How to plot 3-D bode from the derived transfer function?

Question

Nitheesh R am 20 Mär. 2024

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https://de.mathworks.com/matlabcentral/answers/2096826-how-to-plot-3-d-bode-from-the-derived-transfer-function

Kommentiert: Aquatris am 26 Mär. 2024

I want to plot my derived transfer function in this format as shown in figure below. The transfer function is derived using state matrices and using this following expression: G_vd=q*(inv((s*I)-A))*f

I used symb to get the transfer function with 'ws=2*pi*Fs - switching frequency' as a variable. 'wo=2*pi*Fo' is a constant and I can vary 'ws' as per the ratio needed. So, now I have a transfer function with variable 'ws' and the complex frequency 's'.

This is what I obtained after simplifying. How to proceed further? I found answers where manual multiplication was performed. Also, I want to use surf command to obtain a neat surface.

G_vd =-(1.6872e+30*ws*(2.0616e+11*ws^2 - 1.5981e+19)*(- 1.0434e+209*s^14*ws^2 + 9.7644e+213*s^14*ws + 3.4484e+220*s^14 - 1.2991e+213*s^13*ws^2 + 1.2158e+218*s^13*ws + 4.2937e+224*s^13 - 5.2168e+209*s^12*ws^4 + 3.9142e+214*s^12*ws^3 + 6.8734e+220*s^12*ws^2 + 1.2884e+226*s^12*ws + 3.4203e+232*s^12 - 5.6241e+213*s^11*ws^4 + 4.8516e+218*s^11*ws^3 + 9.9349e+224*s^11*ws^2 + 9.4516e+229*s^11*ws + 2.8572e+236*s^11 - 1.0434e+210*s^10*ws^6 + 5.8925e+214*s^10*ws^5 + 3.3573e+220*s^10*ws^4 + 4.185e+226*s^10*ws^3 + 6.8393e+232*s^10*ws^2 + 3.2035e+237*s^10*ws + 1.131e+244*s^10 - 9.5051e+213*s^9*ws^6 + 7.2633e+218*s^9*ws^5 + 5.6111e+224*s^9*ws^4 + 3.0823e+230*s^9*ws^3 + 7.0634e+236*s^9*ws^2 + 9.3038e+240*s^9*ws + 4.8152e+247*s^9 - 1.0434e+210*s^8*ws^8 + 3.9566e+214*s^8*ws^7 - 1.3383e+219*s^8*ws^6 + 4.8276e+226*s^8*ws^5 + 3.4139e+232*s^8*ws^4 + 9.5864e+237*s^8*ws^3 + 2.2626e+244*s^8*ws^2 + 3.8015e+246*s^8*ws + 1.2478e+255*s^8 - 7.7621e+213*s^7*ws^8 + 4.8387e+218*s^7*ws^7 - 5.7637e+222*s^7*ws^6 + 3.5915e+230*s^7*ws^5 + 4.2122e+236*s^7*ws^4 + 2.7369e+241*s^7*ws^3 + 1.4076e+248*s^7*ws^2 + 2.6339e+249*s^7*ws + 2.0572e+257*s^7 - 5.2168e+209*s^6*ws^10 + 1.0103e+214*s^6*ws^9 - 3.5371e+220*s^6*ws^8 + 2.2567e+226*s^6*ws^7 + 3.4001e+232*s^6*ws^6 + 9.5471e+237*s^6*ws^5 + 6.907e+241*s^6*ws^4 + 9.913e+246*s^6*ws^3 + 3.7354e+255*s^6*ws^2 + 8.413e+254*s^6*ws + 2.891e+263*s^6 - 3.0095e+213*s^5*ws^10 + 1.2146e+218*s^5*ws^9 + 1.3223e+224*s^5*ws^8 + 1.7168e+230*s^5*ws^7 - 1.3395e+236*s^5*ws^6 + 2.6851e+241*s^5*ws^5 + 1.3718e+248*s^5*ws^4 + 2.9996e+249*s^5*ws^3 + 3.9942e+257*s^5*ws^2 + 2.5473e+257*s^5*ws + 4.5819e+265*s^5 - 1.0434e+209*s^4*ws^12 + 8.4668e+211*s^4*ws^11 - 6.9202e+220*s^4*ws^10 + 3.2845e+225*s^4*ws^9 + 6.818e+232*s^4*ws^8 + 3.146e+237*s^4*ws^7 - 2.2528e+244*s^4*ws^6 + 9.4169e+246*s^4*ws^5 + 3.7335e+255*s^4*ws^4 + 8.9376e+254*s^4*ws^3 + 2.891e+263*s^4*ws^2 + 4.474e+262*s^4*ws + 1.7485e+271*s^4 - 4.276e+212*s^3*ws^12 + 3.47e+215*s^3*ws^11 + 1.3494e+224*s^3*ws^10 + 2.6238e+229*s^3*ws^9 - 1.3454e+236*s^3*ws^8 + 8.7872e+240*s^3*ws^7 + 4.4564e+247*s^3*ws^6 + 1.2063e+249*s^3*ws^5 + 1.9823e+257*s^3*ws^4 + 2.6028e+256*s^3*ws^3 + 9.8906e+262*s^3*ws^2 + 8.3904e+264*s^3*ws + 2.7391e+273*s^3 - 3.4492e+220*s^2*ws^12 + 2.799e+223*s^2*ws^11 + 3.4125e+232*s^2*ws^10 - 1.8193e+235*s^2*ws^9 - 1.1279e+244*s^2*ws^8 + 3.3039e+246*s^2*ws^7 + 1.245e+255*s^2*ws^6 + 2.9442e+254*s^2*ws^5 + 9.7024e+262*s^2*ws^4 + 7.8861e+261*s^2*ws^3 + 2.5095e+270*s^2*ws^2 + 4.8895e+269*s^2*ws + 1.9905e+278*s^2 - 3.3148e+220*s*ws^12 + 2.6899e+223*s*ws^11 + 1.0516e+232*s*ws^10 + 2.0331e+237*s*ws^9 - 1.0373e+244*s*ws^8 + 6.8464e+248*s*ws^7 + 3.4325e+255*s*ws^6 - 6.7804e+256*s*ws^5 + 1.4597e+265*s*ws^4 - 4.3488e+264*s*ws^3 - 2.3319e+273*s*ws^2 + 7.6327e+271*s*ws + 3.1084e+280*s - 2.6732e+228*ws^12 + 2.1693e+231*ws^11 + 2.6488e+240*ws^10 - 1.4429e+243*ws^9 - 8.767e+251*ws^8 + 2.4141e+254*ws^7 + 9.6974e+262*ws^6 - 3.6803e+262*ws^5 - 1.497e+271*ws^4 + 4.8818e+269*ws^3 + 1.9883e+278*ws^2 + 2.9811e+273*ws + 1.2142e+282))/((1.9723e+81*ws^6 + 1.6586e+70*ws^5 - 1.3024e+93*ws^4 + 1.9498e+95*ws^3 + 2.1636e+104*ws^2 + 7.694e+89*ws - 3.024e+112)*(1.8535e+158*s^15 + 2.3223e+162*s^14 + 9.2675e+158*s^13*ws^2 + 1.8385e+170*s^13 + 1.0063e+163*s^12*ws^2 + 1.5501e+174*s^12 + 1.8535e+159*s^11*ws^4 + 5.5157e+170*s^11*ws^2 - 4.8956e+152*s^11*ws + 6.0797e+181*s^11 + 1.703e+163*s^10*ws^4 + 4.6214e+174*s^10*ws^2 - 8.0497e+160*s^10*ws + 2.6358e+185*s^10 + 1.8535e+159*s^9*ws^6 + 6.1289e+170*s^9*ws^4 - 9.7911e+152*s^9*ws^3 + 1.418e+182*s^9*ws^2 - 5.0127e+164*s^9*ws + 6.7076e+192*s^9 + 1.3934e+163*s^8*ws^6 + 4.607e+174*s^8*ws^4 - 4.0254e+160*s^8*ws^3 + 7.7101e+185*s^8*ws^2 - 2.0666e+183*s^8*ws + 1.6298e+195*s^8 + 9.2675e+158*s^7*ws^8 + 3.6774e+170*s^7*ws^6 + 6.0799e+181*s^7*ws^4 - 1.1547e+165*s^7*ws^3 + 2.0084e+193*s^7*ws^2 - 7.7771e+185*s^7*ws + 1.5541e+201*s^7 + 5.4188e+162*s^6*ws^8 + 1.5552e+174*s^6*ws^6 + 2.0123e+161*s^6*ws^5 + 7.4863e+185*s^6*ws^4 - 5.9779e+183*s^6*ws^3 + 3.717e+195*s^6*ws^2 - 3.6532e+193*s^6*ws + 3.677e+203*s^6 + 1.8535e+158*s^5*ws^10 + 1.8385e+170*s^5*ws^8 + 9.7911e+152*s^5*ws^7 - 6.07e+181*s^5*ws^6 - 8.0586e+164*s^5*ws^5 + 2.0074e+193*s^5*ws^4 - 1.0659e+186*s^5*ws^3 + 1.5545e+201*s^5*ws^2 - 5.7145e+195*s^5*ws + 9.4011e+208*s^5 + 7.7411e+161*s^4*ws^10 + 2.43e+172*s^4*ws^8 + 2.0124e+161*s^4*ws^7 + 2.3803e+185*s^4*ws^6 - 5.7559e+183*s^4*ws^5 + 2.6341e+195*s^4*ws^4 - 3.6377e+193*s^4*ws^3 + 1.22e+203*s^4*ws^2 - 5.3887e+200*s^4*ws + 2.2066e+211*s^4 + 6.1275e+169*s^3*ws^10 + 4.8956e+152*s^3*ws^9 - 4.0486e+181*s^3*ws^8 - 1.5239e+164*s^3*ws^7 + 6.6943e+192*s^3*ws^6 + 1.6657e+185*s^3*ws^5 + 5.2167e+200*s^3*ws^4 + 1.0076e+193*s^3*ws^3 + 1.3493e+208*s^3*ws^2 - 8.4161e+202*s^3*ws + 1.0712e+216*s^3 + 4.8461e+171*s^2*ws^10 + 4.0248e+160*s^2*ws^9 - 3.1534e+183*s^2*ws^8 - 1.8447e+183*s^2*ws^7 + 5.4181e+194*s^2*ws^6 + 3.6831e+193*s^2*ws^5 + 1.1917e+203*s^2*ws^4 - 1.0772e+201*s^2*ws^3 - 1.148e+211*s^2*ws^2 - 3.2874e+204*s^2*ws + 2.5068e+218*s^2 + 4.7489e+177*s*ws^10 + 3.795e+160*s*ws^9 - 3.1449e+189*s*ws^8 + 4.548e+185*s*ws^7 + 5.2104e+200*s*ws^6 + 5.7246e+195*s*ws^5 - 8.046e+208*s*ws^4 - 8.4161e+202*s*ws^3 + 1.0678e+216*s*ws^2 - 4.9815e+197*s*ws + 1.9579e+220*s + 3.7101e+179*ws^10 + 3.12e+168*ws^9 - 2.45e+191*ws^8 + 3.6677e+193*ws^7 + 4.0703e+202*ws^6 - 5.3837e+200*ws^5 - 6.2858e+210*ws^4 - 3.2874e+204*ws^3 + 8.3493e+217*ws^2 - 1.2972e+199*ws + 5.0985e+221))

Fig: taken from https://doi.org/10.1109/TPEL.2015.2464351

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Answer 1

Aquatris am 20 Mär. 2024

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Direkter Link zu dieser Antwort

https://de.mathworks.com/matlabcentral/answers/2096826-how-to-plot-3-d-bode-from-the-derived-transfer-function#answer_1428326

Bearbeitet: Aquatris am 20 Mär. 2024

In MATLAB Online öffnen

Here is one way:

% undamped system where w defines the natural frequency and s is the

% s-domain frequency grid variable

sys = @(s,w) 1./((s*1i).^2+2*0.05*w.*(s*1i)+w.^2); % create your tf as a function of s and w

wV = 10:1:30; % define w values you want

sV = (0:1:50);% define desired frequency

[WW,SS] = meshgrid(wV,sV);

sysV = sys(SS,WW); % evaluate your transfer function in desired sV and wV

% plot

surf(WW,SS,abs(sysV))

xlabel('W')

ylabel('Freq')

zlabel('Magnitude')

Edit: Here is another way for your transfer function, but I think something is wrong with your derivation since the values blow up real when you evaluate:

syms ws s

G_vd =-(1.6872e+30*ws*(2.0616e+11*ws^2 - 1.5981e+19)*(- 1.0434e+209*s^14*ws^2 + 9.7644e+213*s^14*ws + 3.4484e+220*s^14 - 1.2991e+213*s^13*ws^2 + 1.2158e+218*s^13*ws + 4.2937e+224*s^13 - 5.2168e+209*s^12*ws^4 + 3.9142e+214*s^12*ws^3 + 6.8734e+220*s^12*ws^2 + 1.2884e+226*s^12*ws + 3.4203e+232*s^12 - 5.6241e+213*s^11*ws^4 + 4.8516e+218*s^11*ws^3 + 9.9349e+224*s^11*ws^2 + 9.4516e+229*s^11*ws + 2.8572e+236*s^11 - 1.0434e+210*s^10*ws^6 + 5.8925e+214*s^10*ws^5 + 3.3573e+220*s^10*ws^4 + 4.185e+226*s^10*ws^3 + 6.8393e+232*s^10*ws^2 + 3.2035e+237*s^10*ws + 1.131e+244*s^10 - 9.5051e+213*s^9*ws^6 + 7.2633e+218*s^9*ws^5 + 5.6111e+224*s^9*ws^4 + 3.0823e+230*s^9*ws^3 + 7.0634e+236*s^9*ws^2 + 9.3038e+240*s^9*ws + 4.8152e+247*s^9 - 1.0434e+210*s^8*ws^8 + 3.9566e+214*s^8*ws^7 - 1.3383e+219*s^8*ws^6 + 4.8276e+226*s^8*ws^5 + 3.4139e+232*s^8*ws^4 + 9.5864e+237*s^8*ws^3 + 2.2626e+244*s^8*ws^2 + 3.8015e+246*s^8*ws + 1.2478e+255*s^8 - 7.7621e+213*s^7*ws^8 + 4.8387e+218*s^7*ws^7 - 5.7637e+222*s^7*ws^6 + 3.5915e+230*s^7*ws^5 + 4.2122e+236*s^7*ws^4 + 2.7369e+241*s^7*ws^3 + 1.4076e+248*s^7*ws^2 + 2.6339e+249*s^7*ws + 2.0572e+257*s^7 - 5.2168e+209*s^6*ws^10 + 1.0103e+214*s^6*ws^9 - 3.5371e+220*s^6*ws^8 + 2.2567e+226*s^6*ws^7 + 3.4001e+232*s^6*ws^6 + 9.5471e+237*s^6*ws^5 + 6.907e+241*s^6*ws^4 + 9.913e+246*s^6*ws^3 + 3.7354e+255*s^6*ws^2 + 8.413e+254*s^6*ws + 2.891e+263*s^6 - 3.0095e+213*s^5*ws^10 + 1.2146e+218*s^5*ws^9 + 1.3223e+224*s^5*ws^8 + 1.7168e+230*s^5*ws^7 - 1.3395e+236*s^5*ws^6 + 2.6851e+241*s^5*ws^5 + 1.3718e+248*s^5*ws^4 + 2.9996e+249*s^5*ws^3 + 3.9942e+257*s^5*ws^2 + 2.5473e+257*s^5*ws + 4.5819e+265*s^5 - 1.0434e+209*s^4*ws^12 + 8.4668e+211*s^4*ws^11 - 6.9202e+220*s^4*ws^10 + 3.2845e+225*s^4*ws^9 + 6.818e+232*s^4*ws^8 + 3.146e+237*s^4*ws^7 - 2.2528e+244*s^4*ws^6 + 9.4169e+246*s^4*ws^5 + 3.7335e+255*s^4*ws^4 + 8.9376e+254*s^4*ws^3 + 2.891e+263*s^4*ws^2 + 4.474e+262*s^4*ws + 1.7485e+271*s^4 - 4.276e+212*s^3*ws^12 + 3.47e+215*s^3*ws^11 + 1.3494e+224*s^3*ws^10 + 2.6238e+229*s^3*ws^9 - 1.3454e+236*s^3*ws^8 + 8.7872e+240*s^3*ws^7 + 4.4564e+247*s^3*ws^6 + 1.2063e+249*s^3*ws^5 + 1.9823e+257*s^3*ws^4 + 2.6028e+256*s^3*ws^3 + 9.8906e+262*s^3*ws^2 + 8.3904e+264*s^3*ws + 2.7391e+273*s^3 - 3.4492e+220*s^2*ws^12 + 2.799e+223*s^2*ws^11 + 3.4125e+232*s^2*ws^10 - 1.8193e+235*s^2*ws^9 - 1.1279e+244*s^2*ws^8 + 3.3039e+246*s^2*ws^7 + 1.245e+255*s^2*ws^6 + 2.9442e+254*s^2*ws^5 + 9.7024e+262*s^2*ws^4 + 7.8861e+261*s^2*ws^3 + 2.5095e+270*s^2*ws^2 + 4.8895e+269*s^2*ws + 1.9905e+278*s^2 - 3.3148e+220*s*ws^12 + 2.6899e+223*s*ws^11 + 1.0516e+232*s*ws^10 + 2.0331e+237*s*ws^9 - 1.0373e+244*s*ws^8 + 6.8464e+248*s*ws^7 + 3.4325e+255*s*ws^6 - 6.7804e+256*s*ws^5 + 1.4597e+265*s*ws^4 - 4.3488e+264*s*ws^3 - 2.3319e+273*s*ws^2 + 7.6327e+271*s*ws + 3.1084e+280*s - 2.6732e+228*ws^12 + 2.1693e+231*ws^11 + 2.6488e+240*ws^10 - 1.4429e+243*ws^9 - 8.767e+251*ws^8 + 2.4141e+254*ws^7 + 9.6974e+262*ws^6 - 3.6803e+262*ws^5 - 1.497e+271*ws^4 + 4.8818e+269*ws^3 + 1.9883e+278*ws^2 + 2.9811e+273*ws + 1.2142e+282))/((1.9723e+81*ws^6 + 1.6586e+70*ws^5 - 1.3024e+93*ws^4 + 1.9498e+95*ws^3 + 2.1636e+104*ws^2 + 7.694e+89*ws - 3.024e+112)*(1.8535e+158*s^15 + 2.3223e+162*s^14 + 9.2675e+158*s^13*ws^2 + 1.8385e+170*s^13 + 1.0063e+163*s^12*ws^2 + 1.5501e+174*s^12 + 1.8535e+159*s^11*ws^4 + 5.5157e+170*s^11*ws^2 - 4.8956e+152*s^11*ws + 6.0797e+181*s^11 + 1.703e+163*s^10*ws^4 + 4.6214e+174*s^10*ws^2 - 8.0497e+160*s^10*ws + 2.6358e+185*s^10 + 1.8535e+159*s^9*ws^6 + 6.1289e+170*s^9*ws^4 - 9.7911e+152*s^9*ws^3 + 1.418e+182*s^9*ws^2 - 5.0127e+164*s^9*ws + 6.7076e+192*s^9 + 1.3934e+163*s^8*ws^6 + 4.607e+174*s^8*ws^4 - 4.0254e+160*s^8*ws^3 + 7.7101e+185*s^8*ws^2 - 2.0666e+183*s^8*ws + 1.6298e+195*s^8 + 9.2675e+158*s^7*ws^8 + 3.6774e+170*s^7*ws^6 + 6.0799e+181*s^7*ws^4 - 1.1547e+165*s^7*ws^3 + 2.0084e+193*s^7*ws^2 - 7.7771e+185*s^7*ws + 1.5541e+201*s^7 + 5.4188e+162*s^6*ws^8 + 1.5552e+174*s^6*ws^6 + 2.0123e+161*s^6*ws^5 + 7.4863e+185*s^6*ws^4 - 5.9779e+183*s^6*ws^3 + 3.717e+195*s^6*ws^2 - 3.6532e+193*s^6*ws + 3.677e+203*s^6 + 1.8535e+158*s^5*ws^10 + 1.8385e+170*s^5*ws^8 + 9.7911e+152*s^5*ws^7 - 6.07e+181*s^5*ws^6 - 8.0586e+164*s^5*ws^5 + 2.0074e+193*s^5*ws^4 - 1.0659e+186*s^5*ws^3 + 1.5545e+201*s^5*ws^2 - 5.7145e+195*s^5*ws + 9.4011e+208*s^5 + 7.7411e+161*s^4*ws^10 + 2.43e+172*s^4*ws^8 + 2.0124e+161*s^4*ws^7 + 2.3803e+185*s^4*ws^6 - 5.7559e+183*s^4*ws^5 + 2.6341e+195*s^4*ws^4 - 3.6377e+193*s^4*ws^3 + 1.22e+203*s^4*ws^2 - 5.3887e+200*s^4*ws + 2.2066e+211*s^4 + 6.1275e+169*s^3*ws^10 + 4.8956e+152*s^3*ws^9 - 4.0486e+181*s^3*ws^8 - 1.5239e+164*s^3*ws^7 + 6.6943e+192*s^3*ws^6 + 1.6657e+185*s^3*ws^5 + 5.2167e+200*s^3*ws^4 + 1.0076e+193*s^3*ws^3 + 1.3493e+208*s^3*ws^2 - 8.4161e+202*s^3*ws + 1.0712e+216*s^3 + 4.8461e+171*s^2*ws^10 + 4.0248e+160*s^2*ws^9 - 3.1534e+183*s^2*ws^8 - 1.8447e+183*s^2*ws^7 + 5.4181e+194*s^2*ws^6 + 3.6831e+193*s^2*ws^5 + 1.1917e+203*s^2*ws^4 - 1.0772e+201*s^2*ws^3 - 1.148e+211*s^2*ws^2 - 3.2874e+204*s^2*ws + 2.5068e+218*s^2 + 4.7489e+177*s*ws^10 + 3.795e+160*s*ws^9 - 3.1449e+189*s*ws^8 + 4.548e+185*s*ws^7 + 5.2104e+200*s*ws^6 + 5.7246e+195*s*ws^5 - 8.046e+208*s*ws^4 - 8.4161e+202*s*ws^3 + 1.0678e+216*s*ws^2 - 4.9815e+197*s*ws + 1.9579e+220*s + 3.7101e+179*ws^10 + 3.12e+168*ws^9 - 2.45e+191*ws^8 + 3.6677e+193*ws^7 + 4.0703e+202*ws^6 - 5.3837e+200*ws^5 - 6.2858e+210*ws^4 - 3.2874e+204*ws^3 + 8.3493e+217*ws^2 - 1.2972e+199*ws + 5.0985e+221));

G = matlabFunction(G_vd);

G(0,1) % s= 0, w =1

ans = NaN

wV = 0.6:0.05:1.6; % define w values you want

sV = logspace(0,5,1e2)*1i;% define desired frequency

[WW,SS] = meshgrid(wV,sV);

sysV = G(SS,WW); % evaluate your transfer function in desired sV and wV

% plot

surf(WW,abs(SS),abs(sysV))

xlabel('W')

ylabel('Freq')

zlabel('Magnitude')

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Nitheesh R am 21 Mär. 2024

In MATLAB Online öffnen

I'm not sure why you are getting real values. I'm enclosing the main body of code for your reference from where I'm deriving transfer function and plotting bode.

clc;
clear all;
s=tf('s');
fs=100e3;
ws=2*pi*fs;
V_in=80;
fi=(pi*11.2)/180;
D=fi/pi;
L_r=24.4e-6;
C_r=1.24e-7;
R_l=426.66;
R_r=0.1;
n=5.5;
C_o=30e-6;
L_i=107.5e-6;
C_i=30e-6;
A=[-(R_r/L_r) 0 0 0 ((4*sin(D*pi))/(pi*n*L_r)) ((4*cos(D*pi))/(pi*n*L_r)) -(1/L_r) 0 0 0 0 0 0 0 -(4/(pi*L_r));
   0 -(R_r/L_r) ws ((2*sin(D*pi))/(pi*n*L_r)) 0 0 0 -(1/L_r) 0 0 0 0 0 0 0;
   0 -ws -(R_r/L_r) ((2*cos(D*pi))/(pi*n*L_r)) 0 0 0 0 -(1/L_r) 0 0 0 -(2/(pi*L_r)) 0 0;
   0 -((4*sin(D*pi))/(pi*n*C_o)) -((4*cos(D*pi))/(pi*n*C_o)) -(1/(R_l*C_o)) 0 0 0 0 0 0 0 0 0 0 0;
   -((2*sin(D*pi))/(pi*n*C_o)) 0 0 0 -(1/(R_l*C_o)) ws 0 0 0 0 0 0 0 0 0;
   -((2*cos(D*pi))/(pi*n*C_o)) 0 0 0 -ws -(1/(R_l*C_o)) 0 0 0 0 0 0 0 0 0;
   (1/C_r) 0 0 0 0 0 0 0 0 0 0 0 0 0 0;
   0 (1/C_r) 0 0 0 0 0 0 ws 0 0 0 0 0 0;
   0 0 (1/C_r) 0 0 0 0 -ws 0 0 0 0 0 0 0;
   0 0 0 0 0 0 0 0 0 0 0 0 -(1/(2*L_i)) 0 -(2/(pi*L_i));
   0 0 0 0 0 0 0 0 0 0 0 ws 0 -(1/(2*L_i)) 0;
   0 0 0 0 0 0 0 0 0 0 -ws 0 (1/(pi*L_i)) 0 -(1/(2*L_i));
   -(1/(C_i)) 0 0 0 0 0 0 0 0 (1/(2*C_i)) 0 -(2/(pi*C_i)) 0 0 0;
   0 -(1/(C_i)) 0 0 0 0 0 0 0 0 (1/(2*C_i)) 0 0 0 ws;
   0 0 -(1/(C_i)) 0 0 0 0 0 0 -(1/(pi*C_i)) 0 (1/(2*C_i)) 0 -ws 0];
b=[0; 0; 0; 0; 0; 0; 0; 0; 0; (1/(L_i)); 0; 0; 0; 0; 0];
X=(-inv (A))*b*V_in;
Ir_0=X(1,1);
Ir_1R=X(2,1);
Ir_1I=X(3,1);
Vo_0=X(4,1);
Vo_1R=X(5,1);
Vo_1I=X(6,1);
f=[(((4*Vo_1R*cos(D*pi))/(n*L_r))-((4*Vo_1I*sin(D*pi))/(n*L_r)));((2*Vo_0*cos(D*pi))/(n*L_r));-((2*Vo_0*sin(D*pi))/(n*L_r));(((4*Ir_1I*sin(D*pi))/(n*C_o))-((4*Ir_1R*cos(D*pi))/(n*C_o)));-((2*Ir_0*cos(D*pi))/(n*C_o));((2*Ir_0*sin(D*pi))/(n*C_o));0;0;0;0;0;0;0;0;0];
q=[0 0 0 1 0 0 0 0 0 0 0 0 0 0 0];
I=[1 0 0 0 0 0 0 0 0 0 0 0 0 0 0;
   0 1 0 0 0 0 0 0 0 0 0 0 0 0 0;
   0 0 1 0 0 0 0 0 0 0 0 0 0 0 0;
   0 0 0 1 0 0 0 0 0 0 0 0 0 0 0;
   0 0 0 0 1 0 0 0 0 0 0 0 0 0 0;
   0 0 0 0 0 1 0 0 0 0 0 0 0 0 0;
   0 0 0 0 0 0 1 0 0 0 0 0 0 0 0;
   0 0 0 0 0 0 0 1 0 0 0 0 0 0 0;
   0 0 0 0 0 0 0 0 1 0 0 0 0 0 0;
   0 0 0 0 0 0 0 0 0 1 0 0 0 0 0;
   0 0 0 0 0 0 0 0 0 0 1 0 0 0 0;
   0 0 0 0 0 0 0 0 0 0 0 1 0 0 0;
   0 0 0 0 0 0 0 0 0 0 0 0 1 0 0;
   0 0 0 0 0 0 0 0 0 0 0 0 0 1 0;
   0 0 0 0 0 0 0 0 0 0 0 0 0 0 1];
G_vd=q*(inv((s*I)-A))*f;
bode(G_vd)

Aquatris am 26 Mär. 2024

I was getting real values with my example because I was taking the magnitude of the calculated values via the abs() function, which is plotted in the magnitude plot when you call the bode command. The phase, which can be found by the angle() command, is the 2nd plot you get with bode() function.

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How to plot 3-D bode from the derived transfer function?

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How to plot 3-D bode from the derived transfer function?

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