Many complex networks are only a part of larger systems, where a number of coexisting topologies interact and depend on each other. We introduce a layered model to facilitate the description and analysis of such systems. As an example of its application, we study the load distribution in three transportation systems, where the lower layer is the physical infrastructure and the upper layer represents the traffic flows. This layered view allows us to capture the fundamental differences between the real load and commonly used load estimators, which explains why these estimators fail to approximate the real load. DOI: 10.1103/PhysRevLett.96.138701 PACS numbers: 89.75.Hc, 89.20.Hh, 89.40.Bb, 89.75.Fb In recent years, studies of biological, social, infrastructure, or technological networks have drawn a substantial amount of attention in the physics community. Although these networks are usually considered as distinct objects, they are often a part of larger complex systems, where a number of coexisting topologies interact and depend on each other. For instance, the topologies of the Internet at the IP layer [1], of the World Wide Web (WWW) [2], or of the networks formed by peer to peer (P2P) applications [3], although studied separately, are closely related: Each WWW or P2P link virtually connects two IP nodes. These two IP nodes are usually distant in the underlying IP topology, and the virtual connection is realized as a path found by IP routers. In other words, the graph formed by an application is mapped on the underlying IP network. Moreover, the IP links are in turn mapped on the physical layer [4] that consists of a mesh of optical fibers usually buried in the ground along roads, rails, or power lines. The resulting topologies at the three layers are very different from each other.Another important class of real-life systems is transportation networks. Graphs derived from the physical infrastructure of such networks were analyzed on the examples of a power grid [5], a railway network [6], road networks [7], or urban mass transportation systems [8]. This approach often gives a valuable insight into the studied topology, but it ignores the real-life traffic pattern. Interestingly, the networks of traffic flows were studied separately, for instance, the flows of people within a city [9] and commuting traffic flows between different cities [10]. These studies, in turn, neglect the underlying physical topology. A comprehensive view of the system often requires one to analyze both layers (physical and traffic) together. Only in some particular cases is one layer sufficient. This is the case, e.g., in airport networks [11], where all traffic flows are one-hop long and the full knowledge of the traffic pattern is introduced into the physical graph by setting the edge weights equal to the amount of traffic they carry. However, in the presence of traffic flows longer than one hop, a weighted physical graph is not sufficient.
