TY - GEN
T1 - Improving coverage estimation for cellular networks with spatial bayesian prediction based on measurements
AU - Sayrac, Berna
AU - Riihijärvi, Janne
AU - Mähönen, Petri
AU - Ben Jemaa, Sana
AU - Moulines, Eric
AU - Grimoud, Sébastien
PY - 2012/8/13
Y1 - 2012/8/13
N2 - Cellular operators routinely use sophisticated planning tools to estimate the coverage of the network based on building and terrain data combined with detailed propagation modeling. Nevertheless, coverage holes still emerge due to equipment failures, or unforeseen changes in the propagation environment. For detecting these coverage holes, drive tests are typically used. Since carrying out drive tests is expensive and time consuming, there is significant interest in both improving the quality of the coverage estimates obtained from a limited number of drive test measurements, as well as enabling the incorporation of measurements from mobile terminals. In this paper we introduce a spatial Bayesian prediction framework that can be used for both of these purposes. We show that using techniques from modern spatial statistics we can significantly increase the accuracy of coverage predictions from drive test data. Further, we carry out a detailed evaluation of our framework in urban and rural environments, using realistic coverage data obtained from an operator planning tool for an operational cellular network. Our results indicate that using spatial prediction techniques can more than double the likelihood of detecting coverage holes, while retaining a highly acceptable false alarm probability.
AB - Cellular operators routinely use sophisticated planning tools to estimate the coverage of the network based on building and terrain data combined with detailed propagation modeling. Nevertheless, coverage holes still emerge due to equipment failures, or unforeseen changes in the propagation environment. For detecting these coverage holes, drive tests are typically used. Since carrying out drive tests is expensive and time consuming, there is significant interest in both improving the quality of the coverage estimates obtained from a limited number of drive test measurements, as well as enabling the incorporation of measurements from mobile terminals. In this paper we introduce a spatial Bayesian prediction framework that can be used for both of these purposes. We show that using techniques from modern spatial statistics we can significantly increase the accuracy of coverage predictions from drive test data. Further, we carry out a detailed evaluation of our framework in urban and rural environments, using realistic coverage data obtained from an operator planning tool for an operational cellular network. Our results indicate that using spatial prediction techniques can more than double the likelihood of detecting coverage holes, while retaining a highly acceptable false alarm probability.
KW - bayesian kriging
KW - coverage estimation
KW - minimization of drive tests
KW - spatial statistics
UR - https://www.scopus.com/pages/publications/84866489555
U2 - 10.1145/2342468.2342479
DO - 10.1145/2342468.2342479
M3 - Conference contribution
AN - SCOPUS:84866489555
SN - 9781450314756
T3 - CellNet'12 - Proceedings of the ACM Workshop on Cellular Networks: Operations, Challenges, and Future Design
SP - 43
EP - 48
BT - CellNet'12 - Proceedings of the ACM Workshop on Cellular Networks
PB - Association for Computing Machinery
T2 - 2012 ACM SIGCOMM Workshop on Cellular Networks: Operations, Challenges, and Future Design, CellNet 2012
Y2 - 13 August 2012 through 13 August 2012
ER -