Your search keyword '"Schon, Thomas B."' showing total 4 results

1. Quantifying the Uncertainty of the Relative Geometry in Inertial Sensors Arrays.

Author

Carlsson, Hakan, Skog, Isaac, Schon, Thomas B., and Jalden, Joakim

Abstract

We present an algorithm to estimate and quantify the uncertainty of the accelerometers’ relative geometry in an inertial sensor array. We formulate the calibration problem as a Bayesian estimation problem and propose an algorithm that samples the accelerometer positions’ posterior distribution using Markov chain Monte Carlo. By identifying linear substructures of the measurement model, the unknown linear motion parameters are analytically marginalized, and the remaining non-linear motion parameters are numerically marginalized. The numerical marginalization occurs in a low dimensional space where the gyroscopes give information about the motion. This combination of information from gyroscopes and analytical marginalization allows the user to make no assumptions of the motion before the calibration. It thus enables the user to estimate the accelerometer positions’ relative geometry by simply exposing the array to arbitrary twisting motion. We show that the calibration algorithm gives good results on both simulated and experimental data, despite sampling a high dimensional space. [ABSTRACT FROM AUTHOR]

Published

2021

2. A Fast and Robust Algorithm for Orientation Estimation Using Inertial Sensors.

Author

Kok, Manon and Schon, Thomas B.

Subjects

MONTE Carlo method, MAGNETOMETERS, FASTING, ONLINE algorithms, ALGORITHMS, DETECTORS, COMPUTATIONAL complexity, MAGNETIC fields

Abstract

We present a novel algorithm for online, real-time orientation estimation. Our algorithm integrates gyroscope data and corrects the resulting orientation estimate for integration drift using accelerometer and magnetometer data. This correction is computed, at each time instance, using a single gradient descent step with fixed step length. This fixed step length results in robustness against model errors, e.g., caused by large accelerations or by short-term magnetic field disturbances, which we numerically illustrate using Monte Carlo simulations. Our algorithm estimates a three-dimensional update to the orientation rather than the entire orientation itself. This reduces the computational complexity by approximately 1/3 with respect to the state of the art. It also improves the quality of the resulting estimates, specifically when the orientation corrections are large. We illustrate the efficacy of the algorithm using experimental data. [ABSTRACT FROM AUTHOR]

Published

2019

3. Magnetometer Calibration Using Inertial Sensors.

Author

Kok, Manon and Schon, Thomas B.

Abstract

In this paper, we present a practical algorithm for calibrating a magnetometer for the presence of magnetic disturbances and for magnetometer sensor errors. To allow for combining the magnetometer measurements with inertial measurements for orientation estimation, the algorithm also corrects for misalignment between the magnetometer and the inertial sensor axes. The calibration algorithm is formulated as the solution to a maximum likelihood problem, and the computations are performed offline. The algorithm is shown to give good results using data from two different commercially available sensor units. Using the calibrated magnetometer measurements in combination with the inertial sensors to determine the sensor’s orientation is shown to lead to significantly improved heading estimates. [ABSTRACT FROM PUBLISHER]

Published

2016

4. Indoor Positioning Using Ultrawideband and Inertial Measurements.

Author

Kok, Manon, Hol, Jeroen D., and Schon, Thomas B.

Subjects

ULTRA-wideband devices, INDOOR positioning systems, INERTIAL navigation systems, MULTISENSOR data fusion, MAXIMUM likelihood detection, CALIBRATION

Abstract

In this paper, we present an approach to combine measurements from inertial sensors (accelerometers and gyroscopes) with time-of-arrival measurements from an ultrawideband (UWB) system for indoor positioning. Our algorithm uses a tightly coupled sensor fusion approach, where we formulate the problem as a maximum a posteriori (MAP) problem that is solved using an optimization approach. It is shown to lead to accurate 6-D position and orientation estimates when compared to reference data from an independent optical tracking system. To be able to obtain position information from the UWB measurements, it is imperative that accurate estimates of the UWB receivers' positions and their clock offsets are available. Hence, we also present an easy-to-use algorithm to calibrate the UWB system using a maximum-likelihood (ML) formulation. Throughout this work, the UWB measurements are modeled by a tailored heavy-tailed asymmetric distribution to account for measurement outliers. The heavy-tailed asymmetric distribution works well on experimental data, as shown by analyzing the position estimates obtained using the UWB measurements via a novel multilateration approach. [ABSTRACT FROM PUBLISHER]

Published

2015