# How to draw sine waves with SVG (+JS)?

What would be the simplest solution to draw sine waves in SVG? I guess sine waves should be repeated in a simple loop with JavaScript... :)

Here are the X-Y coordinates as a good start... :)

``````<svg>
<line x1="0" y1="250" x2="500" y2="250"
style="stroke:black;stroke-width:1"/>
<line x1="250" y1="0" x2="250" y2="500"
style="stroke:black;stroke-width:1"/>
</svg>
``````
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@FrankvanPuffelen: yes, I saw that, but this is far away from a nice and simple solution... :) I think this has been generated by an external software. –  Sk8erPeter Dec 18 '12 at 12:48
Something like this, presumably? jsbin.com/adaxuy/4 –  Asad Dec 18 '12 at 13:14
@Sk8erPeter: Yes, it was generated by GNUPLOT. Have a look at its source! You're only looking for the last `<path>` element in the document –  Bergi Dec 18 '12 at 13:18
@Bergi: thanks for the info! :) –  Sk8erPeter Dec 19 '12 at 16:30

Here is a proof of concept that adds multiple `line` elements to the SVG element:

``````var svg = document.getElementById('sine_wave').children[0];
var origin = { //origin of axes
x: 100,
y: 100
};
var amplitude = 10; // wave amplitude
var rarity = 1; // point spacing
var freq = 0.1; // angular frequency
var phase = 0; // phase angle

for (var i = -100; i < 1000; i++) {
var line = document.createElementNS("http://www.w3.org/2000/svg", "line");

line.setAttribute('x1', (i - 1) * rarity + origin.x);
line.setAttribute('y1', Math.sin(freq*(i - 1 + phase)) * amplitude + origin.y);

line.setAttribute('x2', i * rarity + origin.x);
line.setAttribute('y2', Math.sin(freq*(i + phase)) * amplitude + origin.y);

line.setAttribute('style', "stroke:black;stroke-width:1");

svg.appendChild(line);
}
``````

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Thank you very much for your answer! It was very hard to decide which answer to accept, but finally I accepted yours, because it's very flexible, and you didn't "print" only one "cycle". (And btw., my first approach was to use `line` elements too.) Thanks again! –  Sk8erPeter Dec 18 '12 at 15:16

The following will add a one-cycle sine wave to your SVG graph:

``````var XMAX = 500;
var YMAX = 500;

// Create path instructions
var path = [];
for (var x = 0; x <= XMAX; x++) {
var angle = (x / XMAX) * Math.PI * 2;  // angle = 0 -> 2π
var y = Math.sin(angle) * (YMAX / 2) + (YMAX / 2);
// M = move to, L = line to
path.push((x == 0 ? 'M' : 'L') + x + ',' + y);
}

// Create PATH element
var pathEl = document.createElementNS("http://www.w3.org/2000/svg", "path");
pathEl.setAttribute('d', path.join(' ') );
pathEl.style.stroke = 'blue';
pathEl.style.fill = 'none';

// Add it to svg element
document.querySelector('svg').appendChild(pathEl);

​    ​
``````

Here's the jsfiddle you can run.

This uses a PATH element made up of 'lineto' (straight line) commands. This works because, not surprisingly, it contains many (500) small line segments. You could simplify the path to have fewer points by using bezier curves to draw the segments, but this complicates the code. And you asked for simple. :)

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Thank you very much! It's a very nice solution, too. I upvoted it, I wish I could accept multiple answers... The reason why I decided to accept the other one is that maybe that was a little bit more flexible, but yours is a very good solution, too. Thanks again, and sorry that I couldn't accept yours too! –  Sk8erPeter Dec 18 '12 at 15:18
@Sk8erPeter For more cycles, just change `Math.sin(angle)` to `Math.sin(angle * X)`, where X = number of cycles. Also, IMHO, a single `path` element (as above) is a more elegant solution than @Asad's many-line element answer, for several several reasons. 1. A path only adds a single DOM element. This improves performance of DOM layout and canvas rendering (important for animation) and a path can be 'fill'ed in the event you want to fill the area under your line. You can't fill separate line segments. –  broofa Dec 18 '12 at 17:10
Thanks for this. Note you can simplify it, x = i unless I missed something. –  Martin Fido Mar 12 '13 at 11:57
@MartinFido: good catch! edited to remove unnecessary `i` var. thx. –  broofa Mar 12 '13 at 17:20

An alternative to straight-line approximations would be a Bézier approximation. A pretty good approximation of the first quarter of one period is a cubic Bézier curve with the following control points:

`````` 0   0
1/2 1/2
1   1
π/2  1
``````

Edit: Even more exact approximations are possible with the following control points:

``````0                    0
0.512286623256592433 0.512286623256592433
1.002313685767898599 1
1.570796326794896619 1
``````

(See NominalAnimal's explanations in the comments)

An approximation that exactly interpolates the slope and curvature in the spline's endpoints is

``````       0                0
(6−(3/2π−3)²)/6  (6−(3/2π−3)²)/6
1                1
π/2               1
``````
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+1, wow, thank you very much for this approach, this is a really good solution, too! –  Sk8erPeter Dec 18 '12 at 15:19
Great find! 'Hadn't realized that you could basically use a single quadratic Bezier curve to model a sine wave this accurately. –  broofa Dec 18 '12 at 17:53
You can get absolute error (when comparing the resulting graph to y = sin x) under 0.0000584414 ≃ 1/17111 using `0, 0`, `0.512286623256592433,0.512286623256592433`, `1.002313685767898599,1`, `1.570796326794896619,1` for the first quarter-period of the sine wave. @broofa: note that this is a cubic Bézier, not a quadratic one, and that Béziers often render faster and smoother than a similar polyline. –  Nominal Animal Dec 18 '12 at 19:47
@NominalAnimal: That's interesting! Initially, I used the control points I found in a blog entry by Chris Idzerda, but I found that my control points above were indeed significantly more accurate. However, I wasn't sure whether they were optimal in some sense. I'll take this as an exercise and calculate some control points rather than estimating them. Where did you get the numbers from? –  Thomas W Dec 18 '12 at 19:58
@broofa: It actually is simple to generalize. Use linear x, and interpolate y using piecewise cubics. So, instead of line segments, use Bézier curve segments defined by `x[n], y[n]`, `x[n]*2/3+x[n+1]/3, y[n]+dy[n]*(x[n+1]-x[n])/3`, `x[n]/3+x[n+1]*2/3, y[n+1]-dy[n+1]*(x[n+1]-x[n])/3`, and `x[n+1], y[n+1]`, where `x[n]` are the sampling points, `y[n] = f(x[n])` (ie. f at x[n]), and `dy[n] = d(f(t)/dt)[t=x[n]]` (ie. derivative or slope of f at x[n]). Optimum curves are harder to find, but this yields an acceptable piecewise cubic approximation. –  Nominal Animal Dec 18 '12 at 23:42

Loop over the X axis and for each iteration compute the Y position using a sine function on the current X value.

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yes, it's OK in theory, but I would like to have a working sample solution (e.g. by editing this one or just posting a sample code :) ). Thanks. –  Sk8erPeter Dec 18 '12 at 12:58
@Sk8erPeter Well, I see stackoverflow a bit different. I use SO to get answers to my questions – not to find someone who does my work and implements the whole thing. –  feeela Dec 18 '12 at 14:38
I think this is a bad approach. If I wanted to ask the mathematical background of the question, I would have posted it to math.stackexchange.com. But this is a programming forum with programming solutions to problems. Not to mention that you are wrong, this is absolutely NOT my work, I just felt professional interest in using SVGs a little bit more advanced, and I haven't seen such a question with a solution. BTW, when multiple codes are shared, multiple approaches can be seen, and we can learn a lot from them. Imagine the internet without different codes, this would be very hard. –  Sk8erPeter Dec 18 '12 at 15:26