Very interesting problem. I've scaled the blob down so it is visible in the preview below.

Here is a codepen as well at a larger size.

```
const SCALE = 0.25;
const TWO_PI = Math.PI * 2;
const HALF_PI = Math.PI / 2;
const canvas = document.createElement("canvas");
const c = canvas.getContext("2d");
canvas.width = window.innerWidth;
canvas.height = window.innerHeight;
document.body.appendChild(canvas);
class Blob {
constructor() {
this.wobbleIncrement = 0;
// use this to change the size of the blob
this.radius = 500;
// think of this as detail level
// number of conections in the `bezierSkin`
this.segments = 12;
this.step = HALF_PI / this.segments;
this.anchors = [];
this.radii = [];
this.thetaOff = [];
const bumpRadius = 100;
const halfBumpRadius = bumpRadius / 2;
for (let i = 0; i < this.segments + 2; i++) {
this.anchors.push(0, 0);
this.radii.push(Math.random() * bumpRadius - halfBumpRadius);
this.thetaOff.push(Math.random() * TWO_PI);
}
this.theta = 0;
this.thetaRamp = 0;
this.thetaRampDest = 12;
this.rampDamp = 25;
}
update() {
this.thetaRamp += (this.thetaRampDest - this.thetaRamp) / this.rampDamp;
this.theta += 0.03;
this.anchors = [0, this.radius];
for (let i = 0; i <= this.segments + 2; i++) {
const sine = Math.sin(this.thetaOff[i] + this.theta + this.thetaRamp);
const rad = this.radius + this.radii[i] * sine;
const theta = this.step * i;
const x = rad * Math.sin(theta);
const y = rad * Math.cos(theta);
this.anchors.push(x, y);
}
c.save();
c.translate(-10, -10);
c.scale(SCALE, SCALE);
c.fillStyle = "blue";
c.beginPath();
c.moveTo(0, 0);
bezierSkin(this.anchors, false);
c.lineTo(0, 0);
c.fill();
c.restore();
}
}
const blob = new Blob();
function loop() {
c.clearRect(0, 0, canvas.width, canvas.height);
blob.update();
window.requestAnimationFrame(loop);
}
loop();
// array of xy coords, closed boolean
function bezierSkin(bez, closed = true) {
const avg = calcAvgs(bez);
const leng = bez.length;
if (closed) {
c.moveTo(avg[0], avg[1]);
for (let i = 2; i < leng; i += 2) {
let n = i + 1;
c.quadraticCurveTo(bez[i], bez[n], avg[i], avg[n]);
}
c.quadraticCurveTo(bez[0], bez[1], avg[0], avg[1]);
} else {
c.moveTo(bez[0], bez[1]);
c.lineTo(avg[0], avg[1]);
for (let i = 2; i < leng - 2; i += 2) {
let n = i + 1;
c.quadraticCurveTo(bez[i], bez[n], avg[i], avg[n]);
}
c.lineTo(bez[leng - 2], bez[leng - 1]);
}
}
// create anchor points by averaging the control points
function calcAvgs(p) {
const avg = [];
const leng = p.length;
let prev;
for (let i = 2; i < leng; i++) {
prev = i - 2;
avg.push((p[prev] + p[i]) / 2);
}
// close
avg.push((p[0] + p[leng - 2]) / 2, (p[1] + p[leng - 1]) / 2);
return avg;
}
```

There are lots of things going on here. In order to create this effect you need a good working knowledge of how quadratic bezier curves are defined. Once you have that, there is an old trick that I've used many many times over the years. To generate smooth linked quadratic bezier curves, define a list of points and calculate their averages. Then use the points as control points and the new averaged points as anchor points. See the `bezierSkin`

and `calcAvgs`

functions.

With the ability to draw smooth bezier curves, the rest is about positioning the points in an arc and then animating them. For this we use a little math:

```
x = radius * sin(theta)
y = radius * cos(theta)
```

That converts polar to cartesian coordinates. Where `theta`

is the angle on the circumference of a circle `[0 - 2pi]`

.

As for the animation, there is a good deal more going on here - I'll see if I have some more time this weekend to update the answer with more details and info, but hopefully this will be helpful.