JavaScript sine wave

``````track : function(x, y, top, ampl) {
return {
top : top + 2,
x   : x + ampl * Math.sin(top / 20),
y   : (top / this.screenHeight < 0.65) ? y + 2 : 1 + y + ampl * Math.cos(top / 25)
};
}
``````

This routine sends snowflakes flying in sine wave manner.

But how does it do that? Please explain.

It uses `Math.sin` for `x`; and `Math.cos` for `y`, but other snippets I've seen use them in the opposite way. Why? Why exactly `top/20` and `top/25`?

The whole code:

``````<script type="text/javascript">
var snowflakes = { // Namespace
/* Settings */

pics : [

['snow.gif' , 24, 24],
['snow2.gif', 24, 24],
['snow3.gif', 24, 24]
],

track : function(x, y, top, ampl) {
return {
top : top + 2,
x   : x + ampl * Math.sin(top / 20),
y   : (top / this.screenHeight < 0.65) ? y + 2 : 1 + y + ampl * Math.cos(top / 25)
};
},

quantity : 30,

minSpeed : 20, // 1 - 100, minSpeed <= maxSpeed

maxSpeed : 40, // 1 - 100, maxSpeed >= minSpeed

isMelt : true, // true OR false
/* Properties */
screenWidth : 0,
screenHeight : 0,
archive : [],
timer : null,
/* Methods */
addHandler : function(object, event, handler, useCapture) {
else if (object.attachEvent)object.attachEvent('on' + event, handler);
else object['on' + event] = handler;
},
create : function(o, index) {
var rand = Math.random();
this.timer = null;
this.o = o;
this.index = index;
this.ampl = 3 + 7*rand;
this.type =  Math.round((o.pics.length - 1) * rand);
this.width = o.pics[this.type][1];
this.height = o.pics[this.type][2];
this.speed = o.minSpeed + (o.maxSpeed - o.minSpeed) * rand;
this.speed = 1000 / this.speed;
this.deviation = o.maxDeviation * rand;
this.x = o.screenWidth * rand - this.width;
this.y = 0 - this.height;
this.top = this.y;
this.img = document.createElement('img');
this.img.src = o.pics[this.type][0];
this.img.style.top = this.y + 'px';
this.img.style.position = 'absolute';
this.img.style.zIndex = 10000;
this.img.style.left = this.x + 'px';
this.img.obj = this;
if (o.isMelt) this.img.onmouseover = function() {
clearTimeout(this.obj.timer);
this.obj.timer = null;
this.parentNode.removeChild(this);
}
document.body.appendChild(this.img);
this.move();
},
init : function() {
this.screenWidth = window.innerWidth ? window.innerWidth : (document.documentElement.clientWidth ? document.documentElement.clientWidth : document.body.offsetWidth);
this.screenWidth = navigator.userAgent.toLowerCase().indexOf('gecko') == -1 ? this.screenWidth : document.body.offsetWidth;
this.screenHeight = window.innerHeight ? window.innerHeight : (document.documentElement.clientHeight ? document.documentElement.clientHeight : document.body.offsetHeight);
this.screenScroll = (window.scrollY) ? window.scrollY : document.documentElement.scrollTop ? document.documentElement.scrollTop : document.body.scrollTop;
this.archive[this.archive.length] = new this.create(this, this.archive.length);
clearTimeout(this.timer);
this.timer = null
this.timer = setTimeout(function(){snowflakes.init()}, 60000 / this.quantity);
}
};
snowflakes.create.prototype = {
move : function() {
var newXY = this.o.track(this.x, this.y, this.top, this.ampl);
this.x   = newXY.x;
this.y   = newXY.y;
this.top = newXY.top;
if (this.y < this.o.screenHeight + this.o.screenScroll - this.height) {
this.img.style.top  = this.y + 'px';
this.x = this.x < this.o.screenWidth - this.width ? this.x : this.o.screenWidth - this.width;
this.img.style.left = this.x + 'px';
var index = this.index;
this.timer = setTimeout(function(){snowflakes.archive[index].move()}, this.speed);
} else {
delete(this.o.archive[this.index]);
this.img.parentNode.removeChild(this.img);
}
}
};
</script>
``````
-
Yes, usually x = cos(theta) and y = sin(theta), but that's ok. If you flip x and y axes you still get wavy motion. all good. The top/20 and top/25 will make x & y a little out-of-phase, which is nice for movement. –  david van brink Aug 26 '11 at 21:01

The basic sine function is defined as:

``````f(x) = A sin(wt + p)
``````

where

• A is the amplitude
• w is the frequency
• p is the phase

These factors determine how the graph of f will look like.

The amplitude can be thought of as a scaling factor, the larger A, the larger (absolute values) the peaks and lows of f.

The frequency determines how fast the sine function will run through all its values until it starts over again - sine is a periodic function. The larger k, the faster f will run through one period.

p is the phase, think of it as "shifting" the starting point of the function to the right (positive p) or left (negative). Hard to explain in words, have a look here for graphs.

The function you give in your example is a generalized version of

``````f: R->R², f(t)=(sin(t), cos(t))
``````

Which is (one of) the parametrizations of the unit circle . If you increase t monotonously and plot x (sin(t)) and y (cos(t)) you will have a point flying on a circle with radius 1.

``````f: R->R², f(t) = (A sin(1/wt), A cos(1/wt)), w > 1
``````

In your case A=ampl, t=top and w=20 for the x coordinate and w=25 for the y coordinate. These slight deviations for w are there make the movement jittery, so that it's no longer a perfect circle, but rather some "distorted" ellipse - snow flakes don't fall in perfect circles, I guess. Additionally this makes the path of the flake appear to be more random than straight perfect circles. It's an illusion though, this is all also very deterministic and still periodic - it's just that x and y movement are "out of phase" so it takes a whole lot longer until one period is completed.

w is chosen > 1 to "slow down" the circular movement. The larger you choose w, the lower the frequency will be and your moving point will complete a full circle much slower.

The larger you choose A, the larger your circle will become.

-
but why w = 5 and 4, i thought it was 20 and 25?? And why it's A sin(1/wt), A cos(1/wt), i thought it was A sin(top/20), A cos(top/25)?? and what is R->R²?? –  DrStrangeLove Aug 27 '11 at 2:26
LOL, that happens when it's late - I read top/20 as o.2*top, so w would have been 5... it's 20 and 25 of course, sorry for that confusion, I'll update that right away. R->R² is domain and range of the function - it takes values from R as input, the output is a two-dimensional vector (x,y) where both y and y are in R, so (x, y) is in RxR which is abbreviated as R² in mathematics. –  emboss Aug 27 '11 at 8:13

It just makes the sine wave bigger so the curves can be more easily observed.

Here's a fiddle I tried making. If I change 20 and 25 to 1, the movement gets less interesting. http://jsfiddle.net/AbM9z/1/

It would help to know what values the function is being called with.

-
ampl makes it bigger, top/20 and top/25 change the wavelength, ya? –  david van brink Aug 26 '11 at 21:06
sounds about right –  bat Aug 26 '11 at 21:14
Where did you change to 1?? In that fiddle i see top/20 and top/25 –  DrStrangeLove Aug 26 '11 at 21:26
I changed it but didn't save it. I should have made it toggle between the two. In fact, I think I'll do that right now. –  bat Aug 26 '11 at 21:31
OK, I've got 'em side-by-side now. –  bat Aug 26 '11 at 21:37