On the Displacement for Covering a d-dimensional Cube with Randomly Placed Sensors

Abstract

Consider n sensors placed randomly and independently with the uniform distribution in a d-dimensional unit cube (d 2). The sensors have identical sensing range equal to r, for some r >0. We are interested in moving the sensors from their initial positions to new positions so as to ensure that the d-dimensional unit cube is completely covered, i.e., every point in the d-dimensional cube is within the range of a sensor. If the i-th sensor is displaced a distance di, what is a displacement of minimum cost? As cost measure for the displacement of the team of sensors we consider the a-total movement defined as the sum Ma:= Σi=1n dia, for some constant a>0. We assume that r and n are chosen so as to allow full coverage of the d-dimensional unit cube and a > 0. The main contribution of the paper is to show the existence of a tradeoff between the d-dimensional cube, sensing radius and a-total movement. The main results can be summarized as follows for the case of the d-dimensional cube. If the d-dimensional cube sensing radius is 12n1/d and n=md, for some m∈ N, then we present an algorithm that uses O(n1-a2d) total expected movement (see Algorithm 2 and Theorem 5). If the d-dimensional cube sensing radius is greater than 33/d(31/d-1)(31/d-1)12n1/d and n is a natural number then the total expected movement is O(n1-a2d( nn)a2d) (see Algorithm 3 and Theorem 7). In addition, we simulate Algorithm 2 and discuss the results of our simulations.