# Animating a sine wave infinitely

I need a function to animate a sine wave infinitely over time. The sine wave moves to the left.

My sine wave is built using the following equation:

``````A * sin(B * x + C) + D
``````

Now to animate the sine wave as if it is moving to the left, I simply increase C by 1 everytime I refresh the screen. Now this is all fine and dandy for a few minutes but I need to have that animation run for hours. I can't just have an integer build up 60 times a second forever. How does someone deal with this? Do I just try to find a point where the sine wave crosses 0 and then restart the animation from 0?

I just need to have the logic of something like this explained.

EDIT #1 I forgot to mention that there's a randomized component to my sine. The sine is not continuously the same. A and D are sinusoidal functions tied to that integer at the moment. The sine needs to look random with varying periods and amplitudes.

EDIT #2

Edited see Edit 3

EDIT #3

@Potatoswatter I tried implementing your technique but I don't think I'm getting it. Here's what I got:

``````        static double i = 0;
i = i + (MPI / 2);
if ( i >= 800 * (MPI / 2) ) i -= 800 * (MPI / 2);

for (k = 0; k < 800; ++k)
{
double A1 = 145 * sin((rand1 * (k - 400) + i) / 300) + rand3;       // Amplitude
double A2 = 100 * sin((rand2 * (k - 400) + i) / 300) + rand2;       // Amplitude
double A3 = 168 * sin((rand3 * (k - 400) + i) / 300) + rand1;       // Amplitude

double B1 = 3 + rand1 + (sin((rand3 * k) * i) / (500 * rand1));     // Period
double B2 = 3 + rand2 + (sin((rand2 * k) * i) / 500);           // Period
double B3 = 3 + rand3 + (sin((rand1 * k) * i) / (500 * rand3));     // Period

double x = k;                               // Current x

double C1 = 10 * i;                         // X axis move
double C2 = 11 * i;                         // X axis move
double C3 = 12 * i;                         // X axis move

double D1 = rand1 + sin(rand1 * x / 600) * 4;               // Y axis move
double D2 = rand2 + sin(rand2 * x / 500) * 4;               // Y axis move
double D3 = rand3 + cos(rand3 * x / 400) * 4;               // Y axis move

sine1[k] = (double)A1 * sin((B1 * x + C1) / 400) + D1;
sine2[k] = (double)A2 * sin((B2 * x + C2) / 300) + D2 + 100;
sine3[k] = (double)A3 * cos((B3 * x + C3) / 500) + D3 + 50;

}
``````

How do I modify this to make it work?

Halp!

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Sine has a period of 2 pi, meaning that `sin(x) = sin(x + 2 * M_PI)`, for any `x`.

So, you could just increase `C` by, say, `pi/n` where `n` is any integer, as you refresh the screen, and after `2n` refreshes, reset `C` (to `0`, or whatever).

Edit for clarity: the integer `n` is not meant to change over time.

Instead, pick some `n`, for example, let's say `n = 10`. Now, every frame, increase `x` by `pi / 10`. After `20` frames, you have increased `x` by a total of `20 * pi / 10 = 2 * pi`. Since `sin(x + 2 * pi) = sin(x)`, you may as well just reset your `sin(...)` input to just `x`, and start the process over.

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Thanks for your answer. Unfortunately my math skills are slightly lacking so I'm wondering if you could clarify your answer a bit. Wouldn't increasing C by pi / n where n is a continuously growing integer slow the animation down over time since the result returned would grow increasingly smaller? –  ReX357 Dec 23 '13 at 8:19
@ReX357 editing in a clarification. –  Andrey Dec 23 '13 at 8:23
Or you mean like n is a constant here? For instance 4800 and then reset to zero after 9600 frames? –  ReX357 Dec 23 '13 at 8:26
@ReX357 yes, exactly. –  Andrey Dec 23 '13 at 8:27
-1, Moving by exactly `pi/n` is unnecessarily restrictive. There's no need to require him to change the animation speed. –  Potatoswatter Dec 23 '13 at 8:31

`sin` is periodic, with a period of 2π. Therefore, if the argument is greater than 2π, you can subtract `2 * M_PI` from it and get the same answer.

Instead of using a single variable `k` to compute all waves of various speeds, use three variables `double k1, k2, k3`, and keep them bound in the range from 0 to 2π.

``````if ( k2 >= 2 * M_PI ) k2 -= 2 * M_PI;
``````

They may be individually updated by adding some value each frame. If the increment may be more than 2π then subtracting a single 2π won't bring them back into range, but you can use `fmod()` instead.

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I see what you mean. However, if you notice, my C (x shift) is tied to variable i not k. All the sines have sinusoidal equations to define A and D so it looks very random over time. I tried the solution that said to increase i by pi / n and then resetting after a multiple of 2n but it simply skips to a totally different set of waves when I wrap back to 0. Does this still apply to a wave with varying amplitude and y shift over time? –  ReX357 Dec 23 '13 at 9:06
To elaborate a little more on k, my view port is 800 pixels wide. I iterate through an array that's 801 values long (Extra value is cause I run a line_to function to draw the line) where each value is y. K is simply x position in my line basically. i is elapsed time basically. Gets updated 60 times a second. –  ReX357 Dec 23 '13 at 9:10
@ReX357 I get it. My best-practices advice would be to keep everything clipped into [0, 2π) because as floating-point numbers grow they lose precision. So, keep three versions of `i`, and use them to initialize three versions of `k`, and constrain all the `i`'s and `k`'s in both the inner and outer loops. –  Potatoswatter Dec 23 '13 at 9:13
I'm sorry I keep quizzing you, I'm just trying to wrap my head around the whole thing here. I still don't understand how I need to initialize 3 versions of k? k is 0 to 800 no matter what. It represents 1 pixel no matter what. I use it in my equations to create some movement in the graph. Are you saying I should leave it out of the equations and simply use i where i is between 0 and 2pi? –  ReX357 Dec 23 '13 at 9:22
@ReX357 You can increment `k1`, `k2`, `k3` 800 times, and each increment represents one pixel. I'm saying to calculate the increment, and add that much to each `k` rather than calculating everything from a single integer which tends to grow. But of course you can also have a separate `int k` if that's what the graphics library expects. Anyway… When things get confusing, I like to write down the equation in comments and simplify using basic algebra. –  Potatoswatter Dec 23 '13 at 9:30

I decided to change my course of action. I just drive `i` with the system's monotonic clock like so:

``````        struct timespec spec;
int ms;
time_t s;
static unsigned long long etime = 0;

clock_gettime(CLOCK_MONOTONIC, &spec);
s = spec.tv_sec;
ms = spec.tv_nsec / 10000000;
etime = concatenate((long)s, ms);
``````

Then I simply changed `i` to `etime` in my sine equations. Here's the concatenating function I used for this purpose:

``````unsigned concatenate(unsigned x, unsigned y) {
x = x * 100;
return x + y;
}
``````
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