TY - GEN
T1 - On the interdependence of routing and data compression in multi-hop sensor networks
AU - Scaglione, Anna
AU - Servetto, Sergio D.
PY - 2002
Y1 - 2002
N2 - We consider a problem of broadcast communication in a multi-hop sensor network, in which samples of a random field are collected at each node of the network, and the goal is for all nodes to obtain an estimate of the entire field within a prescribed distortion value. The main idea we explore in this paper is that of jointly compressing the data generated by different nodes as this information travels over multiple hops, to eliminate correlations in the representation of the sampled field. Our main contributions are: (a) we obtain, using simple network flow concepts, conditions on the rate/distortion function of the random field, so as to guarantee that any node can obtain the measurements collected at every other node in the network, quantized to within any prescribed distortion value; and (b), we construct a large class of physically-motivated stochastic models for sensor data, for which we are able to prove that the joint rate/distortion function of all the data generated by the whole network grows slower than the bounds found in (a). A truly novel aspect of our work is the tight coupling between routing and source coding, explicitly formulated in a simple and analytically tractable model-to the best of our knowledge, this connection had not been studied before.
AB - We consider a problem of broadcast communication in a multi-hop sensor network, in which samples of a random field are collected at each node of the network, and the goal is for all nodes to obtain an estimate of the entire field within a prescribed distortion value. The main idea we explore in this paper is that of jointly compressing the data generated by different nodes as this information travels over multiple hops, to eliminate correlations in the representation of the sampled field. Our main contributions are: (a) we obtain, using simple network flow concepts, conditions on the rate/distortion function of the random field, so as to guarantee that any node can obtain the measurements collected at every other node in the network, quantized to within any prescribed distortion value; and (b), we construct a large class of physically-motivated stochastic models for sensor data, for which we are able to prove that the joint rate/distortion function of all the data generated by the whole network grows slower than the bounds found in (a). A truly novel aspect of our work is the tight coupling between routing and source coding, explicitly formulated in a simple and analytically tractable model-to the best of our knowledge, this connection had not been studied before.
KW - Cross-layer interactions
KW - Multi-hop networks
KW - Routing
KW - Sensor networks
KW - Source coding
UR - https://www.scopus.com/pages/publications/0036949173
UR - https://www.scopus.com/pages/publications/0036949173#tab=citedBy
U2 - 10.1145/570662.570663
DO - 10.1145/570662.570663
M3 - Conference contribution
AN - SCOPUS:0036949173
SN - 9781581134865
T3 - Proceedings of the Annual International Conference on Mobile Computing and Networking, MOBICOM
SP - 140
EP - 147
BT - Proceedings of the Annual International Conference on Mobile Computing and Networking, MOBICOM
PB - Association for Computing Machinery (ACM)
T2 - Proceedings of The Eight Annual International Conference on Mobile Computing and Networking
Y2 - 23 September 2002 through 28 September 2002
ER -