The distributed parameters line (DPL) theory is used to represent a half of the classic constant parameter (CP) model [1]. Overall, the CP model assumes that the line parameters R, L and C are independent of the frequency effects caused by the skin effect on phase conductors and on the ground. The model considers L and C to be distributed (ideal line) and R to be lumped at three places (R/4 on both ends and R/2 in the middle). The shunt conductance G is taken as zero.
Two half CP components must be connected through transceiver elements (or real-time simulator I/Os) to represent a transmission line. Line parameters must be the same in both components. The implementation of the half CP follows the same formulation from the standard CP line [1]. However, note that with the half CP component, the propagation delay of the line is the sum of what is accounted in a buffer inside the component and what is caused by the actual delay outside the components. The latter is referred as "extra delay" in the form of the model. For the digital simulation of the model on one simulator, the actual delay is caused by the transceiver. For the simulation on 2 simulators, the actual delay includes the delay in I/O drivers.
For the three-phase version of this half CP model, please see half CP, 3-ph.
Mask and Parameters
Parameters
Name | Description | Unit | Variable = {Possible Values} | |||
---|---|---|---|---|---|---|
Description | Use this field to add information about the component | Description = {'string'} | ||||
Length | The length of the line | m | length = {'1e-12, 1e12'} | |||
R' | Per unit length resistance | Ω/km | Resistance = {'0, 1e12'} | |||
L' | Per unit length inductance | H/km | Inductance = {'1e-12 1e12'} | |||
C' | Per unit length capacitance | F/km | Capacitance = {'1e-12, 1e12'} | |||
Extra delay | The extra delay variable is an integer that refers to the number of delays produced outside the half CP components. For the digital simulation of the model on one simulator, the extra delay is caused by the transceiver. For the simulation on two simulators, the extra delay includes the delay in IO drive. | extradelaynb = { [0, 200] } |
Ports, Inputs, Outputs and Signals Available for Monitoring
Ports
This component supports a single-phase transmission line
Name | Description |
---|---|
net | Power network connection of one side of the line |
Inputs
Name | Description |
---|---|
hi | Historic current FROM the other side of the line |
Outputs
Name | Description |
---|---|
ho | Historic current TO the other side of the line |
Vt | Terminal voltage in V |
Sensors
None
Theoretical Background
Single-phase model
The half CP parameters are calculated at a given frequency; thus, it is considered as a frequency independent line model. This model is less accurate than frequency-dependent line and cable models. However, it can be successfully used to analyze cases with limited frequency dispersion.
The half CP model is based on the formulation of the classic CP line model, which neglects the frequency dependence of parameters and first assumes a lossless line. The losses are included at a later stage. The following figure shows the equivalent circuit representation of the EMT-type transmission line model.
The lossless single-phase transmission line is described by the following main equations:
where and are history currents defined as:
where, and are the nodal voltages; and are the injected current at both ends of the line; is the characteristic impedance and is the propagation time delay, respectively defined as:
where is the length of the line, and and are the inductance and capacitance per unit length of the line, respectively.
Note that the time-domain model described above creates a decoupling effect on the interconnected network. It is mentioned that the equation system provides an exact solution only when the propagation time is an integer multiple of the simulation time step , i.e., . Therefore, a linear interpolation is used when .
Inclusion of losses
To include the losses , the line is divided into two equal lossless models of halved propagation time. Then, the total is lumped at three places (line ends and line middle ) as shown in the following figure.
The resulted lossy line equivalent model to be implemented is given by:
where
History current buffer
The half CP line is used to represent one Norton equivalent circuit of the lossy equivalent line. Therefore, two half CP model must be linked to each other to represent a transmission line. Both half CP components must be set with the same line parameters and connected through transceiver components. This connection is used to interchange the history current information between both ends of the line. That is,
Then, the output history current from the end becomes the input history current of the end and vice versa. In the implementation of the model, a history buffer is kept and rotated for calculating the history current sources. The buffer length depends on the propagation delay and the simulation time step. The propagation delay must be greater to the integration time-step.
Note that the propagation delay of the line is the sum of what is accounted in the buffer and what is caused by the actual delay outside the components. The latter is referred as "extra delay", which must be indicated in the form of the model. For the digital simulation of the model on one simulator, the actual delay is caused by the transceiver. For the simulation on 2 simulators, the actual delay includes the delay in IO drive.
Example
Two half CP components must be connected through transceiver elements to represent a transmission line. Line parameters must be the same in both components. Next figures show how to build a transmission line using 1 and 3 transceivers.
References
"H. W. Dommel, "Digital computer solution of electromagnetic transients in single and multiphase networks," IEEE Trans. Power App. Syst., vol. pas-88, pp. 388-99, 04/ 1969."