(For Max) Change IPQ circuit_model in steam_models in order to get the signals relevant for SIGMON
SIGNALS that are relevant for SIGMON: Voltage across first Powerconverter --> Called V_MEAS in PostMortem Voltage across second Powerconverter --> Called V_MEAS in PostMortem Current through first Powerconverter --> Called I_MEAS in PostMortem Current through second Powerconverter --> Called I_MEAS in PostMortem Earthing Current --> Called I_EARTH_PCNT in PostMortem
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In a first step do the changes only for IPQ circuits and see if it works -
Include the necessary nodes for all other circuits in a next step
Including e.g. this syntax: R_EC (0mid 0) {1.0E+09} E_I_MEAS_B1 (0_I_MEAS_B1 0) VALUE {I(V_DCCT_1)} E_I_MEAS_B2 (0_I_MEAS_B2 0) VALUE {I(V_DCCT_2)} E_V_MEAS_B1 (0_V_MEAS_B1 0) VALUE {V(2,1)} E_V_MEAS_B2 (0_V_MEAS_B2 0) VALUE {V(0a,7)} E_I_EARTH (0_I_EARTH 0) VALUE {I(V_EC)}
this way, one can probe the signals as: .PROBE
- V(0_I_MEAS_B1)
- V(0_I_MEAS_B2)
- V(0_V_MEAS_B1)
- V(0_V_MEAS_B2)
- V(0_I_EARTH)
Note: V_DCCT_1 (0A 1) {0} is a voltage source between nodes 0A and 1 with a voltage of zero volts Having this voltage source in series with something we want to catch the current of, the component has no real effect, but one can get the current through the source, which is a good way to get the current through e.g. a resistor which is in series with this source
Same holds true for monitoring the current through the earthing circuit: V_EC (0A 0mid) {0} since this is connected in series to R_EC
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A good starting point is maybe to do it one by one and see if the circuit simulation still makes sense -
For more complicated circuits one may start modifying a random circuit file of that model, check if it works and if that is the case, translate it back to a yaml file using the parsepspice. Like this, the model should be easy to modify