Challenges for a hybrid CAI-based INS due to trajectory dynamics derived from real inertial datasets

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Autoren

  • Nikolai Ben Weddig
  • Benjamin Tennstedt
  • Steffen Schön

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Details

OriginalspracheEnglisch
Titel des Sammelwerks2022 DGON Inertial Sensors and Systems, ISS 2022 - Proceedings
Herausgeber/-innenPeter Hecker
Herausgeber (Verlag)Institute of Electrical and Electronics Engineers Inc.
ISBN (elektronisch)9781665490214
ISBN (Print)978-1-6654-9022-1
PublikationsstatusVeröffentlicht - 2022
Veranstaltung2022 DGON Inertial Sensors and Systems, ISS 2022 - Braunschweig, Deutschland
Dauer: 13 Sept. 202214 Sept. 2022

Publikationsreihe

NameInternational Symposium on Inertial Sensors and Systems
ISSN (Print)2377-3464
ISSN (elektronisch)2377-3480

Abstract

The results of an observability analysis of a CAI-based IMU sensor fusion model, based on findings from an extensive analysis of inertial datasets collected over the last 10 years at the Institut für Erdmessung of the Leibniz University of Hannover, are presented. Datasets are analysed with respect to characteristic peaks occurring in the body frame during acceleration, deceleration, and turn maneuvers. This is done for IMU datasets recorded on board trains and cars. Based on these findings, 'characteristic' maneuvers are derived for the forward (x) and right (y) axis of the accelerometer, and the z axis of the gyroscope in the body frame. Maneuvers are derived by ranking multiple possible function fits on a RMSE-based evaluation method. This results in best fitting functions which are used to confirm the observability of different systematic IMU error terms with respect to a CAI-based reference sensor. Turn maneuvers result in dynamics across both accelerometer and the gyroscope axes, which in turn leads to observability of misalignments. For acceleration and deceleration maneuvers, only the longitudinal axis of the vehicle exhibits changes in acceleration, which should also be sufficient to estimate the misalignment terms between the conventional IMU and the CAI-based sensor. Meanwhile, the lever arm (displacement) between the CAI and IMU cannot be reliably estimated by maneuvers considered here, as it requires significant angular rates along two axes. A solution to this problem could be the oscillation due to suspension visible in the car-based datasets, which have a frequency of 0.2-1 Hz, and an amplitude of up to 0.1 rad/s. Based on these results, a follow-up study is suggested with real CAI sensor measurements to estimate the impact of such slow oscillations on the sensor solution.

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Challenges for a hybrid CAI-based INS due to trajectory dynamics derived from real inertial datasets. / Weddig, Nikolai Ben; Tennstedt, Benjamin; Schön, Steffen.
2022 DGON Inertial Sensors and Systems, ISS 2022 - Proceedings. Hrsg. / Peter Hecker. Institute of Electrical and Electronics Engineers Inc., 2022. (International Symposium on Inertial Sensors and Systems).

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Weddig, NB, Tennstedt, B & Schön, S 2022, Challenges for a hybrid CAI-based INS due to trajectory dynamics derived from real inertial datasets. in P Hecker (Hrsg.), 2022 DGON Inertial Sensors and Systems, ISS 2022 - Proceedings. International Symposium on Inertial Sensors and Systems, Institute of Electrical and Electronics Engineers Inc., 2022 DGON Inertial Sensors and Systems, ISS 2022, Braunschweig, Deutschland, 13 Sept. 2022. https://doi.org/10.1109/ISS55898.2022.9926311
Weddig, N. B., Tennstedt, B., & Schön, S. (2022). Challenges for a hybrid CAI-based INS due to trajectory dynamics derived from real inertial datasets. In P. Hecker (Hrsg.), 2022 DGON Inertial Sensors and Systems, ISS 2022 - Proceedings (International Symposium on Inertial Sensors and Systems). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ISS55898.2022.9926311
Weddig NB, Tennstedt B, Schön S. Challenges for a hybrid CAI-based INS due to trajectory dynamics derived from real inertial datasets. in Hecker P, Hrsg., 2022 DGON Inertial Sensors and Systems, ISS 2022 - Proceedings. Institute of Electrical and Electronics Engineers Inc. 2022. (International Symposium on Inertial Sensors and Systems). doi: 10.1109/ISS55898.2022.9926311
Weddig, Nikolai Ben ; Tennstedt, Benjamin ; Schön, Steffen. / Challenges for a hybrid CAI-based INS due to trajectory dynamics derived from real inertial datasets. 2022 DGON Inertial Sensors and Systems, ISS 2022 - Proceedings. Hrsg. / Peter Hecker. Institute of Electrical and Electronics Engineers Inc., 2022. (International Symposium on Inertial Sensors and Systems).
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abstract = "The results of an observability analysis of a CAI-based IMU sensor fusion model, based on findings from an extensive analysis of inertial datasets collected over the last 10 years at the Institut f{\"u}r Erdmessung of the Leibniz University of Hannover, are presented. Datasets are analysed with respect to characteristic peaks occurring in the body frame during acceleration, deceleration, and turn maneuvers. This is done for IMU datasets recorded on board trains and cars. Based on these findings, 'characteristic' maneuvers are derived for the forward (x) and right (y) axis of the accelerometer, and the z axis of the gyroscope in the body frame. Maneuvers are derived by ranking multiple possible function fits on a RMSE-based evaluation method. This results in best fitting functions which are used to confirm the observability of different systematic IMU error terms with respect to a CAI-based reference sensor. Turn maneuvers result in dynamics across both accelerometer and the gyroscope axes, which in turn leads to observability of misalignments. For acceleration and deceleration maneuvers, only the longitudinal axis of the vehicle exhibits changes in acceleration, which should also be sufficient to estimate the misalignment terms between the conventional IMU and the CAI-based sensor. Meanwhile, the lever arm (displacement) between the CAI and IMU cannot be reliably estimated by maneuvers considered here, as it requires significant angular rates along two axes. A solution to this problem could be the oscillation due to suspension visible in the car-based datasets, which have a frequency of 0.2-1 Hz, and an amplitude of up to 0.1 rad/s. Based on these results, a follow-up study is suggested with real CAI sensor measurements to estimate the impact of such slow oscillations on the sensor solution.",
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AU - Weddig, Nikolai Ben

AU - Tennstedt, Benjamin

AU - Schön, Steffen

N1 - Funding Information: This work was sponsored by BMWi, projects 50RK1957 (QGyro) and 50NA2106

PY - 2022

Y1 - 2022

N2 - The results of an observability analysis of a CAI-based IMU sensor fusion model, based on findings from an extensive analysis of inertial datasets collected over the last 10 years at the Institut für Erdmessung of the Leibniz University of Hannover, are presented. Datasets are analysed with respect to characteristic peaks occurring in the body frame during acceleration, deceleration, and turn maneuvers. This is done for IMU datasets recorded on board trains and cars. Based on these findings, 'characteristic' maneuvers are derived for the forward (x) and right (y) axis of the accelerometer, and the z axis of the gyroscope in the body frame. Maneuvers are derived by ranking multiple possible function fits on a RMSE-based evaluation method. This results in best fitting functions which are used to confirm the observability of different systematic IMU error terms with respect to a CAI-based reference sensor. Turn maneuvers result in dynamics across both accelerometer and the gyroscope axes, which in turn leads to observability of misalignments. For acceleration and deceleration maneuvers, only the longitudinal axis of the vehicle exhibits changes in acceleration, which should also be sufficient to estimate the misalignment terms between the conventional IMU and the CAI-based sensor. Meanwhile, the lever arm (displacement) between the CAI and IMU cannot be reliably estimated by maneuvers considered here, as it requires significant angular rates along two axes. A solution to this problem could be the oscillation due to suspension visible in the car-based datasets, which have a frequency of 0.2-1 Hz, and an amplitude of up to 0.1 rad/s. Based on these results, a follow-up study is suggested with real CAI sensor measurements to estimate the impact of such slow oscillations on the sensor solution.

AB - The results of an observability analysis of a CAI-based IMU sensor fusion model, based on findings from an extensive analysis of inertial datasets collected over the last 10 years at the Institut für Erdmessung of the Leibniz University of Hannover, are presented. Datasets are analysed with respect to characteristic peaks occurring in the body frame during acceleration, deceleration, and turn maneuvers. This is done for IMU datasets recorded on board trains and cars. Based on these findings, 'characteristic' maneuvers are derived for the forward (x) and right (y) axis of the accelerometer, and the z axis of the gyroscope in the body frame. Maneuvers are derived by ranking multiple possible function fits on a RMSE-based evaluation method. This results in best fitting functions which are used to confirm the observability of different systematic IMU error terms with respect to a CAI-based reference sensor. Turn maneuvers result in dynamics across both accelerometer and the gyroscope axes, which in turn leads to observability of misalignments. For acceleration and deceleration maneuvers, only the longitudinal axis of the vehicle exhibits changes in acceleration, which should also be sufficient to estimate the misalignment terms between the conventional IMU and the CAI-based sensor. Meanwhile, the lever arm (displacement) between the CAI and IMU cannot be reliably estimated by maneuvers considered here, as it requires significant angular rates along two axes. A solution to this problem could be the oscillation due to suspension visible in the car-based datasets, which have a frequency of 0.2-1 Hz, and an amplitude of up to 0.1 rad/s. Based on these results, a follow-up study is suggested with real CAI sensor measurements to estimate the impact of such slow oscillations on the sensor solution.

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