Error Estimation for Reduced‐Order Models of Dynamical Systems

Homescu, Cristian; Petzold, Linda R.; Serban, Radu

doi:10.1137/070684392

Cited by 53 publications

(31 citation statements)

References 26 publications

(22 reference statements)

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“…However, we demonstrated that this control law is energetically inefficient. These numerical results agree to a large extent to those obtained previously by other researchers [38,40,69] using the twodimensional Navier-Stokes equations to solve the optimal control problem. Compared with those studies, the main advantage of our approach is that it leads to a significant reduction of the numerical costs because the optimization process itself is completely based on reduced-order models only.…”

Section: Discussionsupporting

confidence: 89%

Optimal control of the cylinder wake in the laminar regime by trust-region methods and POD reduced-order models

Bergmann

Cordier

2008

Journal of Computational Physics

174

154

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In this paper, optimal control theory is used to minimize the total mean drag for a circular cylinder wake flow in the laminar regime (Re = 200). The control parameters are the amplitude and the frequency of the time-harmonic cylinder rotation. In order to reduce the size of the discretized optimality system, a Proper Orthogonal Decomposition (POD) Reduced-Order Model (ROM) is derived to be used as state equation. We then propose to employ the Trust-Region Proper Orthogonal Decomposition (TRPOD) approach, originally introduced by Fahl (2000), to update the reduced-order models during the optimization process. A lot of computational work is saved because the optimization process is now based only on low-fidelity models. A particular care was taken to derive a POD ROM for the pressure and velocity fields with an appropriate balance between model accuracy and robustness. The key enablers are the extension of the POD basis functions to the pressure data, the use of calibration methods for the POD ROM and the addition in the POD expansion of several non-equilibrium modes to describe various operating conditions. When the TRPOD algorithm is applied to the wake flow configuration, this approach converges to the minimum predicted by an open-loop control approach and leads to a relative mean drag reduction of 30% at reduced cost.

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Section: Discussionsupporting

confidence: 89%

Optimal control of the cylinder wake in the laminar regime by trust-region methods and POD reduced-order models

Bergmann

Cordier

2008

Journal of Computational Physics

174

154

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“…As expected, L2 error relative to a ground truth solution increases as the dynamics diverge from those of the training simulation. Characterizing the error of subspace simulations under arbitrary perturbations is an interesting and subtle topic [Homescu et al 2005], so we leave a more thorough analysis as future work.…”

Section: Implementation and Resultsmentioning

confidence: 99%

Subspace fluid re-simulation

Kim

Delaney

2013

ACM Trans. Graph.

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Figure 1: An efficient subspace re-simulation of novel fluid dynamics. This scene was generated an order of magnitude faster than the original. The solver itself, without velocity reconstruction ( §5), runs three orders of magnitude faster. AbstractWe present a new subspace integration method that is capable of efficiently adding and subtracting dynamics from an existing highresolution fluid simulation. We show how to analyze the results of an existing high-resolution simulation, discover an efficient reduced approximation, and use it to quickly "re-simulate" novel variations of the original dynamics. Prior subspace methods have had difficulty re-simulating the original input dynamics because they lack efficient means of handling semi-Lagrangian advection methods. We show that multi-dimensional cubature schemes can be applied to this and other advection methods, such as MacCormack advection. The remaining pressure and diffusion stages can be written as a single matrix-vector multiply, so as with previous subspace methods, no matrix inversion is needed at runtime. We additionally propose a novel importance sampling-based fitting algorithm that asymptotically accelerates the precomputation stage, and show that the Iterated Orthogonal Projection method can be used to elegantly incorporate moving internal boundaries into a subspace simulation. In addition to efficiently producing variations of the original input, our method can produce novel, abstract fluid motions that we have not seen from any other solver.

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“…Such backups are not acceptable in offline animation, since they would require coupled simulators (fluids, rigid bodies) to be backed up as well, which would invalidate any performance gains. The dual weighted residual (DWR) method [Meyer and Matthies 2003] as well as the method of Homescu et al [2006] take a different approach and solve the adjoint of a known simulation result backwards in time to obtain a priori reduced-order error bounds on perturbed versions of the simulation. These two methods still bootstrap off of existing simulation data, so they cannot be applied to the case where the simulation is only computed once.…”

Section: Related Workmentioning

confidence: 99%

“…This estimate is conservative -subspace error is usually characterized as a sum of projection error and integration error (for example, see Homescu et al [2006]), with integration error being the only component that compounds over time. We pessimistically assume that all of the error is integration error.…”

Section: Estimating How Many Steps To Skipmentioning

confidence: 99%

Skipping steps in deformable simulation with online model reduction

Kim¹,

James²

2009

ACM SIGGRAPH Asia 2009 Papers

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Figure 1: We learn fast subspace models on-the-fly to accelerate deformable simulation: (Top) Ground truth frames from a 1000-frame deformable character simulation with 165,941 tetrahedra and Arruda-Boyce material which took 48 hours (174,521 seconds). (Middle) Frames from our online integrator which were generated in only 51 minutes (3,101 seconds) -56.28× faster -by learning a fast 11-dimensional subspace model on-the-fly (Bottom) Visualization of the temporal behavior of the online integrator reveal full steps (in black), reduced steps (in gray), and basis updates (red ticks). A reduced basis is detected quickly, and the first "skip" occurs at timestep 2. Only a handful of full steps are needed, and our reduced solver computes over 98% of the the steps. AbstractFinite element simulations of nonlinear deformable models are computationally costly, routinely taking hours or days to compute the motion of detailed meshes. Dimensional model reduction can make simulations orders of magnitude faster, but is unsuitable for general deformable body simulations because it requires expensive precomputations, and it can suppress motion that lies outside the span of a pre-specified low-rank basis. We present an online model reduction method that does not have these limitations. In lieu of precomputation, we analyze the motion of the full model as the simulation progresses, incrementally building a reduced-order nonlinear model, and detecting when our reduced model is capable of performing the next timestep. For these subspace steps, full-model computation is "skipped" and replaced with a very fast (on the order of milliseconds) reduced order step. We present algorithms for both dynamic and quasistatic simulations, and a "throttle" parameter that allows a user to trade off between faster, approximate previews and slower, more conservative results. For detailed meshes undergoing low-rank motion, we have observed speedups of over an order of magnitude with our method.

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Error Estimation for Reduced‐Order Models of Dynamical Systems

Cited by 53 publications

References 26 publications

Optimal control of the cylinder wake in the laminar regime by trust-region methods and POD reduced-order models

Optimal control of the cylinder wake in the laminar regime by trust-region methods and POD reduced-order models

Subspace fluid re-simulation

Skipping steps in deformable simulation with online model reduction

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