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IMPLEMENTATION OF FAST FOURIER TRANSFORM
Self Study Course
By Rohit Singh Amit Kumar Singh (M.Tech (VST))
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Report by Rohit Singh and Amit Kumar Singh for Self – Self – Study-Course, Study-Course, M.Tech. (VST), Deptt. Of EE,SOE, Shiv Nadar University
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Contents
1.
Introduction to fast fourier transform ...…………………
2.
Butterfly structures for FFT F FT
3.
Implementation of 16-point FFT blocks …………………...
11
4.
Matlab code for DFT
12
5.
Matlab code for 8 point FFT
6.
VHDL code for 16 point FFT Processor ……………
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...…………………
…………………. ………………….
03 08
13 14
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1. INTRODUCTION TO FAST FOURIER TRANSFORM A Fast Fourier Transform (FFT) is an efficient algorithm to compute the Discrete Fourier Transform (DFT) and its inverse. There are many distinct FFT algorithms involving a wide range of mathematics, from simple complex-number arithmetic to group theory and number theory. The fast Fourier Transform is a highly efficient procedure for computing the DFT of a finite series and requires less number of computations than that of direct evaluation of DFT. It reduces the computations by taking advantage of the fact that the calculation of the coefficients of the DFT can be carried out iteratively. Due to this, FFT computation technique is used in digital spectral analysis, filter simulation, autocorrelation and pattern recognition.
The FFT is based on decomposition and breaking the transform into smaller transforms and combining them to get the total transform. FFT reduces the computation time required to compute a discrete Fourier transform and improves the performance by a factor of 100 or more over direct evaluation of the DFT.
A DFT decomposes a sequence of values into components of different frequencies. This operation is useful in many fields but computing it directly from the definition is often too slow to be practical. An FFT is a way to compute the same result more quickly: computing a DFT of N points in the obvious way, using the definition, 2
takes O( N ) arithmetical operations, while an FFT can compute the same result in only O( N log N ) operations.
The difference in speed can be substantial, especially for long data sets where N may be in the thousands or millions — in practice, the computation time can be reduced by several orders of magnitude in such cases, and the improvement is roughly proportional to N /log ( N ). This huge improvement made many DFT-based algorithms practical. FFT’s are of great importance to a wide variety of applications, from digital signal processing ..
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and solving partial differential equations to algorithms for quick multiplication of large integers.
The most well known FFT algorithms depend upon the factorization of N , but there are FFT with O ( N log N ) complexity for all N , even for prime N . Many FFT algorithms only depend on the fact that is an N th primitive root of unity, and thus can be applied to analogous transforms over any finite field, such as number-theoretic transforms.
The Fast Fourier Transform algorithm exploit the two basic properties of the twiddle factor - the symmetry property and periodicity property which reduces the number of complex multiplications required to perform DFT. FFT algorithms are based on the fundamental principle of decomposing the computation of discrete Fourier Transform of a sequence of length N into successively smaller discrete Fourier transforms. There are basically two classes of FFT algorithms. A) Decimation In Time (DIT) algorithm B) Decimation In Frequency (DIF) algorithm. In decimation-in-time, the sequence for which we need the DFT is successively divided into smaller sequences and the DFTs of these subsequences are combined in a certain pattern to obtain the required DFT of the entire sequence. In the decimation-infrequency approach, the frequency samples of the DFT are decomposed into smaller and smaller subsequences in a similar manner. The number of complex multiplication and addition operations required by the simple forms both the Discrete Fourier Transform (DFT) and Inverse Discrete Fourier 2
Transform (IDFT) is of order N as there are N data points to calculate, each of which requires N complex arithmetic operations.
The discrete Fourier transform (DFT) is defined by the formula: ..
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N 1 X ( K ) x(n) e n0
j 2nK N
;
Where K is an integer ranging from 0 to N − 1.
2
The algorithmic complexity of DFT will O( N ) and hence is not a very efficient method. If we can't do any better than this then the DFT will not be very useful for the majority of practical DSP application. However, there are a number of different 'Fast Fourier Transform' (FFT) algorithms that enable the calculation the Fourier transform of a signal much faster than a DFT. As the name suggests, FFTs are algorithms for quick calculation of discrete Fourier transform of a data vector. The FFT is a DFT algorithm 2
which reduces the number of computations needed for N points from O( N ) to O( N log N ) where log is the base-2 logarithm. If the function to be transformed is not harmonically related to the sampling frequency, the response of an FFT looks like a ‘sinc’ function (sin x) / x.
The Radix-2 DIT algorithm rearranges the DFT of the function xn into two parts: a sum over the even-numbered indices n = 2m and a sum over the odd-numbered indices n = 2m + 1:
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One can factor a common multiplier
out of the second sum in the
equation. It is the two sums are the DFT of the even-indexed part x2m and the DFT of
odd-indexed part x2m + 1 of the function xn. Denote the DFT of the E ven-indexed inputs x2m by E k and the DFT of the Odd-indexed inputs x2m + 1 by Ok and we obtain:
However, these smaller DFTs have a length of N /2, so we need compute only N /2 outputs: thanks to the periodicity properties of the DFT, the outputs for N/2 < k < N from a DFT of length N /2 are identical to the outputs for 0< k < N/2. That is, E k + N / 2 = E k and Ok + N / 2 = Ok . The phase factor exp[ − 2πik / N ] called a twiddle factor which obeys the relation: exp[ − 2πi(k + N / 2) / N ] = e − πiexp[ − 2πik / N ] = − exp[ − 2πik / N ], flipping the sign of the Ok + N / 2 terms. Thus, the whole DFT can be calculated as follows:
This result, expressing the DFT of length N recursively in terms of two DFTs of size N /2, is the core of the radix-2 DIT fast Fourier transform. The algorithm gains its speed by re-using the results of intermediate computations to compute multiple DFT outputs. Note that final outputs are obtained by a +/− combination of E k and Ok exp( − 2πik / N ), which is simply a size-2 DFT; when this is generalized to larger radices below, the size-2 DFT is replaced by a larger DFT (which itself can be evaluated with an FFT).
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This process is an example of the general technique of divide and conquers algorithms. In many traditional implementations, however, the explicit recursion is avoided, and instead one traverses the computational tree in breadth-first fashion.
Fig 1.1 Decimation In Time FFT
In the DIT algorithm, the twiddle multiplication is performed before the butterfly stage whereas for the DIF algorithm, the twiddle multiplication comes after the Butterfly
stage.
Fig 1.2 Decimation In Frequency FFT
The 'Radix 2' algorithms are useful if N is a regular power of 2 ( N =2 p). If we assume that algorithmic complexity provides a direct measure of execution time and that the relevant logarithm base is 2 then as shown in table 1.1, ratio of execution times for the (DFT) vs. (Radix 2 FFT) increases tremendously with increase in N.
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The term 'FFT' is actually slightly ambiguous, because there are several commonly used 'FFT' algorithms. There are two different Radix 2 algorithms, the socalled 'Decimation in Time' (DIT) and 'Decimation in Frequency' (DIF) algorithms. Both of these rely on the recursive decomposition of an N point transform into 2 ( N /2) point transforms.
Number
Complex Multiplications
Complex Multiplication
Speed
of Points,
in Direct computations,
in FFT Algorithm, (N/2)
improvement
log2 N
Factor
2
N
N
4
16
4
4.0
8
64
12
5.3
16
256
32
8.0
32
1024
80
12.8
64
4096
192
21.3
128
16384
448
36.6
Table 1.1: Comparison of Execution Times, DFT & Radix – 2 FFT
2. BUTTERFLY STRUCTURES FOR FFT Basically FFT algorithms are developed by means of divide and conquer method, the is depending on the decomposition of an N point DFT in to smaller DFT’s. If N is factored as N = r 1,r 2,r 3 ..r L where r 1=r 2=…=r L=r, then r L =N. where r is called as Radix of FFT algorithm. If r= 2, then it is called as radix-2 FFT algorithm,. The basic DFT is of size of 2. The N point DFT is decimated into 2 point DFT by two ways such as Decimation In Time (DIT) and Decimation In Frequency (DIF) algorithm. Both the algorithm take the advantage of periodicity and symmetry property of the twiddle factor. j 2nK
W nK e N ..
N
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The radix-2 decimation-in-frequency FFT is an important algorithm o btained by the divide and conquers approach. The Fig. 1.3 below shows the first stage of the 8-point DIF algorithm.
Fig. 1.3 First Stage of 8 point Decimation in Frequency Algorithm.
The decimation, however, causes shuffling in data. The entire process involves v = log2 N stages of decimation, where each stage involves N /2 butterflies of the type shown in the Fig. 1.3.
Fig. 1.4: Butterfly Scheme.
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j 2nk
Here
W nk e
N
is the Twiddle factor.
Consequently, the computation of N-point DFT via this algorithm requires ( N /2) log2 N complex multiplications. For illustrative purposes, the eight-point decimation-in frequency algorithm is shown in the Figure below. We observe, as previously stated, that the output sequence occurs in bit-reversed order with respect to the input. Furthermore, if we abandon the requirement that the computations occur in place, it is also possible to have both the input and output in normal order. The 8 point Decimation In frequency algorithm is shown in Fig 1.5.
Fig. 1.5 8 point Decimation in Frequency Algorithm
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3. IMPLEMENTATION OF 16-POINT FFT BLOCKS
The FFT computation is accomplished in three stages. The x(0) until x(15) variables are denoted as the input values for FFT computation and X(0) until X(15) are denoted as the outputs. The pipeline architecture of the 16 point FFT is shown in Fig 2.1 consisting of butterfly schemes in it. There are two operations to complete the computation in each stage.
Fig 2.1: Architecture of 16 point FFT.
The upward arrow will execute addition operation while downward arrow will execute subtraction operation. The subtracted value is multiplied with twiddle factor
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value before being processed into the next stage. This operation is done concurrently and is known as butterfly process.
4. Matlab Code for DFT
% program to calculate DFT. clear all; clc; x=input ('enter the sequence '); tic N=size(x,2); w=zeros(N); for a=1:N for b=1:N w(a,b)=exp((-1j*2*pi*(a-1)*(b-1))/N); end end Xk = w*x'; Xk Toc
..
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5. Matlab Code for 8 point FFT % program to calculate 8 point FFT clear all; clc; x=input (' enter the sequence of length 8 '); tic s0=zeros(1,8); s1=zeros(1,8); s2=zeros(1,8); s3=zeros(1,8); N=size(x,2); if (N < 8 || N > 8) disp(' sequence is of not proper length '); else stage1=[1 1 1 0-1j 1 1 1 0-1j]; stage2=[1 1 1 1 1 0.707-0.707j 0-1j -0.707-0.707j]; p=[0:7]'; t=bitrevorder(p); % calculation of stage zero for i=1:N s0(i)=x(t(i)+1); end % calculation of stage one for i=1:2:N s1(i)=s0(i)+s0(i+1); s1(i+1)=s0(i)-s0(i+1); end for a=1:N s1(a)=s1(a)*stage1(a); end % calculation of stage two for i=1:4:N s2(i)=s1(i)+s1(i+2); s2(i+1)=s1(i+1)+s1(i+3); s2(i+2)=s1(i)-s1(i+2); s2(i+3)=s1(i+1)-s1(i+3); end for a=1:N s2(a)=s2(a)*stage2(a); end % calculation of stage three s3(1)=s2(1)+s2(5); s3(2)=s2(2)+s2(6); s3(3)=s2(3)+s2(7); s3(4)=s2(4)+s2(8); s3(5)=s2(1)-s2(5); s3(6)=s2(2)-s2(6); s3(7)=s2(3)-s2(7); s3(8)=s2(4)-s2(8); end disp(' FFT result '); s3 toc ..
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6. VHDL CODE FOR 16 POINT FFT PROCESSOR FFT MAIN PROGRAM
library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_SIGNED.all; use IEEE.STD_LOGIC_ARITH.all; use work.fft_package.all;
entity Parallel_FFT is Port ( x : in signed_vector; y : out
comp_array);
end Parallel_FFT;
architecture Behavioral of Parallel_FFT is
component real_input_to_complex is Port ( input_real : in
signed_vector;
input_comp : out
comp_array);
end component;
component butterfly is port( c1,c2 : in complex; w :in complex; g1,g2 :out complex ..
--inputs -- phase factor -- outputs
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); end component;
constant w : comp_array := ( ("0100000000000000", "0000000000000000"), ("0011101100100001", "1110011110000010"), ("0010110101000001", "1101001010111111"), ("0001100001111110", "1100010011011111"), ("0000000000000000", "1100000000000000"), ("1110011110000010", "1100010011011111"), ("1101001010111111", "1101001010111111"), ("1100010011011111", "1110011110000010"), ("1100000000000000", "0000000000000000"), ("1100010011011111", "0001100001111110"), ("1101001010111111", "0010110101000001"), ("1110011110000010", "0011101100100001"), ("0000000000000000", "0100000000000000"), ("0001100001111110", "0011101100100001"), ("0010110101000001", "0010110101000001"), ("0011101100100001", "0001100001111110") ); signal s, g1, g2, g3 : comp_array := (others => ("0000000000000000","0000000000000000")); ..
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begin --Real Input value transformed in complex value sixteen_bits_complex_transform : real_input_to_complex port map(x, s);
--first stage of butterfly's. bf11 : butterfly port map(s(0),s(8),w(0),g1(0),g1(8)); bf12 : butterfly port map(s(1),s(9),w(1),g1(1),g1(9)); bf13 : butterfly port map(s(2),s(10),w(2),g1(2),g1(10)); bf14 : butterfly port map(s(3),s(11),w(3),g1(3),g1(11)); bf15 : butterfly port map(s(4),s(12),w(4),g1(4),g1(12)); bf16 : butterfly port map(s(5),s(13),w(5),g1(5),g1(13)); bf17 : butterfly port map(s(6),s(14),w(6),g1(6),g1(14)); bf18 : butterfly port map(s(7),s(15),w(7),g1(7),g1(15));
--second stage of butterfly's. bf21 : butterfly port map(g1(0),g1(4),w(0),g2(0),g2(4)); bf22 : butterfly port map(g1(1),g1(5),w(2),g2(1),g2(5)); bf23 : butterfly port map(g1(2),g1(6),w(4),g2(2),g2(6)); bf24 : butterfly port map(g1(3),g1(7),w(6),g2(3),g2(7)); bf25 : butterfly port map(g1(8),g1(12),w(0),g2(8),g2(12)); bf26 : butterfly port map(g1(9),g1(13),w(2),g2(9),g2(13)); ..
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bf27 : butterfly port map(g1(10),g1(14),w(4),g2(10),g2(14)); bf28 : butterfly port map(g1(11),g1(15),w(6),g2(11),g2(15));
--third stage of butterfly's. bf31 : butterfly port map(g2(0),g2(2),w(0),g3(0),g3(2)); bf32 : butterfly port map(g2(1),g2(3),w(4),g3(1),g3(3)); bf33 : butterfly port map(g2(4),g2(6),w(0),g3(4),g3(6)); bf34 : butterfly port map(g2(5),g2(7),w(4),g3(5),g3(7)); bf35 : butterfly port map(g2(8),g2(10),w(0),g3(8),g3(10)); bf36 : butterfly port map(g2(9),g2(11),w(4),g3(9),g3(11)); bf37 : butterfly port map(g2(12),g2(14),w(0),g3(12),g3(14)); bf38 : butterfly port map(g2(13),g2(15),w(4),g3(13),g3(15));
--fourth stage of butterfly's. bf41 : butterfly port map(g3(0),g3(1),w(0),y(0),y(8)); bf42 : butterfly port map(g3(2),g3(3),w(0),y(4),y(12)); bf43 : butterfly port map(g3(4),g3(5),w(0),y(2),y(10)); bf44 : butterfly port map(g3(6),g3(7),w(0),y(6),y(14)); bf45 : butterfly port map(g3(8),g3(9),w(0),y(1),y(9)); bf46 : butterfly port map(g3(10),g3(11),w(0),y(5),y(13)); bf47 : butterfly port map(g3(12),g3(13),w(0),y(3),y(11)); ..
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bf48 : butterfly port map(g3(14),g3(15),w(0),y(7),y(15));
end Behavioral;
BUTTERFLY.VHD
library IEEE; use IEEE.STD_LOGIC_1164.ALL; use work.fft_package.all; entity butterfly is port( c1,c2 : in complex; w :in complex; g1,g2 :out complex
--inputs -- phase factor -- outputs
); end butterfly; architecture Behavioral of butterfly is begin
--butterfly equations. g1 <= add(c1,c2); ..
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g2 <= mult(sub(c1,c2),w);
end Behavioral;
FFT PACKAGE
library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_SIGNED.all; use IEEE.STD_LOGIC_ARITH.all;
package fft_package is
type complex is record r : signed(15 downto 0); i : signed(15 downto 0); end record;
type signed_vector is array (0 to 15) of signed(7 downto 0); type comp_array is array (0 to 15) of complex;
function add (n1,n2 : complex) return complex; function sub (n1,n2 : complex) return complex; function mult (n1,n2 : complex) return complex; ..
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end fft_package;
package body fft_package is --addition of complex numbers function add (n1,n2 : complex) return complex is
variable sum : complex; begin sum.r:=n1.r + n2.r; sum.i:=n1.i + n2.i; return sum; end add; --subtraction of complex numbers. function sub (n1,n2 : complex) return complex is variable diff : complex;
begin diff.r:=n1.r - n2.r; diff.i:=n1.i - n2.i; return diff; end sub; --multiplication of complex numbers. function mult (n1,n2 : complex) return complex is ..
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variable prod : complex; variable prod_aux_r : signed(31 downto 0); variable prod_aux_i : signed(31 downto 0);
begin prod_aux_r := (n1.r * n2.r) - (n1.i * n2.i); prod.r:= prod_aux_r(29 downto 14);
prod_aux_i := (n1.r * n2.i) + (n1.i * n2.r); prod.i:= prod_aux_i(29 downto 14); return prod; end mult;
end fft_package;
REAL TO COMPLEX
library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_SIGNED.all; use IEEE.STD_LOGIC_ARITH.all; use work.fft_package.all;
entity real_input_to_complex is ..
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Port ( input_real : in
signed_vector;
input_comp : out
comp_array);
end real_input_to_complex;
architecture Behavioral of real_input_to_complex is component sig_ext_8_to_16_bits is Port ( sig_in : in
signed(7 downto 0);
sig_out : out
complex);
end component;
begin input0 : sig_ext_8_to_16_bits port map (input_real(0), input_comp(0)); input1 : sig_ext_8_to_16_bits port map (input_real(1), input_comp(1)); input2 : sig_ext_8_to_16_bits port map (input_real(2), input_comp(2)); input3 : sig_ext_8_to_16_bits port map (input_real(3), input_comp(3)); input4 : sig_ext_8_to_16_bits port map (input_real(4), input_comp(4)); input5 : sig_ext_8_to_16_bits port map (input_real(5), input_comp(5)); input6 : sig_ext_8_to_16_bits port map (input_real(6), input_comp(6)); input7 : sig_ext_8_to_16_bits port map (input_real(7), input_comp(7)); ..
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input8 : sig_ext_8_to_16_bits port map (input_real(8), input_comp(8)); input9 : sig_ext_8_to_16_bits port map (input_real(9), input_comp(9)); input10 : sig_ext_8_to_16_bits port map (input_real(10), input_comp(10)); input11 : sig_ext_8_to_16_bits port map (input_real(11), input_comp(11)); input12 : sig_ext_8_to_16_bits port map (input_real(12), input_comp(12)); input13 : sig_ext_8_to_16_bits port map (input_real(13), input_comp(13)); input14 : sig_ext_8_to_16_bits port map (input_real(14), input_comp(14)); input15 : sig_ext_8_to_16_bits port map (input_real(15), input_comp(15));
end Behavioral;
EIGHT TO SIXTEEN
library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_SIGNED.all; use IEEE.STD_LOGIC_ARITH.all; ..
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use work.fft_package.all;
entity sig_ext_8_to_16_bits is Port ( sig_in : in
signed(7 downto 0);
sig_out : out
complex);
end sig_ext_8_to_16_bits;
architecture Behavioral of sig_ext_8_to_16_bits is signal sig_out_real : signed(15 downto 0); begin sig_out_real <= X"ff" & sig_in ;
X"00" & sig_in when sig_in(7)='0' else
sig_out <= (sig_out_real, "0000000000000000"); end Behavioral;
TEST BENCH
library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_SIGNED.all; use IEEE.STD_LOGIC_ARITH.all; use work.fft_package.all;
ENTITY fft_cooley_tukey_tb IS END fft_cooley_tukey_tb;
..
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ARCHITECTURE behavior OF fft_cooley_tukey_tb IS
-- Component Declaration for the Unit Under Test (UUT)
COMPONENT Parallel_FFT Port ( x : in signed_vector; y : out
comp_array);
END COMPONENT;
--Inputs signal x : signed_vector:= (others => "00000000");
--Outputs signal y : comp_array;
BEGIN
-- Instantiate the Unit Under Test (UUT) uut: Parallel_FFT PORT MAP ( x => x, y => y );
-- Stimulus process stim_proc: process ..
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begin -- hold reset state for 100 ns. wait for 100 ns;
--
--
x<=("00000001",
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001"
--
);
--
x<=("00000000",
..
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--
"00000000",
--
"00000000",
--
"00000000",
--
"00000000",
--
"00000000",
--
"00000000",
--
"00000000",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001",
--
"00000001"
--
); x<=("00000101", "00001010", "00001111", "00010100", "00011001", "00011110",
..
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"00100011", "00101000", "00101101", "00110010", "00110111", "00111100", "01000001", "01000110", "01001011", "01010000" ); wait; end process; END;
..
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