Simon Hecker scite author profile

In this paper, we introduce a general descriptor-type linear fractional transformation (LFT) representation of rational parametric matrices. This is a generalized representation of arbitrary rationally dependent multivariate functions in LFT-form. As applications, we develop explicit LFT-realizations of the transferfunction matrix of a linear descriptor system whose state-space matrices depend rationally on a set of uncertain parameters. The resulting descriptor LFTbased uncertainty models generally have smaller orders than those obtained by using the standard LFT-based modelling approach. An example of an uncertain vehicle model illustrates the capability of the method.

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Experimental and analytical study of secondary path variations in active engine mounts

Hausberg

Scheiblegger

Pfeffer

et al. 2015

Journal of Sound and Vibration

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Learning Accurate, Comfortable and Human-like Driving

Hecker¹,

Dai²,

Gool³

2019

Preprint

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Autonomous vehicles are more likely to be accepted if they drive accurately, comfortably, but also similar to how human drivers would. This is especially true when autonomous and human-driven vehicles need to share the same road. The main research focus thus far, however, is still on improving driving accuracy only. This paper formalizes the three concerns with the aim of accurate, comfortable and human-like driving. Three contributions are made in this paper. First, numerical map data from HERE Technologies are employed for more accurate driving; a set of map features -which are believed to be relevant to driving -are engineered to navigate better. Second, the learning procedure is improved from a pointwise prediction to a sequence-based prediction and passengers' comfort measures are embedded into the learning algorithm. Finally, we take advantage of the advances in adversary learning to learn human-like driving; specifically, the standard L1 or L2 loss is augmented by an adversary loss which is based on a discriminator trained to distinguish between human driving and machine driving. Our model is trained and evaluated on the Drive360 dataset, which features 60 hours and 3000 km of real-world driving data. Extensive experiments show that our driving model is more accurate, more comfortable and behaves more like a human driver than previous methods. The resources of this work will be released on the project page.

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Generation of optimal linear parametric models for LFT-based robust stability analysis and control design

Pfifer

Hecker

2008

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Generation of Optimal Linear Parametric Models for LFT-Based Robust Stability Analysis and Control Design

Pfifer¹,

Hecker²

2011

IEEE Trans. Contr. Syst. Technol.

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Simon Hecker

Generalized LFT-Based Representation of Parametric Uncertain Models

Experimental and analytical study of secondary path variations in active engine mounts

Learning Accurate, Comfortable and Human-like Driving

Generation of optimal linear parametric models for LFT-based robust stability analysis and control design

Generation of Optimal Linear Parametric Models for LFT-Based Robust Stability Analysis and Control Design

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