Hi Nerma,
Check freqresp. The second argument should be a real vector of frequencies (typically > 0). The multiplication by 1j is done inside the function.
Frequency input to Transform Function
7 visualizaciones (últimos 30 días)
Mostrar comentarios más antiguos
I have developed set of transfer functions, with the final one being the acceleration. I have ran it successfully for an arbitary angular frequency range from 0.01 to 100 rad/s. Now I am trying to input a specific frequency response I have extracted using Fourier Transform, into the final Transfer function. I am not sure how to do this. I have tried using the function "freqresp", but I keep getting errors and weird graphs. Does anyone recommend any changes to the existing function or another function?
This is the code of the transfer functions and attempt signal input:
%%%%%Given Values
K_1 = 500000; % gain of the displacem transducer (V./m)
K_2 = 0.000016; % coil-magnet transfer function (m./s.^2)./V
K_3 = 31.6; % amplifier gain of the feedback output
omega_a = 0.0628; % output high pass cut-off angular frequency (rad./s)
omega_l = 8.72665; % output low pass cut-off angular frequency (rad./s)
f_l0 = 0.06667; % responant frequency of the pendulum (Hz)
h = 0.85; % damping constant
omega_d = 47.62; % demodulator low-pass cut-off angular frequency (rad./s)
omega_f = 0.000997; % feedback low-pass cut-off angular frequency (rad./s)
K = 208.4; % Conversion from V/(m/s^2) to DU/(m/s^2) [DU/V]
omega_f0 = 2*pi*f_l0;
%%%%Flat-Response Mode of the Long-Period Seismometer
% Transfer function of single-pole high-pass filter in the output amplifier
numerator_Fa = [1, 0];
denominator_Fa = [1, omega_a];
F_a = tf(numerator_Fa, denominator_Fa);
%Traner function of the feedback low-pass filter
numerator_Ff = [omega_f];
denominator_Ff = [1, omega_f];
F_f = tf(numerator_Ff, denominator_Ff);
% Tranfer function of the demodulator low-pass filter
numerator_Fd = [omega_d];
denominator_Fd = [1, omega_d];
F_d = tf(numerator_Fd, denominator_Fd);
% Transfer function of the seismometer for accleration
numerator_Sf = [1];
denominator_Sf = [1, 2*h*omega_f0, (omega_f0)^2];
S_f = tf(numerator_Sf, denominator_Sf);
% Transfer function of the feedback component of the seismometer
numerator_Fsf = K_1*S_f*F_d;
denominator_Fsf = 1 + K_1*K_2*S_f*F_d*F_f;
F_sf = numerator_Fsf/denominator_Fsf;
% Transfer function of 8-pole output low-pass anti-aliasing filter
numerator_Fla = [omega_l^2];
denominator_Fla = [1, 2*cos(pi/8)*omega_l,omega_l^2];
F_la = tf(numerator_Fla, denominator_Fla);
numerator_Flb = [omega_l^2];
denominator_Flb = [1, 2*cos((3*pi)/8)*omega_l,omega_l^2];
F_lb = tf(numerator_Flb, denominator_Flb);
F_l = [(F_la)^2] * [(F_lb)^2];
% Input of Frequnecy response (w) through the transfer functions
A_LPF_DU = K*K_3.*F_a*F_l*F_sf; % [DU/(m/s^2)]
s = j.*w;
[resp,freq] = freqresp(A_LPF_DU,s);
resp2 = abs(squeeze(resp))
figure (4)
loglog(freq,resp2)
xlabel('Frequency');
ylabel('Magnitude of Frequency Response');
Thank You!
0 comentarios
Respuestas (1)
Ver también
Community Treasure Hunt
Find the treasures in MATLAB Central and discover how the community can help you!
Start Hunting!
Translated by 
También puede seleccionar uno de estos países/idiomas:
América
- América Latina (Español)
- Canada (English)
- United States (English)
Europa
- Belgium (English)
- Denmark (English)
- Deutschland (Deutsch)
- España (Español)
- Finland (English)
- France (Français)
- Ireland (English)
- Italia (Italiano)
- Luxembourg (English)
- Netherlands (English)
- Norway (English)
- Österreich (Deutsch)
- Portugal (English)
- Sweden (English)
- Switzerland
- United Kingdom (English)
Asia-Pacífico
- Australia (English)
- India (English)
- New Zealand (English)
- 中国
- 日本Japanese (日本語)
- 한국Korean (한국어)