Improved heuristic drift elimination with magnetically-aided dominant directions (MiHDE) for pedestrian navigation in complex buildings

Jiménez, Antonio R.; Seco, Fernando; Zampella, Francisco; Prieto, José Carlos Sánchez; Guevara, J.

doi:10.1080/17489725.2012.687779

Cited by 36 publications

(14 citation statements)

References 12 publications

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“…A heuristic drift elimination system, although only for some special shapes of indoor pedestrian positioning, gradually adjusts the direction to the closest dominant directions. In [21], an improved heuristic drift elimination with magnetically-assisted dominant headings was used to reduce the direction drift. Considering the interference of the complex indoor environment to magnetic field readings, many scholars do not recommend the use of magnetic field correction direction.…”

Section: Related Workmentioning

confidence: 99%

An INS/Floor-Plan Indoor Localization System Using the Firefly Particle Filter

Chen

Peng

et al. 2018

IJGI

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Location-based services for smartphones are becoming more and more popular. The core of location-based services is how to estimate a user’s location. An INS/floor-plan indoor localization system, using the Firefly Particle Filter (FPF), is proposed to estimate a user’s location. INS includes an attitude angle module, a step length module and a step counting module. In the step length module, we propose a hybrid step length model. The proposed step length algorithm reasonably calculates a user’s step length. Because of sensor deviation, non-orthogonality and the user’s jitter, the main bottleneck for INS is that the error grows over time. To reduce the cumulative error, we design cascade filters including the Kalman Filter (KF) and FPF. To a certain extent, KF reduces velocity error and heading drift. On the other hand, the firefly algorithm is used to solve the particle impoverishment problem. Considering that a user may not cross an obstacle, the proposed particle filter is proposed to improve positioning performance. Results show that the average positioning error in walking experiments is 2.14 m.

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Section: Related Workmentioning

confidence: 99%

An INS/Floor-Plan Indoor Localization System Using the Firefly Particle Filter

Chen

Peng

et al. 2018

IJGI

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“…The main research in this area has taken into consideration road networks [13] and section shapes [14]. In particular, the magnetic field information [15] and direction information [16] of the indoor building are analyzed and extracted to reduce the PDR error and match the pedestrian trajectory. Moreover, topology information, including the relationship between road networks, was considered in [17].…”

Section: Related Workmentioning

confidence: 99%

A Novel Semantic Matching Method for Indoor Trajectory Tracking

Guo

Xiong

Zheng

2017

IJGI

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The rapid development of smartphone sensors has provided rich indoor pedestrian trajectory data for indoor location-based applications. To improve the quality of these collected trajectory data, map matching methods are widely used to correct trajectories. However, these existing matching methods usually cannot achieve satisfactory accuracy and efficiency and have difficulty in exploiting the rich information contained in the obtained trajectory data. In this study, we proposed a novel semantic matching method for indoor pedestrian trajectory tracking. Similar to our previous work, pedestrian dead reckoning (PDR) and human activity recognition (HAR) are used to obtain the raw user trajectory data and the corresponding semantic information involved in the trajectory, respectively. To improve the accuracy and efficiency for user trajectory tracking, a semantic-rich indoor link-node model is then constructed based on the input floor plan, in which navigation-related semantics are extracted and formalized for the following trajectory matching. PDR and HAR are further utilized to segment the trajectory and infer the semantics (e.g., "Turn left", "Turn right", and "Go straight"). Finally, the inferred semantic information is matched with the semantic-rich indoor link-node model to derive the correct user trajectory. To accelerate the matching process, the semantics inferred from the trajectory are also assigned weights according to their relative importance. The experiments confirm that the proposed method achieves accurate trajectory tracking results while guaranteeing a high matching efficiency. In addition, the resulting semantic information has great application potential in further indoor location-based services.

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“…Previous versions (e.g. Finlay et al 2010;Thébault et al 2015) are widely used in many disciplines of Earth sciences and applied for navigational purposes (Jiménez et al 2012;Canciani & Raquet 2016) and in satellite orientation (Slavinskis et al 2014).applied sciences.…”

Section: Introductionmentioning

confidence: 99%

Geomagnetic core field models and secular variation forecasts for the 13th International Geomagnetic Reference Field (IGRF-13)

Wardinski

Saturnino

Amit

et al. 2020

Preprint

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Abstract Observations of the geomagnetic field taken at Earth's surface and at satellite altitude are combined to construct continuous models of the geomagnetic field and its secular variation from 1957 to 2020. From these parent models, we derive candidate main field models for the epochs 2015 and 2020 to the 13th generation of the International Geomagnetic Reference Field (IGRF). The secular variation candidate model for the period 2020 - 2025 is derived from a forecast of the secular variation in 2022.5, which results from a multi-variate singular spectrum analysis of the secular variation from 1957 to 2020.

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Improved heuristic drift elimination with magnetically-aided dominant directions (MiHDE) for pedestrian navigation in complex buildings

Cited by 36 publications

References 12 publications

An INS/Floor-Plan Indoor Localization System Using the Firefly Particle Filter

An INS/Floor-Plan Indoor Localization System Using the Firefly Particle Filter

A Novel Semantic Matching Method for Indoor Trajectory Tracking

Geomagnetic core field models and secular variation forecasts for the 13th International Geomagnetic Reference Field (IGRF-13)

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