Tellegen's theorem

Last updated October 28, 2023

Tellegen's theorem is one of the most powerful theorems in network theory. Most of the energy distribution theorems and extremum principles in network theory can be derived from it. It was published in 1952 by Bernard Tellegen.^[1] Fundamentally, Tellegen's theorem gives a simple relation between magnitudes that satisfy Kirchhoff's laws of electrical circuit theory.

The Tellegen theorem is applicable to a multitude of network systems. The basic assumptions for the systems are the conservation of flow of extensive quantities (Kirchhoff's current law, KCL) and the uniqueness of the potentials at the network nodes (Kirchhoff's voltage law, KVL). The Tellegen theorem provides a useful tool to analyze complex network systems including electrical circuits, biological and metabolic networks, pipeline transport networks, and chemical process networks.

The theorem

Consider an arbitrary lumped network that has $b$ branches and $n$ nodes. In an electrical network, the branches are two-terminal components and the nodes are points of interconnection. Suppose that to each branch we assign arbitrarily a branch potential difference $W_{k}$ and a branch current $F_{k}$ for $k=1,2,\dots ,b$ , and suppose that they are measured with respect to arbitrarily picked associated reference directions. If the branch potential differences $W_{1},W_{2},\dots ,W_{b}$ satisfy all the constraints imposed by KVL and if the branch currents $F_{1},F_{2},\dots ,F_{b}$ satisfy all the constraints imposed by KCL, then

\sum _{k=1}^{b}W_{k}F_{k}=0.

Tellegen's theorem is extremely general; it is valid for any lumped network that contains any elements, linear or nonlinear , passive or active, time-varying or time-invariant. The generality is extended when $W_{k}$ and $F_{k}$ are linear operations on the set of potential differences and on the set of branch currents (respectively) since linear operations don't affect KVL and KCL. For instance, the linear operation may be the average or the Laplace transform. More generally, operators that preserve KVL are called Kirchhoff voltage operators, operators that preserve KCL are called Kirchhoff current operators, and operators that preserve both are simply called Kirchhoff operators. These operators need not necessarily be linear for Tellegen's theorem to hold.^[2]

The set of currents can also be sampled at a different time from the set of potential differences since KVL and KCL are true at all instants of time. Another extension is when the set of potential differences $W_{k}$ is from one network and the set of currents $F_{k}$ is from an entirely different network, so long as the two networks have the same topology (same incidence matrix) Tellegen's theorem remains true. This extension of Tellegen's Theorem leads to many theorems relating to two-port networks.^[3]

Definitions

We need to introduce a few necessary network definitions to provide a compact proof.

Incidence matrix: The $n\times b$ matrix $\mathbf {A_{a}}$ is called node-to-branch incidence matrix for the matrix elements $a_{ij}$ being

a_{ij}={\begin{cases}1,&{\text{if current in branch }}j{\text{ leaves node }}i\\-1,&{\text{if current in branch }}j{\text{ enters node }}i\\0,&{\text{otherwise}}\end{cases}}

A reference or datum node $P_{0}$ is introduced to represent the environment and connected to all dynamic nodes and terminals. The $(n-1)\times b$ matrix $\mathbf {A}$ , where the row that contains the elements $a_{0j}$ of the reference node $P_{0}$ is eliminated, is called reduced incidence matrix.

The conservation laws (KCL) in vector-matrix form:

\mathbf {A} \mathbf {F} =\mathbf {0}

The uniqueness condition for the potentials (KVL) in vector-matrix form:

\mathbf {W} =\mathbf {A^{T}} \mathbf {w}

where $w_{k}$ are the absolute potentials at the nodes to the reference node $P_{0}$ .

Proof

Using KVL:

{\begin{aligned}\mathbf {W^{T}} \mathbf {F} =\mathbf {(A^{T}w)^{T}} \mathbf {F} =\mathbf {(w^{T}A)} \mathbf {F} =\mathbf {w^{T}AF} =\mathbf {0} \end{aligned}}

because $\mathbf {AF} =\mathbf {0}$ by KCL. So:

\sum _{k=1}^{b}W_{k}F_{k}=\mathbf {W^{T}} \mathbf {F} =0

Applications

Network analogs have been constructed for a wide variety of physical systems, and have proven extremely useful in analyzing their dynamic behavior. The classical application area for network theory and Tellegen's theorem is electrical circuit theory. It is mainly in use to design filters in signal processing applications.

A more recent application of Tellegen's theorem is in the area of chemical and biological processes. The assumptions for electrical circuits (Kirchhoff laws) are generalized for dynamic systems obeying the laws of irreversible thermodynamics. Topology and structure of reaction networks (reaction mechanisms, metabolic networks) can be analyzed using the Tellegen theorem.

Another application of Tellegen's theorem is to determine stability and optimality of complex process systems such as chemical plants or oil production systems. The Tellegen theorem can be formulated for process systems using process nodes, terminals, flow connections and allowing sinks and sources for production or destruction of extensive quantities.

A formulation for Tellegen's theorem of process systems:

\sum _{j=1}^{n_{P}}W_{j}{\frac {\operatorname {d} Z_{j}}{\operatorname {d} t}}=\sum _{k=1}^{b}W_{k}f_{k}+\sum _{j=1}^{n_{P}}w_{j}p_{j}+\sum _{j=1}^{n_{t}}w_{j}t_{j},\quad j=1,\dots ,n_{p}+n_{t}

where $p_{j}$ are the production terms, $t_{j}$ are the terminal connections, and ${\frac {\operatorname {d} Z_{j}}{\operatorname {d} t}}$ are the dynamic storage terms for the extensive variables.

Related Research Articles

In mathematics, and more specifically in linear algebra, a linear map is a mapping $between two vector spaces that preserves the operations of vector addition and scalar multiplication. The same names and the same definition are also used for the more general case of modules over a ring; see Module homomorphism.$

In mathematics, a symmetric matrix $with real entries is positive-definite if the real number is positive for every nonzero real column vector where is the transpose of . More generally, a Hermitian matrix is positive-definite if the real number is positive for every nonzero complex column vector where denotes the conjugate transpose of$

In linear algebra, the trace of a square matrix $A$ , denoted $tr(A)$ , is defined to be the sum of elements on the main diagonal of $A$ . The trace is only defined for a square matrix.

<span class="mw-page-title-main">Rank–nullity theorem</span> In linear algebra, relation between 3 dimensions

The rank–nullity theorem is a theorem in linear algebra, which asserts:

In linear algebra, a Hankel matrix, named after Hermann Hankel, is a square matrix in which each ascending skew-diagonal from left to right is constant, e.g.:

In mathematics, the Heisenberg group $, named after Werner Heisenberg, is the group of 3\times3 upper triangular matrices of the form$

Kirchhoff's circuit laws are two equalities that deal with the current and potential difference in the lumped element model of electrical circuits. They were first described in 1845 by German physicist Gustav Kirchhoff. This generalized the work of Georg Ohm and preceded the work of James Clerk Maxwell. Widely used in electrical engineering, they are also called Kirchhoff's rules or simply Kirchhoff's laws. These laws can be applied in time and frequency domains and form the basis for network analysis.

In electrical engineering and electronics, a network is a collection of interconnected components. Network analysis is the process of finding the voltages across, and the currents through, all network components. There are many techniques for calculating these values; however, for the most part, the techniques assume linear components. Except where stated, the methods described in this article are applicable only to linear network analysis.

A magnetic circuit is made up of one or more closed loop paths containing a magnetic flux. The flux is usually generated by permanent magnets or electromagnets and confined to the path by magnetic cores consisting of ferromagnetic materials like iron, although there may be air gaps or other materials in the path. Magnetic circuits are employed to efficiently channel magnetic fields in many devices such as electric motors, generators, transformers, relays, lifting electromagnets, SQUIDs, galvanometers, and magnetic recording heads.

In the mathematical field of graph theory, Kirchhoff's theorem or Kirchhoff's matrix tree theorem named after Gustav Kirchhoff is a theorem about the number of spanning trees in a graph, showing that this number can be computed in polynomial time from the determinant of a submatrix of the Laplacian matrix of the graph; specifically, the number is equal to any cofactor of the Laplacian matrix. Kirchhoff's theorem is a generalization of Cayley's formula which provides the number of spanning trees in a complete graph.

In mathematics, the discrete Laplace operator is an analog of the continuous Laplace operator, defined so that it has meaning on a graph or a discrete grid. For the case of a finite-dimensional graph, the discrete Laplace operator is more commonly called the Laplacian matrix.

<span class="mw-page-title-main">Nodal analysis</span> Method in electric circuits analysis

In electric circuits analysis, nodal analysis, node-voltage analysis, or the branch current method is a method of determining the voltage between "nodes" in an electrical circuit in terms of the branch currents.

In classical electromagnetism, reciprocity refers to a variety of related theorems involving the interchange of time-harmonic electric current densities (sources) and the resulting electromagnetic fields in Maxwell's equations for time-invariant linear media under certain constraints. Reciprocity is closely related to the concept of symmetric operators from linear algebra, applied to electromagnetism.

In queueing theory, a discipline within the mathematical theory of probability, a Jackson network is a class of queueing network where the equilibrium distribution is particularly simple to compute as the network has a product-form solution. It was the first significant development in the theory of networks of queues, and generalising and applying the ideas of the theorem to search for similar product-form solutions in other networks has been the subject of much research, including ideas used in the development of the Internet. The networks were first identified by James R. Jackson and his paper was re-printed in the journal Management Science’s ‘Ten Most Influential Titles of Management Sciences First Fifty Years.’

Mason's gain formula (MGF) is a method for finding the transfer function of a linear signal-flow graph (SFG). The formula was derived by Samuel Jefferson Mason, whom it is also named after. MGF is an alternate method to finding the transfer function algebraically by labeling each signal, writing down the equation for how that signal depends on other signals, and then solving the multiple equations for the output signal in terms of the input signal. MGF provides a step by step method to obtain the transfer function from a SFG. Often, MGF can be determined by inspection of the SFG. The method can easily handle SFGs with many variables and loops including loops with inner loops. MGF comes up often in the context of control systems, microwave circuits and digital filters because these are often represented by SFGs.

The circuit topology of an electronic circuit is the form taken by the network of interconnections of the circuit components. Different specific values or ratings of the components are regarded as being the same topology. Topology is not concerned with the physical layout of components in a circuit, nor with their positions on a circuit diagram; similarly to the mathematical concept of topology, it is only concerned with what connections exist between the components. There may be numerous physical layouts and circuit diagrams that all amount to the same topology.

In mathematics, there are many kinds of inequalities involving matrices and linear operators on Hilbert spaces. This article covers some important operator inequalities connected with traces of matrices.

Symmetries in quantum mechanics describe features of spacetime and particles which are unchanged under some transformation, in the context of quantum mechanics, relativistic quantum mechanics and quantum field theory, and with applications in the mathematical formulation of the standard model and condensed matter physics. In general, symmetry in physics, invariance, and conservation laws, are fundamentally important constraints for formulating physical theories and models. In practice, they are powerful methods for solving problems and predicting what can happen. While conservation laws do not always give the answer to the problem directly, they form the correct constraints and the first steps to solving a multitude of problems.

Reciprocity in electrical networks is a property of a circuit that relates voltages and currents at two points. The reciprocity theorem states that the current at one point in a circuit due to a voltage at a second point is the same as the current at the second point due to the same voltage at the first. The reciprocity theorem is valid for almost all passive networks. The reciprocity theorem is a feature of a more general principle of reciprocity in electromagnetism.

A graph neural network (GNN) is a class of artificial neural networks for processing data that can be represented as graphs.

References

In-line references

↑ Tellegen, B. D. H. (1952). "A general network theorem with applications". Philips Research Reports. 7: 259–269.
↑ Penfield, P. (1970). "A Generalized Form of Tellegen's Theorem" (PDF). IEEE Transactions on Circuit Theory. CT-17: 302–305. Retrieved November 8, 2016.
↑ Tellegen's Theorem and Electrical Networks by Paul Penfield, Jr., Robert Spence, and Simon Duinker, The MIT Press, Cambridge, MA, 1970

General references

Basic Circuit Theory by C.A. Desoer and E.S. Kuh, McGraw-Hill, New York, 1969
"Tellegen's Theorem and Thermodynamic Inequalities", G.F. Oster and C.A. Desoer, J. Theor. Biol 32 (1971), 219–241
"Network Methods in Models of Production", Donald Watson, Networks, 10 (1980), 1–15

External links

Circuit example for Tellegen's theorem
G.F. Oster and C.A. Desoer, Tellegen's Theorem and Thermodynamic Inequalities
Network thermodynamics

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Tellegen-1] Tellegen, B. D. H. (1952). "A general network theorem with applications". Philips Research Reports. 7: 259–269.

[Penfield-2] Penfield, P. (1970). "A Generalized Form of Tellegen's Theorem" (PDF). IEEE Transactions on Circuit Theory. CT-17: 302–305. Retrieved November 8, 2016.

[3] Tellegen's Theorem and Electrical Networks by Paul Penfield, Jr., Robert Spence, and Simon Duinker, The MIT Press, Cambridge, MA, 1970

[1]

[2]

[3]