电子说
作者:OpenSLee
在《基于FPGA的多级CIC滤波器实现四倍抽取一》和《基于FPGA的多级CIC滤波器实现四倍抽取二》中我们先来了解滑动平均滤波器、微分器、积分器以及梳状滤波器原理以及它们的幅频响应。此篇我们将用verilog实现基于FPGA的多级CIC滤波器实现四倍插值。
1 CIC滤波器的基本概述
CIC(积分梳状)滤波器是无线通信中的常用模块,一般用于数字下变频(DDC)和数字上变频(DUC)系统。CIC滤波器结构简单,只有加法器、积分器和寄存器,适合于工作在搞采样率条件下,而且CIC滤波器是一种基于零点相消的FIR滤波器,已经被证明是在高速抽取或插值系统中非常有效的单元。
整数倍内插是先在已知抽样序列的相邻两个抽样点之间等间隔地插入(I-1)个零值点,然后进行低通滤波器,即可求得I倍内插的结果。
此篇我们采用多级CIC滤波器实现整数倍内插提升采样率。
2 matlab实现CIC滤波器的四倍插值
设计目标:将载波频率44.1khz的1khz sine升采样率到176.4khz。
close all clear all clc %set system parameter fs = 1000; %The frequency of the local oscillator signal Fs = 44100; %sampling frequency Fs1 = 176400; N = 24; %Quantitative bits L = 81920; %Generating an input signal t =0:1/Fs:(1/Fs)*(L-1); %Generating the time series of sampling frequencies sc =sin(2*pi*fs*t); %a sinusoidal input signal that produces a random starting phase b =[1,-1];%comb a =[1,-1];%integerator %comb c1=filter(b,1,sc); c2=filter(b,1,c1); c3=filter(b,1,c2); y = upsample(c3,4); %integerater i1 =filter(1,a,y); i2 =filter(1,a,i1); i3 =filter(1,a,i2); sf = i3./16; f_osc =fft(sc,L); f_osc=20*log(abs(f_osc))/log(10); %换算成dBW单位 ft1=[0:(Fs/L):Fs/2]; %转换横坐标以Hz为单位 f_osc=f_osc(1:length(ft1)); f_o =fft(sf,L); f_o=20*log(abs(f_o))/log(10); %换算成dBW单位 ft2=[0:(Fs1/L):Fs1/8]; %转换横坐标以Hz为单位 f_o=f_o(1:length(ft2)); figure(1), subplot(211),stem(t(1:32),sc(1:32)); xlabel('时间(t)','fontsize',8); ylabel('幅度(dB)','fontsize',8); title('sc','fontsize',8); subplot(212),stem(t(1:128),sf(1:128)); xlabel('时间(t)','fontsize',8); ylabel('幅度(dB)','fontsize',8); title('sf','fontsize',8); figure(2), subplot(211),plot(ft1,f_osc); xlabel('频率(Hz)','fontsize',8); ylabel('功率(dBW)','fontsize',8); title('原始信号信号频谱图','fontsize',8);legend('sc'); subplot(212),plot(ft2,f_o); xlabel('频率(Hz)','fontsize',8); ylabel('功率(dBW)','fontsize',8); title('滤波后信号频谱图','fontsize',8);legend('sf');
3 FPGA实现CIC滤波器的四倍插值
FPGA设计:FPGA由i2s输入44.1khz的1khz sine(当然也可以是歌曲44.1khz采样率),经过i2s串转并后经过mult_cic模块进行采样率提升处理(变成176.4khz 1khz sine或者歌曲),再通过i2s_tx_master并转串送到DAC 。
多级CIC滤波器的结构主要由梳状滤波器+插值+积分器构成。
FPGA代码:
`timescale 1ps/1ps module mult_cic#(parameter DW = 38)( input mclk,//45.1584MHZ input reset_n, input signed[31:0] pcm_in,//44.1khz output signed[31:0] pcm_out //176.4khz ); wire signed [DW-1:0] temp; wire signed [DW-1:0]integrator_temp; wire signed [DW-1:0] interpolation_temp; wire signed [DW-1:0] comb_temp; assign temp = {{(DW-32){pcm_in[31]}},pcm_in}; comb#(.DW(DW)) U_comb( .mclk(mclk), .reset_n(reset_n), .din(temp), .dout(comb_temp) ); interpolation#(.DW(DW)) U_interpolation( .mclk(mclk), .reset_n(reset_n), .din(comb_temp), .dout(interpolation_temp) ); integrator#(.DW(DW)) U_integrator( .mclk(mclk), .reset_n(reset_n), .din(interpolation_temp), .dout(integrator_temp) ); //divide assign pcm_out = integrator_temp[35:4]; endmodule
module integrator#(parameter DW = 38)( input mclk, input reset_n, input signed [DW-1:0] din, output signed [DW-1:0] dout ); localparam LAST_CYCLE = 256; reg [7:0] i; reg signed [DW-1:0] temp_xin1,temp_xin2,temp_xin3; wire signed [DW-1:0] i1_temp,i2_temp,i3_temp; always @(posedge mclk or negedge reset_n) begin if(reset_n == 1'b0) i <= 0; else i < = i+1; end always @(posedge mclk or negedge reset_n) begin //The first level integrator if(reset_n == 1'b0) temp_xin1 <= 0; else if(i == (LAST_CYCLE-1)) temp_xin1 <= i1_temp; end assign i1_temp = (reset_n == 1'b0)?38'b0:( din + temp_xin1); always @(posedge mclk or negedge reset_n) begin //The second level integrator if(reset_n == 1'b0) temp_xin2 <= 0; else if(i == (LAST_CYCLE-1)) temp_xin2 <= i2_temp; end assign i2_temp = (reset_n == 1'b0)?38'b0:( i1_temp + temp_xin2); always @(posedge mclk or negedge reset_n) begin //The third level integrator if(reset_n == 1'b0) temp_xin3 <= 0; else if(i == (LAST_CYCLE-1)) temp_xin3 <= i3_temp; end assign i3_temp = (reset_n == 1'b0)?38'b0:( i2_temp + temp_xin3); assign dout = i3_temp; endmodule
module interpolation#(parameter DW = 38)( input mclk, input reset_n, input signed [DW-1:0] din, output signed [DW-1:0] dout ); localparam LAST_CYCLE = 256; reg [9:0] i; reg signed [DW-1:0] dout_pcm; assign dout = dout_pcm; always @(posedge mclk or negedge reset_n) begin if(reset_n == 1'b0) begin i <= 0; dout_pcm<=0; end else begin i <= i+1; if(i == (LAST_CYCLE-1)) dout_pcm<=din; //upsample(x,n)--n--4 if(i == (LAST_CYCLE*2-1)) dout_pcm<=32'b0; //upsample(x,n)--n--4 if(i == (LAST_CYCLE*3-1)) dout_pcm<=32'b0; //upsample(x,n)--n--4 if(i == (LAST_CYCLE*4-1)) dout_pcm<=32'b0; //upsample(x,n)--n--4 end end endmodule
module comb#(parameter DW = 38)( input mclk, input reset_n, input signed [DW-1:0] din, output signed [DW-1:0] dout ); localparam LAST_CYCLE = 1024; reg [9:0] i;//88.2 reg signed [DW-1:0] d1,d2,d3,d4; wire signed [DW-1:0] c1,c2; always @(posedge mclk or negedge reset_n) begin if(reset_n == 1'b0) begin i <= 0; d1 <=0; d2 <=0; d3 <=0; d4 <=0; end else begin i <= i+1; if(i == (LAST_CYCLE-1)) begin d1<=din; d2<=d1; d3<=c1; d4<=c2; end end end assign c1 = (reset_n ==1'b0)?38'b0:(d1-d2);//comb1 assign c2 = (reset_n ==1'b0)?38'b0:(c1-d3);//comb2 assign dout =(reset_n ==1'b0)?38'b0:(c2-d4);//comb3 endmodule
FPGA仿真:
仿真输入1khz sine输出依然为1khz sine,设计成功。
至此我们可以去完成3倍抽取5倍插值等采样率转化算法。
编辑:hfy
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