I am using R and attempting to recover frequencies (really, just a number close to the actual frequency) from a large number of sound waves (1000s of audio files) by applying Fast Fourier transforms to each of them and identifying the frequency with the highest magnitude for each file. I'd like to be able to recover these peak frequencies as quickly as possible. The FFT method is one method that I've learned about recently and I think it should work for this task, but I am open to answers that do not rely on FFTs. I have tried a few ways of applying the FFT and getting the frequency of highest magnitude, and I have seen significant performance gains since my first method, but I'd like to speed up the execution time much more if possible.

Here is sample data:

```
s.rate<-44100 # sampling frequency
t <- 2 # seconds, for my situation, I've got 1000s of 1 - 5 minute files to go through
ind <- seq(s.rate*t)/s.rate # time indices for each step
# let's add two sin waves together to make the sound wave
f1 <- 600 # Hz: freq of sound wave 1
y <- 100*sin(2*pi*f1*ind) # sine wave 1
f2 <- 1500 # Hz: freq of sound wave 2
z <- 500*sin(2*pi*f2*ind+1) # sine wave 2
s <- y+z # the sound wave: my data isn't this nice, but I think this is an OK example
```

The first method I tried was using the fpeaks and spec functions from the seewave package, and it seems to work. However, it is prohibitively slow.

```
library(seewave)
fpeaks(spec(s, f=s.rate), nmax=1, plot=F) * 1000 # *1000 in order to recover freq in Hz
[1] 1494
# pretty close, quite slow
```

After doing a bit more reading, I tried this next approach, wherein

```
spec(s, f=s.rate, plot=F)[which(spec(s, f=s.rate, plot=F)[,2]==max(spec(s, f=s.rate, plot=F)[,2])),1] * 1000 # again need to *1000 to get Hz
x
1494
# pretty close, definitely faster
```

After a bit more looking around, I found this approach to work reasonably well.

```
which(Mod(fft(s)) == max(abs(Mod(fft(s))))) * s.rate / length(s)
[1] 1500
# recovered the exact frequency, and quickly!
```

Here is some performance data:

```
library(microbenchmark)
microbenchmark(
WHICH.MOD = which(Mod(fft(s))==max(abs(Mod(fft(s))))) * s.rate / length(s),
SPEC.WHICH = spec(s,f=s.rate,plot=F)[which(spec(s,f=s.rate,plot=F)[,2] == max(spec(s,f=s.rate,plot=F)[,2])),1] * 1000, # this is spec from the seewave package
# to recover a number around 1500, you have to multiply by 1000
FPEAKS.SPEC = fpeaks(spec(s,f=s.rate),nmax=1,plot=F)[,1] * 1000, # fpeaks is from the seewave package... again, need to multiply by 1000
times=10)
Unit: milliseconds
expr min lq median uq max neval
WHICH.MOD 10.78 10.81 11.07 11.43 12.33 10
SPEC.WHICH 64.68 65.83 66.66 67.18 78.74 10
FPEAKS.SPEC 100297.52 100648.50 101056.05 101737.56 102927.06 10
```

Good solutions will be the ones that recover a frequency close (± 10 Hz) to the real frequency the fastest.

# More Context

I've got many files (several GBs), each containing a tone that gets modulated several times a second, and sometimes the signal actually disappears altogether so that there is just silence. I want to identify the frequency of the unmodulated tone. I know they should all be somewhere less than 6000 Hz, but I don't know more precisely than that. If (big if) I understand correctly, I've got an OK approach here, it's just a matter of making it faster. Just fyi, I have no previous experience in digital signal processing, so I appreciate any tips and pointers related to the mathematics / methods in addition to advice on how better to approach this programmatically.