其他分享
首页 > 其他分享> > 《DSP using MATLAB》Problem 8.43

《DSP using MATLAB》Problem 8.43

作者:互联网

代码:

%% ------------------------------------------------------------------------
%%            Output Info about this m-file
fprintf('\n***********************************************************\n');
fprintf('        <DSP using MATLAB> Problem 8.43 \n\n');

banner();
%% ------------------------------------------------------------------------

% Digital Highpass Filter Specifications:
wphp = 0.4*pi;                 % digital passband freq in rad
wshp = 0.3*pi;                 % digital stopband freq in rad
Rp = 1.0;                      % passband ripple in dB
As = 40;                       % stopband attenuation in dB

Ripple = 10 ^ (-Rp/20)           % passband ripple in absolute
Attn = 10 ^ (-As/20)             % stopband attenuation in absolute

fprintf('\n*******Digital Highpass, Coefficients of DIRECT-form***********\n');
%[bhp, ahp] = butthpf(wphp, wshp, Rp, As)
%[bhp, ahp] = cheb1hpf(wphp, wshp, Rp, As)
%[bhp, ahp] = cheb2hpf(wphp, wshp, Rp, As)
[bhp, ahp] = eliphpf(wphp, wshp, Rp, As);
[C, B, A] = dir2cas(bhp, ahp)

% Calculation of Frequency Response:
%[dblp, maglp, phalp, grdlp, wwlp] = freqz_m(blp, alp);
[dbhp, maghp, phahp, grdhp, wwhp] = freqz_m(bhp, ahp);

% ---------------------------------------------------------------
%    find Actual Passband Ripple and Min Stopband attenuation
% ---------------------------------------------------------------
delta_w = 2*pi/1000;
Rp_hp = -(min(dbhp(ceil(wphp/delta_w+1):1:501)));                       % Actual Passband Ripple

fprintf('\nActual Passband Ripple is %.4f dB.\n', Rp_hp);

As_hp = -round(max(dbhp(1:1:ceil(wshp/delta_w)+1)));                % Min Stopband attenuation
fprintf('\nMin Stopband attenuation is %.4f dB.\n\n', As_hp);

%% -----------------------------------------------------------------
%%                             Plot
%%    overall analog filter over the [0, 5KHz] inteval
%% -----------------------------------------------------------------  

figure('NumberTitle', 'off', 'Name', 'Problem 8.43 Elliptic Highpass by eliphpf function')
set(gcf,'Color','white'); 
M = 1;                          % Omega max
Fs = 10;                        % sampling rate of 10 KHz

subplot(2,2,1); plot(wwhp*Fs/(2*pi), maghp); grid on;%axis([0, M, 0, 1.2]); 
%xlabel('Digital frequency in \pi units'); 
xlabel('analog frequency in KHz units'); 
ylabel('|H|'); title('Highpass Filter Magnitude Response');
set(gca, 'XTickMode', 'manual', 'XTick', [0, 0.3, 0.4, M]*Fs/2);
set(gca, 'YTickMode', 'manual', 'YTick', [0, 0.8913, 1]);

subplot(2,2,2); plot(wwhp*Fs/(2*pi), dbhp); grid on;%axis([0, M, -100, 2]); 
%xlabel('Digital frequency in \pi units'); 
xlabel('analog frequency in KHz units'); 
ylabel('Decibels'); title('Highpass Filter Magnitude in dB');
set(gca, 'XTickMode', 'manual', 'XTick', [0, 0.3, 0.4, M]*Fs/2);
set(gca, 'YTickMode', 'manual', 'YTick', [-70, -40, -1, 0]);
set(gca,'YTickLabelMode','manual','YTickLabel',['70'; '40';'1 ';' 0']);


subplot(2,2,3); plot(wwhp*Fs/(2*pi), phahp/pi); grid on; %axis([0, M, -1.1, 1.1]); 
%xlabel('Digital frequency in \pi nuits'); 
xlabel('analog frequency in KHz units');
ylabel('radians in \pi units'); title('Highpass Filter Phase Response');
set(gca, 'XTickMode', 'manual', 'XTick', [0, 0.3, 0.4, M]*Fs/2);
set(gca, 'YTickMode', 'manual', 'YTick', [-1:1:1]);

subplot(2,2,4); plot(wwhp*Fs/(2*pi), grdhp); grid on; %axis([0, M, 0, 25]); 
%xlabel('Digital frequency in \pi units'); 
xlabel('analog frequency in KHz units');
ylabel('Samples'); title('Highpass Filter Group Delay');
set(gca, 'XTickMode', 'manual', 'XTick', [0, 0.3, 0.4, M]*Fs/2);
set(gca, 'YTickMode', 'manual', 'YTick', [0:10:25]);



% ----------------------------------------------------------
%              Part 2  digital prototype lowpass filter
% ----------------------------------------------------------
% Digital lowpass Filter Specifications:
[wpLP, wsLP, alpha] = hp2lpfre(wphp, wshp);

% Calculation of Elliptic lp filter parameters:
[N, wn] = ellipord(wpLP/pi, wsLP/pi, Rp, As);
fprintf('\n********** Elliptic Filter Order = %3.0f \n', N)

% Digital Elliptic lowpass Filter Design:
[blp, alp] = ellip(N, Rp, As, wn, 'low');

[C, B, A] = dir2cas(blp, alp)

% Calculation of Frequency Response:
[dblp, maglp, phalp, grdlp, wwlp] = freqz_m(blp, alp);


% ---------------------------------------------------------------
%    find Actual Passband Ripple and Min Stopband attenuation
% ---------------------------------------------------------------
delta_w = 2*pi/1000;
Rp_lp = -(min(dblp(1:1:ceil(wpLP/delta_w+1)+1)));                       % Actual Passband Ripple

fprintf('\nActual Passband Ripple is %.4f dB.\n', Rp_lp);

As_lp = -round(max(dblp(ceil(wsLP/delta_w)+1):1:501));                % Min Stopband attenuation
fprintf('\nMin Stopband attenuation is %.4f dB.\n\n', As_lp);

%% -----------------------------------------------------------------
%%                             Plot
%% -----------------------------------------------------------------  

figure('NumberTitle', 'off', 'Name', 'Problem 8.43 Elliptic Prototype Lowpass by ellip function')
set(gcf,'Color','white'); 
M = 1;                          % Omega max

subplot(2,2,1); plot(wwlp/pi, maglp); axis([0, M, 0, 1.2]); grid on;
xlabel('Digital frequency in \pi units'); ylabel('|H|'); 
title('lowpass Filter Magnitude Response');
set(gca, 'XTickMode', 'manual', 'XTick', [0, wpLP, wsLP, pi]/pi);
set(gca, 'YTickMode', 'manual', 'YTick', [0, 0.8913, 1]);

subplot(2,2,2); plot(wwlp/pi, dblp); axis([0, M, -100, 2]); grid on;
xlabel('Digital frequency in \pi units'); ylabel('Decibels'); 
title('lowpass Filter Magnitude in dB');
set(gca, 'XTickMode', 'manual', 'XTick', [0, wpLP, wsLP, pi]/pi);
set(gca, 'YTickMode', 'manual', 'YTick', [-70, -40, -1, 0]);
set(gca,'YTickLabelMode','manual','YTickLabel',['70'; '40';'1 ';' 0']);


subplot(2,2,3); plot(wwlp/pi, phalp/pi); axis([0, M, -1.1, 1.1]); grid on;
xlabel('Digital frequency in \pi nuits'); ylabel('radians in \pi units'); 
title('lowpass Filter Phase Response');
set(gca, 'XTickMode', 'manual', 'XTick', [0, wpLP, wsLP, pi]/pi);
set(gca, 'YTickMode', 'manual', 'YTick', [-1:1:1]);

subplot(2,2,4); plot(wwlp/pi, grdlp); axis([0, M, 0, 25]); grid on;
xlabel('Digital frequency in \pi units'); ylabel('Samples'); 
title('lowpass Filter Group Delay');
set(gca, 'XTickMode', 'manual', 'XTick', [0, wpLP, wsLP, pi]/pi);
set(gca, 'YTickMode', 'manual', 'YTick', [0:5:25]);




% -----------------------------------------------------
%              Part 3  ellip function
% -----------------------------------------------------
% Calculation of Elliptic hp filter parameters:
[N, wn] = ellipord(wphp/pi, wshp/pi, Rp, As);
fprintf('\n********** Elliptic Filter Order = %3.0f \n', N)

% Digital Elliptic Highpass Filter Design:
[bhp, ahp] = ellip(N, Rp, As, wn, 'high');

[C, B, A] = dir2cas(bhp, ahp)

% Calculation of Frequency Response:
%[dblp, maglp, phalp, grdlp, wwlp] = freqz_m(blp, alp);
[dbhp, maghp, phahp, grdhp, wwhp] = freqz_m(bhp, ahp);

% ---------------------------------------------------------------
%    find Actual Passband Ripple and Min Stopband attenuation
% ---------------------------------------------------------------
delta_w = 2*pi/1000;
Rp_hp = -(min(dbhp(ceil(wphp/delta_w+1):1:501)));                       % Actual Passband Ripple

fprintf('\nActual Passband Ripple is %.4f dB.\n', Rp_hp);

As_hp = -round(max(dbhp(1:1:ceil(wshp/delta_w)+1)));                % Min Stopband attenuation
fprintf('\nMin Stopband attenuation is %.4f dB.\n\n', As_hp);

%% -----------------------------------------------------------------
%%                             Plot
%% -----------------------------------------------------------------  

figure('NumberTitle', 'off', 'Name', 'Problem 8.43 Elliptic Highpass by ellip function')
set(gcf,'Color','white'); 
M = 1;                          % Omega max

subplot(2,2,1); plot(wwhp/pi, maghp); axis([0, M, 0, 1.2]); grid on;
xlabel('Digital frequency in \pi units'); ylabel('|H|'); title('Highpass Filter Magnitude Response');
set(gca, 'XTickMode', 'manual', 'XTick', [0, 0.3, 0.4, M]);
set(gca, 'YTickMode', 'manual', 'YTick', [0, 0.8913, 1]);

subplot(2,2,2); plot(wwhp/pi, dbhp); axis([0, M, -100, 2]); grid on;
xlabel('Digital frequency in \pi units'); ylabel('Decibels'); title('Highpass Filter Magnitude in dB');
set(gca, 'XTickMode', 'manual', 'XTick', [0, 0.3, 0.4, M]);
set(gca, 'YTickMode', 'manual', 'YTick', [-70, -40, -1, 0]);
set(gca,'YTickLabelMode','manual','YTickLabel',['70'; '40';'1 ';' 0']);


subplot(2,2,3); plot(wwhp/pi, phahp/pi); axis([0, M, -1.1, 1.1]); grid on;
xlabel('Digital frequency in \pi nuits'); ylabel('radians in \pi units'); title('Highpass Filter Phase Response');
set(gca, 'XTickMode', 'manual', 'XTick', [0, 0.3, 0.4, M]);
set(gca, 'YTickMode', 'manual', 'YTick', [-1:1:1]);

subplot(2,2,4); plot(wwhp/pi, grdhp); axis([0, M, 0, 25]); grid on;
xlabel('Digital frequency in \pi units'); ylabel('Samples'); title('Highpass Filter Group Delay');
set(gca, 'XTickMode', 'manual', 'XTick', [0, 0.3, 0.4, M]);
set(gca, 'YTickMode', 'manual', 'YTick', [0:5:25]);

  运行结果:

       通带、阻带设计指标,绝对值单位

        Elliptic型数字高通,滤波器系统函数串联形式的系数如下,阶数是5阶

        采用eliphpf函数,设计的Elliptic型数字高通,幅度谱、相位谱和群延迟响应

 

        第2小题,要画出数字低通原型的幅度谱。

        Elliptic型数字低通滤波器,系统函数串联形式系数如下

        采用ellip函数(MATLAB工具箱函数),设计的Elliptic型数字高通滤波器,系统函数串联形式系数如下,

        幅度谱、相位谱和群延迟响应如下

 

标签:gca,set,manual,Filter,MATLAB,Digital,using,Problem,pi
来源: https://www.cnblogs.com/ky027wh-sx/p/11832292.html