Any even order nonlinearity produce DC components.From the simulation, I can get HB.I_Probe1.i[2] to be close to the theoretical prediction but the DC term is very different.
Any even order nonlinearity produce DC components.
I can not understand what you want to mean at all.The problem I am facing is that the magnitude of this extra DC current (due to 2nd order nonlinearity) is different from the theoretically predicted value.
HB.I_Probe1.i[0] is a result from all even order nonlinearity.
You consider only static I-V characteristics as nonlinearity.
Capacitor also behave nonlinearly
I mean capacitor in diode.I did not get your point. I am using either ideal DC blocks or ideal capacitors from ADS.
I mean capacitor in diode.
I can not understand what you want mean at all.Also, I am assuming that HB.I_Probe1.i[0] includes the static DC as well as the current due to nonlinearities.
I can not understand what you want mean at all.**That is why I subtract DC.I_Probe1.i from it to calculate the current due to nonlinearity of the circuit.**
No.Does it make sense to you now?
Increase HB order.
Or try transient analysis.
Not right.There will be a static DC current due to the dc source Vb too, right?
Did you surely increase order such as 15 or 31 ?I did increase the HB order but that does not help.
Not right.
It is not static DC current, if input power is large.
Did you surely incease order such as 15 or 31 ?
Try transient analysis.
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