Time Synchronization and Ranging in OFDM Systems Using Time-Reversal

Abrudan, Traian E.; Haghparast, Azadeh; Koivunen, Visa

doi:10.1109/tim.2013.2272840

Cited by 35 publications

(19 citation statements)

References 50 publications

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“…, R ℓ K[n] obtained from the DoA/ToA tracking phase. In the following, we apply the Kalman-gain form of the EKF to the presented models (41) and (46) in order to obtain the joint DoA/ToA Pos&Sync EKF. Since our measurement model contains now also the clock offset parameters for the LoS-ANs, we need to modify the Jacobian matrix H in (33)-(37) by adding the corresponding elements for each LoS-ANs, namely…”

Section: A Positioning and Network Synchronization Ekf At Central Unitmentioning

confidence: 99%

Joint Device Positioning and Clock Synchronization in 5G Ultra-Dense Networks

Koivisto

Costa²,

Werner

et al. 2017

IEEE Trans. Wireless Commun.

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198

152

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In this article, we address the prospects and key enabling technologies for highly efficient and accurate device positioning and tracking in fifth generation (5G) radio access networks. Building on the premises of ultra-dense networks (UDNs) as well as on the adoption of multicarrier waveforms and antenna arrays in the access nodes (ANs), we first formulate extended Kalman filter (EKF)-based solutions for computationally efficient joint estimation and tracking of the time of arrival (ToA) and direction of arrival (DoA) of the user nodes (UNs) using uplink (UL) reference signals. Then, a second EKF stage is proposed in order to fuse the individual DoA/ToA estimates from one or several ANs into a UN position estimate. Since all the processing takes place at the network side, the computing complexity and energy consumption at the UN side are kept to a minimum. The cascaded EKFs proposed in this article also take into account the unavoidable relative clock offsets between UNs and ANs, such that reliable clock synchronization of the access-link is obtained as a valuable by-product. The proposed cascaded EKF scheme is then revised and extended to more general and challenging scenarios where not only the UNs have clock offsets against the network time, but also the ANs themselves are not mutually synchronized in time. Finally, comprehensive performance evaluations of the proposed solutions on a realistic 5G network setup, building on the METIS project based outdoor Madrid map model together with complete ray tracing based propagation modeling, are provided. The obtained results clearly demonstrate that by using the developed methods, sub-meter scale positioning and tracking accuracy of moving devices is indeed technically feasible in future 5G radio access networks operating at sub-6 GHz frequencies, despite the realistic assumptions related to clock offsets and potentially even under unsynchronized network elements.

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Section: A Positioning and Network Synchronization Ekf At Central Unitmentioning

confidence: 99%

Joint Device Positioning and Clock Synchronization in 5G Ultra-Dense Networks

Koivisto

Costa²,

Werner

et al. 2017

IEEE Trans. Wireless Commun.

Self Cite

198

152

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“…Figure 9: Our experimental setup consists of two multicarrier phase ranging devices based on the Atmel AT86RF233 radio transceiver, that function as the prover (1) and verifier (3). The distance measured by the verifier is recorded to the connected laptop (4). The attacker's hardware (2) consists of an USRP [2] and two directional antennas, one each for receiving the prover's response signal and the other for transmitting the attacker's signal to the verifier.~5 0m Figure 10: Hallway in which the experiment took place.…”

Section: Experimental Evaluationmentioning

confidence: 99%

On the Security of Carrier Phase-Based Ranging

Ólafsdóttir

Ranganathan

Čapkun

2017

Lecture Notes in Computer Science

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Multicarrier phase-based ranging is fast emerging as a cost-optimized solution for a wide variety of proximitybased applications due to its low power requirement, low hardware complexity and compatibility with existing standards such as ZigBee and 6LoWPAN. Given potentially critical nature of the applications in which phasebased ranging can be deployed (e.g., access control, asset tracking), it is important to evaluate its security guarantees. Therefore, in this work, we investigate the security of multicarrier phase-based ranging systems and specifically focus on distance decreasing relay attacks that have proven detrimental to the security of proximity-based access control systems (e.g., vehicular passive keyless entry and start systems). We show that phase-based ranging, as well as its implementations, are vulnerable to a variety of distance reduction attacks. We describe different attack realizations and verify their feasibility by simulations and experiments on a commercial ranging system. Specifically, we successfully reduced the estimated range to less than 3 m even though the devices were more than 50 m apart. We discuss possible countermeasures against such attacks and illustrate their limitations, therefore demonstrating that phase-based ranging cannot be fully secured against distance decreasing attacks.

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“…Time-delay based (ToA/RTT/TDOA) (e.g. [21], [22] and angle-of-arrival methods are more accurate, but they are still impaired by multi-path and/or non-line-ofsight effects in indoor environments. Ultrawideband (UWB) has enhanced ability to separate multipath contributions in line-of-sight conditions, but still suffers to some extent from dispersion/attenuation in non-line-of sight conditions.…”

Section: Introductionmentioning

confidence: 99%

Distortion Rejecting Magneto-Inductive Three-Dimensional Localization (MagLoc)

Abrudan

Xiao

Markham

et al. 2015

IEEE J. Select. Areas Commun.

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Localization is a research area that, due to its overarching importance as an enabler for higher level services, has attracted a vast amount of research and commercial interest. For the most part, it can be claimed that GPS provides an unparalleled solution for outdoor tracking and navigation. However, the same cannot yet be said about positioning in GPSdenied or challenged environments, such as indoor environments, where obstructions such as floors and walls heavily attenuate or reflect high frequency radio signals. This has led to a plethora of competing solutions targeted towards a particular application scenario, yielding a fragmented solution landscape. In this paper, we present a fresh approach to 3-D positioning based on the use of very low frequency (kHz) magneto-inductive (MI) fields. The most important property of MI positioning is that obstacles like walls, floors and people that heavily impact the performance of competing approaches are largely "transparent" to the quasi-static magnetic fields. MI has a number of challenges to robust operation that distort positions, including the presence of ferrous materials and sensitivity to user rotation. Through signal processing and sensor fusion across multiple system layers, we show how we can overcome these challenges. We showcase its highly accurate 3-D positioning in a number of environments, with positioning accuracy below 0.8 m even in heavily distorted areas.

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Time Synchronization and Ranging in OFDM Systems Using Time-Reversal

Cited by 35 publications

References 50 publications

Joint Device Positioning and Clock Synchronization in 5G Ultra-Dense Networks

Joint Device Positioning and Clock Synchronization in 5G Ultra-Dense Networks

On the Security of Carrier Phase-Based Ranging

Distortion Rejecting Magneto-Inductive Three-Dimensional Localization (MagLoc)

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