دانلود رایگان مقاله TDL: محلی سازی دو بعدی با حسگر فشار در شبکه حسگر بی سیم

Abstract

Many applications in wireless sensor networks (WSNs) (e.g., traffic monitoring, environment surveillance and intruder tracking) rely heavily on the availability and accuracy of targets’ locations. Compressive sensing (CS) has been widely applied to localization as it asserts that a small number of samples will suffice for sparse or compressible signal recovery. Despite much progress in CS-based localization, existing solutions mainly consider static targets and often perform poorly for mobile targets. In this paper, we develop a novel two-dimensional localization (TDL) framework for mobile targets using compressive sensing. TDL is composed of two modules: (i) spatial localization module (SLM) that first achieves localization at sampling times by exploiting the sparse nature of Received Signal Strength (RSS) vector in space domain, and (ii) temporal localization module (TLM) that then achieves localization at all times by exploiting the compressible nature of location vector in time domain. Furthermore, two practicable measurement matrices are constructed to conduct linear measurements. We analyze the flexibility and effectiveness of TDL in theory. Extensive numerical evaluations with real mobility traces further confirm the superior performance of our localization framework.

8. Conclusion

In this paper, we consider the problem of mobile target localization and develop a novel two-dimensional localization framework using compressive sensing. We design representation bases by exploiting the sparse or compressible nature hidden in the spatial signal (e.g., RSS vector) and the temporal signal (e.g., location vector). We investigate what types of measurement matrices are consistent with the physical constraints and sufficiently incoherent with the representation bases. TDL can significantly reduce spatial and temporal measurement numbers at the cost of small localization error. The effectiveness and robustness of TDL are confirmed through extensive numerical evaluations.