AbstractIntuitively, Braess’s paradox states that destroying a part of a network may improve the common latency of selfish flows at Nash equilibrium. Such a paradox is a pervasive phenomenon in real-world networks. Any administrator who wants to improve equilibrium delays in selfish networks, is facing some basic questions:–Is the network paradox-ridden?–How can we delete some edges to optimize equilibrium flow delays?–How can we modify edge latencies to optimize equilibrium flow delays? Unfortunately, such questions lead to NP-hard problems in general. In this work, we impose some natural restrictions on our networks, e.g. we assume strictly increasing linear latencies. Our target is to formulate efficient algorithms for the three question...
Let M be a single s-t network of parallel links with load dependent latency functions shared by an i...
Dynamic flow networks can model traffic, optical networks, building evacuations, and more. In these ...
AbstractLet M be a single s–t network of parallel links with load dependent latency functions shared...
AbstractIntuitively, Braess’s paradox states that destroying a part of a network may improve the com...
AbstractWe consider a directed network in which every edge possesses a latency function that specifi...
We consider a directed network in which every edge pos-sesses a latency function specifying the time...
Braess’s paradox states that removing a part of a network may improve the players’ latency at equili...
Global communication networks like the Internet often lack a central authority that monitors and reg...
AbstractWe study the degradation in network performance caused by the selfish behavior of noncoopera...
It is well known that in a network with arbitrary (convex) latency functions that are a function of ...
Noncooperative network routing games are a natural model of users trying to selfishly route flow thr...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Sloan School of Management, Operations Resea...
In this work, we study the combinatorial structure and the computational complexity of Nash equilibr...
We study the problem of minimizing the maximum latency of flows in networks with congestion. We show...
It is well known that in a network with arbitrary (convex) latency functions that are a function of...
Let M be a single s-t network of parallel links with load dependent latency functions shared by an i...
Dynamic flow networks can model traffic, optical networks, building evacuations, and more. In these ...
AbstractLet M be a single s–t network of parallel links with load dependent latency functions shared...
AbstractIntuitively, Braess’s paradox states that destroying a part of a network may improve the com...
AbstractWe consider a directed network in which every edge possesses a latency function that specifi...
We consider a directed network in which every edge pos-sesses a latency function specifying the time...
Braess’s paradox states that removing a part of a network may improve the players’ latency at equili...
Global communication networks like the Internet often lack a central authority that monitors and reg...
AbstractWe study the degradation in network performance caused by the selfish behavior of noncoopera...
It is well known that in a network with arbitrary (convex) latency functions that are a function of ...
Noncooperative network routing games are a natural model of users trying to selfishly route flow thr...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Sloan School of Management, Operations Resea...
In this work, we study the combinatorial structure and the computational complexity of Nash equilibr...
We study the problem of minimizing the maximum latency of flows in networks with congestion. We show...
It is well known that in a network with arbitrary (convex) latency functions that are a function of...
Let M be a single s-t network of parallel links with load dependent latency functions shared by an i...
Dynamic flow networks can model traffic, optical networks, building evacuations, and more. In these ...
AbstractLet M be a single s–t network of parallel links with load dependent latency functions shared...