Tight coupling of GPS, laser scanner, and inertial measurements for navigation in urban environments

Soloviev, Andrey

doi:10.1109/plans.2008.4570059

Cited by 60 publications

(33 citation statements)

References 7 publications

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“…Wei et al used a normalized innovation squared (NIS) method to evaluate each camera/laser/GPS sensor validity before fusing the sensors with an unscented information filter for localization [17]. Soloviev used a Kalman filter with GPS, inertial measurements, and LIDAR [18]. Hentsche et al used a Kalman filter to integrate GPS and the inertia measurement.…”

Section: Related Workmentioning

confidence: 99%

Consistent map building in petrochemical complexes for firefighter robots using SLAM based on GPS and LIDAR

et al. 2018

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The objective of this study was to achieve simultaneous localization and mapping (SLAM) of firefighter robots for petrochemical complexes. Consistency of the SLAM map is important because human operators compare the map with aerial images and identify target positions on the map. The global positioning system (GPS) enables increased consistency. Therefore, this paper describes two Rao-Blackwellized particle filters (RBPFs) based on GPS and light detection and ranging (LIDAR) as SLAM solutions. Fast-SLAM 1.0 and Fast-SLAM 2.0 were used in grid maps for RBPFs in this study. We herein propose the use of Fast-SLAM to combine GPS and LIDAR. The difference between the original Fast-SLAM and the proposed method is the use of the log-likelihood function of GPS; the proposed combination method is implemented using a probabilistic mathematics formulation. The proposed methods were evaluated using sensor data measured in a real petrochemical complex in Japan ranging in size from 550-380 m. RTK-GPS data was used for the GPS measurement and had an availability of 56%. Our results showed that Fast-SLAM 2.0 based on GPS and LIDAR in a dense grid map produced the best results. There was significant improvement in alignment to aerial data, and the mean square root error was 0.65 m. To evaluate the mapping consistency, accurate 3D point cloud data measured by Faro Focus 3D (± 3 mm) was used as the ground truth. Building sizes were compared; the minimum mean errors were 0.17 and 0.08 m for the oil refinery and management building area and the area of a sparse building layout with large oil tanks, respectively. Consequently, a consistent map, which was also consistent with an aerial map (from Google Maps), was built by Fast-SLAM 1.0 and 2.0 based on GPS and LIDAR. Our method reproduced map consistency results for ten runs with a variance of ± 0.3 m. Our method reproduced map consistency results with a global accuracy of 0.52 m in a low RTK-Fix-GPS environment, which was a factory with a building layout similar to petrochemical complexes with 20.9% of RTK-Fix-GPS data availability.

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Section: Related Workmentioning

confidence: 99%

Consistent map building in petrochemical complexes for firefighter robots using SLAM based on GPS and LIDAR

et al. 2018

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“…The state vector is simplified to position, velocity and orientation (5D), assuming that optic gyro biases are negligible. With an analogous strategy to facilitate inertial calibration, in [30], GPS, INS and laser scanners are fused in urban environments, proposing the exploitation of complementary nature of GPS and laser scanner sensors in urban conditions (when GPS is occluded by buildings is when laser images become available). A Kalman filter estimates inertial error states using as observables the measurement domain of GPS and laser scanner (range-domain data fusion).…”

Section: Related Workmentioning

confidence: 99%

Context-Aided Sensor Fusion for Enhanced Urban Navigation

Martí

Martín

García

et al. 2012

Sensors

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The deployment of Intelligent Vehicles in urban environments requires reliable estimation of positioning for urban navigation. The inherent complexity of this kind of environments fosters the development of novel systems which should provide reliable and precise solutions to the vehicle. This article details an advanced GNSS/IMU fusion system based on a context-aided Unscented Kalman filter for navigation in urban conditions. The constrained non-linear filter is here conditioned by a contextual knowledge module which reasons about sensor quality and driving context in order to adapt it to the situation, while at the same time it carries out a continuous estimation and correction of INS drift errors. An exhaustive analysis has been carried out with available data in order to characterize the behavior of available sensors and take it into account in the developed solution. The performance is then analyzed with an extensive dataset containing representative situations. The proposed solution suits the use of fusion algorithms for deploying Intelligent Transport Systems in urban environments.

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“…Despite the improvement on accuracy obtained by a INSaided system, it does not comply with the reliability requirements for safety-critical applications. Alternative techniques such as dead reckoning [14], video-aided systems [15], laser scanner aided [16] or RFID technology [17] are also not suitable for the application considered in this paper.…”

Section: Related Workmentioning

confidence: 99%

GPS and Electronic Fence Data Fusion for Positioning within Railway Worksite Scenarios

Figueiras

Grønbæk

Ceccarelli

et al. 2012

2012 IEEE 14th International Symposium on High-Assurance Systems Engineering

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Context-dependent decisions in safety-critical applications require careful consideration of accuracy and timeliness of the underlying context information. Relevant examples include location-dependent actions in mobile distributed systems. This paper considers localization functions for personalized warning systems for railway workers, where the safety aspects require timely and precise identification whether a worker is located in a dangerous (red) or safe (green) zone within the worksite. The paper proposes and analyzes a data fusion approach based on low-cost GPS receivers integrated on mobile devices, combined with electronic fences strategically placed in the adjacent boundaries between safe and unsafe geographic zones. An approach based on the combination of a Kalman Filter for GPS-based trajectory estimation and a Hidden Markov Model for inclusion of mobility constraints and fusion with information from the electronic fences is developedand analyzed. Different accuracy metrics are proposed and the benefit obtained from the fusion with electronic fences is quantitatively analyzed in the scenarios of a single mobile entity: By having fence information, the correct zone estimation can increase by 30%, while false alarms can be reduced one order of magnitude in the tested scenario.

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Tight coupling of GPS, laser scanner, and inertial measurements for navigation in urban environments

Cited by 60 publications

References 7 publications

Consistent map building in petrochemical complexes for firefighter robots using SLAM based on GPS and LIDAR

Consistent map building in petrochemical complexes for firefighter robots using SLAM based on GPS and LIDAR

Context-Aided Sensor Fusion for Enhanced Urban Navigation

GPS and Electronic Fence Data Fusion for Positioning within Railway Worksite Scenarios

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