PRIMITIVE NETWORKS
So far, the matrices of the interconnected network have been defined. These matrices contain complete information about the network connectivity, the orientation of current, the loops and cut sets. However, these matrices contain no information on the nature of the elements which form the interconnected network. The complete behaviour of the network can be obtained from the knowledge of the behaviour of the individual elements which make the network, along with the incidence matrices. An element in an electrical network is completely characterized by the relationship between the current through the element and the voltage across it.
General representation of a network element: In general, a network element may contain active or passive components. Figure 2 represents the alternative impedance and admittance forms of representation of a general network component.
The network performance can be represented by using either the impedance or the admittance form of representation. With respect to the element, p-q, let,
vpq = voltage across the element p-q,
epq = source voltage in series with the element pq, ipq= current through the element p-q,
jpq= source current in shunt with the element pq, zpq= self impedance of the element p-q and
ypq= self admittance of the element p-q.
Performance equation: Each element p-q has two variables, vpq and ipq. The performance of the given element p-q can be expressed by the performance equations as under:
vpq + epq = zpqipq (in its impedance form) ipq + jpq = ypqvpq (in its admittance form)
Thus the parallel source current jpq in admittance form can be related to the series source voltage, epq in impedance form as per the identity:
jpq = - ypq epq
A set of non-connected elements of a given system is defined as a primitive Network and an element in it is a fundamental element that is not connected to any other element. In the equations above, if the variables and parameters are replaced by the corresponding vectors and matrices, referring to the complete set of elements present in a given system, then, we get the performance equations of the primitive network in the form as under:
v + e = [z] i i + j = [y] v
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