Screening and eradication of <i>Helicobacter pylori</i> for gastric cancer prevention: the Taipei global consensus

Nonlinear dynamical systems have been used in many disciplines to model complex behaviors, including biological motor control, robotics, perception, economics, traffic prediction, and neuroscience. While often the unexpected emergent behavior of nonlinear systems is the focus of investigations, it is of equal importance to create goal-directed behavior (e.g., stable locomotion from a system of coupled oscillators under perceptual guidance). Modeling goal-directed behavior with nonlinear systems is, however, rather difficult due to the parameter sensitivity of these systems, their complex phase transitions in response to subtle parameter changes, and the difficulty of analyzing and predicting their long-term behavior; intuition and time-consuming parameter tuning play a major role. This letter presents and reviews dynamical movement primitives, a line of research for modeling attractor behaviors of autonomous nonlinear dynamical systems with the help of statistical learning techniques. The essence of our approach is to start with a simple dynamical system, such as a set of linear differential equations, and transform those into a weakly nonlinear system with prescribed attractor dynamics by means of a learnable autonomous forcing term. Both point attractors and limit cycle attractors of almost arbitrary complexity can be generated. We explain the design principle of our approach and evaluate its properties in several example applications in motor control and robotics.

show abstract

Learning and generalization of motor skills by learning from demonstration

Pástor

et al. 2009

View full text Add to dashboard Cite

Kernel PCA for novelty detection

Hoffmann

2007

Pattern Recognition

628

363

View full text Add to dashboard Cite

Biologically-inspired dynamical systems for movement generation: Automatic real-time goal adaptation and obstacle avoidance

Hoffmann¹,

et al. 2009

View full text Add to dashboard Cite

Explainability Methods for Graph Convolutional Neural Networks

et al. 2019

View full text Add to dashboard Cite

Universal Litmus Patterns: Revealing Backdoor Attacks in CNNs

et al. 2020

View full text Add to dashboard Cite

The unprecedented success of deep neural networks in many applications has made these networks a prime target for adversarial exploitation. In this paper, we introduce a benchmark technique for detecting backdoor attacks (aka Trojan attacks) on deep convolutional neural networks (CNNs). We introduce the concept of Universal Litmus Patterns (ULPs), which enable one to reveal backdoor attacks by feeding these universal patterns to the network and analyzing the output (i.e., classifying the network as 'clean' or 'corrupted'). This detection is fast because it requires only a few forward passes through a CNN. We demonstrate the effectiveness of ULPs for detecting backdoor attacks on thousands of networks with different architectures trained on four benchmark datasets, namely the German Traffic Sign Recognition Benchmark (GTSRB), MNIST, CIFAR10, and Tiny-ImageNet. The codes and train/test models for this paper can be found here: https://umbcvision. github.io/Universal-Litmus-Patterns/.

show abstract

Computational Models for Neuromuscular Function

Valero-Cuevas

Hoffmann

Kurse

et al. 2009

IEEE Rev. Biomed. Eng.

View full text Add to dashboard Cite

Computational models of the neuromuscular system hold the potential to allow us to reach a deeper understanding of neuromuscular function and clinical rehabilitation by complementing experimentation. By serving as a means to distill and explore specific hypotheses, computational models emerge from prior experimental data and motivate future experimental work. Here we review computational tools used to understand neuromuscular function including musculoskeletal modeling, machine learning, control theory, and statistical model analysis. We conclude that these tools, when used in combination, have the potential to further our understanding of neuromuscular function by serving as a rigorous means to test scientific hypotheses in ways that complement and leverage experimental data.

show abstract

Sliced Wasserstein Distance for Learning Gaussian Mixture Models

Kolouri

Rohde

Hoffmann

2018

View full text Add to dashboard Cite

Gaussian mixture models (GMM) are powerful parametric tools with many applications in machine learning and computer vision. Expectation maximization (EM) is the most popular algorithm for estimating the GMM parameters. However, EM guarantees only convergence to a stationary point of the log-likelihood function, which could be arbitrarily worse than the optimal solution. Inspired by the relationship between the negative log-likelihood function and the Kullback-Leibler (KL) divergence, we propose an alternative formulation for estimating the GMM parameters using the sliced Wasserstein distance, which gives rise to a new algorithm. Specifically, we propose minimizing the sliced-Wasserstein distance between the mixture model and the data distribution with respect to the GMM parameters. In contrast to the KL-divergence, the energy landscape for the sliced-Wasserstein distance is more well-behaved and therefore more suitable for a stochastic gradient descent scheme to obtain the optimal GMM parameters. We show that our formulation results in parameter estimates that are more robust to random initializations and demonstrate that it can estimate high-dimensional data distributions more faithfully than the EM algorithm.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

hi@scite.ai

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Herbert Hoffmann

Dynamical Movement Primitives: Learning Attractor Models for Motor Behaviors

Learning and generalization of motor skills by learning from demonstration

Kernel PCA for novelty detection

Biologically-inspired dynamical systems for movement generation: Automatic real-time goal adaptation and obstacle avoidance

Explainability Methods for Graph Convolutional Neural Networks

Universal Litmus Patterns: Revealing Backdoor Attacks in CNNs

Computational Models for Neuromuscular Function

Sliced Wasserstein Distance for Learning Gaussian Mixture Models

Contact Info

Product

Resources

About