首页 > 代码库 > 《DSP using MATLAB》示例Example 8.24
《DSP using MATLAB》示例Example 8.24
代码:
%% ------------------------------------------------------------------------ %% Output Info about this m-file fprintf(‘\n***********************************************************\n‘); fprintf(‘ <DSP using MATLAB> Exameple 8.24 \n\n‘); time_stamp = datestr(now, 31); [wkd1, wkd2] = weekday(today, ‘long‘); fprintf(‘ Now is %20s, and it is %8s \n\n‘, time_stamp, wkd2); %% ------------------------------------------------------------------------ % Digital Filter Specifications: wp = 0.2*pi; % digital passband freq in rad ws = 0.3*pi; % digital stopband freq in rad Rp = 1; % passband ripple in dB As = 15; % stopband attenuation in dB % Analog prototype specifications: Inverse Mapping for frequencies T = 1; % set T = 1 OmegaP = (2/T)*tan(wp/2); % Prewarp(Cutoff) prototype passband freq OmegaS = (2/T)*tan(ws/2); % Prewarp(cutoff) prototype stopband freq % Analog Elliptic Prototype Order Calculations: ep = sqrt(10^(Rp/10)-1); % Passband Ripple Factor A = 10^(As/20); % Stopband Attenuation Factor OmegaC = OmegaP; % Analog Elliptic prototype cutoff freq k = OmegaP/OmegaS; % Analog prototype Transition ratio k1 = ep/sqrt(A*A-1); % Analog prototype Intermediate cal capk = ellipke([k.^2 1-k.^2]); capk1 = ellipke([(k1 .^2) 1-(k1 .^2)]); N = ceil(capk(1)*capk1(2)/(capk(2)*capk1(1))); fprintf(‘\n\n ********** Elliptic Filter Order = %3.0f \n‘, N) % Digital Chebyshev-2 Filter Design: wn = wp/pi; % Digital cutoff freq in pi units [b, a] = ellip(N, Rp, As, wn); [C, B, A] = dir2cas(b, a) % Calculation of Frequency Response: [db, mag, pha, grd, ww] = freqz_m(b, a); %% ----------------------------------------------------------------- %% Plot %% ----------------------------------------------------------------- figure(‘NumberTitle‘, ‘off‘, ‘Name‘, ‘Exameple 8.24‘) set(gcf,‘Color‘,‘white‘); M = 1; % Omega max subplot(2,2,1); plot(ww/pi, mag); axis([0, M, 0, 1.2]); grid on; xlabel(‘ frequency in \pi units‘); ylabel(‘|H|‘); title(‘Magnitude Response‘); set(gca, ‘XTickMode‘, ‘manual‘, ‘XTick‘, [0, 0.2, 0.3, M]); set(gca, ‘YTickMode‘, ‘manual‘, ‘YTick‘, [0, 0.1778, 0.8913, 1]); subplot(2,2,2); plot(ww/pi, pha/pi); axis([0, M, -1.1, 1.1]); grid on; xlabel(‘frequency in \pi nuits‘); ylabel(‘radians in \pi units‘); title(‘Phase Response‘); set(gca, ‘XTickMode‘, ‘manual‘, ‘XTick‘, [0, 0.2, 0.3, M]); set(gca, ‘YTickMode‘, ‘manual‘, ‘YTick‘, [-1:1:1]); subplot(2,2,3); plot(ww/pi, db); axis([0, M, -30, 10]); grid on; xlabel(‘frequency in \pi units‘); ylabel(‘Decibels‘); title(‘Magnitude in dB ‘); set(gca, ‘XTickMode‘, ‘manual‘, ‘XTick‘, [0, 0.2, 0.3, M]); set(gca, ‘YTickMode‘, ‘manual‘, ‘YTick‘, [-30, -15, -1, 0]); subplot(2,2,4); plot(ww/pi, grd); axis([0, M, 0, 15]); grid on; xlabel(‘frequency in \pi units‘); ylabel(‘Samples‘); title(‘Group Delay‘); set(gca, ‘XTickMode‘, ‘manual‘, ‘XTick‘, [0, 0.2, 0.3, M]); set(gca, ‘YTickMode‘, ‘manual‘, ‘YTick‘, [0:5:15]);
运行结果:
《DSP using MATLAB》示例Example 8.24
声明:以上内容来自用户投稿及互联网公开渠道收集整理发布,本网站不拥有所有权,未作人工编辑处理,也不承担相关法律责任,若内容有误或涉及侵权可进行投诉: 投诉/举报 工作人员会在5个工作日内联系你,一经查实,本站将立刻删除涉嫌侵权内容。