An Efficient Single-Anchor Localization Method Using Ultra-Wide Bandwidth Systems

Wang, Tianyu; Zhao, Hanying; Shen, Yuan

doi:10.3390/app10010057

Cited by 31 publications

(12 citation statements)

References 45 publications

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“…There is a body of research on improving the performance of wireless systems under interference, including studies on avoiding interference by TDMA schemes, ALOHA, or combining localization and communication traffic [12]; mitigating interference [13], [14]; and exploiting interference [15]- [17]. More recently, researchers used (quasi-)simultaneous transmissions with UWB radios for indoor localization to increase air time efficiency by simultaneously extracting time of arrival (TOA) or phase of arrival (POA) of multiple transmitters from the combined from the channel impulse response (CIR) of the concurrently received packets [5]- [11], [18].…”

Section: Related Workmentioning

confidence: 99%

“…Traditional ranging systems make use of the ability of UWB radios to measure TOA of the arriving packet. Concurrency-based ranging systems measure range with multiple UWB transceivers by measuring the difference between TOA of later arriving packets and TOA of the first arriving packet [5], [7], [9], [18]. TOA-based solutions are not scalable in terms of the number of tags as they require two-way message passing between anchors and tags, and CIR can only accommodate a limited number of concurrent signals.…”

Section: A Uwb Concurrent Time-based Localizationmentioning

confidence: 99%

“…Our work explores the possibility of combining the idea of intra-anchor concurrency with inter-anchor concurrency (packets concurrently transmitted from multiple anchors) to measure AOA from multiple dual-UWB radio anchors on single-antenna tags. Another research study combines AOA with ranging (TOA) to build a single-anchor localization system [18]. However, this solution is not scalable in terms of the number of tags as it requires two-way message passing between anchors and tags, and CIR can only accommodate a limited number of concurrent signals.…”

Section: B Uwb Concurrent Phase-based Localizationmentioning

confidence: 99%

See 2 more Smart Citations

Anchor-oriented Time and Phase-based Concurrent Self-localization using UWB Radios

Smaoui

Heydariaan

Gnawali

2021

2021 IEEE 46th Conference on Local Computer Networks (LCN)

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Positioning plays an important role in many IoT applications. Ultra-wideband (UWB)-based positioning is an alternative to GPS in indoor environments due to its multipath resilience and its accuracy and precision. In the presence of a large number of targets to localize, conventional UWB localization fails to provide a practical location update rate. UWB concurrency in conjunction with self-localization has been used in both time-based and phase-based localization making the targets to localize (tags), a relatively passive device with the sole role of receiving wireless packets and calculating its own location. More recently, phase-based concurrent angle estimation also offloaded the hardware complexity and cost to the anchors instead of the tags. In this work, our anchor-oriented approach combines inter-anchor and intra-anchor concurrency for phasebased localization but also allows time-based localization. Our experimental evaluation on a testbed consisting of Decawave platform shows that our technique is not only practical but also performant.

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Section: Related Workmentioning

confidence: 99%

Section: A Uwb Concurrent Time-based Localizationmentioning

confidence: 99%

Section: B Uwb Concurrent Phase-based Localizationmentioning

confidence: 99%

See 1 more Smart Citation

Anchor-oriented Time and Phase-based Concurrent Self-localization using UWB Radios

Smaoui

Heydariaan

Gnawali

2021

2021 IEEE 46th Conference on Local Computer Networks (LCN)

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“…Recently, these works have also inspired the use of UWB concurrent transmissions with angleof-arrival (AoA) localization. In Reference [60], a multi-antenna anchor sends a poll to which mobile nodes in range reply concurrently, allowing the anchor not only to measure their distance but also the AoA of their signals; combining the two enables the anchor to estimate the position of each node. The techniques we proposed in this article (Section 5) addressing the TX uncertainty, clock drift, and unreliability caused by packet loss, are applicable and likely beneficial also for this AoA technique.…”

Section: Concurrent Transmissions For Ranging and Localizationmentioning

confidence: 99%

Ultra-wideband Concurrent Ranging

Corbalán

Picco

2020

ACM Trans. Sen. Netw.

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We propose a novel concurrent ranging technique for distance estimation with ultra-wideband (UWB) radios. Conventional schemes assume that the necessary packet exchanges occur in isolation to avoid collisions. Concurrent ranging relies on the overlapping of replies from nearby responders to the same ranging request issued by an initiator node. As UWB transmissions rely on short pulses, the individual times of arrival can be discriminated by examining the channel impulse response (CIR) of the initiator transceiver. By ranging against N responders with a single, concurrent exchange, our technique drastically abates network overhead, enabling higher ranging frequency with lower latency and energy consumption w.r.t. conventional schemes. Concurrent ranging can be implemented with a strawman approach requiring minimal changes to standard schemes. Nevertheless, we empirically show that this limits the attainable accuracy, reliability, and therefore applicability. We identify the main challenges in realizing concurrent ranging without dedicated hardware and tackle them by contributing several techniques, used in synergy in our prototype based on the popular DW1000 transceiver. Our evaluation, with static targets and a mobile robot, confirms that concurrent ranging reliably achieves decimeter-level distance and position accuracy, comparable to conventional schemes but at a fraction of the network and energy cost.

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“…An algorithm for localization and synchronization of cooperating full-duplex agents using a single-anchor is developed in [16]. The authors of [17] propose a protocol and an accompanying algorithm that enables a single-anchor to (quasi-)simultaneously receive messages from multiple agents in order to localize them using TOA and AOA measurements. The proposed approach is verified on an experimental setup.…”

Section: Introductionmentioning

confidence: 99%

Power Allocation and Parameter Estimation for Multipath-based 5G Positioning

Kakkavas¹,

Wymeersch²,

Seco‐Granados³

et al. 2020

Preprint

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We consider a single-anchor multiple-input multiple-output orthogonal frequency-division multiplexing system with imperfectly synchronized transmitter (Tx) and receiver (Rx) clocks, where the Rx estimates its position based on the received reference signals. The Tx, having (imperfect) prior knowledge about the Rx location and the surrounding geometry, transmits the reference signals based on a set of fixed beams. In this work, we develop strategies for the power allocation among the beams

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An Efficient Single-Anchor Localization Method Using Ultra-Wide Bandwidth Systems

Cited by 31 publications

References 45 publications

Anchor-oriented Time and Phase-based Concurrent Self-localization using UWB Radios

Anchor-oriented Time and Phase-based Concurrent Self-localization using UWB Radios

Ultra-wideband Concurrent Ranging

Power Allocation and Parameter Estimation for Multipath-based 5G Positioning

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