Routing | EPFL Graph Search

Routing is the process of selecting a path for traffic in a network or between or across multiple networks. Broadly, routing is performed in many types of networks, including circuit-switched networks, such as the public switched telephone network (PSTN), and computer networks, such as the Internet. In packet switching networks, routing is the higher-level decision making that directs network packets from their source toward their destination through intermediate network nodes by specific packet forwarding mechanisms. Packet forwarding is the transit of network packets from one network interface to another. Intermediate nodes are typically network hardware devices such as routers, gateways, firewalls, or switches. General-purpose computers also forward packets and perform routing, although they have no specially optimized hardware for the task. The routing process usually directs forwarding on the basis of routing tables. Routing tables maintain a record of the routes to various net

Routing in large-scale buses ad hoc networks

Michel Sède

A Disruption-Tolerant Network (DTN) attempts to route packets between nodes that are temporarily connected. Difficulty in such networks is that nodes have no information about the network status and contact opportunities. The situation is different in public bus networks because the movement of buses exhibits some regularity so that routing in a deterministic way is possible. Many algorithms use a Contacts Oracle that provides the exact meeting times and durations between all nodes. However, in a real vehicular environment, an oracle is not always accurate, and deterministic routing gives poor results. In this paper, we present BLER, a routing algorithm that achieves effective routing in a buses environment. BLER, compared to other algorithms, performs routing at bus line level instead of bus level; it uses specific bus lines information to achieve good performances. We evaluate BLER on real traces of the bus network of Shanghai, and compare it to other routing algorithms. Performances provide good results for this kind of DTNs.

Ieee Service Center, 445 Hoes Lane, Po Box 1331, Piscataway, Nj 08855-1331 Usa2008

Routing and search on large scale networks

Dominique Florian Tschopp

In this thesis, we address two seemingly unrelated problems, namely routing in large wireless ad hoc networks and comparison based search in image databases. However, the underlying problem is in essence similar and we can use the same strategy to attack those two problems. In both cases, the intrinsic complexity of the problem is in some sense low, and we can exploit this fact to design efficient algorithms. A wireless ad hoc network is a communication network consisting of wireless devices such as for instance laptops or cell phones. The network does not have any fixed infrastructure, and hence nodes which cannot communicate directly over the wireless medium must use intermediate nodes as relays. This immediately raises the question of how to select the relay nodes. Ideally, one would like to find a path from the source to the destination which is as short as possible. The length of the found path, also called route, typically depends on how much signaling traffic is generated in order to establish the route. This is the fundamental trade-off that we will investigate in this thesis. As mentioned above, we try and exploit the fact that the communication network is intrinsically low-dimensional, or in other words has low complexity. We show that this is indeed the case for a large class of models and that we can design efficient algorithms for routing that use this property. Low dimensionality implies that we can well embed the network in a low-dimensional space, or build simple hierarchical decompositions of the network. We use both those techniques to design routing algorithms. Comparison based search in image databases is a new problem that can be defined as follows. Given a large database of images, can a human user retrieve an image which he has in mind, or at least an image similar to that image, without going sequentially through all images? More precisely, we ask whether we can search a database of images only by making comparisons between images. As a case in point, we ask whether we can find a query image q only by asking questions of the type "does image q look more like image A or image B"? The analogous to signaling traffic for wireless networks would here be the questions we can ask human users in a learning phase anterior to the search. In other words, we would like to ask as few questions as possible to pre-process and prepare the database, while guaranteeing a certain quality of the results obtained in the search phase. As the underlying image space is not necessarily metric, this raises new questions on how to search spaces for which only rank information can be obtained. The rank of A with respect to B is k, if A is B's kth nearest neighbor. In this setup, low-dimensionality is analogous to the homogeneity of the image space. As we will see, the homogeneity can be captured by properties of the rank relationships. In turn, homogeneous spaces can be well decomposed hierarchically using comparisons. Further, it allows us to design good hash functions. To design efficient algorithms for these two problems, we can apply the same techniques mutatis mutandis. In both cases, we relied on the intuition that the problem has a low intrinsic complexity, and that we can exploit this fact. Our results come in the form of simulation results and asymptotic bounds.

EPFL2010

Collaborative routing in mobile partitioned networks

Natasa Sarafijanovic-Djukic

Embedded wireless networks find a broad spectrum of applications in transportation, environmental monitoring, logistics, supply chain management, and "pocketswitched" communication. The node mobility patterns in these applications tend to give rise to spatially heterogeneous node distributions, which may cause network partitions. In this thesis, we consider the problem of routing in mobile networks under such challenging conditions. More specifically, we endeavor to identify features of mobility common to different applications, in order to devise routing methods that are tailored to exploit these features. We explore two features in particular, (i) predictability and (ii) stable and heterogeneous spatial node distribution. A mobility process is predictable if the future location of a node can be well estimated, given knowledge of its current and past locations and possibly other statistics. We show how the performance of routing can be improved by explicitly incorporating mobility prediction. Specifically, we consider the performance of Last Encounter Routing (LER) under a simple synthetic random waypoint (RWP) mobility model. We extend the LER algorithm so that it takes into account predicted node trajectories when making routing decisions, and we show that this significantly improves its performance. A mobility process has a stable spatial node distribution if, informally, the node density remains the same over time, even though individual nodes are not constrained in space. This is a common feature of many mobility patterns because the spatial distribution is determined by the natural or constructed environment, regardless of the behavior of individual nodes. This typically leads to heterogeneous connectivity and to network partition, where highly connected clusters are interspersed with low-connectivity regions. We model such a situation with a set of stable concentration points (CPs) characterized by high node density, and with a mobility process that describes how nodes move between these islands of connectivity. We study two instances of this model: the G-model, where the CPs and the flow of nodes are abstracted as a graph, and the H-model, where nodes perform heterogeneous random walks on the plane. We exploit the presence of this stable CP topology in order to develop an efficient routing algorithm under these two mobility models. Our routing algorithm, Island Hopping (IH), exploits knowledge of the CP topology to make routing decisions. IH achieves a very good delay-throughput trade-off compared with several other existing routing algorithms, and it scales well with the network size. In many situations, it would be unrealistic to assume that CPs and the flows of mobile nodes among them are known a-priori. We develop methods, collectively called Collaborative Graph Discovery (COGRAD), that allow the nodes to discover the CP graph without any explicit signals from the environment (such as GPS coordinates or fixed beacons). We show that COGRAD can replace an oracle with knowledge of the CP topology after a sufficient warm-up period, allowing IH to operate even in scenarios without any cues from the environment.

EPFL2010

Routing and search on large scale networks

Dominique Florian Tschopp

EPFL2010

Collaborative routing in mobile partitioned networks

Natasa Sarafijanovic-Djukic

EPFL2010