Hyperbolicity, shadowing directions and sensitivity analysis of a turbulent three-dimensional flow

Ni, Angxiu

doi:10.1017/jfm.2018.986

Cited by 35 publications

(65 citation statements)

References 55 publications

(78 reference statements)

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“…For example, the 3D cylinder flow we investigate later in this paper has at least two neutral CLVs, corresponding to translations in time and in the span-wise directions, due to the periodic boundary condition. In fact, in [27] we also showed that the smallest angle between tangent CLVs depends on meshes and may fall below a threshold value: this further violates our assumptions. However, we did found the trend that angles between tangent CLVs gets larger when their indices are further apart: this property is related to hyperbolicity, but has not been well investigated yet.…”

Section: Miscellaneousmentioning

confidence: 63%

“…First, our system has at least two neutral CLVs: the first one corresponds to the common time translation of continuous dynamical systems, and the second corresponds to span-wise translations due to the periodic boundary conditions. Second, due to the similarity of this fluid problem with the one investigated in [27], whose tangent CLVs appear to have occasional tangencies, it is reasonable to assume that adjoint CLVs in our current system may also have occasional tangencies. Still, like NILSS did in [27], NILSAS computes a correct sensitivity: this en- courages us to test NILSS and NILSAS on more general chaotic systems.…”

Section: Application On a Weakly Turbulent Flow Past A Three-dimensiomentioning

confidence: 93%

“…A major variant of NILSS is the Finite Difference NILSS (FD-NILSS) algorithm [26], whose implementation requires only primal solvers, but not tangent solvers. FD-NILSS has been applied to several complicated flow problems [27,26] which were too expensive for previous sensitivity analysis methods.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Adjoint sensitivity analysis on chaotic dynamical systems by Non-Intrusive Least Squares Adjoint Shadowing (NILSAS)

Talnikar

2019

Journal of Computational Physics

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We develop the NILSAS algorithm, which performs adjoint sensitivity analysis of chaotic systems via computing the adjoint shadowing direction. NILSAS constrains its minimization to the adjoint unstable subspace, and can be implemented with little modification to existing adjoint solvers. The computational cost of NILSAS is independent of the number of parameters. We demonstrate NILSAS on the Lorenz 63 system and a weakly turbulent three-dimensional flow over a cylinder.

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Section: Miscellaneousmentioning

confidence: 63%

Section: Application On a Weakly Turbulent Flow Past A Three-dimensiomentioning

confidence: 93%

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Adjoint sensitivity analysis on chaotic dynamical systems by Non-Intrusive Least Squares Adjoint Shadowing (NILSAS)

Talnikar

2019

Journal of Computational Physics

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“…The LEs, CLVs and shadowing directions of the same physical problem, on both the current mesh and a finer mesh with twice as many cells, are studied with more details in [40], which shows that for both meshes, (1) there are only a few unstable CLVs, (2) CLVs are active at different area in the flow field, indicating angles are large between CLVs whose indices are far-apart, and (3) shadowing directions exists and can give accurate sensitivities. Moreover, [40] also plots snapshots of CLVs and shadowing directions. Using above settings, the cost of FD-NILSS is from integrating the primal solution over 400 × 200 × 42 = 3.36 × 10 6 time steps.…”

Section: Resultsmentioning

confidence: 99%

“…For very chaotic systems, if we still have m us m, then NILSS and NILSAS may still be competitive in computational efficiency; at least, the idea of the 'non-intrusive' formulation, that is, reducing the computation to unstable subspace, will still be important. Current investigation on some computersimulated fluid systems all have m us ≤ 0.1%m [32,36,39,40], but we do not yet have a good estimation for very chaotic systems. On the other hand, there are systems with m us ≈ m, such as Hamiltonian systems, which has equally many stable and unstable CLVs; for these systems, NILSS or NILSAS may not be faster than other methods.…”

Section: Remarks On Fd-nilssmentioning

confidence: 89%

Sensitivity analysis on chaotic dynamical systems by Finite Difference Non-Intrusive Least Squares Shadowing (FD-NILSS)

Wang

Fernández

et al. 2019

Journal of Computational Physics

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We present the Finite Difference Non-Intrusive Least Squares Shadowing (FD-NILSS) algorithm for computing sensitivities of long-time averaged quantities in chaotic dynamical systems. FD-NILSS does not require tangent solvers, and can be implemented with little modification to existing numerical simulation software. We also give a formula for solving the least-squares problem in FD-NILSS, which can be applied in NILSS as well. Finally, we apply FD-NILSS for sensitivity analysis of a chaotic flow over a 3-D cylinder at Reynolds number 525, where FD-NILSS computes accurate sensitivities and the computational cost is in the same order as the numerical simulation.

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Optimisation of chaotically perturbed acoustic limit cycles

Huhn

Magri

2020

Nonlinear Dyn

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In an acoustic cavity with a heat source, the thermal energy of the heat source can be converted into acoustic energy, which may generate a loud oscillation. If uncontrolled, these acoustic oscillations, also known as thermoacoustic instabilities, can cause mechanical vibrations, fatigue and structural failure. The objective of manufacturers is to design stable thermoacoustic configurations. In this paper, we propose a method to optimise a chaotically perturbed limit cycle in the bistable region of a subcritical bifurcation. In this situation, traditional stability and sensitivity methods, such as eigenvalue and Floquet analysis, break down. First, we propose covariant Lyapunov analysis and shadowing methods as tools to calculate the stability and sensitivity of chaotically perturbed acoustic limit cycles. Second, covariant Lyapunov vector analysis is applied to an acoustic system with a heat source. The acoustic velocity at the heat source is chaotically perturbed to qualitatively mimic the effect of the turbulent hydrodynamic field. It is shown that the tangent space of the acoustic attractor is hyperbolic, which has a practical implication: the sensitivities of time-averaged cost functionals exist and can be robustly calculated by a shadowing method. Third, we calculate the sensitivities of the time-averaged acoustic energy and Rayleigh index to small changes to the heat-source intensity and time delay. By embedding the sensitivities into a gradient-update routine, we suppress an existing chaotic acoustic oscillation by optimal design of the heat source. The analysis and methods proposed enable the reduction of chaotic oscillations in thermoacoustic systems by optimal passive control. Because the theoretical framework is general, the techniques presented can be used in other unsteady deterministic multi-physics problems with virtually no modification.

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Hyperbolicity, shadowing directions and sensitivity analysis of a turbulent three-dimensional flow

Cited by 35 publications

References 55 publications

Adjoint sensitivity analysis on chaotic dynamical systems by Non-Intrusive Least Squares Adjoint Shadowing (NILSAS)

Adjoint sensitivity analysis on chaotic dynamical systems by Non-Intrusive Least Squares Adjoint Shadowing (NILSAS)

Sensitivity analysis on chaotic dynamical systems by Finite Difference Non-Intrusive Least Squares Shadowing (FD-NILSS)

Optimisation of chaotically perturbed acoustic limit cycles

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