On the Critical Total Power for k -Connectivity in Wireless Networks

1. On the Critical Total Power for k-Connectivity in Wireless Networks Honghai Zhang, Jennifer C. Hou Department of Computer Science University of Illinois at Urbana-Champaign

2. Wireless Networks • Characteristics of wireless networks • Nodes may be mobile • Energy is often supplied by batteries • Benefit of reducing transmission power • Extending network lifetime • Increasing network capacity • Mitigating MAC-level interference

3. How to Reduce Transmission Power • Two ways of reducing transmission power • All nodes use a minimum common power • All nodes may choose different power • Which one is better? • Intuitively, the latter is better • How do we define “better”? • Total power consumption How much power can be saved by using power control compared with using common power ?

4. Problem Statement • We investigate the critical total power required to maintain asymptotic k-connectivity on a unit square S=[0,1]2. • We consider the heterogeneous case in which each node can choose its own transmission power. • Formulation: • Wt,i : critical transmission power node i uses • Rt,i: corresponding transmission range of node i Wt,i = Rt,ia. • Total power: • Problem: Given the assumption that wireless nodes are distributed on S according to a Poisson point process with density l, how does the minimal power Wc scale with l as l infinity?

5. Network Model • Nodes are randomly distributed as a Poisson point process with density n in a unit-area square • A good approximation for uniformly random distribution withnnodes 1 1

6. Network Model (con’t) • Xi: location of nodei • Ri : transmission range of nodei • Link (j,i) exists if Rj  | Xi– Xj | • : transmission power of nodei • Total power: • k-connectivity: requires removing at least k nodes to disconnect the network • Critical total power Wc: minimum total power W for maintaining k-connectivity 1 Xj Rj Ri Xi 1

7. Previous Studies • All nodes choose the common power • [Gupta & Kumar 98] studied the critical transmission range rn for 1-connectivity • [Wan & Yi 04] for k-connectivity • All nodes choose different power • [Blough 02] Critical total power for 1-connectivity • Our study: critical total power for k-connectivity

8. Major Results • Main theory: • The critical total power for maintaining k-connectivity is with probability approaching 1 • Comparison with common power • The critical total power for k-connectivity with common power is • Allowing power control reduces the total power by a factor of

9. Sketched Proof of the Main Theory • Main theory: the critical total power for maintaining k-connectivity is with high probability • We derive a lower bound based on the necessary condition that every node has to be able to reach at least k nearest nodes in order to maintain strong k-connectivity. • We derive an upper bound based on an assertion that the network is strongly k-connected if every node can reach k other nodes in each of its four quadrants.

10. Proof of the Lower Bound Every node has to be able to reach at least k nearest nodes • Ri: the distance from node i to its kth nearest neighbor • is a lower bound for the critical power Ri r

11. Proof of the Lower Bound (con’t) • Goal • We have got • Suffices to show Chebyshev Inequality

12. Ri Proof of the Upper Bound • Each node has a coordinate system centered at itself • All x-axes and y-axes are in parallel, respectively • Lemma 1: The network has k-connectivity if every node can reach at least k nearest neighbors in each of the four quadrants of its own coordinate system • If a quadrant contains less than k nodes, it is sufficient to reach all of them.

13. Proof of Lemma 1 (for k=1) • (xi,yi): Node i’s location • Proof using contradiction • Choose the pair of nodes A, B such that • No path from A to B, and • A, B have the minimum • Goal: find another pair of nodes X, Y such that • No path from X to Y, and

14. Proof of Lemma 1 for k=1 • Assume B is in the first quadrant of A’s coordinate system • A must be able to reach the nearest neighbor C in the same quadrant • If C is not on x-axis or y-axis, then (C,B) is the pair needed for contradiction • No path from C to B • The case for C on x-axis or y-axis in in the paper! B C A x

15. Proving • Assume B C C’’ 45o A C’ D B’ x Contradiction!

16. Conclusion • The critical total power for k-connectivity is • Using power control can save the power by a factor of compared with using common power • This can make a difference between bounded value and infinite value