The present invention relates to a fast Fourier transform (FFT) system, and more particularly, to a memory address generating method for reducing a memory area and a twiddle factor generator using the memory address generating method.
An orthogonal frequency division multiplexing (OFDM) method is used in wireless communication systems including an IEEE 802.11 wireless local area network (WLAN) and an IEEE 802.16 wireless metropolitan area network (MAN), and in digital broadcasting systems including a digital multimedia broadcasting (DMB) system. In this case, a fast Fourier transform (FFT) processor is one of the most important constituent elements in the OFDM system.
An FFT algorithm is used to operate a discrete Fourier transform operation at a high speed, and the discrete Fourier transform (DFT) operation is given as Equation 1.
Here, X(K) denotes a result of the Fourier transform, x(n) denotes a FFT input data row, and WN denotes a twiddle factor, which are formed as complex numbers. In this case, the twiddle factor is a periodic function used to convert a time domain signal to a frequency domain signal. The FFT algorithm is performed to realize Equation 1.
Various methods for realizing the FFT algorithm have been suggested, which include a Radix-2 method and a Radix-4 method. Here, a configuration and a controlling operation of the Radix-4 method is more complicated compared to that of the Radix-2, but the Raix-4 method is more widely used since it has better multiplication performance. In the Radix-4 FFT algorithm, complex multiplication of the twiddle factor is performed, and twiddle factor values are stored in a memory.
An algorithm by M. Hasan and T. Arslan has been suggested to reduce the memory area of the twiddle factors in the FFT processor. In the algorithm, since all twiddle factors are formed in blocks by using a symmetry characteristic of the twiddle factor in the Radix-2 FFT processor,
twiddle factors are reduced to
twiddle factors.
However, the above algorithm is used in the Radix-2 method. In addition, it is required to respectively apply different memory address calculations and output equations for the respective divided blocks. That is, a memory address calculation and a realizing configuration that are commonly applied to the respective blocks are not suggested.
The above information disclosed in this Background section is only for enhancement of understanding of the background of the invention and therefore it may contain information that does not form the prior art that is already known in this country to a person of ordinary skill in the art.
The present invention has been made in an effort to provide a device for reducing a memory area required to store twiddle factors when a Radix-4 fast Fourier transform (FFT) system is realized, and a method thereof.
An exemplary twiddle factor generator for generating a twiddle factor in a fast Fourier transform (FFT) system includes a memory address calculator, a twiddle factor storage unit, and a controller. The memory address calculator generates a temporary address value for calculating a twiddle factor address value, generates a twiddle factor memory address value based on the temporary address value, and outputs a control signal based on the generated temporary address value for the twiddle factor. The twiddle factor storage unit stores a twiddle factor value corresponding to the twiddle factor memory address value, the twiddle factor value is generated based on a previously generated twiddle factor, and the twiddle factor storage unit outputs the twiddle factor value as a real part and an imaginary part. The controller outputs the twiddle factor value to the FFT system based on the control signal output from the memory address calculator.
In an exemplary method for generating a memory address of a twiddle factor in a fast Fourier transform (FFT) system according to an embodiment of the present invention: a temporary address value of the twiddle factor is obtained; a control signal for controlling the FFT system is generated based on the generated temporary address value of the twiddle factor; and a twiddle factor memory address value is output after generating the twiddle factor memory address value based on the generated temporary address value and the control signal.
In the following detailed description, only certain exemplary embodiments of the present invention have been shown and described, simply by way of illustration. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not restrictive. Like reference numerals designate like elements throughout the specification.
Throughout this specification and the claims that follow, unless explicitly described to the contrary, the word “comprise”, and variations such as “comprises” or “comprising”, will be understood to imply the inclusion of stated elements but not the exclusion of any other elements.
A signal flow of a conventional Radix-4 fast Fourier transform (FFT) butterfly operation will be described with reference to
Equation 3 is obtained by dividing output results X(k) of a Fourier transform operation of Equation 2 into four sub-groups.
A butterfly basic signal flow of the Radix-4 FFT algorithm is shown as
As shown in
To realize the Radix-4 FFT, FFT realizing methods are provided, such as a Radix-4 single-path delay feedback (R4SDF), a Radix-4 multi-path delay commutator (R4MDC), and a Radix-4 single-path delay commutator (R4SDC). In the various methods, the twiddle factor multiplication is performed in the same manner, and the twiddle factor is generally stored in the memory.
In an exemplary embodiment of the present invention, a device for reducing a memory area by using the R4SDF method and a method thereof are suggested. Firstly, a configuration of a R4SDF FFT processor will be described with reference to
As shown in
In a like manner of other FFT algorithms, in the Radix-4 FFT processor, the complex multiplication of the twiddle factor is performed, and the twiddle factor values are stored in the twiddle factor storage memory 13 to use. In this case, as a size N of the FFT operation is increased, the number of the twiddle factors is increased, and therefore it is require to increase the memory area. The increased memory area widely covers an integrated circuit (IC) area, and power consumption is increased. When the N-point FFT operation is performed in the conventional Radix-4 FFT processor, it is required to provide 3N/4 twiddle factor memories.
The R4SDF is exemplified in the exemplary embodiment of the present invention, but it is not limited thereto, and the Radix-4 FFT algorithms may be applied.
Referring to
When performing the N-point FFT operation (N=256), 256 twiddle factors are multiplied. The 64 twiddle factors from W2560 to W256189 in the 0 twiddle factor case, and the 64 twiddle factors from W2560 to W25663 in the 1 twiddle factor case are input to complex multiplier 14. The 64 twiddle factors from W2560 to W256126 in the 2 twiddle factor case, and the 64 twiddle factors from W2560 to W256189 in the 3 twiddle factor case are input to the complex multiplier 14. Here, when a different number is provided as N, the twiddle factor sequence is formed the same above, but a subfix of the twiddle factor is changed and the number of each twiddle factor case becomes N/4.
Twiddle factor values according to an exemplary embodiment of the present invention will be described with reference to
Numbers shown in
For example, the twiddle factors 6 and 7 and the twiddle factors 9 and 10 are symmetrical based on the twiddle factor 8. That is, a real number value and an imaginary number value of the twiddle factor 7 are switched, and signs thereof are changed to obtain the twiddle factor 9.
In addition, the twiddle factor 18 and the twiddle factor 14 are symmetrical based on an imaginary axis. Since the twiddle factors 2 and 4 are symmetrical based on the twiddle factor 8, the twiddle factor 18 may be obtained from the twiddle factor 2.
By using the symmetry characteristic of the twiddle factor, the twiddle factors (N=64) may be induced from the twiddle factors 0 to 8. That is, the number of twiddle factor memories may be reduced to
by storing the twiddle factors 0 to 8 in a memory, according to the exemplary embodiment of the present invention.
The twiddle factors (N=64) may be obtained from the twiddle factor memories (N=256). For example, W6415=W25660. That is, the twiddle factor 15 (N=64) is equal to the twiddle factor 60 (N=256). Accordingly, in the FFT configuration (N=256) shown in
twiddle factor memories stored in the twiddle factor storage memory 13 subsequent to the first butterfly unit.
Table 1 shows twiddle factors 0 to 8 induced by using the symmetrical characteristics of the twiddle factors (N=64) shown in
An
Here, An
NQ denotes a parameter indicating the respective twiddle factor cases, and it has values of 0, 1, 2, and 3 when a corresponding operation is performed. That is, to obtain an nth temporary address value An
{circle around (1)} When D>An
{circle around (2)} When An
{circle around (3)} When An
Here, D denotes a minimum symmetric point of the twiddle factor. When the N-point FFT is performed, D=N/8. That is, when N=64, D=8 in
That is, a temporary address value of an nth twiddle factor obtained by Equation 4 and the minimum symmetric point of a (n−1)th twiddle factor are compared. When the temporary address value is equal to or greater than the minimum symmetric point, the memory address value of the nth twiddle factor is set by doubling the minimum symmetric point of the twiddle factor and subtracting the temporary address value of the nth twiddle factor. In addition, when the temporary address value of the nth twiddle factor is lower than 0, the memory address value of the nth twiddle factor is set by reversing the sign of the temporary address value of the nth twiddle factor.
A device for generating the twiddle factor will be described with reference to
As shown in
The twiddle factor storage unit 100 stores the twiddle factors required to perform the N-point FFT algorithm, and separates the twiddle factor into a real
part and an imaginary part. In this case, storage spaces are required as described with reference to
The memory address calculator 200 operates Equation 4 and Equation 5. That is, the memory address calculator 200 generates a memory address of the twiddle factor stored in the twiddle factor storage unit 100.
As described in
The controller 300 includes switches 310 and 360, and sign inverters 320, 330, 340, and 350. The switch 310 (also, referred to as a “first switch”) switches the real and imaginary parts of the twiddle factor output by the twiddle factor storage unit 100 when An
The switch 360 (also, referred to a “second switch”) operates the sign inverters 330 and 350. That is, when An
The sign inverters 320, 330, 340, and 350 receive operation signals from the memory address calculator 200, and invert signs of signals from the switch 310 to output final twiddle factors as shown in
For example, the sign inverters 320 and 340 alternately output signals having the sign of the original signal, the inverted sign, and the sign of the original signal when the control signal corresponding to the case {circle around (2)} shown in Equation 2 is generated. Hereinafter, the control signal that is output from an upper terminal of the memory address calculator 200 shown in
The control signal (hereinafter, referred to as a “second control signal”) output from a lower terminal of the memory address calculator 200 shown in
The second switch 360 operates when the second control signal is generated. The second control signal may be generated twice to the maximum during one twiddle factor case. When the second control signal is initially generated, the second switch 360 is connected to the sign inverter 330 to invert the sign of the output signal. When the second control signal is subsequently generated, the switch 360 is connected to the sign inverter 350 to invert the sign of the signal output as the imaginary part. When one twiddle factor case is finished, the state of the sign inverters 330 and 350 is turned back to an original state thereof, and the sign inverters 330 and 350 output an input signal without switching the sign.
The sign inverters 320, 330, 340, and 350, the switches 310 and 360, and the first and second control signals are initialized when the respective twiddle factor cases are started.
In the cases {circle around (2)} and {circle around (3)} shown in Equation 5, W(n)_real and W(n)_imag are output as values of which signs are inverted or the real and imaginary parts are switched. In the case {circle around (1)} shown in Equation 5, the control operations of the switch 360 and the sign inverters 320, 330, 340, and 350 are not performed.
That is, when the case {circle around (2)} shown in Equation 5 is initially generated and the switch 310 operates, the real and imaginary parts may be switched and the signs may be inverted. When the subsequent temporary twiddle factor calculation value corresponds to the case {circle around (2)}, the switch 310 and the sign inverters 320, 330, 340, and 350 are maintained to output the value of which the real part and the imaginary part are switched and the signs are inverted. The output values are input to complex multiplier 14 shown in
A method for finally generating the twiddle factor by the twiddle factor generator described in
As shown in
When the temporary address value of the nth twiddle factor is induced in step S100, the corresponding temporary address value is determined in step S10 based on the three cases shown in Equation 5.
When the temporary address value is given as D>An
When the temporary address value is given as An
The generated first control signal operates the first switch 310 and the sign inverters 320 and 340 to switch the real part and the imaginary part of the nth twiddle factor output from the twiddle factor storage unit 100 in step S160. The twiddle factor, in which the real part and the imaginary part are switched, is output as the final twiddle factor value in step S130.
When the temporary address value is given as An
The generated second control signal operates the sign inverters 330 and 350 to invert the signs of the real and imaginary parts of the nth twiddle factor output from the twiddle factor storage unit 100, in step S190. The twiddle factor, of which the sign of the real part or the imaginary part is inverted, is output as the final twiddle factor value in step S130.
Variations of the control signal, which is described in
Since all twiddle factor values are WN0 in the 0 twiddle factor case as shown in Table 1, descriptions thereof will be omitted. Referring to
As shown in
In addition, a dotted line shows that the {circle around (2)} or {circle around (3)} case is generated according to the calculation of Equation 4 and Equation 5 and shows a time for generating the first control signal or the second control signal according to the {circle around (2)} or {circle around (3)} case. Accordingly, after the dotted line, a type of an output signal is changed.
Referring to
In the 2 twiddle factor case (i.e., the index of the twiddle factor is 2), four twiddle factor values are calculated, the first control signal is generated, and a fifth twiddle factor value is calculated. After the first signal is generated and the four twiddle factor values are calculated, the second control signal is generated, and the ninth twiddle factor value is calculated.
In further detail, when the fourth twiddle factor value is 6, An-1 is 4 (refer to the 2 twiddle factor case shown in Table 1), S is 1, and NQ is 2. An-tmp, which is a temporary address value of the fourth twiddle factor, is 6 (i.e., 4+1·2). In this case, since a result value 6 corresponds to the {circle around (1)} shown in Equation 5, the temporary address value 6 is set as a memory address value of the fourth twiddle factor.
When a fifth twiddle factor value is 8, An-1 is 6, S is 1, NQ is 2. An
The above-described methods and apparatuses are not only realized by the exemplary embodiment of the present invention, but, on the contrary, are intended to be realized by a program for realizing functions corresponding to the configuration of the exemplary embodiment of the present invention or a recording medium for recording the program.
While this invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
According to the exemplary embodiment of the present invention, since the number of memories for storing the twiddle factors is reduced to
when the Radix-4 FFT processor is realized, an IC chip area may be minimized, and power consumption may be reduced.
In addition, since the address of the twiddle factor is calculated by the suggested equations and algorithm, the control signal may be formed by a simplified switch.
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10-2005-0119889 | Dec 2005 | KR | national |
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PCT/KR2006/005217 | 12/6/2006 | WO | 00 | 6/9/2008 |
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