Dear 'RFSimulator' and 'Kit-the-great',
thks a lot for your reply.
Just now I tried to restore the normalization process. In CST, the time-domain and freuqncy domain voltage and current are recorded, i.e. Vol(time), Cur(time), Vol(frequency),Cur(frequency).
Applying DFT operation to time-domain data, we can get Vol(DFT), Cur(DFT). Then 'Vol(DFT)/Vol(frequency)' and 'Cur(DFT)/Cur(frequency)' should be the original frequency-domain reference signals.
I noticed that both the reference signals are idential gaussian pulse. In other words, the frequency-domain input voltage and current are same. so the excitation of discrete port is current source, and the interal impedance actually is only a resistance, is it?
if anything wrong with my 'ratiocination', pls correct me, thks in advance. :roll:
for the recording of electric or magnetic energy, still trying, will let you know if i can find something. :lol:
regards,
tenderne
Added after 2 hours 53 minutes:
Hi, 'RFSimulator'
I tried the 0D template you mentioned, I select
'Results' -> 'Template Based Postprocessing' -> '0D Results' -> 'Evaluate Field in arbitrary Coordinated' -> '3D', 'max range', 'integral-3D'
However, only a maximum 3D energy value at a specified location is output. seems not right, i want the total electric or magnetic energy varied with time.
anyway, i will keep trying... :|