Design of inertial navigation systems for marine craft with adaptive wave filtering aided by triple‐redundant sensor packages

Bryne, Torleiv H.; Fossen, Thor I.; Johansen, Tor Arne

doi:10.1002/acs.2645

Cited by 14 publications

(9 citation statements)

References 33 publications

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“…Finally, in order to mitigate the interference signals, the frequencies obtained from the proposed CPHD filter are used to design the AMLKNF, which eliminates the multiple frequencies of GNSS interference in the received signal. The notch filter (especially, the second‐order infinite impulse response (IIR) notch filter) removes a specific frequency bandwidth and is widely used to cancel unnecessary frequencies in various fields . In order to improve tracking performance compared with the conventional notch filters, an interference frequency tracking and mitigation method using a linear Kalman notch filter (LKNF) is proposed to track and mitigate the GNSS interference signal.…”

Section: Introductionmentioning

confidence: 99%

Frequency tracking and mitigation method based on CPHD filter and adaptive multiple linear Kalman notch filter for multiple GNSS interference

2019

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In this paper, a frequency tracking method based on a cardinalized probability hypothesis density (CPHD) filter with cardinality compensation and fuzzy-c means (FCM) clustering is proposed to precisely estimate multiple interference frequencies in the received Global Navigation Satellite System (GNSS) signal. In addition, an adaptive multiple linear Kalman notch filter is applied in order to mitigate multiple GNSS interference signals by using tracking results from the proposed CPHD filter. The cardinality refers to the number of interference frequencies, and estimation accuracy on the cardinality has an effect on the tracking and mitigation performance of the filter. For that reason, the cardinality compensation process and FCM clustering are added in the CPHD filter.The proposed tracking and mitigation method is evaluated by theoretical analysis including simulations. It is confirmed that the proposed algorithm has better tracking and mitigation performance compared with the conventional algorithms.

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Section: Introductionmentioning

confidence: 99%

Frequency tracking and mitigation method based on CPHD filter and adaptive multiple linear Kalman notch filter for multiple GNSS interference

2019

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“…In addition, since specific force and angu- lar rate measurements are available, an INS can be sufficient as DP estimator, and vessel-model-based DP estimator is not necessary. This claim is supported by developments of INS-based wave filters [10], where wave filters are utilized to prevent the oscillatory wave-induced motions to be considered by the control system, [11].…”

Section: Proposed Sensor Configurationmentioning

confidence: 99%

“…While testifying the great effects and upsides the deployment of an INS may have, these references primarily suggest using one or two IMUs per position reference system for performance, and not fully integrate a redundant IMU solution in the DP system. [10] and [20] demonstrated the potential for using IMUs as a mean for fault detection and isolation in triple and dual position reference systems, and [21] for fault detection in the case of having a single position reference. Granted, INS based on MEMS might not be satisfactory as a separate position reference, as in the purported purpose of such systems.…”

Section: Dual Vs Triple-redundant Posrefs and Gyrocompassmentioning

confidence: 99%

Inertial Sensors for Risk-Based Redundancy in Dynamic Positioning

Bryne

Rogne

Fossen

et al. 2017

Volume 1: Offshore Technology

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In this paper we present an alternative configuration of sensors, position and heading reference systems for dynamically positioned (DP) vessels. The approach uses a sensor structure based on low-cost inertial measurements units (IMUs), satisfying fault tolerance against single-point failures that is at the essence of the IMO guidelines for both DP class 2 and 3 vessels. Recent results have shown that dual-redundant position and heading reference systems are sufficient to prevent loss of position within some well-defined time horizons by exploiting sensor fusion of the reference systems and triple-redundant MEMS-based IMUs. These IMUs also function as Vertical Reference Units (VRUs), since vessel motions is obtained using the same IMU configuration and sensor fusion framework. In this proposition, the acceleration measurements provided by the IMUs make wind and other force sensors unnecessary, except possibly for an advisory role. The proposed framework has the potential to significantly reduce the cost of dynamic positioning systems without compromising safety.

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“…Nonlinear observers that do not require knowledge of the vessel model have also been proposed for marine vessels operating in stationkeeping mode, often referred to as Dynamic Positioning (DP). Bryne, Fossen and Johansen performed wave filtering based on the Inertial Navigation System (INS) output [8], while Rogne et al used Inertial Measurement Unit (IMU) data for DR [9]. The difference being that the IMU provides the raw angular velocity and specific force measurements, while the INS integrates these measurements into a navigation solution in terms of a position, velocity and attitude.…”

Section: Introductionmentioning

confidence: 99%

Dead Reckoning of Dynamically Positioned Ships: Using an Efficient Recurrent Neural Network

Skulstad

Fossen

et al. 2019

IEEE Robot. Automat. Mag.

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When a ship experiences a loss of position reference systems, the ship's navigation system typically enters a mode known as dead reckoning to maintain an estimate of the position of the ship. Commercial systems perform this task using a state estimator that includes mathematical model knowledge. Such a model is non-trivial to derive and needs tuning if the dynamic properties of the vessel change. To this end we propose to use machine learning to estimate the horizontal velocity of the vessel without the help of position, velocity or acceleration sensors. A simulation study was conducted to show the ability to maintain position estimates during a Global Navigation Satellite System outage. Comparable performance is seen relative to the established Kalman Filter model-based approach.

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Design of inertial navigation systems for marine craft with adaptive wave filtering aided by triple‐redundant sensor packages

Cited by 14 publications

References 33 publications

Frequency tracking and mitigation method based on CPHD filter and adaptive multiple linear Kalman notch filter for multiple GNSS interference

Frequency tracking and mitigation method based on CPHD filter and adaptive multiple linear Kalman notch filter for multiple GNSS interference

Inertial Sensors for Risk-Based Redundancy in Dynamic Positioning

Dead Reckoning of Dynamically Positioned Ships: Using an Efficient Recurrent Neural Network

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