# Drawing a spiral on an HTML canvas using JavaScript

I have searched and haven't found anything really on how to draw spirals in canvas using JavaScript.

I thought it might be possible to do it with the bezier curve and if that didn't work use `lineTo()`, but that seemed a lot harder.

Also, to do that I'm guessing I would have to use trigonometry and graphing with polar coordinates and its been a while since I did that. If that is the case could you point me in the right direction on the math.

• what kind of spiral?: en.wikipedia.org/wiki/Spiral Jul 26, 2011 at 1:53
• Do you have a particular type of spiral in mind?
– Gabe
Jul 26, 2011 at 1:53
• I was thinking something like the Archimedean spiral. Preferably I could adjust some parameters to get a range of different spirals.
– qw3n
Jul 26, 2011 at 1:58

The Archimedean spiral is expressed as `r=a+b(angle)`. Convert that into x, y coordinate, it will be expressed as `x=(a+b*angle)*cos(angle)`, `y=(a+b*angle)*sin(angle)`. Then you can put angle in a for loop and do something like this:

``````for (i=0; i< 720; i++) {
angle = 0.1 * i;
x=(1+angle)*Math.cos(angle);
y=(1+angle)*Math.sin(angle);
context.lineTo(x, y);
}
``````

Note the above assumes a = 1 and b = 1.

Here is a jsfiddle link: http://jsfiddle.net/jingshaochen/xJc7M/

• This worked except to get the sprial you need to set the increment to something like `i+=.1` as it is, it looks like polygons.
– qw3n
Jul 26, 2011 at 2:28
• Mild variation in this fiddle jsfiddle.net/pTymD with variable angle increment for speed: `var incr = angle ? 1/(a + b*angle) : 0.1;`. This avoids oversampling at low angles and undersampling at high ones by aiming at 1px line lengths. Oct 18, 2012 at 9:12
• Can you show a modified jsfiddle? I wasn't able to implement your suggestion. Jun 24, 2016 at 13:44
• @geoidesic What modification do you mean? Jun 24, 2016 at 16:26
• Sorry, that comment of mine was @Phil H. Jun 25, 2016 at 20:45

This is a slightly-changed, javascript-ified version of a Java spiral I once borrowed from here

It uses `lineTo()` and its not all that hard.

``````<!DOCTYPE HTML>
<html><body>
<canvas id="myCanvas" width="300" height="300" style="border:1px solid #c3c3c3;"></canvas>
<script type="text/javascript">
var c=document.getElementById("myCanvas");
var cxt=c.getContext("2d");
var centerX = 150;
var centerY = 150;
cxt.moveTo(centerX, centerY);

var STEPS_PER_ROTATION = 60;
var increment = 2*Math.PI/STEPS_PER_ROTATION;
var theta = increment;

while( theta < 40*Math.PI) {
var newX = centerX + theta * Math.cos(theta);
var newY = centerY + theta * Math.sin(theta);
cxt.lineTo(newX, newY);
theta = theta + increment;
}
cxt.stroke();
</script></body></html>
``````

Here's a function I wrote for drawing Archimedean spirals:

``````CanvasRenderingContext2D.prototype.drawArchimedeanSpiral =
CanvasRenderingContext2D.prototype.drawArchimedeanSpiral ||
function(centerX, centerY, stepCount, loopCount,
innerDistance, loopSpacing, rotation)
{
this.beginPath();

var stepSize = 2 * Math.PI / stepCount,
endAngle = 2 * Math.PI * loopCount,
finished = false;

for (var angle = 0; !finished; angle += stepSize) {
// Ensure that the spiral finishes at the correct place,
// avoiding any drift introduced by cumulative errors from
// repeatedly adding floating point numbers.
if (angle > endAngle) {
angle = endAngle;
finished = true;
}

var scalar = innerDistance + loopSpacing * angle,
rotatedAngle = angle + rotation,
x = centerX + scalar * Math.cos(rotatedAngle),
y = centerY + scalar * Math.sin(rotatedAngle);

this.lineTo(x, y);
}

this.stroke();
}
``````

there is a fine free tool that will help if you have illustrator ai2canvas

it will create all the curves to javascript in html canvas tag for you!

(if you are looking for archmedes spiral than you will first have to get it from coreldraw and copy that to illustrator, because the default spiral tool enlarges the angle with each point)

this is example of drawing spiral using function below:

``````spiral(ctx, {
start: {//starting point of spiral
x: 200,
y: 200
},
angle: 30 * (Math.PI / 180), //angle from starting point
direction: false,
number: 3 // number of circles
});
``````

spiral drawing code:

``````spiral = function(ctx,obj) {
var center, eAngle, increment, newX, newY, progress, sAngle, tempTheta, theta;
sAngle = Math.PI + obj.angle;
eAngle = sAngle + Math.PI * 2 * obj.number;
center = {
x: obj.start.x + Math.cos(obj.angle) * obj.radius,
y: obj.start.y + Math.sin(obj.angle) * obj.radius
};
increment = 2 * Math.PI / 60/*steps per rotation*/;
theta = sAngle;
ctx.beginPath();
ctx.moveTo(center.x, center.y);
while (theta <= eAngle + increment) {
progress = (theta - sAngle) / (eAngle - sAngle);
tempTheta = obj.direction ? theta : -1 * (theta - 2 * obj.angle);
newX = obj.radius * Math.cos(tempTheta) * progress;
newY = obj.radius * Math.sin(tempTheta) * progress;
theta += increment;
ctx.lineTo(center.x + newX, center.y + newY);
}
ctx.stroke();
};
``````

The following code approximates a spiral as a collection of quarters of a circle each with a slightly larger radius. It might look worse than an Archimedes spiral for small turning numbers but it should run faster.

``````function drawSpiral(ctx, centerx, centery, innerRadius, outerRadius, turns=2, startAngle=0){
ctx.save();
ctx.translate(centerx, centery);
ctx.rotate(startAngle);
let turns_ = Math.floor(turns*4)/4;
let cx = 0, cy = 0;
let directionx = 0, directiony = -1;

ctx.beginPath();
let angle=0;
for(; angle < turns_*2*Math.PI; angle += Math.PI/2){
//draw a quarter arc around the center point (x, cy)
ctx.arc( cx, cy, r, angle, angle + Math.PI/2);

//move the center point and increase the radius so we can draw a bigger arc
cx += directionx*dr;
cy += directiony*dr;
r+= dr;

//rotate direction vector by 90 degrees
[directionx, directiony] = [ - directiony, directionx ];
}
//draw the remainder of the last quarter turn
ctx.arc( cx, cy, r, angle, angle + 2*Math.PI*( turns - turns_ ))
ctx.stroke();
ctx.restore();
}
``````

Result: