Entropy condition satisfying approximations for the full potential equation of transonic flow

Osher, Stanley; Hafez, M.; Whitlow, Woodrow

doi:10.1090/s0025-5718-1985-0771027-5

Cited by 48 publications

(10 citation statements)

References 24 publications

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“…Similar results could not yet be obtained for the finite difference method. Engquist and Osher [8], Osher [24][25][26] and Osher et al [27] propose in their papers a consistent finite difference method for the full potential equation and the transonic small disturbance equation. Under the a priori assumption that the difference solutions converge they show that they must converge to a physical solution.…”

Section: Then a Subsequence Of {Uh} Converges In Wi'p(o)mentioning

confidence: 99%

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A convergent finite element formulation for transonic flow

Berger

1989

Numer. Math.

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Summary. A finite element formulation for the full potential equation in the case of two-dimensional transonic flow is presented. The formulation is based on an optimal control approach developed by Glowinski and Pironneau. The solution of the full potential equation is obtained by a minimization problem. Using a new compactness result it is possible to prove convergence for the solutions of the minimization problem. The a priori assumption of existence and uniqueness of a weak solution of the full potential equation satisfying an entropy condition implies that the limit function must be the solution. It is possible to extend the convergence result to the case of threedimensional transonic potential flow.

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Section: Then a Subsequence Of {Uh} Converges In Wi'p(o)mentioning

confidence: 99%

“…For the finite difference method a similar result is not yet known. Engquist and Osher [8], Osher [24][25][26] and Osher et al [27] prove in their papers the existence of finite difference approximations satisfying an entropy condition. But there the convergence of the difference solutions is still an open problem.…”

Section: Introductionmentioning

confidence: 99%

A convergent finite element formulation for transonic flow

Berger

1989

Numer. Math.

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“…Following [11] (see also [12] - [14]) the modified density takes the form P = P -UP 6.s, s (2.13) where is the derivative of the density P along the streamwise direction. Since the density has the form P P ( I grad <P I ), the derivative ps formally involves second derivatives of <p.…”

Section: Second There Is the Issue Of Complicated Boundaries In The mentioning

confidence: 99%

Least squares finite element simulation of transonic flows

Chen

Fix

1986

Applied Numerical Mathematics

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Finite difference approximation of transonic flow problems is a welldeveloped and largely· successful approach.Nevertheless, there is still a real need to develop finite element methods for applications arising from fluid-structure interactions and problems with complicated boundaries. In this paper we introduce a least squares based finite element scheme. It is shown that, if suitably formulated, such an approach can lead to physically meaningful results. Bottlenecks that arise from such schemes are also discussed.

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“…In [2], [19], [18], [14] and [3], a number of shock-capturing finite difference approximations for solving the TSD and the FP equations have been proposed. These schemes satisfy properties (iii) and (v), and with the inclusion of flux limiters, property (iv) as well.…”

Section: Introductionmentioning

confidence: 99%

“…For the FP equation, the upwinding can be performed separately for the ^-dependent term and the ^-dependent term. This approach was labeled directional flux biasing in [14]. Recently, this approach was refined by introducing the method of streamwise flux biasing (see [17]) in which the upwinding is performed in a direction close to that of the actual flow.…”

Section: Introductionmentioning

confidence: 99%

On Some Numerical Schemes for Transonic Flow Problems

Mostrel¹

1989

Mathematics of Computation

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Abstract.New second-order accurate finite difference approximations for a class of nonlinear PDE's of mixed type, which includes the 2D Low Frequency Transonic Small Disturbance equation (TSD) and the 2D Full Potential equation (FP), are presented.For the TSD equation, the scheme is implemented via a time splitting algorithm; the inclusion of flux limiters keeps the total variation nonincreasing and eliminates spurious oscillations near shocks. Global Linear Stability, Total Variation Diminishing and Entropy Stability results are proven. Numerical results for the flow over a thin airfoil are presented. Current techniques used to solve the TSD equation may easily be extended to second-order accuracy by this method.For the FP equation, the new scheme requires no subsonic/supersonic switching and no numerical flux biasing. Global Linear Stability for all values of the Mach number is proven. Introduction.Recently, a number of new shock-capturing finite difference approximations for solving scalar conservation law nonlinear partial differential equations in several space dimensions have been constructed and applied to solve numerically the equations of inviscid compressible flows of aerodynamics. Those partial differential equations are, in the time-independent (steady) case, of mixed type, i.e., their type changes from elliptic to hyperbolic as the flow regime changes from subsonic to supersonic and vice versa.In this paper, we present some new shock-capturing finite difference approximations for solving scalar conservation laws. Our new schemes have the following properties:(i) second-order accuracy throughout the computational domain; (ii) global linear stability in all elliptic and all hyperbolic regions; (iii) sharp steady discrete shock solutions; (iv) total variation nonincreasing property of the approximate solutions; (v) entropy stability, at least in some cases, i.e., the approximate solutions satisfy a discrete entropy condition consistent with the differential entropy condition of

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Entropy condition satisfying approximations for the full potential equation of transonic flow

Cited by 48 publications

References 24 publications

A convergent finite element formulation for transonic flow

A convergent finite element formulation for transonic flow

Least squares finite element simulation of transonic flows

On Some Numerical Schemes for Transonic Flow Problems

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