DFT

42 visualizaciones (últimos 30 días)
Lisa Justin
Lisa Justin el 22 de Feb. de 2012
Comentada: Amilton Pensamento el 22 de Jul. de 2022
How do i calculate DFT in matlab? I do not want FFT.
  1 comentario
Bahloul Derradji
Bahloul Derradji el 11 de En. de 2019
use KSSOLVE a matlab package for density functional calculations

Iniciar sesión para comentar.

Iniciar sesión para responder a esta pregunta.

Respuesta aceptada

Wayne King
Wayne King el 22 de Feb. de 2012
Hi Lisa, you had a couple problems with your code:
N= 4;
x=1:4;
for k=0:3
for n = 0:3;
y(n+1) = x(n+1).*exp(-(1j*2*pi*k*n)/N);
end
xdft(k+1)= sum(y);
end
compare to
fft(x)
  3 comentarios
Mostrar 1 comentario más antiguo
Lisa Justin
Lisa Justin el 22 de Feb. de 2012
yes it is same but i do not think it will be same with real vibration time series. check this http://www.dataq.com/applicat/articles/an11.htm
Amilton Pensamento
Amilton Pensamento el 22 de Jul. de 2022
Thanks, Wayne. I tried to use the same code as starting point to come up with the IDFT. Still using x as my input sequence.
N = 4;
x = 1:4;
for n = 0:3
for k = 0:3;
y(k+1) = x(k+1).*exp((1j*2*pi*k*n)/N);
end
xdft(n+1)= (1./N).*sum(y);
end

Iniciar sesión para comentar.

Más respuestas (4)

Wayne King
Wayne King el 22 de Feb. de 2012
FFT() is just an efficient algorithm (actually a family of algorithms) for computing the DFT. The DFT is the mathmatical concept, the FFT is just an algorithm. You can form a matrix to compute the DFT by brute force, but the result will be identical to the output of fft().
  1 comentario
Lisa Justin
Lisa Justin el 22 de Feb. de 2012
i want to avoid using any window function, that is the reason i need DFT. How do i represent an interval of 0:N-1 summation in matlab? I am just experimenting with DFT to see what i get. I want to compare the results with windowing(FFT) and without windowing (DFT).

Iniciar sesión para comentar.

Wayne King
Wayne King el 22 de Feb. de 2012
The DFT can be written as a matrix multiplication of a Nx1 vector, your signal, with a NxN matrix -- the DFT matrix. But that will involve N^2 multiplications and N additions. You can see that if your signal gets even reasonably large that is going to be a huge computational effort. The FFT() exploits symmetries in the DFT to reduce the number of computations greatly.
For example, here is the brute force way for N=4
x = (1:4)'; % the signal
W = -1j*2*pi/4;
W = repmat(W,4,4);
k = (0:3)';
k = repmat(k,1,4);
n = 0:3;
n = repmat(n,4,1);
W = exp(W.*k.*n);
% W is the DFT matrix, now to get the DFT
xdft1 = W*x
% but that is exactly the same as
xdft2 = fft(x)
  1 comentario
Lisa Justin
Lisa Justin el 22 de Feb. de 2012
N=1024
k = (1:N/2-1);
x=1:1024
for n=0:1024
xl(n+1) = (x.*exp(-i.*2.*pi.*(k./N).*n));
end
xs=sum(xl)
please can you make correction on the loop, it is easier for me to understand. i do not understand repmat on your code. thanks

Iniciar sesión para comentar.

Wayne King
Wayne King el 22 de Feb. de 2012
With all due respect to that author, I think she is overstating her point. The DFT takes a N-point periodic vector (the N-point periodicity is implicit in the DFT) and projects it onto N discrete-time complex exponentials with period N. Those complex exponentials are a basis for vectors (a vector space) with period N.
Now, in reality, the DFT is most often used for sampled data, data sampled from a continuous-time process, which may or may not be periodic, and even if it is periodic, most likely does not have period N.
The problems that motivate using a window with the DFT, come from this "translation". You're taking a process which is continous, may or may not be periodic, and may not have an abrupt on and off transition, and you are creating a N-point vector out of it, which has those qualities.
So I think it is wholly artificial to draw a line between the DFT and FFT.
I think you still have to window in many cases whether you compute the DFT by brute force or use an FFT implementation.
  1 comentario
Lisa Justin
Lisa Justin el 23 de Feb. de 2012
Thanks!

Iniciar sesión para comentar.

Dr. Seis
Dr. Seis el 22 de Feb. de 2012
Here is another (inefficient) way of saying the same thing as Wayne by way of example:
Fs = 100; % samples per second
dt = 1/Fs;
N = 128; % Number of samples
time = (0:1:(N-1))*dt;
timedata = sin(2*pi*time);
figure;
plot(time,timedata);
df = 1/(N*dt); % frequency increment
Nyq = 1/(dt*2); % Nyquist Frequency
freq = -Nyq:df:Nyq-df;
freqdata = zeros(size(timedata));
for i = 1 : N
for j = 1 : N
freqdata(i) = freqdata(i) + timedata(j)*exp(-1i*2*pi*freq(i)*time(j));
end
end
figure;
plot(freq,real(freqdata),freq,imag(freqdata));
And both (actually all 3) implementations should give the same results as FFT. I can't see any reason why they wouldn't work with real data either.
  1 comentario
Lisa Justin
Lisa Justin el 23 de Feb. de 2012
Thanks guys!

Iniciar sesión para comentar.

Categorías

Más información sobre Transforms en Help Center y File Exchange.

Etiquetas

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by