Locating the nodes: cooperative localization in wireless sensor networks

Patwari, Neal; Ash, Joshua N.; Kyperountas, S.; Hero, Alfred O.; Moses, Randolph L.; Correal, N.S.

doi:10.1109/msp.2005.1458287

Cited by 2,667 publications

(1,848 citation statements)

References 76 publications

(85 reference statements)

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“…4, the proximate points due to the 4 corner-diffracted paths are close to each other as compared with those involving threebounce building reflected paths. As the noise increases to σ d = 4 m, σ θ = σ φ = 8 • , our proposed scheme has an accuracy of about 39 m as compared to 85 m of Seow and Tan's Line Segment Intersection in [32] for a mobile device located at MD 1 The improvement is about 54%.…”

Section: Resultsmentioning

confidence: 88%

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Peer-to-Peer Localization in Urban and Indoor Environments

Chen¹,

Tan

Seow³

2011

PIER B

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Abstract-This paper presents a novel peer-to-peer or mobileto-mobile localization scheme for general indoor and outdoor environments. In this scheme, two mobile nodes at arbitrary locations are able to locate each other without the need of Line-of-Sight (LOS) path between the two mobile device, and without the need for any reference devices such as GPS or land base beacons. Existing peerto-peer localization techniques make use of Time of Arrival (TOA) and Angle of Arrival (AOA) of LOS and single bounce scattering paths to derive line of possible mobile device positions (LPMDs). The intersections of LPMDs are then used to estimate the unknown mobile device position -referred to as the Line Segment Intersection. However, in a heavy multipath environment with many multiplebounce scattering paths, existing techniques require weighting factors and threshold values which are specifically chosen for that particular environment in order to select the LPMDs that correspond to LOS and single-bounce scattering paths for localization. Large localization error will occur if multiple-bounce scattering paths' LPMDs are mistakenly used for intersections. In addition, existing techniques also do not work well in a multipath environment with high level of TOA and AOA noises especially when the angles between LPMDs are small. The accuracy of the Line Segment Intersection also deteriorates as the distance traveled by multipath signals become comparable to each other. This renders the weighting and threshold values ineffective. This paper presents a novel Gaussian weighting process to remove the abovementioned limitations. The Gaussian weighting process also dramatically improves the accuracy of the localization. Experimental coupled with simulation results show that our proposed localization scheme outperforms existing Peer-to-peer localization technique by a significant margin of up to 83% and 54%

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Section: Resultsmentioning

confidence: 88%

“…Each set of σ rms is computed based on 10,000 independent simulation runs using MatLab. RD is positioned at (5, 2, 1) and two different MDs are at positioned (13, 4, 1) and (16,8,1) as shown in Figs. 3(a) and 3(b) respectively.…”

Section: Resultsmentioning

confidence: 99%

Peer-to-Peer Localization in Urban and Indoor Environments

Chen¹,

Tan

Seow³

2011

PIER B

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“…The dominant location techniques in ad-hoc networks, e.g., WLANs, are TOA and RSS [5]. Whereas TOA measurements are preferred for sparse networks, for sufficiently high density ones, since the distances are sensibly reduced and hence the likehood to have a fixed reference point close to the located device is substantial, RSS can perform as well as TOA [6].…”

Section: Related Work 21 Cellular and Ad-hoc Positioning Techniquesmentioning

confidence: 99%

Enhancement of localization accuracy in cellular networks via cooperative ad-hoc links

Lhomme

Frattasi

Figueiras

et al. 2006

Proceedings of the 3rd International Conference on Mobile Technology, Applications &Amp; Systems - Mobility '06

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Positioning information enables new applications for cellular phones, personal communication systems, and specialized mobile radios. The network heterogeneity emerging in the fourth generation (4G) of mobile networks can be utilized for enhancements of the location estimation accuracy. In this paper, we propose a method to perform the localization in a system based on the coexistence of the cellular and the ad-hoc links. The main contribution of this paper is the implementation and evaluation of an Extended Kalman Filter, which merges two available domains of measurements: the time difference of arrival and the received signal strength, respectively retrieved from the long-and the short-range segments. The simulation results show that the proposed localization system outperforms a stand-alone cellular system in the considered scenarios.

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“…In a WSN localization problem, known-position sensors (anchor sensors) try to estimate the position of unknown-location sensors (source sensors) via noisy measurements [1]. Based on application requirements, accuracy, and efficiency, different types of measurements are employed in localization such as time-of-arrival, time-differenceof-arrival, received-signal-strength (RSS), and angle-of-arrival [1]. RSS is always an interesting method mainly because of its low complexity and cost of devices [1].…”

Section: Introductionmentioning

confidence: 99%

RSS-based sensor localization with unknown transmit power

Vaghefi

Gholami

Ström

2011

2011 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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Received signal strength (RSS)-based single source localization when there is not a prior knowledge about the transmit power of the source is investigated. Because of nonconvex behavior of maximum likelihood (ML) estimator, convoluted computations are required to achieve its global minimum. Therefore, we propose a novel semidefinite programming (SDP) approach by approximating ML problem to a convex optimization problem which can be solved very efficiently. Computer simulations show that our proposed SDP has a remarkable performance very close to ML estimator. Linearizing RSS model, we also derive the partly novel least squares (LS) and weighted total least squares (WTLS) algorithms for this problem. Simulations illustrate that WTLS improves the performance of LS considerably.

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Locating the nodes: cooperative localization in wireless sensor networks

Cited by 2,667 publications

References 76 publications

Peer-to-Peer Localization in Urban and Indoor Environments

Peer-to-Peer Localization in Urban and Indoor Environments

Enhancement of localization accuracy in cellular networks via cooperative ad-hoc links

RSS-based sensor localization with unknown transmit power

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