The design and implementation of a self-calibrating distributed acoustic sensing platform

Girod, Lewis; Lukáč, Martin; Trifa, Vlad; Estrin, Deborah

doi:10.1145/1182807.1182815

Cited by 143 publications

(110 citation statements)

References 33 publications

(49 reference statements)

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“…The major differences among them are the calibration methods and the usage of signal sources, such as sonic, ultrasonic, infrared, camera, RF, etc. For example, Acoustic ENSBox [16] develops a distribution acoustic sensing platform, which an acoustic embedded networked sensing box can be rapidly deployed and perform self-calibration. It claims to achieve 5 centimeters positional accuracy in a partially obstructed 80m×50m outdoor.…”

Section: Resultsmentioning

confidence: 99%

“…To address this need, there have been many sensor network localization systems utilizing different sensing techniques, e.g., MoteTrack [9], Cricket [10], Spotlight [13], APIT [14], ENSBox [16], etc. Among them, the radio interferometric positioning (RIP) method from the NEST project [1] has shown a promising, exciting location sensing technique for sensor network applications.…”

Section: Introductionmentioning

confidence: 99%

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Modeling and Optimizing Positional Accuracy Based on Hyperbolic Geometry for the Adaptive Radio Interferometric Positioning System

Wu¹,

Chang²,

You³

et al.

Location- And Context-Awareness

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Abstract.One of the most important performance objectives for a localization system is positional accuracy. It is fundamental and essential to general location-aware services. The radio interferometric positioning (RIP) method [1] is an exciting approach which promises sub-meter positional accuracy. In this work, we would like to enhance the RIP method by dynamically selecting the best anchor nodes as beacon senders, and further optimizing the positional accuracy when tracking multiple targets. We have developed an estimation error model to predict positional error of the RIP algorithm given different combinations of beacon senders. Building upon this estimation error model, we further devise an adaptive RIP method that selects the optimal sender-pair combination (SPC) according to the locations of targets relative to anchor nodes. We have implemented the adaptive RIP method and conducted experiments in a real sensor network testbed. Experimental results have shown that our adaptive RIP method outperforms the static RIP method in both single-target and multi-target tracking, and improves the average positional accuracy by 47%~60% and reduces the 90% percentile error by 55%~61%.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modeling and Optimizing Positional Accuracy Based on Hyperbolic Geometry for the Adaptive Radio Interferometric Positioning System

Wu¹,

Chang²,

You³

et al.

Location- And Context-Awareness

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show abstract

“…The localization techniques use diverse hardware, algorithms and signal modalities, which can be categorized along several different dimensions. We start by describing the three phases typically used in localization ( [26], [27], [28]): (1) coordination, (2) measurement, and (3) position estimation. We then focus on other aspects of MWSN-based localization, such as the effects of mobility, centralized versus distributed processing, and the environment.…”

Section: Localization In Mwsnsmentioning

confidence: 99%

A Survey on Localization for Mobile Wireless Sensor Networks

Amundson

Koutsoukos

2009

Lecture Notes in Computer Science

252

142

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Abstract. Over the past decade we have witnessed the evolution of wireless sensor networks, with advancements in hardware design, communication protocols, resource efficiency, and other aspects. Recently, there has been much focus on mobile sensor networks, and we have even seen the development of small-profile sensing devices that are able to control their own movement. Although it has been shown that mobility alleviates several issues relating to sensor network coverage and connectivity, many challenges remain. Among these, the need for position estimation is perhaps the most important. Not only is localization required to understand sensor data in a spatial context, but also for navigation, a key feature of mobile sensors. In this paper, we present a survey on localization methods for mobile wireless sensor networks. We provide taxonomies for mobile wireless sensors and localization, including common architectures, measurement techniques, and localization algorithms. We conclude with a description of real-world mobile sensor applications that require position estimation.

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“…Existing work basically use three types of measurements of acoustic signals: TDOA [24], [19], [32], [9], DOA (direction of arrival) [22], [14], [12], [15] and received signal energy [25], [26], [4], [21], [3].…”

Section: Related Workmentioning

confidence: 99%