We investigate the electrical current and flow (number of parallel paths) between two sets of n sources and n sinks in complex networks. We derive analytical formulas for the average current and flow as a function of n. We show that for small n, increasing n improves the total transport in the network, while for large n bottlenecks begin to form. For the case of flow, this leads to an optimal n* above which the transport is less efficient. For current, the typical decrease in the length of the connecting paths for large n compensates for the effect of the bottlenecks. We also derive an expression for the average flow as a function of n under the common limitation that transport takes place between specific pairs of sources and sinks
In their paper [Doulliez, P. J., M. R. Rao. 1971. Maximal flow in a multi-terminal network with any ...
Consider a network G = (V, E), where V denotes the set of vertices in G, and E denotes the set of ed...
Abstract We derive an analytical expression for the mean load at each node of an arbitrary undirecte...
We study the transport properties of model networks such as scale-free and Erdös-Rényi networks as w...
Designing and optimizing different flows in networks is a relevant problem in many contexts. While a...
M.Sc. (Mathematics)In Chapter 1, we consider the relevant theory pertaining to graphs and digraphs t...
For an integer h ≥ 1, an elementary h-route flow is a flow along h edge disjoint paths between a sou...
Optimizing passengers routes is crucial to design efficient transportation networks. Recent results ...
If we have a set of sources $S$ with total capacity $C$ and a set of sinks $T$ with the same capacit...
Many real-world systems such as traffic and electrical flow are described as flows following paths o...
Whether it be the passengers’ mobility demand in transportation systems, or the consumers’ energy de...
The properties found in complex networks (e.g., small-world, scale-free) have been used to character...
Includes bibliographical references (pages 52)The study of networks and flows is an area of linear p...
In network design, the gap between theory and practice is woefully broad. This book narrows it, comp...
The problem of sending the maximum amount of flow q between two arbitrary nodes s and t of complex n...
In their paper [Doulliez, P. J., M. R. Rao. 1971. Maximal flow in a multi-terminal network with any ...
Consider a network G = (V, E), where V denotes the set of vertices in G, and E denotes the set of ed...
Abstract We derive an analytical expression for the mean load at each node of an arbitrary undirecte...
We study the transport properties of model networks such as scale-free and Erdös-Rényi networks as w...
Designing and optimizing different flows in networks is a relevant problem in many contexts. While a...
M.Sc. (Mathematics)In Chapter 1, we consider the relevant theory pertaining to graphs and digraphs t...
For an integer h ≥ 1, an elementary h-route flow is a flow along h edge disjoint paths between a sou...
Optimizing passengers routes is crucial to design efficient transportation networks. Recent results ...
If we have a set of sources $S$ with total capacity $C$ and a set of sinks $T$ with the same capacit...
Many real-world systems such as traffic and electrical flow are described as flows following paths o...
Whether it be the passengers’ mobility demand in transportation systems, or the consumers’ energy de...
The properties found in complex networks (e.g., small-world, scale-free) have been used to character...
Includes bibliographical references (pages 52)The study of networks and flows is an area of linear p...
In network design, the gap between theory and practice is woefully broad. This book narrows it, comp...
The problem of sending the maximum amount of flow q between two arbitrary nodes s and t of complex n...
In their paper [Doulliez, P. J., M. R. Rao. 1971. Maximal flow in a multi-terminal network with any ...
Consider a network G = (V, E), where V denotes the set of vertices in G, and E denotes the set of ed...
Abstract We derive an analytical expression for the mean load at each node of an arbitrary undirecte...