Abstract
To comply with the increasing complexity of new mechatronic systems and stricter safety regulations, advanced estimation algorithms are currently undergoing a transformation towards higher model complexity. However, more complex models often face issues regarding the observability and computational effort needed. Moreover, sensor selection is often still conducted pragmatically based on experience and convenience, whereas a more cost-effective approach would be to evaluate the sensor performance based on its effective estimation performance. In this work, a novel estimation and sensor selection approach is presented that is able to stabilise the estimator Riccati equation for unobservable and non-linear system models. This is possible when estimators only target some specific quantities of interest that do not necessarily depend on all system states. An Extended Kalman Filter-based estimation framework is proposed where the Riccati equation is projected onto an observable subspace based on a Singular Value Decomposition (SVD) of the Kalman observability matrix. Furthermore, a sensor selection methodology is proposed, which ranks the possible sensors according to their estimation performance, as evaluated by the error covariance of the quantities of interest. This allows evaluating the performance of a sensor set without the need for costly test campaigns. Finally, the proposed methods are evaluated on a numerical example, as well as an automotive experimental validation case.
Highlights
Nowadays, many new mechatronic systems become available on the market, designed to perform tasks with increasing complexity while ensuring machine/operator safety
Sensor selection is often still conducted pragmatically based on experience and convenience, whereas a more cost-effective approach would be to evaluate the sensor performance based on its effective estimation performance
An Extended Kalman Filter-based estimation framework is proposed where the Riccati equation is projected onto an observable subspace based on a Singular Value Decomposition (SVD) of the Kalman observability matrix
Summary
Many new mechatronic systems become available on the market, designed to perform tasks with increasing complexity while ensuring machine/operator safety. In many applications, this information cannot be directly measured because either no sensor exists that is capable of measuring the quantity of interest or the available sensors are expensive or impractical to implement [1] This has led to the development of various virtual sensing techniques that aim at obtaining the dynamic information of a mechatronic system indirectly through estimations based on simple measurements [2]. Driven by the need for more accurate system information, model complexity has significantly increased up to flexible multibody-related formulations [10,11,12] This comes at the cost of increased computational effort and additional issues towards observability and estimator stability
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