Abstract
This paper addresses a detection problem where sparse measurements are utilized to estimate the source parameters in a mixed multi-modal radiation field. As the limitation of dimensional scalability and the unimodal characteristic, most existing algorithms fail to detect the multi-point sources gathered in narrow regions, especially with no prior knowledge about intensity and source number. The proposed Peak Suppressed Particle Filter (PSPF) method utilizes a hybrid scheme of multi-layer particle filter, mean-shift clustering technique and peak suppression correction to solve the major challenges faced by current existing algorithms. Firstly, the algorithm realizes sequential estimation of multi-point sources in a cross-mixed radiation field by using particle filtering and suppressing intensity peak value, while existing algorithms could just identify single point or spatially separated point sources. Secondly, the number of radioactive sources could be determined in a non-parametric manner as the fact that invalid particle swarms would disperse automatically. In contrast, existing algorithms either require prior information or rely on expensive statistic estimation and comparison. Additionally, to improve the prediction stability and convergent performance, distance correction module and configuration maintenance machine are developed to sustain the multimodal prediction stability. Finally, simulations and physical experiments are carried out in aspects such as different noise level, non-parametric property, processing time and large-scale estimation, to validate the effectiveness and robustness of the PSPF algorithm.
Highlights
With the growing number of aging nuclear facilities and uncontrollable nuclear incidents, the ability to efficiently inspect and localize radioactive materials has become an important prerequisite for rapid rescue missions [1,2,3,4]
The topic of sources localization has received a fair bit of attention in recent decades [5,6,7], the localization for mixed multi-modal radiation filed formed with several gathered radiation sources has not been carefully investigated and resolved yet
Earlier works only deal with separately distributed sources [8,9,10,11], that is, the radiation field could be characterized by several unimodal distributions
Summary
With the growing number of aging nuclear facilities and uncontrollable nuclear incidents, the ability to efficiently inspect and localize radioactive materials has become an important prerequisite for rapid rescue missions [1,2,3,4] Under those circumstances, autonomous mobile robots such as Unmanned Ground Vehicles (UGVs) could be deployed to monitor and locate radiation sources in hazardous area. Each simulation case has been repeated for 10 times and average performance of the three radiation sources and different background radiation are completed to the evaluate the radiation and different radiation level arelevel completed to evaluate algorithm algorithmsources is illustrated in Figurebackground algorithm robustness, as shown in Table.
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