rand(0.01,1);
this.col = randHSLA(220,280,100,100,50,100);
this.dx = Math.cos(this.dir) * this.speed;
this.dy = Math.sin(this.dir) * this.speed;
}
Point.prototype = {
reset : Point, // resets the point
update(){ // moves point and returns false when outside
this.speed *= hyperSpeed; // increase speed the more it has moved
this.x += Math.cos(this.dir) * this.speed;
this.y += Math.sin(this.dir) * this.speed;
var x = this.x - cw;
var y = this.y - ch;
this.alpha = (Math.sqrt(x * x + y * y) - this.distStart) / (diag * 0.5 - this.distStart);
if(this.alpha > 1 || this.x < 0 || this.y < 0 || this.x > w || this.h > h){
this.dead = true;
}
return !this.dead;
},
draw(){ // draws the point
ctx.strokeStyle = this.col;
ctx.globalAlpha = 0.25 + this.alpha *0.75;
ctx.beginPath();
ctx.lineTo(this.x - this.dx * this.speed, this.y - this.dy * this.speed);
ctx.lineTo(this.x, this.y);
ctx.stroke();
}
}
const maxStarCount = 400;
const p = {x : 0, y : 0};
var hyperSpeed = 1.001;
const alphaZero = sCurve(1,2);
var startTime;
function loop(time){
if(startTime === undefined){
startTime = time;
}
if(w !== innerWidth || h !== innerHeight){
resizeCanvas();
}
// if mouse down then go to hyper speed
if(mouse.button){
if(hyperSpeed < 1.75){
hyperSpeed += 0.01;
}
}else{
if(hyperSpeed > 1.01){
hyperSpeed -= 0.01;
}else if(hyperSpeed > 1.001){
hyperSpeed -= 0.001;
}
}
var hs = sCurve(hyperSpeed,2);
ctx.globalAlpha = 1;
ctx.setTransform(1,0,0,1,0,0); // reset transform
//==============================================================
// UPDATE the line below could be the problem. Remove it and try
// what is under that
//==============================================================
//ctx.fillStyle = `rgba(0,0,0,${1-(hs-alphaZero)*2})`;
// next two lines are the replacement
ctx.fillStyle = "Black";
ctx.globalAlpha = 1-(hs-alphaZero) * 2;
//==============================================================
ctx.fillRect(0,0,w,h);
// the amount to expand canvas feedback
var sx = (hyperSpeed-1) * cw * 0.1;
var sy = (hyperSpeed-1) * ch * 0.1;
// increase alpha as speed increases
ctx.globalAlpha = (hs-alphaZero)*2;
ctx.globalCompositeOperation = "lighter";
// draws feedback twice
ctx.drawImage(canvas,-sx, -sy, w + sx*2 , h + sy*2)
ctx.drawImage(canvas,-sx/2, -sy/2, w + sx , h + sy)
ctx.globalCompositeOperation = "source-over";
// add stars if count < maxStarCount
if(points.getCount() < maxStarCount){
var cent = (hyperSpeed - 1) *0.5; // pulls stars to center as speed increases
doFor(10,()=>{
p.x = rand(cw * cent ,w - cw * cent); // random screen position
p.y = rand(ch * cent,h - ch * cent);
spawnPoint(p)
})
}
// as speed increases make lines thicker
ctx.lineWidth = 2 + hs*2;
ctx.lineCap = "round";
points.update(); // update points
points.draw(); // draw points
ctx.globalAlpha = 1;
// scroll the perspective star wars text FX
var scrollTime = (time - startTime) / 5 - 2312;
if(scrollTime < 1024){
starWarIntro(textImage,cw - h * 0.5, h * 0.2, cw - h * 3, h , scrollTime );
}
requestAnimationFrame(loop);
}
requestAnimationFrame(loop);
canvas { position : absolute; top : 0px; left : 0px; }
<canvas id="canvas"></canvas>
Here's another simple example, based mainly on the same idea as Blindman67, concetric lines moving away from center at different velocities (the farther from center, the faster it moves..) also no recycling pool here.
"use strict"
var c = document.createElement("canvas");
document.body.append(c);
var ctx = c.getContext("2d");
var w = window.innerWidth;
var h = window.innerHeight;
var ox = w / 2;
var oy = h / 2;
c.width = w; c.height = h;
const stars = 120;
const speed = 0.5;
const trailLength = 90;
ctx.fillStyle = "#000";
ctx.fillRect(0, 0, w, h);
ctx.fillStyle = "#fff"
ctx.fillRect(ox, oy, 1, 1);
init();
function init() {
var X = [];
var Y = [];
for(var i = 0; i < stars; i++) {
var x = Math.random() * w;
var y = Math.random() * h;
X.push( translateX(x) );
Y.push( translateY(y) );
}
drawTrails(X, Y)
}
function translateX(x) {
return x - ox;
}
function translateY(y) {
return oy - y;
}
function getDistance(x, y) {
return Math.sqrt(x * x + y * y);
}
function getLineEquation(x, y) {
return function(n) {
return y / x * n;
}
}
function drawTrails(X, Y) {
var count = 1;
ctx.fillStyle = "#000";
ctx.fillRect(0, 0, w, h);
function anim() {
for(var i = 0; i < X.length; i++) {
var x = X[i];
var y = Y[i];
drawNextPoint(x, y, count);
}
count+= speed;
if(count < trailLength) {
window.requestAnimationFrame(anim);
}
else {
init();
}
}
anim();
}
function drawNextPoint(x, y, step) {
ctx.fillStyle = "#fff";
var f = getLineEquation(x, y);
var coef = Math.abs(x) / 100;
var dist = getDistance( x, y);
var sp = speed * dist / 100;
for(var i = 0; i < sp; i++) {
var newX = x + Math.sign(x) * (step + i) * coef;
var newY = translateY( f(newX) );
ctx.fillRect(newX + ox, newY, 1, 1);
}
}
body {
overflow: hidden;
}
canvas {
position: absolute;
left: 0;
top: 0;
}
I'm trying to learn HTML5 and found a very simple particle system wich i modded a bit.
I would like to create a line, between particles, if the distance between the particles is within the range 0-20.
What I currently have draws a line between every particle, no matter the distance.
This is where I try to check the distance, but I can't figure out how to do this. Would appreciate any help and explanations. Thanks in advance.
// This particle
var p = particles[t];
// Check position distance to other particles
for (var q = 0; q < particles.length; q++) {
if (particles[q].x - p.x < line_distance || p.x - particles[q].x < line_distance) {
ctx.beginPath();
ctx.lineWidth = .1;
ctx.strokeStyle = '#fff';
ctx.moveTo(p.x, p.y);
ctx.lineTo(particles[q].x, particles[q].y);
ctx.stroke();
}
}
// Request animation frame
var requestAnimationFrame = window.requestAnimationFrame ||
window.mozRequestAnimationFrame ||
window.webkitRequestAnimationFrame ||
window.msRequestAnimationFrame;
// Canvas
var canvas = document.getElementById('canvas');
var ctx = canvas.getContext('2d');
// Set fullscreen
canvas.width = document.documentElement.clientWidth;
canvas.height = document.documentElement.clientHeight;
// Options
var num =30; // Number of particles to draw
var size = 3; // Particle size
var color = '#fff'; // Particle color
var min_speed = 1; // Particle min speed
var max_speed = 3; // Particle max speed
var line_distance = 20; // This is the max distance between two particles
// if we want to draw a line between them
// Particles array
var particles = [];
for (var i = 0; i < num; i++) {
particles.push(
new create_particle()
);
}
// Lets animate the particle
function draw() {
// Background
ctx.fillStyle = "#000";
ctx.fillRect(0, 0, canvas.width, canvas.height);
// Lets draw particles from the array now
for (var t = 0; t < particles.length; t++) {
// This particle
var p = particles[t];
for (var q = 0; q < particles.length; q++) {
// Check position distance
if (particles[q].x - p.x < line_distance || p.x - particles[q].x < line_distance) {
ctx.beginPath();
ctx.lineWidth = .1;
ctx.strokeStyle = '#fff';
ctx.moveTo(p.x, p.y);
ctx.lineTo(particles[q].x, particles[q].y);
ctx.stroke();
}
}
// Color
ctx.fillStyle = color;
// Circle path
ctx.beginPath();
ctx.arc(p.x, p.y, p.radius, Math.PI * 2, false);
ctx.fill();
// Lets use the velocity now
p.x += p.vx;
p.y += p.vy;
// If there is only 1 particle
// show X, Y, and velocity
if (num === 1) {
ctx.fillText('Y:'+ p.y, 20, 20);
ctx.fillText('X:'+ p.x, 20, 40);
ctx.fillText('YV:'+ p.vy, 20, 60);
ctx.fillText('XV:'+ p.vx, 20, 80);
}
// To prevent the balls from moving out of the canvas
if (p.x < size) p.vx*= (p.vx / -p.vx);
if (p.y < size) p.vy*= (p.vy / -p.vy);
if (p.x > canvas.width - size) p.vx*= (-p.vx / p.vx);
if (p.y > canvas.height - size) p.vy*= (-p.vy / p.vy);
}
// Loop
requestAnimationFrame(draw);
}
// Function for particle creation
function create_particle() {
// Random position
this.x = Math.random() * canvas.width;
this.y = Math.random() * canvas.height;
// Velocity
this.vx = random_int_between(min_speed, max_speed);
this.vy = random_int_between(min_speed, max_speed);
// Color & Size
this.color = color;
this.radius = size;
}
// Random number between (used for speed)
function random_int_between(min, max) {
return Math.floor(Math.random() * max) + min;
}
draw();
<canvas id="canvas"></canvas>
N body Particle systems
As this is an N body case and no one said anything about CPU load.
CPU Load
Particle systems can quickly bog down a CPU in an overload of processing. This is particularly true when you are testing each particle against the other. As particle systems are almost always for realtime graphics ineffective coding can destroy the whole animation.
Do nothing not needed
First as you are only looking for a threshold distance you can optimise the calculations by not continuing to calculate as soon as you know that there is a fail in the test.
So set up the threshold distance
var dist = 20;
var distSq = dist * dist; // No need to square this inside loops
Then in the loop as you calculate test and continue. Assuming p1 and p2 are particles
x = p2.x-p1.x; // do x first
if((x *= x) < distSq){ // does it pass?? if not you have saved calculating y
y = p2.y-p1.y; // now do y as you know x is within distance
if(x + (y * y) < distSq){ // now you know you are within 20
// draw the line
Assuming only 1/6 will pass and 1/3 come close you save over half the CPU load. You will also notice that I don't use the CPU heavy sqrt of the distance. There is no need as there is a one to one match between a number and the square of a number. If the square root of a number is less than the distance so will the square of the number be less than the square of the distance.
N body Squared
Never do a N body sim with two for loops like this.
for(i = 0; i < particles.length; i ++){
for(j = 0; j < particles.length; j ++){
// you will test all i for j and all j for i but half of them are identical
// and the square root of the number are self to self
This hurts me just to look at as the solution is so so simple.
Assuming you have 100 particles at 60 frames a second you are doing 60 * 100 * 100 comparisons a second (600,000) for 100 particles. Thats is a total waste of CPU time.
Never do something twice, or that you know the answer to.
To improve the for loops and avoid testing distances you already know and testing how far each particle is from itself
var len = particles.length; // move the length out as it can be expensive
// and pointless as the value does not change;
for(i = 0; i < len; i ++){
for(j = i + 1; j < len; j ++){
// Now you only test each particle against each other once rather than twice
Thus with just a few simple characters (for(j = 0 becomes for(j = i + 1) you more than half the CPU load, from 600,000 comparisons down to less than 300,000
The human eye is easy to fool
Fooling the eye is the best way to get extra performance from your animations.
This is a visual effect and the human eye does not see pixels nor does it it see individual frames at 1/60th a second, but it does see a drop in frame rate. Creating a complex particle system can an excellent FX but if it drops the frame rate the benefit is lost. Take advantage of the fact that pixels are to small and 1/20th of a second is way beyond the human ability to find error is the best way to optimise FXs and add more bang per CPU tick.
The demo below has two particle sims. 100 points each. Any points that come within 49 pixels have a line drawn between them. One does all the stuff I demonstrated above the other sacrifices a little memory and a lot off acuracy and only calculates the distances between 1/3rd of the points every frame. As the max speed can be close to half the line length a frame, skipping 2 frames can make a line twice as long or two points be too close without a line. There is a massive CPU saving in doing this, but you can not pick which is which.
Click on which sim you think is skipping points to find out which is which.
var canvas = document.createElement("canvas");
canvas.width= 540;
canvas.height = 270;
var ctx = canvas.getContext("2d");
document.body.appendChild(canvas);
mouseX = 0;
mouseB = false;
function clickedFun(event){
mouseX = event.clientX
mouseB = true;
}
canvas.addEventListener("click",clickedFun);
var w = 250;
var h = 250;
var wh = w/2;
var hh = h/2;
var speedMax = 5;
var partSize = 2;
var count = 100
var grav = 1;
var pA1 = []; // particle arrays
var pA2 = [];
var PI2 = Math.PI * 2;
// populate particle arrays
for(var i = 0; i < count; i += 1){
// dumb list
pA1.push({
x : Math.random() * w,
y : Math.random() * h,
dx : (Math.random() -0.5)*speedMax,
dy : (Math.random() -0.5)*speedMax,
})
// smart list
pA2.push({
x : Math.random() * w,
y : Math.random() * h,
dx : (Math.random() -0.5)*speedMax,
dy : (Math.random() -0.5)*speedMax,
links : [], // add some memory
})
for(var j = 0; j < count; j += 1){
pA2[i].links[i] = false; // set memory to no links
}
}
// move and draw the dots. Just a simple gravity sim
function drawAll(parts){
var x,y,d;
var i = 0;
var len = parts.length;
var p;
ctx.beginPath();
for(;i < len; i++){
p = parts[i];
x = wh-p.x;
y = hh-p.y;
d = x*x + y*y;
x *= grav / d;
y *= grav / d;
p.dx += x;
p.dy += y;
p.x += p.dx;
p.y += p.dy;
if(p.x <= 0){
p.dx -= p.dx/2;
p.x = 1;
}else
if(p.x >= w){
p.dx -= p.dx/2;
p.x = w-1;
}
if(p.y <= 0){
p.dy -= p.dy/2;
p.y = 1;
}else
if(p.y >= h){
p.dy -= p.dy/2;
p.y = w-1;
}
ctx.moveTo(p.x+partSize,p.y)
ctx.arc(p.x,p.y,partSize,0,PI2)
}
ctx.fill();
}
//Old style line test. If two particles are less than dist apart
// draw a line between them
function linesBetween(parts,dist){
var distSq = dist*dist;
var x,y,d,j;
var i = 0;
var len = parts.length;
var p,p1;
ctx.beginPath();
for(; i < len; i ++){
p = parts[i];
for(j = i + 1; j < len; j ++){
p1 = parts[j];
x = p1.x-p.x;
if((x *= x) < distSq){
y = p1.y-p.y;
if(x + (y*y) < distSq){
ctx.moveTo(p.x,p.y);
ctx.lineTo(p1.x,p1.y)
}
}
}
}
ctx.stroke();
}
var counter = 0;// counter for multyplexing
// Fast version. As the eye can not posible see the differance of
// of 4 pixels over 1/30th of a second only caculate evey third
// particls
function linesBetweenFast(parts,dist){
var distSq = dist*dist;
var x,y,d,j,l;
var i = 0;
counter += 1;
var cc = counter % 3;
var wr,re;
var len = parts.length;
var p,p1;
var lineSet
ctx.beginPath();
for(; i < len; i ++){
p = parts[i];
l = p.links;
for(j = i + 1; j < len; j += 1){
p1 = parts[j];
if((j + cc)%3 === 0){ // only every third particle
lineSet = false; // test for diferance default to fail
x = p1.x-p.x;
if((x *= x) < distSq){
y = p1.y-p.y;
if(x + (y*y) < distSq){
lineSet = true; // yes this needs a line
}
}
l[j] = lineSet; // flag it as needing a line
}
if(l[j]){ // draw the line if needed
ctx.moveTo(p.x,p.y);
ctx.lineTo(p1.x,p1.y);
}
}
}
ctx.stroke();
}
var drawLines; // to hold the function that draws lines
// set where the screens are drawn
var left = 10;
var right = 10 * 2 + w;
// Now to not cheat swap half the time
if(Math.random() < 0.5){
right = 10;
left = 10 * 2 + w;
}
// draws a screem
var doScreen = function(parts){
ctx.fillStyle = "red"
drawAll(parts);
ctx.strokeStyle = "black";
ctx.lineWidth = 1;
drawLines(parts,49);
}
var guess = ""
var guessPos;
var gueesCol;
ctx.font = "40px Arial Black";
ctx.textAlign = "center";
ctx.textBasline = "middle"
var timer = 0;
function update(){
ctx.setTransform(1,0,0,1,0,0);
ctx.clearRect(0,0,canvas.width,canvas.height);
ctx.setTransform(1,0,0,1,left,10);
ctx.strokeStyle = "red";
ctx.lineWidth = 4;
ctx.strokeRect(0,0,w,h);
drawLines = linesBetween;
doScreen(pA1)
ctx.setTransform(1,0,0,1,right,10);
ctx.strokeStyle = "red";
ctx.lineWidth = 4;
ctx.strokeRect(0,0,w,h);
drawLines = linesBetweenFast
doScreen(pA2)
if(mouseB){
if((mouseX > 270 && right >250) ||
(mouseX < 250 && right < 250)){
guess = "CORRECT!"
guessPos = right;
guessCol = "Green";
}else{
guess = "WRONG"
guessPos = left
guessCol = "Red";
}
timer = 120;
mouseB = false;
}else
if(timer > 0){
timer -= 1;
if(timer > 30){
ctx.setTransform(1,0,0,1,guessPos,10);
ctx.font = "40px Arial Black";
ctx.fillStyle = guessCol;
ctx.fillText(guess,w/2,h/2);
}else{
if(Math.random() < 0.5){
right = 10;
left = 10 * 2 + w;
}else{
left = 10;
right = 10 * 2 + w;
}
}
}else{
ctx.setTransform(1,0,0,1,0,0);
ctx.font = "16px Arial Black";
var tw = ctx.measureText("Click which sim skips 2/3rd of").width +30;
ctx.beginPath();
ctx.fillStyle = "#DDD";
ctx.strokeStyle = "Red";
ctx.rect(270-tw/2,-5,tw,40);
ctx.stroke();
ctx.fill();
ctx.fillStyle = "blue";
ctx.fillText("Click which sim skips 2/3rd of",270,15) ;
ctx.fillText("particle tests every frame",270,30) ;
}
requestAnimationFrame(update);
}
update();
This is just your test which is wrong.
a-b < c || b-a < c is always true (except if a-b == c)
replace by abs(a-b) < c if you want to test "x" distance, or by using the above formula if you want an euclidian distance
// Request animation frame
var requestAnimationFrame = window.requestAnimationFrame ||
window.mozRequestAnimationFrame ||
window.webkitRequestAnimationFrame ||
window.msRequestAnimationFrame;
// Canvas
var canvas = document.getElementById('canvas');
var ctx = canvas.getContext('2d');
// Set fullscreen
canvas.width = document.documentElement.clientWidth;
canvas.height = document.documentElement.clientHeight;
// Options
var num =30; // Number of particles to draw
var size = 3; // Particle size
var color = '#fff'; // Particle color
var min_speed = 1; // Particle min speed
var max_speed = 3; // Particle max speed
var line_distance = 20; // This is the max distance between two particles
// if we want to draw a line between them
// Particles array
var particles = [];
for (var i = 0; i < num; i++) {
particles.push(
new create_particle()
);
}
// Lets animate the particle
function draw() {
// Background
ctx.fillStyle = "#000";
ctx.fillRect(0, 0, canvas.width, canvas.height);
// Lets draw particles from the array now
for (var t = 0; t < particles.length; t++) {
// This particle
var p = particles[t];
for (var q = 0; q < particles.length; q++) {
// Check position distance
if (Math.abs(particles[q].x - p.x) < line_distance) {
ctx.beginPath();
ctx.lineWidth = .1;
ctx.strokeStyle = '#fff';
ctx.moveTo(p.x, p.y);
ctx.lineTo(particles[q].x, particles[q].y);
ctx.stroke();
}
}
// Color
ctx.fillStyle = color;
// Circle path
ctx.beginPath();
ctx.arc(p.x, p.y, p.radius, Math.PI * 2, false);
ctx.fill();
// Lets use the velocity now
p.x += p.vx;
p.y += p.vy;
// If there is only 1 particle
// show X, Y, and velocity
if (num === 1) {
ctx.fillText('Y:'+ p.y, 20, 20);
ctx.fillText('X:'+ p.x, 20, 40);
ctx.fillText('YV:'+ p.vy, 20, 60);
ctx.fillText('XV:'+ p.vx, 20, 80);
}
// To prevent the balls from moving out of the canvas
if (p.x < size) p.vx*= (p.vx / -p.vx);
if (p.y < size) p.vy*= (p.vy / -p.vy);
if (p.x > canvas.width - size) p.vx*= (-p.vx / p.vx);
if (p.y > canvas.height - size) p.vy*= (-p.vy / p.vy);
}
// Loop
requestAnimationFrame(draw);
}
// Function for particle creation
function create_particle() {
// Random position
this.x = Math.random() * canvas.width;
this.y = Math.random() * canvas.height;
// Velocity
this.vx = random_int_between(min_speed, max_speed);
this.vy = random_int_between(min_speed, max_speed);
// Color & Size
this.color = color;
this.radius = size;
}
// Random number between (used for speed)
function random_int_between(min, max) {
return Math.floor(Math.random() * (max-min)) + min;
}
draw();
<canvas id="canvas" width="300" height="300"></canvas>
// Request animation frame
var requestAnimationFrame = window.requestAnimationFrame ||
window.mozRequestAnimationFrame ||
window.webkitRequestAnimationFrame ||
window.msRequestAnimationFrame;
// Canvas
var canvas = document.getElementById('canvas');
var ctx = canvas.getContext('2d');
// Set fullscreen
canvas.width = document.documentElement.clientWidth;
canvas.height = document.documentElement.clientHeight;
// Options
var num =30; // Number of particles to draw
var size = 3; // Particle size
var color = '#fff'; // Particle color
var min_speed = 1; // Particle min speed
var max_speed = 3; // Particle max speed
var line_distance = 20; // This is the max distance between two particles
// if we want to draw a line between them
// Particles array
var particles = [];
for (var i = 0; i < num; i++) {
particles.push(
new create_particle()
);
}
// Lets animate the particle
function draw() {
// Background
ctx.fillStyle = "#000";
ctx.fillRect(0, 0, canvas.width, canvas.height);
// Lets draw particles from the array now
for (var t = 0; t < particles.length; t++) {
// This particle
var p = particles[t];
for (var q = 0; q < particles.length; q++) {
// Check position distance
if (particles[q].x - p.x < line_distance || p.x - particles[q].x < line_distance) {
ctx.beginPath();
ctx.lineWidth = .1;
ctx.strokeStyle = '#fff';
ctx.moveTo(p.x, p.y);
ctx.lineTo(particles[q].x, particles[q].y);
ctx.stroke();
}
}
// Color
ctx.fillStyle = color;
// Circle path
ctx.beginPath();
ctx.arc(p.x, p.y, p.radius, Math.PI * 2, false);
ctx.fill();
// Lets use the velocity now
p.x += p.vx;
p.y += p.vy;
// If there is only 1 particle
// show X, Y, and velocity
if (num === 1) {
ctx.fillText('Y:'+ p.y, 20, 20);
ctx.fillText('X:'+ p.x, 20, 40);
ctx.fillText('YV:'+ p.vy, 20, 60);
ctx.fillText('XV:'+ p.vx, 20, 80);
}
// To prevent the balls from moving out of the canvas
if (p.x < size) p.vx*= (p.vx / -p.vx);
if (p.y < size) p.vy*= (p.vy / -p.vy);
if (p.x > canvas.width - size) p.vx*= (-p.vx / p.vx);
if (p.y > canvas.height - size) p.vy*= (-p.vy / p.vy);
}
// Loop
requestAnimationFrame(draw);
}
// Function for particle creation
function create_particle() {
// Random position
this.x = Math.random() * canvas.width;
this.y = Math.random() * canvas.height;
// Velocity
this.vx = random_int_between(min_speed, max_speed);
this.vy = random_int_between(min_speed, max_speed);
// Color & Size
this.color = color;
this.radius = size;
}
// Random number between (used for speed)
function random_int_between(min, max) {
return Math.floor(Math.random() * max) + min;
}
draw();
<canvas id="canvas"></canvas>
To calculate the distance between two points, you should use pythagoras theorem:
length = sqrt(a² + b²)
Where a is the length of one side, and b is the length of the other side.
var a = (x2 - x1);
var b = (y2 - y1);
var sum = (a * a) + (b * b);
var length = Math.sqrt(sum);
This can be turned into a function, since you know you'll have particles that have an x and y.
function calcLength(particle1, particle2) {
var xDiff = particle2.x - particle1.x;
var yDiff = particle2.y - particle1.y;
var sum = (xDiff * xDiff) + (yDiff * yDiff);
return Math.sqrt(sum);
}
Then you can use that function in your code:
for (var t = 0; t < particles.length; t++) {
var p = particles[t];
for (var q = 0; q < particles.length; q++) {
var p2 = particles[q];
if (calcLength(p, p2) < 20) {
// draw a line between the particles
}
}
}
To calculate the distance between two points you use the pythagorean theorem. http://www.purplemath.com/modules/distform.htm
// Request animation frame
var requestAnimationFrame = window.requestAnimationFrame ||
window.mozRequestAnimationFrame ||
window.webkitRequestAnimationFrame ||
window.msRequestAnimationFrame;
// Canvas
var canvas = document.getElementById('canvas');
var ctx = canvas.getContext('2d');
// Set fullscreen
canvas.width = document.documentElement.clientWidth;
canvas.height = document.documentElement.clientHeight;
// Options
var num =30; // Number of particles to draw
var size = 3; // Particle size
var color = '#fff'; // Particle color
var min_speed = 1; // Particle min speed
var max_speed = 3; // Particle max speed
var line_distance = 20; // This is the max distance between two particles
// if we want to draw a line between them
// Particles array
var particles = [];
for (var i = 0; i < num; i++) {
particles.push(
new create_particle()
);
}
// Lets animate the particle
function draw() {
// Background
ctx.fillStyle = "#000";
ctx.fillRect(0, 0, canvas.width, canvas.height);
// Lets draw particles from the array now
for (var t = 0; t < particles.length; t++) {
// This particle
var p = particles[t];
for (var q = 0; q < particles.length; q++) {
// Check position distance
if (distance(particles[q], p) < line_distance) {
ctx.beginPath();
ctx.lineWidth = 1;
ctx.strokeStyle = '#fff';
ctx.moveTo(p.x, p.y);
ctx.lineTo(particles[q].x, particles[q].y);
ctx.stroke();
}
}
// Color
ctx.fillStyle = color;
// Circle path
ctx.beginPath();
ctx.arc(p.x, p.y, p.radius, Math.PI * 2, false);
ctx.fill();
// Lets use the velocity now
p.x += p.vx;
p.y += p.vy;
// If there is only 1 particle
// show X, Y, and velocity
if (num === 1) {
ctx.fillText('Y:'+ p.y, 20, 20);
ctx.fillText('X:'+ p.x, 20, 40);
ctx.fillText('YV:'+ p.vy, 20, 60);
ctx.fillText('XV:'+ p.vx, 20, 80);
}
// To prevent the balls from moving out of the canvas
if (p.x < size) p.vx*= (p.vx / -p.vx);
if (p.y < size) p.vy*= (p.vy / -p.vy);
if (p.x > canvas.width - size) p.vx*= (-p.vx / p.vx);
if (p.y > canvas.height - size) p.vy*= (-p.vy / p.vy);
}
// Loop
requestAnimationFrame(draw);
}
// Function for particle creation
function create_particle() {
// Random position
this.x = Math.random() * canvas.width;
this.y = Math.random() * canvas.height;
// Velocity
this.vx = random_int_between(min_speed, max_speed);
this.vy = random_int_between(min_speed, max_speed);
// Color & Size
this.color = color;
this.radius = size;
}
// Random number between (used for speed)
function random_int_between(min, max) {
return Math.floor(Math.random() * max) + min;
}
draw();
function distance(pointA, pointB){
var dx = pointB.x - pointA.x;
var dy = pointB.y - pointA.y;
return Math.sqrt(dx*dx + dy*dy);
}
<canvas id="canvas"></canvas>
Please note I increased the lineWidth to 1, so you could see better the result
You have a coordinate system - use the Pythagorean theorem.