Your search keyword '"robust filtering"' showing total 632 results

1. Connectivity of high-frequency bursts as SOZ localization biomarker.

Author

Pinto-Orellana, Marco and Lopour, Beth

Subjects

BIOMARKERS, ELECTRODES, EPILEPSY, GABOR transforms, ELECTROENCEPHALOGRAPHY

Abstract

For patients with refractory epilepsy, the seizure onset zone (SOZ) plays an essential role in determining the specific regions of the brain that will be surgically resected. High-frequency oscillations (HFOs) and connectivity-based approaches have been identified among the potential biomarkers to localize the SOZ. However, there is no consensus on how connectivity between HFO events should be estimated, nor on its subject-specific short-term reliability. Therefore, we propose the channel-level connectivity dispersion (CLCD) as a metric to quantify the variability in synchronization between individual electrodes and to identify clusters of electrodes with abnormal synchronization, which we hypothesize to be associated with the SOZ. In addition, we developed a specialized filtering method that reduces oscillatory components caused by filtering broadband artifacts, such as sharp transients, spikes, or direct current shifts. Our connectivity estimates are therefore robust to the presence of these waveforms. To calculate our metric, we start by creating binary signals indicating the presence of high-frequency bursts in each channel, from which we calculate the pairwise connectivity between channels. Then, the CLCD is calculated by combining the connectivity matrices and measuring the variability in each electrode's combined connectivity values. We test our method using two independent open-access datasets comprising intracranial electroencephalography signals from 89 to 15 patients with refractory epilepsy, respectively. Recordings in these datasets were sampled at approximately 1000 Hz, and our proposed CLCDs were estimated in the ripple band (80-200 Hz). Across all patients in the first dataset, the average ROC-AUC was 0.73, and the average Cohen's d was 1.05, while in the second dataset, the average ROC-AUC was 0.78 and Cohen's d was 1.07. On average, SOZ channels had lower CLCD values than non-SOZ channels. Furthermore, based on the second dataset, which includes surgical outcomes (Engel I-IV), our analysis suggested that higher CLCD interquartile (as a measure of CLCD distribution spread) is associated with favorable outcomes (Engel I). This suggests that CLCD could significantly assist in identifying SOZ clusters and, therefore, provide an additional tool in surgical planning for epilepsy patients. [ABSTRACT FROM AUTHOR]

Published

2024

2. Robust error-state Kalman-type filters for attitude estimation

Author

Andrea Bellés, Daniel Medina, Paul Chauchat, Samy Labsir, and Jordi Vilà-Valls

Subjects

Attitude estimation, Quaternion estimation, GNSS, Error-state filters, Robust filtering, Robust statistics, Telecommunication, TK5101-6720, Electronics, TK7800-8360

Abstract

Abstract State estimation techniques appear in a plethora of engineering fields, in particular for the attitude estimation application of interest in this contribution. A number of filters have been devised for this problem, in particular Kalman-type ones, but in their standard form they are known to be fragile against outliers. In this work, we focus on error-state filters, designed for states living on a manifold, here unit-norm quaternions. We propose extensions based on robust statistics, leading to two robust M-type filters able to tackle outliers either in the measurements, in the system dynamics or in both cases. The performance and robustness of these filters is explored in a numerical experiment. We first assess the outlier ratio that they manage to mitigate, and second the type of dynamics outliers that they can detect, showing that the filter performance depends on the measurements’ properties.

Published

2024

3. Robust error-state Kalman-type filters for attitude estimation.

Author

Bellés, Andrea, Medina, Daniel, Chauchat, Paul, Labsir, Samy, and Vilà-Valls, Jordi

Subjects

ROBUST statistics, KALMAN filtering, QUATERNIONS, SYSTEM dynamics, GLOBAL Positioning System

Abstract

State estimation techniques appear in a plethora of engineering fields, in particular for the attitude estimation application of interest in this contribution. A number of filters have been devised for this problem, in particular Kalman-type ones, but in their standard form they are known to be fragile against outliers. In this work, we focus on error-state filters, designed for states living on a manifold, here unit-norm quaternions. We propose extensions based on robust statistics, leading to two robust M-type filters able to tackle outliers either in the measurements, in the system dynamics or in both cases. The performance and robustness of these filters is explored in a numerical experiment. We first assess the outlier ratio that they manage to mitigate, and second the type of dynamics outliers that they can detect, showing that the filter performance depends on the measurements' properties. [ABSTRACT FROM AUTHOR]

Published

2024

4. Robust State-Feedback Control and Convergence Analysis for Uncertain LPV Systems Using State and Parameter Estimation.

Author

Silva, Esdras Battosti da, Souza, Ruhan Pontes Policarpo de, Agulhari, Cristiano Marcos, Bressan, Glaucia Maria, and Souza, Wesley Angelino de

Subjects

*UNCERTAIN systems, *PARAMETER estimation, *ROBUST control, *LINEAR matrix inequalities, *KALMAN filtering, *DYNAMICAL systems

Abstract

This study introduces the design of a state-feedback controller for Linear Parameter Varying (LPV) systems in scenarios where exogenous parameters are not directly accessible, and the state vector is to be estimated. Instead of considering a static feedback gain, it proposes a method for estimating these parameters and synthesizing a parameter-dependent state-feedback gain that is robust against uncertainties in parameter estimation. The state vector used by the state-feedback controller, and some quantities required by the estimation law, are both obtained by a robust filter synthesized by LMI (Linear Matrix Inequalities). This paper outlines the estimation, filtering, and control laws, detailing the conditions necessary for ensuring convergence and stability. A numerical experiment and a 2 DoF torsional system application show the enhanced dynamic performance of the method when applied to uncertain dynamic systems. The findings highlight the effectiveness of the proposed approach in maintaining system stability and improving performance despite the inherent uncertainties in parameter estimation, offering a significant contribution to the field of robust control for LPV systems. [ABSTRACT FROM AUTHOR]

Published

2024

5. Connectivity of high-frequency bursts as SOZ localization biomarker

Author

Marco Pinto-Orellana and Beth Lopour

Subjects

seizure onset zone, intracranial EEG, connectivity, gabor transform, robust filtering, epilepsy, Electronic computers. Computer science, QA75.5-76.95

Abstract

For patients with refractory epilepsy, the seizure onset zone (SOZ) plays an essential role in determining the specific regions of the brain that will be surgically resected. High-frequency oscillations (HFOs) and connectivity-based approaches have been identified among the potential biomarkers to localize the SOZ. However, there is no consensus on how connectivity between HFO events should be estimated, nor on its subject-specific short-term reliability. Therefore, we propose the channel-level connectivity dispersion (CLCD) as a metric to quantify the variability in synchronization between individual electrodes and to identify clusters of electrodes with abnormal synchronization, which we hypothesize to be associated with the SOZ. In addition, we developed a specialized filtering method that reduces oscillatory components caused by filtering broadband artifacts, such as sharp transients, spikes, or direct current shifts. Our connectivity estimates are therefore robust to the presence of these waveforms. To calculate our metric, we start by creating binary signals indicating the presence of high-frequency bursts in each channel, from which we calculate the pairwise connectivity between channels. Then, the CLCD is calculated by combining the connectivity matrices and measuring the variability in each electrode’s combined connectivity values. We test our method using two independent open-access datasets comprising intracranial electroencephalography signals from 89 to 15 patients with refractory epilepsy, respectively. Recordings in these datasets were sampled at approximately 1000 Hz, and our proposed CLCDs were estimated in the ripple band (80–200 Hz). Across all patients in the first dataset, the average ROC-AUC was 0.73, and the average Cohen’s d was 1.05, while in the second dataset, the average ROC-AUC was 0.78 and Cohen’s d was 1.07. On average, SOZ channels had lower CLCD values than non-SOZ channels. Furthermore, based on the second dataset, which includes surgical outcomes (Engel I-IV), our analysis suggested that higher CLCD interquartile (as a measure of CLCD distribution spread) is associated with favorable outcomes (Engel I). This suggests that CLCD could significantly assist in identifying SOZ clusters and, therefore, provide an additional tool in surgical planning for epilepsy patients.

Published

2024

6. Huber-Based Robust Tracking Method of Hypersonic Cruise Vehicle

Author

Liu, Lili, Mu, Rongjun, Cui, Naigang, Chinese Society of Aeronautics and Astronautics, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, and Xu, Jinyang, Editorial Board Member

Published

2024

7. Enhanced Multiple Target Tracking Using a Generalized Multi-Target Smoothing Algorithm With Tracklet Association

Author

In Ho Lee and Chan Gook Park

Subjects

Multi-target track, data association, state estimation, trajectory smoothing, robust filtering, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Multiple Target Tracking (MTT) is an extensively researched field with significant importance and a wide range of applications. However, in challenging scenarios where the targets are closely spaced, and the complexity is high, many existing MTT methods often struggle to accurately distinguish and track individual targets. To address this issue, we propose an effective smoothing strategy. Our approach extends the Rauch-Tung-Striebel technique to handle multiple targets while also employing tracklet association techniques to manage dense multi-target scenarios. This strategy involves designing a smoothing multi-target distribution model using a Bayesian approach that utilizes both kinematic and identification information about multiple targets. It can be applied to all widely used MTT algorithms in the forward filtering step. The recursive smoothing algorithm we developed for the backward filtering step enhances inter-subject discrimination and improves track quality. Consequently, we achieve enhanced trajectories by integrating orbital correlation and smoothing techniques, especially when each trajectory is entangled with nearby objects. In this paper, we demonstrate a backward smoothing strategy tailored for a linear Gaussian model and present experimental results using infrared imaging that show improved tracking performance. Additionally, we illustrate its superiority over existing smoothing algorithms.

Published

2024

8. Estimation of the potential GDP by a new robust filter method.

Author

Gyurkovics, Éva and Takács, Tibor

Subjects

COVID-19 pandemic, GROSS domestic product, FINANCIAL crises, KALMAN filtering, DYNAMIC stability

Abstract

The first purpose of this paper is to propose a theoretically new robust filter method to estimate non-observable macroeconomic indicators. The second purpose is to apply the proposed method to estimate the Hungarian potential GDP in 2000–2021. The novelty of the proposed filter method is that — unlike papers published so far — it does not require the stability of the dynamic model, only a partial stability condition must be satisfied. Moreover, such time-dependent uncertainties and nonlinearities can arise in the model that satisfy a general quadratic constraint. An important advantage of the proposed robust filter method over the traditional Kalman filter is that no stochastic assumptions is needed that may not be valid for the problem at hand. The proposed filter method has never been applied to estimate the potential GDP. To estimate the Hungarian potential GDP, the proposed method is applied using uni-, bi- and trivariate models. Estimations up to 2021 has not been published yet for the Hungarian economy. The examined period includes both the financial world crisis and the Covid-19 crisis. The results of the different models are consistent. It turned out that the economic policy was very procyclical after 2012, and the GDP gap was still positive during and also after the Covid-19 crisis. [ABSTRACT FROM AUTHOR]

Published

2023

9. Robust State-Feedback Control and Convergence Analysis for Uncertain LPV Systems Using State and Parameter Estimation

Author

Esdras Battosti da Silva, Ruhan Pontes Policarpo de Souza, Cristiano Marcos Agulhari, Glaucia Maria Bressan, and Wesley Angelino de Souza

Subjects

LPV systems, parametric estimation, state-feedback control, linear matrix inequalities, robust filtering, estimation uncertainty, Mathematics, QA1-939

Abstract

This study introduces the design of a state-feedback controller for Linear Parameter Varying (LPV) systems in scenarios where exogenous parameters are not directly accessible, and the state vector is to be estimated. Instead of considering a static feedback gain, it proposes a method for estimating these parameters and synthesizing a parameter-dependent state-feedback gain that is robust against uncertainties in parameter estimation. The state vector used by the state-feedback controller, and some quantities required by the estimation law, are both obtained by a robust filter synthesized by LMI (Linear Matrix Inequalities). This paper outlines the estimation, filtering, and control laws, detailing the conditions necessary for ensuring convergence and stability. A numerical experiment and a 2 DoF torsional system application show the enhanced dynamic performance of the method when applied to uncertain dynamic systems. The findings highlight the effectiveness of the proposed approach in maintaining system stability and improving performance despite the inherent uncertainties in parameter estimation, offering a significant contribution to the field of robust control for LPV systems.

Published

2024

10. Unmanned ground vehicle‐unmanned aerial vehicle relative navigation robust adaptive localization algorithm

Author

Jun Dai, Songlin Liu, Hao Xiangyang, Zongbin Ren, Xiao Yang, and Yunzhu Lv

Subjects

adaptive filtering, relative navigation, robust filtering, unmanned aerial vehicles (UAV), unmanned ground vehicles (UGV), Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Abstract The unmanned aerial vehicle (UAV) and the unmanned ground vehicle (UGV) can complete complex tasks through information sharing and ensure the mission execution capability of multiple unmanned carrier platforms. At the same time, cooperative navigation can use the information interaction between multi‐platform sensors to improve the relative navigation and positioning accuracy of the entire system. Aiming at the problem of deviation of the system model due to gross errors in sensor measurement data or strong manoeuvrability in complex environments, a robust and adaptive UGV‐UAV relative navigation and positioning algorithm is proposed. In this paper, the relative navigation and positioning of UGV‐UAV is studied based on inertial measurement unit (IMU)/Vision. Based on analyzing the relative kinematics model and sensor measurement model, a leader (UGV)‐follow (UAV) relative navigation model is established. In the implementation of the relative navigation and positioning algorithm, the robust adaptive algorithm and the non‐linear Kalman filter (extended Kalman filter [EKF]) algorithm are combined to dynamically adjust the system state parameters. Finally, a mathematical simulation of the accompanying and landing process in the UGV‐UAV cooperative scene is carried out. The relative position, velocity and attitude errors calculated by EKF, Robust‐EKF and Robust‐Adaptive‐EKF algorithms are compared and analyzed by simulating two cases where the noise obeys the Gaussian distribution and the non‐Gaussian distribution. The results show that under the non‐Gaussian distribution conditions, the accuracy of the Robust‐Adaptive‐EKF algorithm is improved by about two to three times compared with the EKF and Robust‐EKF and can almost reach the relative navigation accuracy under the Gaussian distribution conditions. The robust self‐adaptive relative navigation and positioning algorithm proposed in this paper has strong adaptability to the uncertainty and deviation of system modelling in complex environments, with higher accuracy and stronger robustness.

Published

2023

11. Rotor Asymmetry Detection in Wound Rotor Induction Motor Using Kalman Filter Variants and Investigations on Their Robustness: An Experimental Implementation.

Author

John Basha, Furzana and Somasundaram, Kumar

Subjects

KALMAN filtering, INDUCTION motors, ROTORS, FALSE alarms, WOUNDS & injuries

Abstract

This paper analyzes the performance of Kalman filter-based estimators for robust filtering and rotor asymmetry detection in wound rotor induction machines (WRIMs) using real-time data. Filter models were designed based on an extended model of WRIMs. The detection of rotor asymmetry was achieved by estimating the states of rotor resistance and speed using four filters. The sensitivity of the parameters under healthy and asymmetry conditions was thoroughly analyzed and categorized as low, medium, and high sensitivity parameters. Robust model-based estimators were designed to minimize the probability of false alarms. The performance analysis demonstrated that the dual unscented Kalman filter (DUKF) outperformed other Kalman filters such as the extended Kalman filter (EKF), dual extended Kalman filter (DEKF), and unscented Kalman filter (UKF) for state estimation of WRIM. [ABSTRACT FROM AUTHOR]

Published

2023

12. Unmanned ground vehicle‐unmanned aerial vehicle relative navigation robust adaptive localization algorithm.

Author

Dai, Jun, Liu, Songlin, Xiangyang, Hao, Ren, Zongbin, Yang, Xiao, and Lv, Yunzhu

Subjects

*AERONAUTICAL navigation, *REMOTELY piloted vehicles, *RANDOM noise theory, *DRONE aircraft, *GAUSSIAN distribution, *KALMAN filtering, *MEASUREMENT errors

Abstract

The unmanned aerial vehicle (UAV) and the unmanned ground vehicle (UGV) can complete complex tasks through information sharing and ensure the mission execution capability of multiple unmanned carrier platforms. At the same time, cooperative navigation can use the information interaction between multi‐platform sensors to improve the relative navigation and positioning accuracy of the entire system. Aiming at the problem of deviation of the system model due to gross errors in sensor measurement data or strong manoeuvrability in complex environments, a robust and adaptive UGV‐UAV relative navigation and positioning algorithm is proposed. In this paper, the relative navigation and positioning of UGV‐UAV is studied based on inertial measurement unit (IMU)/Vision. Based on analyzing the relative kinematics model and sensor measurement model, a leader (UGV)‐follow (UAV) relative navigation model is established. In the implementation of the relative navigation and positioning algorithm, the robust adaptive algorithm and the non‐linear Kalman filter (extended Kalman filter [EKF]) algorithm are combined to dynamically adjust the system state parameters. Finally, a mathematical simulation of the accompanying and landing process in the UGV‐UAV cooperative scene is carried out. The relative position, velocity and attitude errors calculated by EKF, Robust‐EKF and Robust‐Adaptive‐EKF algorithms are compared and analyzed by simulating two cases where the noise obeys the Gaussian distribution and the non‐Gaussian distribution. The results show that under the non‐Gaussian distribution conditions, the accuracy of the Robust‐Adaptive‐EKF algorithm is improved by about two to three times compared with the EKF and Robust‐EKF and can almost reach the relative navigation accuracy under the Gaussian distribution conditions. The robust self‐adaptive relative navigation and positioning algorithm proposed in this paper has strong adaptability to the uncertainty and deviation of system modelling in complex environments, with higher accuracy and stronger robustness. [ABSTRACT FROM AUTHOR]

Published

2023

13. Improved robust filter synthesis combining linear matrix inequalities and heuristic algorithms.

Author

de Souza, Ruhan Pontes Policarpo, Agulhari, Cristiano Marcos, Goedtel, Alessandro, and Bugatti, Pedro Henrique

Subjects

HEURISTIC algorithms, MATRIX inequalities, OPTIMIZATION algorithms, LINEAR matrix inequalities, CONTINUOUS time systems, GENETIC algorithms

Abstract

This article introduces an alternative and less conservative ℋ∞$$ {\mathscr{H}}_{\infty } $$ filter design procedure applied to continuous time uncertain systems. In order to provide a reduction in conservatism and an ℋ∞$$ {\mathscr{H}}_{\infty } $$ norm improvement, the proposed technique avoids the conventional convexification procedure—which uses structure restrictions and slack variables. Instead, it defines an unconstrained structure. The proposed technique consists of a hybrid procedure, combining the application of linear matrix inequalities (LMIs) with heuristic optimization algorithms (HOAs). The HOAs, specifically genetic algorithms, are used to optimize terms that could cause bilinearities, subsequently evaluated by LMIs and generating the desired filter. Numerical examples and a comparison with other methodologies are presented, testifying to the proposed method's efficacy and the performance. [ABSTRACT FROM AUTHOR]

Published

2023

14. Robust linear quadratic regulator applied to an inverted pendulum.

Author

Escalante, Felix M., Jutinico, Andres L., Terra, Marco H., and Siqueira, Adriano A. G.

Subjects

PENDULUMS, DISCRETE-time systems, PROBLEM solving, ROBUST control

Abstract

The natural instability of an inverted pendulum and its dynamics richness, in terms of nonlinearity, provide a nice apparatus to reproduce behaviors of analogous systems. In this way, it is useful to perform benchmark tests for new control approaches developed. In this paper, we address the main inverted pendulum problems: pendulum stabilization, tracking, and catching swing‐up control. We show how robust recursive, control and filtering, techniques improve the system performance. They are developed to solve stochastic problems based on deterministic approaches, in order to decrease the worst influence of uncertainties. Experimental results of the proposed robust approach provide robust stability and performance despite parametric uncertainties, disturbances, and noise effects. [ABSTRACT FROM AUTHOR]

Published

2023

15. A robust score-driven filter for multivariate time series.

Author

D'Innocenzo, Enzo, Luati, Alessandra, and Mazzocchi, Mario

Subjects

*TIME series analysis, *ASYMPTOTIC normality, *DEGREES of freedom, *HOME prices, *CONSUMER price indexes, *SCANNING systems

Abstract

A multivariate score-driven filter is developed to extract signals from noisy vector processes. By assuming that the conditional location vector from a multivariate Student's t distribution changes over time, we construct a robust filter which is able to overcome several issues that naturally arise when modeling heavy-tailed phenomena and, more in general, vectors of dependent non-Gaussian time series. We derive conditions for stationarity and invertibility and estimate the unknown parameters by maximum likelihood. Strong consistency and asymptotic normality of the estimator are derived. Analytical formulae are derived which consent to develop estimation procedures based on a fast and reliable Fisher scoring method. An extensive Monte–Carlo study is designed to assess the finite samples properties of the estimator, the impact of initial conditions on the filtered sequence, the performance when some of the underlying assumptions are violated, such as symmetry of the underlying distribution and homogeneity of the degrees of freedom parameter across marginals. The theory is supported by a novel empirical illustration that shows how the model can be effectively applied to estimate consumer prices from home scanner data. [ABSTRACT FROM AUTHOR]

Published

2023

16. Score-Driven Modeling of Spatio-Temporal Data.

Author

Gasperoni, Francesca, Luati, Alessandra, Paci, Lucia, and D'Innocenzo, Enzo

Subjects

*FUNCTIONAL magnetic resonance imaging, *EXTREME value theory, *MAXIMUM likelihood statistics, *ASYMPTOTIC normality, *AUTOREGRESSIVE models

Abstract

A simultaneous autoregressive score-driven model with autoregressive disturbances is developed for spatio-temporal data that may exhibit heavy tails. The model specification rests on a signal plus noise decomposition of a spatially filtered process, where the signal can be approximated by a nonlinear function of the past variables and a set of explanatory variables, while the noise follows a multivariate Student-t distribution. The key feature of the model is that the dynamics of the space-time varying signal are driven by the score of the conditional likelihood function. When the distribution is heavy-tailed, the score provides a robust update of the space-time varying location. Consistency and asymptotic normality of maximum likelihood estimators are derived along with the stochastic properties of the model. The motivating application of the proposed model comes from brain scans recorded through functional magnetic resonance imaging when subjects are at rest and not expected to react to any controlled stimulus. We identify spontaneous activations in brain regions as extreme values of a possibly heavy-tailed distribution, by accounting for spatial and temporal dependence. [ABSTRACT FROM AUTHOR]

Published

2023

17. Improving the performance of GNSS precise point positioning by developed robust adaptive Kalman filter

Author

Ahmed Lotfy, Mohamed Abdelfatah, and Gamal El-Fiky

Subjects

PPP, Kalman Filter, Stochastic Model, Robust Filtering, Geodesy, QB275-343

Abstract

Global Navigation Satellite Systems (GNSS) Precise Point Positioning (PPP) is a great precision positioning method based on GNSS. PPP based on multi-constellation GNSS uses the extended Kalman filter (EKF). Inappropriately, the measurement outliers and the system's dynamic model might produce mistakes in the positioning accuracy acquired using this method. An adaptive robust Kalman filter (RKF) was recently developed in order to alleviate these errors. In addition, the preceding variance is sometimes used to determine the weights of different categories of observations, which has an effect on PPP performance. A novel developed robust adaptive filtering (DRKF) has been developed to provide better placement results. For the equivalent weight matrix to be generated, an equivalent weight model that is statistically robust by the chi-square test for classification is constructed in this technique. According to prior Kalman filter models employing International GNSS Service (IGS) final clock and orbit products, the performance of GNSS PPP using the DRKF is confirmed in contrast to those produced using the current model. DRKF surpasses traditional robust adaptive filters in terms of positioning accuracy, convergence time, and PPP sturdiness according to the results of this study. In comparison to RKF, DRKF improves the positioning solution by 201 mm with 119.10 %, 77 mm with 164.86 %, and 160 mm with 211.74 % in the east, north, and up (ENZ) directions, respectively. It is recommended to use the newly developed robust adaptive Kalman filter in kinematic mode, especially in urban areas, due to the noticeable improvement in position accuracy.

Published

2022

18. UWB Localization Based on Improved Robust Adaptive Cubature Kalman Filter.

Author

Dong, Jiaqi, Lian, Zengzeng, Xu, Jingcheng, and Yue, Zhe

Subjects

*ADAPTIVE filters, *REAL-time computing, *KALMAN filtering

Abstract

Aiming at the problems of Non-Line-of-Sight (NLOS) observation errors and inaccurate kinematic model in ultra-wideband (UWB) systems, this paper proposed an improved robust adaptive cubature Kalman filter (IRACKF). Robust and adaptive filtering can weaken the influence of observed outliers and kinematic model errors on filtering, respectively. However, their application conditions are different, and improper use may reduce positioning accuracy. Therefore, this paper designed a sliding window recognition scheme based on polynomial fitting, which can process the observation data in real-time to identify error types. Simulation and experimental results indicate that compared to the robust CKF, adaptive CKF, and robust adaptive CKF, the IRACKF algorithm reduces the position error by 38.0%, 45.1%, and 25.3%, respectively. The proposed IRACKF algorithm significantly improves the positioning accuracy and stability of the UWB system. [ABSTRACT FROM AUTHOR]

Published

2023

19. Improving the performance of GNSS precise point positioning by developed robust adaptive Kalman filter.

Author

Lotfy, Ahmed, Abdelfatah, Mohamed, and El-Fiky, Gamal

Abstract

Global Navigation Satellite Systems (GNSS) Precise Point Positioning (PPP) is a great precision positioning method based on GNSS. PPP based on multi-constellation GNSS uses the extended Kalman filter (EKF). Inappropriately, the measurement outliers and the system's dynamic model might produce mistakes in the positioning accuracy acquired using this method. An adaptive robust Kalman filter (RKF) was recently developed in order to alleviate these errors. In addition, the preceding variance is sometimes used to determine the weights of different categories of observations, which has an effect on PPP performance. A novel developed robust adaptive filtering (DRKF) has been developed to provide better placement results. For the equivalent weight matrix to be generated, an equivalent weight model that is statistically robust by the chi-square test for classification is constructed in this technique. According to prior Kalman filter models employing International GNSS Service (IGS) final clock and orbit products, the performance of GNSS PPP using the DRKF is confirmed in contrast to those produced using the current model. DRKF surpasses traditional robust adaptive filters in terms of positioning accuracy, convergence time, and PPP sturdiness according to the results of this study. In comparison to RKF, DRKF improves the positioning solution by 201 mm with 119.10 %, 77 mm with 164.86 %, and 160 mm with 211.74 % in the east, north, and up (ENZ) directions, respectively. It is recommended to use the newly developed robust adaptive Kalman filter in kinematic mode, especially in urban areas, due to the noticeable improvement in position accuracy. [ABSTRACT FROM AUTHOR]

Published

2022

20. Rotor Asymmetry Detection in Wound Rotor Induction Motor Using Kalman Filter Variants and Investigations on Their Robustness: An Experimental Implementation

Author

Furzana John Basha and Kumar Somasundaram

Subjects

wound rotor induction machine, rotor asymmetry detection, diagnosis, robust filtering, parameter sensitivity analysis, model-based approach, Mechanical engineering and machinery, TJ1-1570

Abstract

This paper analyzes the performance of Kalman filter-based estimators for robust filtering and rotor asymmetry detection in wound rotor induction machines (WRIMs) using real-time data. Filter models were designed based on an extended model of WRIMs. The detection of rotor asymmetry was achieved by estimating the states of rotor resistance and speed using four filters. The sensitivity of the parameters under healthy and asymmetry conditions was thoroughly analyzed and categorized as low, medium, and high sensitivity parameters. Robust model-based estimators were designed to minimize the probability of false alarms. The performance analysis demonstrated that the dual unscented Kalman filter (DUKF) outperformed other Kalman filters such as the extended Kalman filter (EKF), dual extended Kalman filter (DEKF), and unscented Kalman filter (UKF) for state estimation of WRIM.

Published

2023

21. A New Robust Filtering Method of GNSS/MINS Integrated System for Land Vehicle Navigation.

Author

Xu, Tongxu, Xu, Xiang, Xu, Dacheng, Zou, Zelan, and Zhao, Heming

Subjects

*GLOBAL Positioning System, *INTELLIGENT transportation systems, *AIR filters, *DYNAMIC positioning systems, *KALMAN filtering

Abstract

Combining a global navigation satellite system (GNSS) and microelectromechanical technology-based inertial system (MINS) has become essential in land vehicle navigation systems. In an urban environment, the error of position output by GNSS receiver increases because of the blocking and reflection of the signal by buildings, which affects the positioning accuracy of the integrated system. In order to improve the positioning accuracy under these scenarios, this paper proposed a new robust method based on the estimation of the standard deviation of GNSS positioning error. In our study, a method for estimating the standard deviation ${\boldsymbol{\sigma}}^p$ (or variance) of the position error of GNSS receiver is firstly proposed. Then a robust filtering method combined multi-factor scaling and bias estimation is proposed based on the estimation of ${\boldsymbol{\sigma}}^p$. The simulations and vehicle navigation test show that the proposed method has a robust positioning effect. When ${\boldsymbol{\sigma}}^p$ increases, the position accuracy is closed to the Sage-Husa filtering method with boundary constraint (SH-KF). Simulations also indicate that the proposed method has better robust effect than the traditional Kalman filter and SH-KF when a large bias error of position exists. [ABSTRACT FROM AUTHOR]

Published

2022

22. Sequential State and Unknown Parameter Estimation Strategy and its Application to a Sensor Fusion Problem.

Author

Patil, Prashant V., Vachhani, Leena, Ravitharan, Sivapragasam, and Chauhan, Sunita

Abstract

Soft-sensing and state-space-based methods play crucial roles in fault-tolerant sensor fusion schemes. Kalman filtering is one of the most employed sensor fusion methods. In practice, filtering (or state estimation) is sensitive to initial conditions, variations in model parameters, and faults in sensors and actuators. Cumulatively, these uncertainties that affect the state estimator can be modeled as unknown parameters. In this article, we present the development of a discrete-time minimum variance unbiased estimator (MVUE) that is robust to a class of unknown parameters. The estimation gain of MVUE is designed to facilitate unbiased state estimates in the presence of unknown parameters. We then use the innovations that are generated by the proposed state estimator (MVUE) to estimate the unknown parameters, thus proposing a sequential state and unknown parameter estimation strategy. The development of the decoupled state and unknown parameter estimation strategy is motivated by the fault-tolerant sensor fusion exercise for railway track geometry inspection. This exercise aims to formulate the state-space realization of the track geometry inspection problem to enable sequential state and unknown parameter estimation. The track geometry parameters, initial conditions, and sensor faults are considered unknown parameters for the application. The simulation analysis shows the importance of developing the trinity of the state-space realization for track geometry inspection, the state estimation framework, and the decoupled unknown parameter estimator. [ABSTRACT FROM AUTHOR]

Published

2022

23. Strain‐based joint damage estimation approach robust to unknown non‐stationary input force.

Author

Aswal, Neha, Sen, Subhamoy, and Mevel, Laurent

Subjects

*KALMAN filtering, *CYCLIC loads, *STEEL framing, *STRUCTURAL health monitoring, *FLOOD damage

Abstract

Summary: To avert catastrophic failure in the structures, joints are typically designed to yield, but not fail, so that energy accumulated under cyclic loading is dissipated. Eventually, this renders the structural joints to be characteristically weaker and more vulnerable than the members. Yet, damage detection research mostly assumes damage in the members only. This article proposes a model‐based predictor–corrector algorithm that uses an interacting filtering approach to efficiently estimate joint damage in the presence of input and measurement uncertainties. For the predictor model, a novel strain‐displacement relationship specific to semi‐rigid frames is developed to map nodal displacements to corresponding strain measurements. The proposed estimation method embeds robustness against non‐stationary input (e.g., seismic excitation) in the state filter, itself. For this, an output injection technique is integrated within the state filter. The modified state filter (robust Kalman filter) runs within an enveloping parameter filter (particle filter) to simultaneously estimate the system states and joint damage parameters, respectively, using the response signal. Strain has been adopted as measurement since it is frame independent (beneficial for seismic activity) and also comparatively cheaper to use. Numerical studies are performed on a two‐dimensional (2‐D) three‐story three‐bay shear frame for different joint damage locations and severities. The sensitivity and the stability of the proposed approach are further investigated. Experimental validation of the proposed algorithm is carried out on a 2‐D steel frame. [ABSTRACT FROM AUTHOR]

Published

2022

24. Retarded state-multiplicative stochastic systems - Robust H∞ and H2 vertex-dependent filtering.

Author

Gershon, Eli and Shaked, Uri

Subjects

*KALMAN filtering, *STOCHASTIC systems, *LINEAR orderings, *AEROSPACE engineers, *AEROSPACE engineering, *LYAPUNOV functions

Abstract

We consider linear continuous-time retarded systems with multiplicative noise and polytopic type parameter uncertainty and we address the problems of H ∞ and H 2 general filtering of these systems. These problems are solved by applying a modified version of the descriptor method that leads to a considerable reduction in the over-design associated with the "quadratic" solution that assigns a single Lyapunov function to all the points in the uncertainty polytope. The theory is extended to the robust gain-scheduling case where on-line parameter measurement is exercised in the estimation process. Two examples are given that demonstrate the superiority of our solution method. The first example relates to a simple second order system whereas the second example is one of altitude estimation taken from the field of aerospace engineering. [ABSTRACT FROM AUTHOR]

Published

2022

25. Multi-Layer Fault-Tolerant Robust Filter for Integrated Navigation in Launch Inertial Coordinate System.

Author

Kang, Jun, Xiong, Zhi, Wang, Rong, and Zhang, Ling

Subjects

LAUNCH vehicles (Astronautics), NAVIGATION, FAULT tolerance (Engineering), EQUATIONS of state

Abstract

As to an aerospace vehicle, the flight span is large and the flight environment is complex. More than that, the existing navigation algorithms cannot meet the needs to provide accurate navigation parameters for aerospace vehicles, which results in the decline of navigation accuracy. This paper proposes a multi-layer, fault-tolerant robust filtering algorithm of aerospace vehicle in the launch inertial coordinate system to address this problem. Firstly, the launch inertial coordinate system is used as the reference coordinate system for navigation calculation, and the state equation and measurement equation of the navigation system are established in this coordinate system to improve the modeling accuracy of the navigation system. On this basis, a multi-layer, fault-tolerant robust filtering algorithm is designed to estimate and compensate the unknown input in the state equation in real time and adjust the noise variance matrix in the measurement equation adaptively. Simulation results show that the errors about the integrated navigation system output parameters are reduced, through this algorithm, which improves the attitude, velocity and position estimation accuracy of the integrated navigation system. In addition, the algorithm enhances the fault tolerance and robustness of the filtering algorithm. [ABSTRACT FROM AUTHOR]

Published

2022

26. Consensus-based robust least-squares filter for multi-sensor systems.

Author

Roshan, Soheila Amiri and Rahmani, Mehdi

Abstract

In this article, a consensus-based robust regularized least-squares filter is designed for multi-sensor systems with norm-bounded uncertainties. In this approach, a min-max optimization problem is presented based on a consensus protocol on estimates. The advantage of a consensus filter is that each node estimates its local states, in addition to reaching an agreement on estimatesmade by all sensors on the network. By introducing appropriate conversions the proposed optimization problem is converted to a robust regularized least-squares problem. Solving this problem results in the structure of the proposed filter. Then, the recursive formulation of the filter is obtained in measurement form and information form. Finally, in order to investigate the efficacy, good proficiency, and robustness of the proposed consensus-based robust least-squares filter, it has been applied to an uncertain multi-sensor system with 100 nodes and its results have been compared with existing consensus filters. [ABSTRACT FROM AUTHOR]

Published

2022

27. Robust Two-Stage Filtering for INS/Gravity Matching Passive Integrated Navigation Systems.

Author

Luo, Kaixin, Cai, Shaokun, Yu, Ruihang, Cao, Juliang, and Guo, Yan

Abstract

With the expansion of the exploration scope of underwater vehicles and the improvement of their safety requirements, integrated navigation under passive conditions has become a hot topic in the field of navigation. Due to the stability and detectability of the Earth’s gravity field, the use of a matching result for external correction of inertial navigation systems (INSs) can be effective. For practical navigation applications, an inertial gravity matching integrated navigation algorithm must be designed for real-time applicability, diversified output information capability, and anti-interference capability. In this paper, an INS/gravity matching (INS-GM) integrated navigation algorithm is improved to extract the information of gravity fields in real time and correct the navigation results, and a robust integrated algorithm is proposed. Through two-hierarchy filtering, correction of the gravity field to the carrier position and of the integrated navigation system is obtained. According to the first-hierarchy filtering noise characteristics of gravity matching, the robustness of the algorithm to a complex environment is improved by second-hierarchy filtering. The ocean experiment data processing results show that the algorithm can effectively handle a certain degree of initial error, and an integrated navigation accuracy of 205 m is achieved in a good experimental environment. In the case of severe test conditions, the accuracy of the robust integrated navigation algorithm is 72% higher than that of the ordinary navigation algorithm, and it has a strong anti-jamming ability, which can meet the requirements of marine inertial gravity matching integrated navigation tasks. [ABSTRACT FROM AUTHOR]

Published

2022

28. Nonlinear Spline Adaptive Filtering Against Non-Gaussian Noise.

Author

Guo, Wenyan and Zhi, Yongfeng

Subjects

*ADAPTIVE filters, *SYSTEM identification, *NONLINEAR systems, *SPLINES

Abstract

In this paper, a generalized maximum Versoria criterion algorithm (GMVC) based on wiener spline adaptive filter, called SAF–GMVC, is proposed. The proposed algorithm is used for nonlinear system identification under non-Gaussian environment. To improve the convergence performance of the SAF–GMVC, the momentum stochastic gradient descent (MSGD) is introduced. In order to further reduce the steady-state error, the variable step-size algorithm is introduced, called as SAF–GMVC–VMSGD. Simulation results demonstrate that SAF–GMVC–VMSGD achieves better filtering effective against non-Gaussian noise. [ABSTRACT FROM AUTHOR]

Published

2022

29. Innovative and Additive Outlier Robust Kalman Filtering With a Robust Particle Filter.

Author

Fisch, Alexander T. M., Eckley, Idris A., and Fearnhead, Paul

Subjects

*TIME series analysis

Abstract

In this paper, we propose CE-BASS, a particle mixture Kalman filter which is robust to both innovative and additive outliers, and able to fully capture multi-modality in the distribution of the hidden state. Furthermore, the particle sampling approach re-samples past states, which enables CE-BASS to handle innovative outliers which are not immediately visible in the observations, such as trend changes. The filter is computationally efficient as we derive new, accurate approximations to the optimal proposal distributions for the particles. The proposed algorithm is shown to compare well with existing approaches and is applied to both machine temperature and server data. [ABSTRACT FROM AUTHOR]

Published

2022

30. An MFV-based image processing filter and its application to seismic tomographic images.

Author

Dobróka, Tünde Edit

Subjects

*TOMOGRAPHY, *IMAGING systems in seismology, *IMAGE processing, *LIGHT filters, *SEISMIC tomography, *SEISMOLOGY

Abstract

In the tomographic reconstruction of seismic travel time data, care must be taken to keep the propagation of data errors to the model space under control. The non-Gaussian noise distribution—especially the outliers in the data sets- can cause appreciable distortions in the tomographic imaging. To reduce the noise sensitivity well-developed tomography algorithms can be used. On the other hand, the quality of the tomogram can further be improved by using image processing tools. In the paper, a newly developed robust filter is presented, in which the Most Frequent Value (MFV) method developed by Steiner is applied. To analyze the noise reduction capability of the new filter (called Steiner-filter) and to compare it to smoothing filters based on arithmetic- and binomial mean, as well as median, medium-sized tomographic images are used. The MFV-based filter is successfully tested also in edge detection procedures. [ABSTRACT FROM AUTHOR]

Published

2021

31. UWB Localization Based on Improved Robust Adaptive Cubature Kalman Filter

Author

Jiaqi Dong, Zengzeng Lian, Jingcheng Xu, and Zhe Yue

Subjects

ultra-wideband, NLOS signal, robust filtering, adaptive filtering, Chemical technology, TP1-1185

Abstract

Aiming at the problems of Non-Line-of-Sight (NLOS) observation errors and inaccurate kinematic model in ultra-wideband (UWB) systems, this paper proposed an improved robust adaptive cubature Kalman filter (IRACKF). Robust and adaptive filtering can weaken the influence of observed outliers and kinematic model errors on filtering, respectively. However, their application conditions are different, and improper use may reduce positioning accuracy. Therefore, this paper designed a sliding window recognition scheme based on polynomial fitting, which can process the observation data in real-time to identify error types. Simulation and experimental results indicate that compared to the robust CKF, adaptive CKF, and robust adaptive CKF, the IRACKF algorithm reduces the position error by 38.0%, 45.1%, and 25.3%, respectively. The proposed IRACKF algorithm significantly improves the positioning accuracy and stability of the UWB system.

Published

2023

32. Real-time GNSS precise point positioning using improved robust adaptive Kalman filter.

Author

Elmezayen, Abdelsatar and El-Rabbany, Ahmed

Subjects

*KALMAN filtering, *ADAPTIVE filters, *MEASUREMENT errors, *OUTLIER detection, *DYNAMIC models, *GLOBAL Positioning System

Abstract

Multi-constellation GNSS precise point positioning (PPP) typically uses the extended Kalman filter (EKF) for kinematic applications. Unfortunately, the obtained positioning accuracy in this approach is prone to errors caused by measurement outliers and the system's dynamic model. An adaptive robust Kalman filter (RKF) was recently developed to mitigate these errors. However, RKF uses empirical values as detection thresholds for the outliers, which requires the measurements to be from the same constellation and of equal precision to obtain an optimal PPP solution. The classification robust adaptive Kalman filter (CAKF) has subsequently been developed to deal with measurements of different precisions, namely pseudorange and carrier-phase measurements. This paper proposes a real-time GPS/Galileo PPP system, which employs a modified version of CAKF called the Improved Robust adaptive Kalman Filter (IRKF). The positioning performance of GPS/Galileo PPP through the IRKF is initially verified in comparison with those obtained through the EKF, RKF, and CAKF using the Centre for Orbit Determination in Europe (CODE) final orbit and clock products in both of static and kinematic modes. The real-time GPS/Galileo PPP solution through the IRKF is then assessed in comparison with its near-real-time counterpart. The results indicate that when the IRKF approach is utilised, the positioning accuracy is significantly improved and the convergence behaviour is enhanced compared with results from EKF, conventional RKF, and CAKF. In the real-time mode, centimeter-level horizontal positioning accuracy is achieved under an open sky environment, while decimeter-level horizontal positioning accuracy is achieved under a challenging environment. On the other hand, decimeter-level accuracy is achieved for the vertical positioning component under all environmental scenarios. Moreover, the positioning accuracy of the real-time solution is comparable to the near-real-time counterpart. [ABSTRACT FROM AUTHOR]

Published

2021

33. Redundant Adaptive Robust Tracking for Active Satellite

Author

Jing, Zhongliang, Pan, Han, Li, Yuankai, Dong, Peng, Leung, Henry, Series Editor, Jing, Zhongliang, Pan, Han, Li, Yuankai, and Dong, Peng

Published

2018

34. Robust Methods for Detecting Spontaneous Activations in fMRI Data

Author

Gasperoni, Francesca, Luati, Alessandra, Canale, Antonio, editor, Durante, Daniele, editor, Paci, Lucia, editor, and Scarpa, Bruno, editor

Published

2018

35. Robust Parametric Identification Procedure for Stochastic Nonlinear Continuous-Discrete Systems.

Author

Chubich, V. M. and Kulabukhova, S. O.

Abstract

Basing on the weighted maximum likelihood method and the correntropy cubature Kalman filter, we develop some software for solving the problem of parametric estimation of the models for the stochastic nonlinear continuous-discrete systems in presence of anomalous observations in measurement data. The effectiveness of the proposed procedure is demonstrated by two model structures for the stochastic and the grouped nature of anomalous data location. [ABSTRACT FROM AUTHOR]

Published

2021

36. Robust Kalman filter for fractional order systems with uncertain colored noise variance.

Author

Wang, Guanran and Sun, Xiaojun

Abstract

For fractional order systems with colored process noise, the discretization fractional order system model is used to construct the augmented vector defined by the state vector and colored process noise vector. Based on the augmented equation of fractional order systems, the robust local Kalman filtering algorithm for fractional order systems with colored process noise is derived. The matrix weighted fusion, weighted measurement fusion and centralized fusion methods were used to fuse and estimate the state of multi-sensor fractional order system. Simulation results show the effectiveness of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2024

37. In Between the - and -Control Theories.

Author

Kurdyukov, A. P., Andrianova, O. G., Belov, A. A., and Gol'din, D. A.

Subjects

*CONTROL theory (Engineering), *INFORMATION theory, *DESCRIPTOR systems, *ROBUST control, *LINEAR systems

Abstract

In this survey, we discuss various approaches to control theory that have arisen in the recent decades and reflect the desire to reach a trade-off between the -control theory and the -control theory. The theories of the kind include the theory of risk-sensitive controllers, the theory of suboptimal control with a constraint on the -entropy functional, the mixed -control theory, the minimax -control theory, the anisotropy-based theory, and some others. The survey discusses in more detail the anisotropy-based control theory, which includes both the - and the -theory within a single statement of the problem. [ABSTRACT FROM AUTHOR]

Published

2021

38. Robust Filtering for 2-D Discrete-Time Switched Systems.

Author

Ren, Wei and Xiong, Junlin

Subjects

*DISCRETE-time systems, *DISCRETE time filters, *WATER filtration, *LYAPUNOV functions, *SYMMETRIC matrices

Abstract

In this article, we study the robust filtering problem for 2-D switched systems with convex-bounded uncertainties. The studied switched system is formulated by Fornasini–Marchesini local state-space model, and system matrices depend affinely on convex-bounded uncertain parameters. We first derive synthesis results for 2-D switched systems, which extends the existing results and lays a foundation for the robust filter design. To design the robust filter, we transform the 2-D switched system into an equivalent difference-algebraic representation form. Using the equivalent representation and the parameter-dependent Lyapunov function approach, sufficient conditions are established for system stability, and 2-D stationary discrete-time linear filters are designed to ensure the prescribed $\mathcal {H}_{\infty }$ or $\mathcal {H}_{2}$ performance for all admissible uncertain parameters. Finally, a numerical example is presented to illustrate the obtained results. [ABSTRACT FROM AUTHOR]

Published

2021

39. Multi-Layer Fault-Tolerant Robust Filter for Integrated Navigation in Launch Inertial Coordinate System

Author

Jun Kang, Zhi Xiong, Rong Wang, and Ling Zhang

Subjects

aerospace vehicle, launch inertial coordinate system, fault-tolerant, robust filtering, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

As to an aerospace vehicle, the flight span is large and the flight environment is complex. More than that, the existing navigation algorithms cannot meet the needs to provide accurate navigation parameters for aerospace vehicles, which results in the decline of navigation accuracy. This paper proposes a multi-layer, fault-tolerant robust filtering algorithm of aerospace vehicle in the launch inertial coordinate system to address this problem. Firstly, the launch inertial coordinate system is used as the reference coordinate system for navigation calculation, and the state equation and measurement equation of the navigation system are established in this coordinate system to improve the modeling accuracy of the navigation system. On this basis, a multi-layer, fault-tolerant robust filtering algorithm is designed to estimate and compensate the unknown input in the state equation in real time and adjust the noise variance matrix in the measurement equation adaptively. Simulation results show that the errors about the integrated navigation system output parameters are reduced, through this algorithm, which improves the attitude, velocity and position estimation accuracy of the integrated navigation system. In addition, the algorithm enhances the fault tolerance and robustness of the filtering algorithm.

Published

2022

40. Robust linearly constrained extended Kalman filter for mismatched nonlinear systems.

Author

Hrustic, Emir, Ben Abdallah, Rayen, Vilà‐Valls, Jordi, Vivet, Damien, Pagès, Gaël, and Chaumette, Eric

Subjects

*NONLINEAR systems, *PARAMETRIC modeling, *FILTERS & filtration, *KALMAN filtering, *PLANCK (Artificial satellite)

Abstract

Summary: Standard state estimation techniques, ranging from the linear Kalman filter (KF) to nonlinear extended KF (EKF), sigma‐point or particle filters, assume a perfectly known system model, that is, process and measurement functions and system noise statistics (both the distribution and its parameters). This is a strong assumption which may not hold in practice, reason why several approaches have been proposed for robust filtering, mainly because the filter performance is particularly sensitive to different model mismatches. In the context of linear filtering, a solution to cope with possible system matrices mismatch is to use linear constraints. In this contribution we further explore the extension and use of recent results on linearly constrained KF for robust nonlinear filtering under both process and measurement model mismatch. We first investigate how linear equality constraints can be incorporated within the EKF and derive a new linearly constrained extended KF (LCEKF). Then we detail its use to mitigate parametric modeling errors in the nonlinear process and measurement functions. Numerical results are provided to show the performance improvement of the new LCEKF for robust vehicle navigation. [ABSTRACT FROM AUTHOR]

Published

2021

41. Robust Variational-Based Kalman Filter for Outlier Rejection With Correlated Measurements.

Author

Li, Haoqing, Medina, Daniel, Vila-Valls, Jordi, and Closas, Pau

Subjects

*KALMAN filtering, *UNCERTAIN systems, *STATE-space methods, *NOISE measurement, *TASK analysis, *PSYCHOLOGICAL adaptation, *MEASUREMENT

Abstract

State estimation is a fundamental task in many engineering fields, and therefore robust nonlinear filtering techniques able to cope with misspecified, uncertain and/or corrupted models must be designed for real-life applicability. In this contribution we explore nonlinear Gaussian filtering problems where measurements may be corrupted by outliers, and propose a new robust variational-based filtering methodology able to detect and mitigate their impact. This method generalizes previous contributions to the case of multiple outlier indicators for both independent and dependent observation models. An illustrative example is provided to support the discussion and show the performance improvement. [ABSTRACT FROM AUTHOR]

Published

2021

42. Vision-based relative navigation using cubature Huber-based filtering

Author

Chen, Cheng, Wang, Xiaogang, Qin, Wutao, and Cui, Naigang

Published

2018

43. Beta–negative binomial auto‐regressions for modelling integer‐valued time series with extreme observations.

Author

Gorgi, Paolo

Subjects

TIME series analysis, NEGATIVE binomial distribution, BINOMIAL distribution, ASYMPTOTIC normality, DRUG traffic, CONDITIONAL expectations, LINEAR equations

Abstract

Summary: The paper introduces a general class of heavy‐tailed auto‐regressions for modelling integer‐valued time series with outliers. The specification proposed is based on a heavy‐tailed mixture of negative binomial distributions that features an observation‐driven dynamic equation for the conditional expectation. The existence of a stationary and ergodic solution for the class of auto‐regressive processes is shown under general conditions. The estimation of the model can be easily performed by maximum likelihood given the closed form of the likelihood function. The strong consistency and the asymptotic normality of the estimator are formally derived. Two examples of specifications illustrate the flexibility of the approach and the relevance of the theoretical results. In particular, a linear dynamic equation and a score‐driven equation for the conditional expectation are studied. The score‐driven specification is shown to be particularly appealing as it delivers a robust filtering method that attenuates the effect of outliers. Empirical applications to the series of narcotics trafficking reports in Sydney and the euro–pound sterling exchange rate illustrate the effectiveness of the method in handling extreme observations. [ABSTRACT FROM AUTHOR]

Published

2020

44. A Bayesian robust Kalman smoothing framework for state-space models with uncertain noise statistics

Author

Roozbeh Dehghannasiri, Xiaoning Qian, and Edward R. Dougherty

Subjects

Kalman smoother, Robust filtering, Bayesian robustness, Innovation process, Orthogonality principle, Telecommunication, TK5101-6720, Electronics, TK7800-8360

Abstract

Abstract The classical Kalman smoother recursively estimates states over a finite time window using all observations in the window. In this paper, we assume that the parameters characterizing the second-order statistics of process and observation noise are unknown and propose an optimal Bayesian Kalman smoother (OBKS) to obtain smoothed estimates that are optimal relative to the posterior distribution of the unknown noise parameters. The method uses a Bayesian innovation process and a posterior-based Bayesian orthogonality principle. The optimal Bayesian Kalman smoother possesses the same forward-backward structure as that of the ordinary Kalman smoother with the ordinary noise statistics replaced by their effective counterparts. In the first step, the posterior effective noise statistics are computed. Then, using the obtained effective noise statistics, the optimal Bayesian Kalman filter is run in the forward direction over the window of observations. The Bayesian smoothed estimates are obtained in the backward step. We validate the performance of the proposed robust smoother in the target tracking and gene regulatory network inference problems.

Published

2018

45. Vertex‐dependent filtering of retarded uncertain state‐multiplicative noisy systems.

Author

Gershon, E. and Shaked, U.

Subjects

*MINIMUM variance estimation, *LINEAR matrix inequalities, *DISCRETE-time systems, *COST functions, *MONEY

Abstract

Summary: The problem of robust H∞ estimation of stochastic, state‐delayed, uncertain, linear, discrete‐time systems is solved by applying a vertex dependent Lyapunov function. In this problem, a cost function is defined, which is the expected value of the standard H∞ performance index with respect to the uncertain parameters. The optimal estimator is obtained by solving a simple set of linear matrix inequalities (LMIs) for either the case where the filter matrices are constant or for the case where these matrices are gain scheduled. The solutions to the corresponding minimum error variance estimation problems are also obtained for the nominal and the uncertain cases, where an additional set of conditions is introduced that guarantees the minimization of the estimation error variance. Two examples are given. The first is a numerical example that demonstrates the advantage of the new design method. The second is an example of a practical nature that is taken from the field of guidance control and estimation. [ABSTRACT FROM AUTHOR]

Published

2020

46. Robust Estimation Based on the Least Absolute Deviations Method and the Kalman Filter.

Author

Miller, B. M. and Kolosov, K. S.

Subjects

*KALMAN filtering, *ADAPTIVE filters, *ALGORITHMS, *LINEAR systems, *SYSTEM dynamics, *TRACKING algorithms

Abstract

We propose a new approach for solving the filtering problem in linear systems based on incomplete measurements, where the characteristics of the dynamic noise are not known exactly, and measurements may contain anomalous non-Gaussian errors. The proposed algorithm is based on the idea of using the adaptive Kalman filter and the generalized least absolute deviations method jointly. With numerical modeling, we show that, compared to the classical optimal linear filtering method, our solution has lower sensitivity to short-term outliers in measurements and provides a quick adjustment of the parameters of the system dynamics. The proposed algorithm can be used to solve onboard navigation and tracking problems on aircrafts. To implement the method of least absolute deviations, we use an efficient L1-optimization algorithm. [ABSTRACT FROM AUTHOR]

Published

2020

47. Nudging the particle filter.

Author

Akyildiz, Ömer Deniz and Míguez, Joaquín

Abstract

We investigate a new sampling scheme aimed at improving the performance of particle filters whenever (a) there is a significant mismatch between the assumed model dynamics and the actual system, or (b) the posterior probability tends to concentrate in relatively small regions of the state space. The proposed scheme pushes some particles toward specific regions where the likelihood is expected to be high, an operation known as nudging in the geophysics literature. We reinterpret nudging in a form applicable to any particle filtering scheme, as it does not involve any changes in the rest of the algorithm. Since the particles are modified, but the importance weights do not account for this modification, the use of nudging leads to additional bias in the resulting estimators. However, we prove analytically that nudged particle filters can still attain asymptotic convergence with the same error rates as conventional particle methods. Simple analysis also yields an alternative interpretation of the nudging operation that explains its robustness to model errors. Finally, we show numerical results that illustrate the improvements that can be attained using the proposed scheme. In particular, we present nonlinear tracking examples with synthetic data and a model inference example using real-world financial data. [ABSTRACT FROM AUTHOR]

Published

2020

48. 基于最大熵方法的鲁棒自适应滤波及其应用.

Author

罗凯鑫, 吴美平, and 范颖

Subjects

BURST noise, NOISE measurement, ADAPTIVE filters, DISTRIBUTION (Probability theory), ENTROPY (Information theory), KALMAN filtering, MAXIMUM entropy method

Abstract

Copyright of Systems Engineering & Electronics is the property of Journal of Systems Engineering & Electronics Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

49. Robust H2 and H∞ Filter Design for Continuous‐time Uncertain Linear Fractional Transformation Systems via LMI.

Author

Aeinfar, Vahid, Askari, Javad, and Sadeghzadeh, Arash

Subjects

UNCERTAIN systems, CONTINUOUS-time filters, LINEAR systems, LINEAR matrix inequalities

Abstract

This paper considers the problem of robust H2 and H∞ filter design for uncertain continuous‐time linear systems. Linear fractional transformation (LFT) representation is considered for the uncertainty modeling and by definition of large number of slack variables, extra free dimensions are provided to the H2 and H∞ filter design optimization problem, so method presented in this paper expected to be less conservative than the existing methods for the polytopic uncertain systems and its efficiency for filter design is illustrated by means of numerical comparisons with some benchmark examples from the literature. [ABSTRACT FROM AUTHOR]

Published

2020

50. Robust Filtering for Discrete Systems with Unknown Inputs and Jump Parameters.

Author

Kim, K. S. and Smagin, V. I.

Abstract

The paper deals with robust filtering algorithms for discrete systems with unknown inputs (disturbances) and Markovian jump parameter. The proposed filtering algorithm is based on the separation principle, minimization of a quadratic criterion and the use of Kalman filters with unknown input and smoothing procedures. Solving a non-stationary problem is represented solving a two-point boundary value problem in kind of difference matrix equations. In the stationary case problem is represented matrix algebraic equations. Robustness ensures the stability of the filter dynamics when errors occur in identifying the jump parameter. An example is provided to illustrate the proposed approach, which showed that the use of smoothing procedures for estimating an unknown input improves the accuracy of estimates. [ABSTRACT FROM AUTHOR]

Published

2020