17 research outputs found
Learning Hybrid Dynamics Models With Simulator-Informed Latent States
Dynamics model learning deals with the task of inferring unknown dynamics
from measurement data and predicting the future behavior of the system. A
typical approach to address this problem is to train recurrent models. However,
predictions with these models are often not physically meaningful. Further,
they suffer from deteriorated behavior over time due to accumulating errors.
Often, simulators building on first principles are available being physically
meaningful by design. However, modeling simplifications typically cause
inaccuracies in these models. Consequently, hybrid modeling is an emerging
trend that aims to combine the best of both worlds. In this paper, we propose a
new approach to hybrid modeling, where we inform the latent states of a learned
model via a black-box simulator. This allows to control the predictions via the
simulator preventing them from accumulating errors. This is especially
challenging since, in contrast to previous approaches, access to the
simulator's latent states is not available. We tackle the task by leveraging
observers, a well-known concept from control theory, inferring unknown latent
states from observations and dynamics over time. In our learning-based setting,
we jointly learn the dynamics and an observer that infers the latent states via
the simulator. Thus, the simulator constantly corrects the latent states,
compensating for modeling mismatch caused by learning. To maintain flexibility,
we train an RNN-based residuum for the latent states that cannot be informed by
the simulator
Exact Inference for Continuous-Time Gaussian Process Dynamics
Physical systems can often be described via a continuous-time dynamical
system. In practice, the true system is often unknown and has to be learned
from measurement data. Since data is typically collected in discrete time, e.g.
by sensors, most methods in Gaussian process (GP) dynamics model learning are
trained on one-step ahead predictions. This can become problematic in several
scenarios, e.g. if measurements are provided at irregularly-sampled time steps
or physical system properties have to be conserved. Thus, we aim for a GP model
of the true continuous-time dynamics. Higher-order numerical integrators
provide the necessary tools to address this problem by discretizing the
dynamics function with arbitrary accuracy. Many higher-order integrators
require dynamics evaluations at intermediate time steps making exact GP
inference intractable. In previous work, this problem is often tackled by
approximating the GP posterior with variational inference. However, exact GP
inference is preferable in many scenarios, e.g. due to its mathematical
guarantees. In order to make direct inference tractable, we propose to leverage
multistep and Taylor integrators. We demonstrate how to derive flexible
inference schemes for these types of integrators. Further, we derive tailored
sampling schemes that allow to draw consistent dynamics functions from the
learned posterior. This is crucial to sample consistent predictions from the
dynamics model. We demonstrate empirically and theoretically that our approach
yields an accurate representation of the continuous-time system
Perkolation auf zufälligen Mosaiken und im Boole\u27schen Modell
We study percolation on random tessellations of the euclidian space. We proof the uniqueness of the infinite cluster and provide two frameworks, that imply the existence of a non-trivial phase-transition. We show that various classes of random tesselations fit into on of these frameworks. In the second part, we study the Boolean model. We give a new proof for the sharpness of the phase transition and solve the Ornstein-Zernike equation. This leads to new lower bounds for the critical intensity
IL-22 Is Produced by Innate Lymphoid Cells and Limits Inflammation in Allergic Airway Disease
Interleukin (IL)-22 is an effector cytokine, which acts primarily on epithelial cells in the skin, gut, liver and lung. Both pro- and anti-inflammatory properties have been reported for IL-22 depending on the tissue and disease model. In a murine model of allergic airway inflammation, we found that IL-22 is predominantly produced by innate lymphoid cells in the inflamed lungs, rather than TH cells. To determine the impact of IL-22 on airway inflammation, we used allergen-sensitized IL-22-deficient mice and found that they suffer from significantly higher airway hyperreactivity upon airway challenge. IL-22-deficiency led to increased eosinophil infiltration lymphocyte invasion and production of CCL17 (TARC), IL-5 and IL-13 in the lung. Mice treated with IL-22 before antigen challenge displayed reduced expression of CCL17 and IL-13 and significant amelioration of airway constriction and inflammation. We conclude that innate IL-22 limits airway inflammation, tissue damage and clinical decline in allergic lung disease
Learning Hybrid Dynamics Models with Simulator-Informed Latent States
Dynamics model learning deals with the task of inferring unknown dynamics from measurement data and predicting the future behavior of the system. A typical approach to address this problem is to train recurrent models. However, predictions with these models are often not physically meaningful. Further, they suffer from deteriorated behavior over time due to accumulating errors. Often, simulators building on first principles are available being physically meaningful by design. However, modeling simplifications typically cause inaccuracies in these models. Consequently, hybrid modeling is an emerging trend that aims to combine the best of both worlds. In this paper, we propose a new approach to hybrid modeling, where we inform the latent states of a learned model via a black-box simulator. This allows to control the predictions via the simulator preventing them from accumulating errors. This is especially challenging since, in contrast to previous approaches, access to the simulator's latent states is not available. We tackle the task by leveraging observers, a well-known concept from control theory, inferring unknown latent states from observations and dynamics over time. In our learning-based setting, we jointly learn the dynamics and an observer that infers the latent states via the simulator. Thus, the simulator constantly corrects the latent states, compensating for modeling mismatch caused by learning. To maintain flexibility, we train an RNN-based residuum for the latent states that cannot be informed by the simulator
Exact Inference for Continuous-Time Gaussian Process Dynamics
Many physical systems can be described as a continuous-time dynamical system. In practice, the true system is often unknown and has to be learned from measurement data. Since data is typically collected in discrete time, e.g. by sensors, most methods in Gaussian process (GP) dynamics model learning are trained on one-step ahead predictions. While this scheme is mathematically tempting, it can become problematic in several scenarios, e.g. if measurements are provided at irregularly-sampled time steps or physical system properties have to be conserved. Thus, we aim for a GP model of the true continuous-time dynamics. We tackle this task by leveraging higher-order numerical integrators. These integrators provide the necessary tools to discretize dynamical systems with arbitrary accuracy. However, most higher-order integrators require dynamics evaluations at intermediate time steps, making exact GP inference intractable. In previous work, this problem is often addressed by approximate inference techniques. However, exact GP inference is preferable in many scenarios, e.g. due to its mathematical guarantees. In order to enable direct inference, we propose to leverage multistep and Taylor integrators. We demonstrate how exact inference schemes can be derived for these types of integrators. Further, we derive tailored sampling schemes that allow one to draw consistent dynamics functions from the posterior. The learned model can thus be integrated with arbitrary integrators, just like a standard dynamical system. We show empirically and theoretically that our approach yields an accurate representation of the continuous-time system
Combining Slow and Fast: Complementary Filtering for Dynamics Learning
Modeling an unknown dynamical system is crucial in order to predict the future behavior of the system. A standard approach is training recurrent models on measurement data. While these models typically provide exact short-term predictions, accumulating errors yield deteriorated long-term behavior. In contrast, models with reliable long-term predictions can often be obtained, either by training a robust but less detailed model, or by leveraging physics-based simulations. In both cases, inaccuracies in the models yield a lack of short-time details. Thus, different models with contrastive properties on different time horizons are available. This observation immediately raises the question: Can we obtain predictions that combine the best of both worlds? Inspired by sensor fusion tasks, we interpret the problem in the frequency domain and leverage classical methods from signal processing, in particular complementary filters. This filtering technique combines two signals by applying a high-pass filter to one signal, and low-pass filtering the other. Essentially, the high-pass filter extracts high-frequencies, whereas the low-pass filter extracts low frequencies. Applying this concept to dynamics model learning enables the construction of models that yield accurate long- and short-term predictions. Here, we propose two methods, one being purely learning-based and the other one being a hybrid model that requires an additional physics-based simulator