I would like to optimize this algorithm. Function `makeFrame`

divides the audio signal into time frames using a Hanning window of about 37 ms. Then function `divideFreqs`

performs the fast fourier transform on each timeframe using jtransforms library (and it is the one that is the most time consuming). How could I cut down the time of this operation as this is taking way too long. For an audio file of 5 secs it takes around 13 secs to perform the operation. I was thinking about using multi-threading but never used it before.

```
public double[][] makeFrame(double[] audioOutput) {
int length = audioOutput.length;
//calculate a hannining window size of 37 ms
int window = (int) Math.round(0.37 * sampleRate);
int interval = (int) Math.round(0.0116 * sampleRate);
length = length - window;
int numintervals = length / interval;
//calculate hanning window values
double[] hanw = hanning(window);
double[][] sections = new double[numintervals + 1][25];
//divide the signal into timeframes using Hanning window of 37ms
int k = 0;
for (int i = 0; i < length; i += interval) {
double[] temp = new double[88200];
int t = 0;
int s;
s = i;
for (; s < i + window; s++) {
temp[t] = audioOutput[s] * hanw[t];
t++;
}
sections[k] = divideFreqs(temp, sampleRate);
k++;
}
return sections;
}
public static double[] hanning(int window) {
int w = 0;
double h_wnd[] = new double[window]; //Hanning window
for (int i = 1; i < window; i++) { //calculate the hanning window
h_wnd[i] = 0.5 * (1 - Math.cos(2.0 * Math.PI * i / (window + 1)));
}
return h_wnd;
}
public static double[] divideFreqs(double[] audioData, float fs) {
DoubleFFT_1D fft = new DoubleFFT_1D(44100);
int len;
double[] secenergy;
//Frequency bands in the range of 1Hz-20000Hz
int[][] bandsec = new int[][]{
{1, 100},
{100, 200},
{200, 300},
{300, 400},
{400, 510},
{510, 630},
{630, 770},
{770, 920},
{920, 1080},
{1080, 1270},
{1270, 1480},
{1480, 1720},
{1720, 2000},
{2000, 2320},
{2320, 2700},
{2700, 3150},
{3150, 3700},
{3700, 4400},
{4400, 5300},
{5300, 6400},
{6400, 7700},
{7700, 9500},
{9500, 12000},
{12000, 15500},
{15500, 20000}};
//perform FFT on the data
fft.realForwardFull(audioData);
//splitting real and imaginary numbers
double[] real = new double[22050];
double[] imaginary = new double[22050];
for (int row = 0; row < 22050; row++) {
real[row] = (double) Math.round(audioData[row + row] * 100000000) / 100000000;
imaginary[row] = (double) Math.round(audioData[row + row + 1] * 100000000) / 100000000;
}
len = bandsec.length;
secenergy = new double[len];
//calculate energy for each critical band
double[] tempReal;
double[] tempImag;
for (int i = 0; i < len; i++) {
int k = 0;
tempReal = new double[bandsec[i][1] - (bandsec[i][0] - 1)];
tempImag = new double[bandsec[i][1] - (bandsec[i][0] - 1)];
for (int j = bandsec[i][0] - 1; j < bandsec[i][1]; j++) {
tempReal[k] = real[j];
tempImag[k] = imaginary[j];
k++;
}
secenergy[i] = energy(tempReal, tempImag);
}
return secenergy;
}
public static double energy(double[] real, double[] imaginary) {
double e = 0;
Complex sum = new Complex(0, 0);
ArrayList<Complex> complexList = new ArrayList<Complex>();
for (int i = 0; i < real.length; i++) {
Complex comp = new Complex(real[i], imaginary[i]);
complexList.add(comp.multiply(comp));
}
for (int i = 0; i < complexList.size(); i++) {
Complex comp = new Complex(complexList.get(i).getReal(), complexList.get(i).getImaginary());
sum = Complex.add(comp, sum);
}
e = Math.sqrt(sum.magnitude());
e = (double) Math.round(e * 10000) / 10000;
return e;
}
```

`tempReal`

and`tempImg`

are the same values - maybe that's a typo?) – Jeff Foster Jun 20 '11 at 12:33