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Impedance Simulation - Solution at angle (phase) setting
Posted 4 août 2016, 06:54 UTC−4 Low-Frequency Electromagnetics Version 5.2 2 Replies
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Hi,
I'm evaluationg the impedance of a 2D structure which is similar to a parallel capacitor. Between the two electrodes a material with a certain conductivity and permittivity is placed. One Electrode has a fixed potential of 1V and the other one has ground potential.
To evaluate the impedance a line integration with the expression ec.nJ is used. This leads to a negative imaginary part. The real part is also negative, which is certainly wrong (the structure is passive --> no negative resistance).
By searching for similar problems in this forum, the setting "Solution at angle (phase)" was mentioned. So if I compute the results for an angle of 180° instead of 0° I get the expected signs (+ for Re and + for Im) if I interprete the result by the admittance (Y = 1/R + j * omega * C).
By having a look at the 2D surface plot of the Electrical Potential the result is -1V to 0V across the geometry for 180°. So it looks like a cosine shifted by 180°, which leads to a negative cosine, is used as excitation source. But that would be the same as using a negative potential of -1 V. Which again leads to the wrong results ( Y = Re(ec.nJ)/V + Im(ec.nJ)/V ).
If a negative sine (+90°) is used I get a negative imaginary part and a positive real part. For a more complex structures without prior knowledge of the imaginary part (capacitive or inductive) it becomes tricky ;-).
Is there any recommendation wich phase angle should be used for impedance analyses?
BR
I'm evaluationg the impedance of a 2D structure which is similar to a parallel capacitor. Between the two electrodes a material with a certain conductivity and permittivity is placed. One Electrode has a fixed potential of 1V and the other one has ground potential.
To evaluate the impedance a line integration with the expression ec.nJ is used. This leads to a negative imaginary part. The real part is also negative, which is certainly wrong (the structure is passive --> no negative resistance).
By searching for similar problems in this forum, the setting "Solution at angle (phase)" was mentioned. So if I compute the results for an angle of 180° instead of 0° I get the expected signs (+ for Re and + for Im) if I interprete the result by the admittance (Y = 1/R + j * omega * C).
By having a look at the 2D surface plot of the Electrical Potential the result is -1V to 0V across the geometry for 180°. So it looks like a cosine shifted by 180°, which leads to a negative cosine, is used as excitation source. But that would be the same as using a negative potential of -1 V. Which again leads to the wrong results ( Y = Re(ec.nJ)/V + Im(ec.nJ)/V ).
If a negative sine (+90°) is used I get a negative imaginary part and a positive real part. For a more complex structures without prior knowledge of the imaginary part (capacitive or inductive) it becomes tricky ;-).
Is there any recommendation wich phase angle should be used for impedance analyses?
BR
2 Replies Last Post 31 août 2016, 03:41 UTC−4