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I'm aware that I could toss this into wolfram alpha and get an answer using the sine function, but assuming I have all of my data in integers, it should be solvable as them as well.

So I've got two waves, and they'll always have integer wavelengths. For my example, it's a 3 wavelength wave and a 4 wavelength wave. In the simplest case of both starting at time 0 sec, they are both 0 at the start and every 12 seconds afterward. Using the lcm to determine these crossing points works in every case I think, but if they start at different times it can only predict the frequency of them both being zero but not when it starts.

For instance, if the 3 length wave starts at time 1, and 4 length at time 0, they both are 0 at time 4 then every 12 afterward. But if the 4 length starts at time 2 and the 3 length at time 1, they are both 0 at time 10 and every 12 afterward.

What is the method to determine that first time they will both be 0 together?

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doesn't work for coprime integers –  airza Oct 5 '12 at 17:35

2 Answers 2

up vote 2 down vote accepted

You're looking for a solution to equations of the form:

sin((2π*A)(x-B)) == 0 

and

sin((2π*C)(x-D)) == 0

By multiplying, note also that:

sin(2πAx - 2πAB) == 0

and similarly

sin(2πCx - 2πCD) == 0

Or:

Ax - AB == 0
Cx - CD == 0

Which provides the following, totally non-shocking values where these functions are zero:

x = B + 2π/(2π*A) * k
x = D + 2π/(2π*C) * k 

Where K is an integer.

Since you're restricting yourself to functions with values where the wavelength is an integer, the values of 1/A and 1/C are similarly guaranteed to be integers. So this simplifies even further:

x = B mod a
x = D mod c

Where a and c are the frequencies here.

You can pick your favorite form of solving simultaneous modular equations, of which I will demonstrate the easiest one:

x = B + k*a
B+ k*a = D mod c
k * a = D - B mod c
k = (a^-1M) (D-B) mod c
k = (a^-1M) (D-B) + j*c
x = B + a*(a^-1M)*(D-B) + (a*j-c)
x = B + a*(a^-1M)(D-B) mod ac

Note that a^-1m is the modulo inverse of a mod c, which you will have to calculate with the extended euclidean algorithm. (I'll omit this since the value is very small for your example):

x = 1 + 3(3)(0-1) mod ac
x = -8 mod ac

Given some value like this you can take the right side mod ac in the script and get the correct first value; however note that some scrub languages like Javascript will allow negative results with absolute value less than ac.

So you want something like:

( ( (B + a*(a^-1M)*(D-B) ) % ac) + ac ) % ac)

With a^-1M being the modulus inverse of a in c. Your function should also puke if a%c == 0 or c%a == 0 since these waves will never intersect

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It looks like your function overall could be simplified to ((AB - CD) / (A - C)) % LCD. I'll experiment with some values and see if it works out ok... –  user173342 Oct 5 '12 at 16:43
    
Now that I think of it, when both of the frequencies are positive integers there are intersections at every integer. Did you mean frequencies of 1/3 hz and 1/4 hz? –  airza Oct 5 '12 at 16:48
    
If I use 3 Hz starting at time 2 and 4 Hz at time 0, I get 1/2. So something isn't quite right... –  user173342 Oct 5 '12 at 16:49
    
Isn't the first equation in this solution satisfied when the 2 waves cross at any value, not just at 0 as the question asks ? –  High Performance Mark Oct 5 '12 at 16:49
    
Yeah, now that I look at this I think that both the problem I've solved and the described problem aren't quite right. –  airza Oct 5 '12 at 16:51

For each wave generate the list of times at which the wave is 0; take the intersection of the lists; take the earliest time from the intersection. Need it be any more complicated than that ? I guess you'll want to generate only a finite number of elements in each list, unless you have a system which can deal with infinite data structures.

The other approach would be to write the terms of each wave as arithmetic series, in your example (1+3m) and (0+4n) and solve the equation

(1+3m)-(0+4n) == 0

which will have infinite solutions. But if you set m==1 then n==1; if you set m==2 then there are no solutions with integer n. It would be easy enough to write a little function in your favourite language to spit out the integer solutions one-by-one.

And a little more algebra shows that, for the example given, the sequence of (m,n) values is (1,1),(5,4),(9,7), ...,(m,n),(m+4,n+3),....

As before, I'm leaving as an exercise to the interested party to generalise this.

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This doesn't work very well with high frequencies. –  airza Oct 5 '12 at 17:58

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