273 lines
8.4 KiB
Java
273 lines
8.4 KiB
Java
/*
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This is the java implementation of performing Discrete Fourier Transform using Fast Fourier Transform algorithm. This class finds the DFT of N (power of 2) complex elements, generated randomly, using FFT. Further verification is done by taking the Inverse Discrete Fourier Transform, again using FFT.
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*/
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// This is a sample program to perform DFT using FFT, FFT is performed on random input sequence
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public class FFT
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{
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public static class Complex
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{
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private final double re; // the real part
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private final double im; // the imaginary part
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// create a new object with the given real and imaginary parts
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public Complex(double real, double imag)
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{
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re = real;
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im = imag;
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}
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// return a string representation of the invoking Complex object
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public String toString()
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{
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if (im == 0)
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return re + "";
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if (re == 0)
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return im + "i";
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if (im < 0)
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return re + " - " + (-im) + "i";
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return re + " + " + im + "i";
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}
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// return abs/modulus/magnitude and angle/phase/argument
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public double abs()
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{
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return Math.hypot(re, im);
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} // Math.sqrt(re*re + im*im)
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public double phase()
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{
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return Math.atan2(im, re);
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} // between -pi and pi
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// return a new Complex object whose value is (this + b)
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public Complex plus(Complex b)
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{
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Complex a = this; // invoking object
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double real = a.re + b.re;
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double imag = a.im + b.im;
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return new Complex(real, imag);
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}
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// return a new Complex object whose value is (this - b)
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public Complex minus(Complex b)
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{
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Complex a = this;
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double real = a.re - b.re;
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double imag = a.im - b.im;
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return new Complex(real, imag);
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}
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// return a new Complex object whose value is (this * b)
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public Complex times(Complex b)
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{
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Complex a = this;
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double real = a.re * b.re - a.im * b.im;
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double imag = a.re * b.im + a.im * b.re;
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return new Complex(real, imag);
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}
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// scalar multiplication
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// return a new object whose value is (this * alpha)
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public Complex times(double alpha)
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{
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return new Complex(alpha * re, alpha * im);
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}
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// return a new Complex object whose value is the conjugate of this
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public Complex conjugate()
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{
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return new Complex(re, -im);
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}
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// return a new Complex object whose value is the reciprocal of this
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public Complex reciprocal()
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{
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double scale = re * re + im * im;
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return new Complex(re / scale, -im / scale);
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}
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// return the real or imaginary part
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public double re()
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{
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return re;
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}
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public double im()
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{
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return im;
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}
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// return a / b
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public Complex divides(Complex b)
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{
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Complex a = this;
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return a.times(b.reciprocal());
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}
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// return a new Complex object whose value is the complex exponential of
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// this
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public Complex exp()
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{
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return new Complex(Math.exp(re) * Math.cos(im), Math.exp(re)
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* Math.sin(im));
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}
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// return a new Complex object whose value is the complex sine of this
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public Complex sin()
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{
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return new Complex(Math.sin(re) * Math.cosh(im), Math.cos(re)
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* Math.sinh(im));
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}
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// return a new Complex object whose value is the complex cosine of this
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public Complex cos()
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{
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return new Complex(Math.cos(re) * Math.cosh(im), -Math.sin(re)
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* Math.sinh(im));
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}
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// return a new Complex object whose value is the complex tangent of
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// this
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public Complex tan()
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{
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return sin().divides(cos());
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}
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// a static version of plus
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public static Complex plus(Complex a, Complex b)
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{
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double real = a.re + b.re;
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double imag = a.im + b.im;
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Complex sum = new Complex(real, imag);
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return sum;
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}
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// compute the FFT of x[], assuming its length is a power of 2
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public static Complex[] fft(Complex[] x)
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{
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int N = x.length;
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// base case
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if (N == 1)
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return new Complex[] { x[0] };
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// radix 2 Cooley-Tukey FFT
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if (N % 2 != 0)
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{
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throw new RuntimeException("N is not a power of 2");
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}
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// fft of even terms
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Complex[] even = new Complex[N / 2];
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for (int k = 0; k < N / 2; k++)
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{
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even[k] = x[2 * k];
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}
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Complex[] q = fft(even);
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// fft of odd terms
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Complex[] odd = even; // reuse the array
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for (int k = 0; k < N / 2; k++)
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{
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odd[k] = x[2 * k + 1];
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}
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Complex[] r = fft(odd);
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// combine
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Complex[] y = new Complex[N];
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for (int k = 0; k < N / 2; k++)
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{
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double kth = -2 * k * Math.PI / N;
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Complex wk = new Complex(Math.cos(kth), Math.sin(kth));
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y[k] = q[k].plus(wk.times(r[k]));
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y[k + N / 2] = q[k].minus(wk.times(r[k]));
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}
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return y;
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}
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// compute the inverse FFT of x[], assuming its length is a power of 2
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public static Complex[] ifft(Complex[] x)
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{
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int N = x.length;
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Complex[] y = new Complex[N];
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// take conjugate
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for (int i = 0; i < N; i++)
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{
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y[i] = x[i].conjugate();
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}
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// compute forward FFT
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y = fft(y);
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// take conjugate again
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for (int i = 0; i < N; i++)
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{
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y[i] = y[i].conjugate();
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}
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// divide by N
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for (int i = 0; i < N; i++)
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{
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y[i] = y[i].times(1.0 / N);
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}
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return y;
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}
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// display an array of Complex numbers to standard output
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public static void show(Complex[] x, String title)
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{
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System.out.println(title);
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for (int i = 0; i < x.length; i++)
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{
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System.out.println(x[i]);
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}
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System.out.println();
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}
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public static void main(String[] args)
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{
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int N = 8;//Integer.parseInt(args[0]);
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Complex[] x = new Complex[N];
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// original data
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for (int i = 0; i < N; i++)
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{
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x[i] = new Complex(i, 0);
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x[i] = new Complex(-2 * Math.random() + 1, 0);
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}
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show(x, "x");
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// FFT of original data
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Complex[] y = fft(x);
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show(y, "y = fft(x)");
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// take inverse FFT
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Complex[] z = ifft(y);
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show(z, "z = ifft(y)");
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}
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}
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}
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/*
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x
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0.5568836254037923
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0.8735842104393365
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0.6099699812709252
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0.5631502515566189
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-0.518857260970139
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-0.5946393148293805
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0.47144753318047794
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-0.3501597962417593
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y = fft(x)
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1.6113792298098721
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1.4681239692650163 - 1.8225209872296184i
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-1.0433911500177497 - 0.06595444029509645i
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0.6833578034828462 - 1.545476091048724i
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0.6275085279602408
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0.6833578034828462 + 1.545476091048724i
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-1.0433911500177497 + 0.06595444029509645i
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1.4681239692650163 + 1.8225209872296184i
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z = ifft(y)
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0.5568836254037923
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0.8735842104393365 - 5.652078740871965E-17i
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0.6099699812709252 - 4.24102681660054E-18i
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0.5631502515566189 - 5.4501515053796015E-17i
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-0.518857260970139
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-0.5946393148293805 + 5.4501515053796015E-17i
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0.47144753318047794 + 4.24102681660054E-18i
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-0.3501597962417593 + 5.652078740871965E-17i
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