Accuracy in WiFi Access Point Position Estimation Using Round Trip Time

García-Fernández, Miquel; Hoyas-Ester, Isaac; Lopez-Cruces, Alex; Siutkowska, Malgorzata; Banque-Casanovas, Xavier

doi:10.3390/s21113828

Cited by 8 publications

(2 citation statements)

References 12 publications

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“…This information is normally not provided by the APs in private networks. The authors in [ 27 ] propose a double-iteration approach to mitigate this issue, where the APs positions are computed in a first stage by using a GNSS solution. Then, in a second stage, these positions feed a hybrid GNSS/FTM-based Wi-Fi position system to compute the user’s position, at the cost of inheriting the errors that come with APs positions.…”

Section: Introductionmentioning

confidence: 99%

Improving Fingerprint-Based Positioning by Using IEEE 802.11mc FTM/RTT Observables

Martín-Escalona

Zola

2022

Sensors

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Received signal strength (RSS) has been one of the most used observables for location purposes due to its availability at almost every wireless device. However, the volatile nature of RSS tends to yield to non-reliable location solutions. IEEE 802.11mc enabled the use of the round trip time (RTT) for positioning, which is expected to be a more consistent observable for location purposes. This approach has been gaining support from several companies such as Google, which introduced that feature in the Android O.S. As a result, RTT estimation is now available in several recent off-the-shelf devices, opening a wide range of new approaches for computing location. However, RTT has been traditionally addressed to multilateration solutions. Few works exist that assess the feasibility of the RTT as an accurate feature in positioning methods based on classification algorithms. An attempt is made in this paper to fill this gap by investigating the performance of several classification models in terms of accuracy and positioning errors. The performance is assessed using different AP layouts, distinct AP vendors, and different frequency bands. The accuracy and precision of the RTT-based position estimation is always better than the one obtained with RSS in all the studied scenarios, and especially when few APs are available. In addition, all the considered ML algorithms perform pretty well. As a result, it is not necessary to use more complex solutions (e.g., SVM) when simpler ones (e.g., nearest neighbor classifiers) achieve similar results both in terms of accuracy and location error.

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Section: Introductionmentioning

confidence: 99%

Improving Fingerprint-Based Positioning by Using IEEE 802.11mc FTM/RTT Observables

Martín-Escalona

Zola

2022

Sensors

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“…In this context, an indoor local positioning system (LPS) is often required and designed to estimate the pose of people or devices in environments where GNSS solutions have attenuation/coverage problems and multi-path effects that limit their performance [2]. For that purpose, different sensory technologies have also been applied in previous work (acoustic [3,4], infrared [5,6], radio-frequency [7,8], etc.). In particular, the use of optical signals (infrared or visible light) [9] has spread significantly due to their low cost, long lifetime and their presence in most of today's infrastructures [10].…”

Section: Introductionmentioning

confidence: 99%

Using Perspective-n-Point Algorithms for a Local Positioning System Based on LEDs and a QADA Receiver

Aparicio-Esteve

Ureña

Hernández

et al. 2021

Sensors

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The research interest on location-based services has increased during the last years ever since 3D centimetre accuracy inside intelligent environments could be confronted with. This work proposes an indoor local positioning system based on LED lighting, transmitted from a set of beacons to a receiver. The receiver is based on a quadrant photodiode angular diversity aperture (QADA) plus an aperture placed over it. This configuration can be modelled as a perspective camera, where the image position of the transmitters can be used to recover the receiver’s 3D pose. This process is known as the perspective-n-point (PnP) problem, which is well known in computer vision and photogrammetry. This work investigates the use of different state-of-the-art PnP algorithms to localize the receiver in a large space of 2 × 2 m2 based on four co-planar transmitters and with a distance from transmitters to receiver up to 3.4 m. Encoding techniques are used to permit the simultaneous emission of all the transmitted signals and their processing in the receiver. In addition, correlation techniques (match filtering) are used to determine the image points projected from each emitter on the QADA. This work uses Monte Carlo simulations to characterize the absolute errors for a grid of test points under noisy measurements, as well as the robustness of the system when varying the 3D location of one transmitter. The IPPE algorithm obtained the best performance in this configuration. The proposal has also been experimentally evaluated in a real setup. The estimation of the receiver’s position at three particular points for roll angles of the receiver of γ={0°, 120°, 210° and 300°} using the IPPE algorithm achieves average absolute errors and standard deviations of 4.33 cm, 3.51 cm and 28.90 cm; and 1.84 cm, 1.17 cm and 19.80 cm in the coordinates x, y and z, respectively. These positioning results are in line with those obtained in previous work using triangulation techniques but with the addition that the complete pose of the receiver (x, y, z, α, β, γ) is obtained in this proposal.

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An Unsupervised Detection Method for Multiple Abnormal Wi-Fi Access Points in Large-Scale Wireless Network

Chen

Liao²

2022

Applied Artificial Intelligence

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Accuracy in WiFi Access Point Position Estimation Using Round Trip Time

Cited by 8 publications

References 12 publications

Improving Fingerprint-Based Positioning by Using IEEE 802.11mc FTM/RTT Observables

Improving Fingerprint-Based Positioning by Using IEEE 802.11mc FTM/RTT Observables

Using Perspective-n-Point Algorithms for a Local Positioning System Based on LEDs and a QADA Receiver

An Unsupervised Detection Method for Multiple Abnormal Wi-Fi Access Points in Large-Scale Wireless Network

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