METHOD AND SYSTEM FOR INVERSE CHIRP-Z TRANSFORMATION

Abstract

Provided are a method and a system for an inverse chirp-z transformation, and more particularly, a method and a system for an inverse chirp-z transformation having improved availability as compared to conventional Inverse Discrete Fourier Transform (IDFT) or Inverse Fast Fourier Transform (IFFT) because a start time of an output signal and an interval between samples are freely adjustable in obtaining a signal on a time domain by performing an inverse transformation for any spectrum signal on a frequency domain.

Claims

1. A system for an inverse chirp-z transformation (ICZT) that inversely transforms any spectrum input signal on a frequency domain into a signal on a time domain, the system comprising: an input unit receiving any spectrum signal (X.sup.(z.sup.n.sup.)) on the frequency domain; a setting unit setting a start time (t.sub.0) of a final output signal (z.sub.k) and a time interval (t) between samples of the output signal (z.sub.k); and a calculating unit calculating the output signal (x.sub.k) on the time domain by reflecting actual frequency information (F.sub.n) of a corresponding spectrum signal, and values (t.sub.0, t) set by the setting unit to the spectrum signal (X.sup.(z.sup.n.sup.)) input to the input unit and performing an Inverse Fast Fourier transform (IFFT) and a Fast Fourier transform (FFT).

2. The system for an ICZT of claim 1, wherein the spectrum signal (X.sup.(z.sup.n.sup.)) is a discrete finite signal obtained by sampling a continuous signal at a constant frequency and performing a Discrete Fourier transform (DFT) or a Fast Fourier transform (FFT) or a Chirp-Z transform (CZT).

3. The system for an ICZT of claim 1, wherein the output signal (z.sub.k) is calculated by the following Equation: $x_k=W^{\frac{k^2}{2}}.Math..Math.\left[\mathrm{FFT}.Math.\left\{\mathrm{IFFT}.Math.\left\{Y_n\right\}.Math.\mathrm{IFFT}.Math.\left\{W^{-\frac{n^2}{2}}\right\}\right\}\right],k=0,1,\mathrm{.Math.}.Math.,M-1$ $Y_n=X\left(z_n\right).Math.B^n.Math.W^{\frac{n^2}{2}},n=\frac{F_n}{.Math..Math.F}$ $B=B_0.Math.\exp \left(j.Math..Math.2.Math.{}_0\right),{}_0=.Math..Math.F.Math.t_0$ $W=W_0.Math.\exp \left({\mathrm{j2}}_0\right),{}_0=.Math..Math.F.Math..Math..Math.t.$ (M is the number of output sample signals, F is a frequency interval of an input spectrum signal, and B.sub.0 and W.sub.0 are amplitude constants).

4. A method for an inverse chirp-z transformation (ICZT) that inversely transforms any spectrum input signal on a frequency domain into a signal on a time domain, the method comprising: a) receiving any spectrum signal (X.sup.(z.sup.n.sup.)) on the frequency domain; b) setting a start time (t.sub.0) of an output signal (x.sub.k) and a time interval (t) between samples of the output signal (x.sub.k); and c) calculating the output signal (x.sub.k) on the time domain by reflecting actual frequency information (F.sub.n) of a corresponding spectrum signal, and values (t.sub.0, t) set in the operation b) to the spectrum signal (X.sup.(z.sup.n.sup.)) input in the operation a) and performing an Inverse Fast Fourier transform (IFFT) and a Fast Fourier transform (FFT).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] FIG. 1 is a schematic configuration diagram of a system for an inverse chirp-z transformation according to an exemplary embodiment of the present invention.

[0019] FIGS. 2A, 2B, 3A, 3B, 4A, 4B, and 4C are verification examples of a method for an inverse chirp-z transformation according to an exemplary embodiment of the present invention.

DETAILED DESCRIPTION OF MAIN ELEMENTS

[0020] 10: input unit

[0021] 20: setting unit

[0022] 30: calculating unit

DETAILED DESCRIPTION OF EMBODIMENTS

[0023] As described above, the CZT is a forward transformation method having a high degree of freedom in functionality as compared to the conventional DFT or FFT. However, since the ICZT, which is an inverse transformation of the CZT, is not derived even if a technology of implementing the CZT is conversely applied, a method for technologically implementing the ICZT was not conventionally suggested.

[0024] The present invention relates to a system and a method for an inverse chirp-z transformation (ICZT) that inversely transforms any spectrum input signal on a frequency domain into a signal on a time domain, and is intended to provide a method and a system which may be actually implemented from a technical form of the ICZT based on a conventional CZT technology.

[0025] Hereinafter, a technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

[0026] The accompanying drawings are only examples shown in order to describe the technical spirit of the present invention in more detail. Therefore, the technical spirit of the present invention is not limited to shapes of the accompanying drawings.

[0027] FIG. 1 is a schematic configuration diagram of a system for an inverse chirp-z transformation according to an exemplary embodiment of the present invention. As shown, the system for an inverse chirp-z transformation according to the present invention may be configured to include an input unit 10, a setting unit 20, and a calculating unit 30.

[0028] The input unit 10 serves to receive any spectrum signal (X.sup.(z.sup.n.sup.)) on a frequency domain. In this case, the spectrum signal (X.sup.(z.sup.n.sup.)) input to the input unit 10 may be a discrete finite signal obtained by sampling a continuous signal at a constant frequency and performing a Discrete Fourier transform (DFT) or a Fast Fourier transform (FFT) or a Chirp-Z transform (CZT).

[0029] In addition, the setting unit 20 sets a start time (t.sub.0) of a signal (z.sub.k) to be finally output from the calculating unit 30 and a time interval (t) between samples of the output signal (z.sub.k). In this case, the set values (t.sub.0, t) may be changed as much as a user wants.

[0030] Finally, the calculating unit 30 calculates the output signal (x.sub.k) on the time domain by reflecting actual frequency information (F.sub.n) of a corresponding spectrum signal (X.sup.(z.sup.n.sup.)) and the values (t.sub.0, t) set by the setting unit 20 to the spectrum signal (X.sup.(z.sup.n.sup.)) input from the input unit 10 and then performing an Inverse Fast Fourier transform (IFFT) and FFT. In this case, on the drawing, F.sub.s means

[00002]$\frac{1}{.Math..Math.t}.$

[0031] Specifically, the output signal (x.sub.k) calculated by the calculating unit 30 is implemented by the following Equation 1.

[00003]$\begin{array}{cc}{x}_k=W^{\frac{k^2}{2}}.Math.\left[\mathrm{FFT}.Math.\left\{\mathrm{IFFT}.Math.\left\{Y_n\right\}.Math.\mathrm{IFFT}.Math.\left\{W^{-\frac{n^2}{2}}\right\}\right\}\right],.Math.k=0,1,\mathrm{.Math.}.Math.,M-1.Math..Math.Y_n=X\left(z_n\right).Math.B^n.Math.W^{\frac{n^2}{2}}.Math.n=\frac{F_n}{.Math..Math.F}.Math..Math.B=B_0.Math.\exp \left({\mathrm{j2}}_0\right),{}_0=.Math..Math.F.Math.t_0.Math..Math.W=W_0.Math.\exp \left({\mathrm{j2}}_0\right),{}_0=.Math..Math.F.Math..Math..Math.t& \left[\mathrm{Equation}.Math..Math.1\right]\end{array}$

[0032] (Here, M is the number of output sample signals, F is a frequency interval of an input spectrum signal, and B.sub.0 and W.sub.0, which are amplitude constants, are set to 1 to increase speed and accuracy of a signal processing).

[0033] As such, since the output signal (x.sub.k) may be easily implemented by a combination of IFFT and FFT, and values of a variable (B) adjusting a time at which the sample signal (x.sub.k) to be output from the calculating unit 30 starts and a variable (W) adjusting a time interval in which the sample signal (x.sub.k) is formed are determined by the values (t.sub.0, t) set by the setting unit 20, the sample signal (x.sub.k) having a high degree of freedom of a selection may be obtained.

[0034] Hereinafter, a process of deriving an implementation form of the output signal (x.sub.k) of the calculating unit expressed by the above Equation 1 will be proved.

[0035] A technology form of the conventional CZT may be expressed as in the following Equation 2 such as being suggested in the Related Art Document 1.

[00004]$\begin{array}{cc}{X}_k=\underset{n=0}{\overset{N-1}{.Math.}}.Math..Math.x_n.Math.B^{-n}.Math.W^{\mathrm{nk}},k=0,1,\mathrm{.Math.}.Math.,M-1& \left[\mathrm{Equation}.Math..Math.2\right]\end{array}$

[0036] A technical form of the ICZT, which is a converse concept of the CZT, is expressed by the following Equation 3.

[00005]$\begin{array}{cc}{x}_k=\underset{n=0}{\overset{N-1}{.Math.}}.Math.X\left(z_n\right).Math..Math.B^n.Math.W^{\mathrm{nk}},k=0,1,\mathrm{.Math.}.Math.,M-1& \left[\mathrm{Equation}.Math..Math.3\right]\end{array}$

[0037] In this case, according to a principle suggested in the related art document 2, Equation 3 is developed by substituting n.Math.k in a phase component of W.sup.nk of Equation 3 as follows.

[00006]$\begin{array}{cc}n.Math.k=\frac{n^2+k^2-{\left(k-n\right)}^2}{2}& \left[\mathrm{Equation}.Math..Math.4\right]\\ x_k=W^{\frac{k^2}{2}}.Math.\underset{n=0}{\overset{N-1}{.Math.}}.Math..Math.\left[X\left(z_n\right).Math.B^n.Math.W^{\frac{n^2}{2}}.Math.W^{\frac{-{\left(k-n\right)}^2}{2}}\right],.Math.k=0,1,\mathrm{.Math.}.Math.,M-1& \left[\mathrm{Equation}.Math..Math.5\right]\end{array}$

[0038] The above Equation 5 may be summarized in a convolution (*) form as follows.

[00007]$\begin{array}{cc}{x}_k=W^{\frac{k^2}{2}}.Math.\left(Y_n*W^{-\frac{n^2}{2}}\right),k=0,1,\mathrm{.Math.}.Math.,M-1.Math..Math.Y_n=X\left(z_n\right).Math.B^n.Math.W^{\frac{n^2}{2}}.& \left[\mathrm{Equation}.Math..Math.6\right]\end{array}$

[0039] Considering that the convolution (*) on the time domain is a product on the frequency domain, the convolution may be simply implemented by performing the IFFT for each of the two signals, multiplying the two signals, and then again performing the FFT. According to the conventional CZT, the FFT is performed for each of the two signals, the two signals are multiplied, and then the IFFT is performed, but according to the present invention, since input data is the spectrum signal on the frequency domain, the implementation of the convolution is inversely performed.

[0040] Therefore, the convolution (*) of the above Equation 6 is expressed by a combination of FFT and IFFT as in Equation 7.

[00008]$\begin{array}{cc}\left(Y_n*W^{-\frac{n^2}{2}}\right)=\mathrm{FFT}.Math.\left\{\mathrm{IFFT}.Math.\left\{Y_n\right\}.Math.\mathrm{IFFT}.Math.\left\{W^{-\frac{n^2}{2}}\right\}\right\}& \left[\mathrm{Equation}.Math..Math.7\right]\end{array}$

[0041] As such, by substituting the derived Equation 7 into Equation 6, the above Equation 1, which is the final implementation form of the ICZT, may be derived.

[0042] At the time of implementing the ICZT according to the present invention, a variable n is defined as an actual frequency sample number of the input spectrum signal. That is, as expressed in Equation 1, n is a value obtained by dividing the actual frequency information (F.sub.n) of the input spectrum sample signal by a frequency interval (F) of the input spectrum signal.

[0043] As such, according to the present invention, since the actual frequency sample number (n) needs to be applied, the actual frequency information (F.sub.n) on the spectrum signal input to the input unit 10 needs to be used, and this information is information which is known before performing the DFT, FFT, or CZT, which is a prior operation of the ICZT, in planning the signal processing.

[0044] Hereinabove, the process of deriving the implementation form of the ICZT according to the present invention was described. Hereinafter, a result obtained by verifying accuracy of the implementation form of the ICZT will be described with reference to FIGS. 2 to 4.

[0045] All verifications were performed based on any continuous time signal (s.sub.0(t)), and a verification method compares magnitude of the signal with a result obtained by performing the ICZT according to the present invention using actual reference data for phase information.

[0046] A first verification compares s.sub.1(t.sub.n) with a result obtained by performing ICZT{FFT{s.sub.1(t.sub.n)}}. That is, a spectrum signal S.sub.1(f.sub.k) is obtained by performing the FFT for

[00009]$s_0\left(\frac{n}{F_1}\right)=s_1\left(t_n\right),$

which is a signal obtained by sampling s.sub.0(t) at a sampling frequency F.sub.1, and s.sub.1.sub._.sub.ICZT(t.sub.n), which is a result obtained by regenerating s.sub.1(t.sub.n) by performing the ICZT using S.sub.1(f.sub.k) as an input, is confirmed.

[0047] FIG. 2A is a graph illustrating an envelope and a phase for a signal

[00010]$s_1\left(t_n\right)=s_0\left(\frac{n}{F_1}\right),$

and FIG. 2B illustrates a result graph obtained by regenerating s.sub.1(t.sub.n) by performing ICZT{FFT{s.sub.1(t.sub.n)}}.

[0048] That is, comparing FIGS. 2A and 2B, it may be confirmed that two signals are very similar to each other within a section in which s.sub.1(t.sub.n), which is the reference signal, exists.

[0049] A second verification verifies a time offset and a time interval adjustment function between samples of the ICZT.

[0050] In the same way as the first verification described above, the spectrum signal S.sub.1(f.sub.k) is obtained by performing the FFT for

[00011]$s_0\left(\frac{n}{F_1}\right)=s_1\left(t_n\right),$

which is the signal obtained by sampling s.sub.0(t) at the sampling frequency F.sub.1, the ICZT is performed using S.sub.1(f.sub.k) as an input, and s.sub.2.sub._.sub.ICZT(t.sub.n) is obtained by applying a time offset t.sub.0 and a new sample frequency

[00012]$F_2.Math.\frac{1}{\left(.Math..Math.t\right)}$

to a final output result signal. This is compared with

[00013]$s_2\left(t_n\right)=s_0\left(t_0+\frac{n}{F_2}\right),$

which is an actual reference signal.

[0051] FIG. 3A shows a graph illustrating an envelope and a phase of

[00014]$s_2\left(t_n\right)=s_0\left(t_0+\frac{n}{F_2}\right),$

which is the reference signal, and FIG. 3B shows a result graph obtained by regenerating s.sub.2(t.sub.n) by performing ICZT_t.sub.0 offset, F.sub.2 samplingfrequency{FFT{s.sub.1(t.sub.n)}}.

[0052] Also in this case, comparing FIGS. 3A and 3B, it may be confirmed that two signals are very similar to each other within a section in which s.sub.2(t.sub.n), which is the reference signal, exists. Therefore, the time offset and the sampling frequency adjustment function of the ICZT were verified.

[0053] A final verification verifies a basic function when the ICZT is performed using CZT result data corresponding to limited spectrum data as an input, and verifies the time offset and the time interval adjustment function between the samples.

[0054] That is, the spectrum signal s.sub.1.sub._.sub.CZT(f.sub.k) is obtained by performing the CZT for

[00015]$s_0\left(\frac{n}{F_1}\right)=s_1\left(t_n\right),$

which is the signal obtained by sampling s.sub.0(t) at the sampling frequency F.sub.1. The ICZT is performed using S.sub.1.sub._.sub.CZT(f.sub.k) as the input, and s.sub.3.sub._.sub.ICZT(t.sub.n) is obtained by applying the time offset t.sub.0 and a new sampling frequency F.sub.2 to the final output result signal. This is compared with

[00016]$s_2\left(t_n\right)=s_0\left(t_0+\frac{n}{F_2}\right),$

which is the actual reference signal.

[0055] FIG. 4A illustrates an envelope and a phase of a signal S.sub.1.sub._.sub.CZT(f.sub.k)=CZT{s.sub.1(t.sub.n)}, FIG. 4B is a result graph obtained by regenerating s.sub.3(t.sub.n) by performing ICZT_t.sub.0offset, F.sub.2samplingfrequency{CZT{s.sub.1(t.sub.n)}}, and FIG. 4C is a graph illustrating an envelope and a phase of

[00017]$s_3\left(t_n\right)=s_0\left(t_0+\frac{n}{F_2}\right),$

which is a reference signal to be compared with the graph of FIG. 4B.

[0056] Similarly in this case, it was confirmed that two signals (FIGS. 4C and 4B) are very similar to each other within a section in which the reference signal exists, and a basic inverse transformation function, the time offset, and the sample frequency adjustment function of ICZT/CZT were verified.

[0057] In summary, according to the present invention, the method and the system capable of implementing the ICZT as a complete implementation form corresponding to the CZT may be provided. In particular, according to the present invention, since the time at which the final output signal on the time domain starts and the interval between the samples may be freely adjusted by arbitrarily setting the setting values (t.sub.0, t), the degree of freedom may be very high at the time of forming the signal.

[0058] The conventional IDFT or IFFT may obtain the inversely transformed result only by the defined start time and the time interval between the samples, and needs to apply a circuitous technology such as additional interpolation, or the like to obtain the desired signal, but according to the present invention, since the above-mentioned processes are unnecessary, it is possible to solve complexity and a difficulty in the implementation.

[0059] The present invention is not limited to the above-mentioned exemplary embodiments, and may be variously applied, and may be variously modified without departing from the gist of the present invention claimed in the claims.