Non-uniform discrete Fourier transform

In applied mathematics, the non-uniform discrete Fourier transform (NDFT) of a signal is a type of Fourier transform, related to a discrete Fourier transform or discrete-time Fourier transform, but in which the input signal is not sampled at equally spaced intervals. As a result of this, the computed Discrete Fourier Transform can also consist of unevenly sampled frequency values. It is however also possible to compute uniformly sampled frequency values from an unevenly sampled input signal.

As a generalized approach for nonuniform sampling, NDFT allows one to obtain frequency domain information of a finite length signal at any frequency. It can also be used to design the FIR filters as the role of DFT, no matter if it's 1-D or 2-D.

One of the reasons to adopt NDFT is that many signals have their energy distributed nonuniformly in the frequency domain. Therefore, a nonuniform sampling scheme could be more convenient and useful in many Digital Signal Processing (DSP) applications. For example, NDFT provides a variable spectral resolution controlled by the user.

Note that NDFT reduces to DFT when the sampling points are located on the unit circle at equally spaced angles.

1-D NDFT

Definition

1-D NDFT of a sequence x[n] of length N is[1]

where is the Z-transform of , and are arbitrarily distinct points in the z-plane.

Expressing the above as matrix, we get

where

As we can see, the NDFT is characterized by and hence the N points. If we further factorize , we can see that is nonsingular provided the N points are distinct. If is nonsingular, we can get a unique inverse NDFT as following:

Given , we can use Gaussian elimination to solve . However, the complexity of this method is . To solve this problem more efficiently, we first determine directly by polynomial interpolation

then x[n] is the coefficients of the above interpolating polynomial which can be solved more efficiently. This is illustrated in the next subsection.

Solving the inverse NDFT

Expressing as the Lagrange polynomial of order N-1, we get

where are the fundamental polynomials:

Expressing by Newton interpolation method, we get

where is the divided difference of the jth order of with respect to :

The disadvantage of Lagrange representation is that any additional point included will increase the order of the interpolating polynomial, leading to the need of recomputing all the fundamental polynomials. However, any additional point included in Newton representation only require one more term.

We can use a lower triangular system to solve :

where

By the above equation, can be computed within operations. In this way Newton interpolation is more efficient than Lagrange Interpolation unless the latter is modified by

2-D NDFT

2-D NDFT of a sequence of size is[2]

where is the 2-D z-transform of , and are arbitrarily distinct points in the 4-D space.

As in the 1-D case, we can express the above equation as

and the matrix is also depends only on the choice of those sampling points. However, even if those sampling points are distinct, could still be singular. No rules for determining whether the matrix is nonsingular or not have been found. Therefore, for all implementation of 2-D NDFT, we just check for a specific set of sampling points. In general, the complexity of 2-D NDFT .

Applications

The applications of NDFT are:

See also

Notes

  1. Marvasti 2001, p. 326.
  2. Marvasti 2001, p. 334.

References

External links

This article is issued from Wikipedia - version of the 11/14/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.