TY - GEN
T1 - Accurate localization of low-level radioactive source under noise and measurement errors
AU - Chin, Jren Chit
AU - Yau, David K.Y.
AU - Rao, Nageswara S.V.
AU - Yang, Yong
AU - Ma, Chris Y.T.
AU - Shankar, Mallikarjun
PY - 2008
Y1 - 2008
N2 - The localization of a radioactive source can be solved in closed-form using 4 ideal sensors and the Apollonius circle in a noise- and error-free environment. When measurement errors and noise such as background radiation are considered, a larger number of sensors is needed to produce accurate results, particularly for extremely low source intensities. In this paper, we present an efficient fusion algorithm that can exploit measurements from n sensors to improve the localization accuracy, and show how the accuracy scales with n. We report testbed results for a 0.911 μCi source to illustrate the effectiveness of our algorithm, in particular performance comparisons with state-of-the-art fusion algorithms based on Mean of Estimates (MoE) and Maximum Likelihood Estimation (MLE). We show that ITP is more accurate than MoE, whereas the choice between ITP and MLE is generally a tradeoff between accuracy and run time efficiency. Higher-intensity radioactive sources are not safe for actual experiments. In this case, we present simulation results based on a validated simulation model. We show that a low-intensity 400 μCi source, similar to the radioactivity of a concealed dirty bomb, can be localized to within 32.5 m using a sensor density of about 1 per 1100 m 2 in a surveillance area.
AB - The localization of a radioactive source can be solved in closed-form using 4 ideal sensors and the Apollonius circle in a noise- and error-free environment. When measurement errors and noise such as background radiation are considered, a larger number of sensors is needed to produce accurate results, particularly for extremely low source intensities. In this paper, we present an efficient fusion algorithm that can exploit measurements from n sensors to improve the localization accuracy, and show how the accuracy scales with n. We report testbed results for a 0.911 μCi source to illustrate the effectiveness of our algorithm, in particular performance comparisons with state-of-the-art fusion algorithms based on Mean of Estimates (MoE) and Maximum Likelihood Estimation (MLE). We show that ITP is more accurate than MoE, whereas the choice between ITP and MLE is generally a tradeoff between accuracy and run time efficiency. Higher-intensity radioactive sources are not safe for actual experiments. In this case, we present simulation results based on a validated simulation model. We show that a low-intensity 400 μCi source, similar to the radioactivity of a concealed dirty bomb, can be localized to within 32.5 m using a sensor density of about 1 per 1100 m 2 in a surveillance area.
KW - iterative pruning
KW - noise and error management
KW - radioactive source localization
KW - sensor data fusion
KW - sensor network
UR - http://www.scopus.com/inward/record.url?scp=70350401005&partnerID=8YFLogxK
U2 - 10.1145/1460412.1460431
DO - 10.1145/1460412.1460431
M3 - Conference contribution
AN - SCOPUS:70350401005
SN - 9781595939906
T3 - SenSys'08 - Proceedings of the 6th ACM Conference on Embedded Networked Sensor Systems
SP - 183
EP - 196
BT - SenSys'08 - Proceedings of the 6th ACM Conference on Embedded Networked Sensor Systems
T2 - 6th ACM Conference on Embedded Networked Sensor Systems, SenSys 2008
Y2 - 5 November 2008 through 7 November 2008
ER -