Doubt regarding MUSCL scheme implementation and associated limiters

SangeethCFD · October 7, 2017, 09:00

Dear all,

My objective is to simulate heating profiles over a blunt body in viscous supersonic/hypersonic ideal gas flow. Presently in the first order version of my code, I am using a Finite Volume based Approximate Riemann solver code. For better accuracy I would like to make the spatial order of accuracy of the code second order. In this regard, I tried implementing van Leer's MUSCL reconstruction procedure and used certain limiters to make the reconstruction monotone. I used Strong Stability Preserving Runge Kutta method of Gottlieb et al [1] to get second order time accuracy.
This is where I am facing problems.

Doubt regarding MUSCL interpolation formula:

Firstly, in literature, MUSCL scheme is expressed in two forms ( consider only left values specified at an interface i-1/2 between Ui-1 and Ui):

Form1: UL = Ui-1 + 1/4 * phi_L* [(1+k)*(Ui-Ui-1) + (1-k)*(Ui-1-Ui-2) ]

Form2: UL = Ui-1 + 1/4 * phi_L* [(1+k*phi_L)*(Ui-Ui-1) + (1-k*phi_L)*(Ui-1-Ui-2) ]

For k=0; these forms are equivalent. While for k=-1, these are clearly not. Most books discuss form 1. While most papers (ex 2563 of ref [2] or pg 1392 of ref [3] ) use form2 usually with k=1/3. Lohner in his book [4] also uses form 2 ( sec 10.4.2 ).

Are they equivalent in all cases or are these forms applicable only to specific situations?

Doubt regarding associated limiter:

Secondly, the doubt is regarding the form of limiters used in conjunction with these forms. Consider two famous limiters:

van Albada form 1: 2R/(R^2+1)

van Albada form 2: R^2 + R/ R^2 + 1

min-mod form 1: min(2/1+R, 2R/1+R)

min-mod form 2: min(1,R)

Berger et al [5] refers to form1 as slope limiter while form 2 as flux limiter.
My understanding is that flux limiters are used directly on flux reconstruction while it is the slope limiters which are employed on the reconstructed solution values. I am aware that flux limiters can be converted into slope limiters if they have the symmetric property.

If that is so, in my particular case, I should be using only form 1 of these limiters for reconstruction of my state variables at a given interface? Will it be wrong if I use flux limiters instead?

Also, for specific value of k (kappa parameter in MUSCL scheme) are there prescribed limiters or can I use any limiter for any k value?

Specifically, if I want to use MUSCL scheme with k=-1 and min-mod limiter and k=1/3 with van Albada limiter, which MUSCL form and which limiter form should I use?

I would really appreciate any help from any kind soul on this doubt. Thanks in advance.

Regards,

[1] S. Gottlieb, C W Shu, E Tadmor, Strong stability preserving higher order time discretization methods, SIAM review, vol 43, 2001.

[2] H. NIshikawa, K. Kitamura, A Very simple, carbuncle free, boundary layer resolving, Rotated hybrid Riemann solver, JCP, 2008.

[3] Y X Ren, A robust shock capturing schemes based on rotated Riemann solvers, Comput and Fluids, 2003.

[4] 'Applied computational fluid dynamics techniques', R. Lohner, 2nd edition, Wiley, 2008.

[5] M Berger, M J Aftosmis, S M Murman, Analysis of slope limiters on unstructured grids, 43rd AIAA Aerospace meetings, 2005.

October 7, 2017, 09:00	Doubt regarding MUSCL scheme implementation and associated limiters	#1
SangeethCFD New Member Sangeeth Join Date: Jul 2015 Posts: 7 Rep Power: 10	Dear all, My objective is to simulate heating profiles over a blunt body in viscous supersonic/hypersonic ideal gas flow. Presently in the first order version of my code, I am using a Finite Volume based Approximate Riemann solver code. For better accuracy I would like to make the spatial order of accuracy of the code second order. In this regard, I tried implementing van Leer's MUSCL reconstruction procedure and used certain limiters to make the reconstruction monotone. I used Strong Stability Preserving Runge Kutta method of Gottlieb et al [1] to get second order time accuracy. This is where I am facing problems. Doubt regarding MUSCL interpolation formula: Firstly, in literature, MUSCL scheme is expressed in two forms ( consider only left values specified at an interface i-1/2 between Ui-1 and Ui): Form1: UL = Ui-1 + 1/4 * phi_L* [(1+k)(Ui-Ui-1) + (1-k)(Ui-1-Ui-2) ] Form2: UL = Ui-1 + 1/4 * phi_L* [(1+kphi_L)(Ui-Ui-1) + (1-kphi_L)(Ui-1-Ui-2) ] For k=0; these forms are equivalent. While for k=-1, these are clearly not. Most books discuss form 1. While most papers (ex 2563 of ref [2] or pg 1392 of ref [3] ) use form2 usually with k=1/3. Lohner in his book [4] also uses form 2 ( sec 10.4.2 ). Are they equivalent in all cases or are these forms applicable only to specific situations? Doubt regarding associated limiter: Secondly, the doubt is regarding the form of limiters used in conjunction with these forms. Consider two famous limiters: van Albada form 1: 2R/(R^2+1) van Albada form 2: R^2 + R/ R^2 + 1 min-mod form 1: min(2/1+R, 2R/1+R) min-mod form 2: min(1,R) Berger et al [5] refers to form1 as slope limiter while form 2 as flux limiter. My understanding is that flux limiters are used directly on flux reconstruction while it is the slope limiters which are employed on the reconstructed solution values. I am aware that flux limiters can be converted into slope limiters if they have the symmetric property. If that is so, in my particular case, I should be using only form 1 of these limiters for reconstruction of my state variables at a given interface? Will it be wrong if I use flux limiters instead? Also, for specific value of k (kappa parameter in MUSCL scheme) are there prescribed limiters or can I use any limiter for any k value? Specifically, if I want to use MUSCL scheme with k=-1 and min-mod limiter and k=1/3 with van Albada limiter, which MUSCL form and which limiter form should I use? I would really appreciate any help from any kind soul on this doubt. Thanks in advance. Regards, [1] S. Gottlieb, C W Shu, E Tadmor, Strong stability preserving higher order time discretization methods, SIAM review, vol 43, 2001. [2] H. NIshikawa, K. Kitamura, A Very simple, carbuncle free, boundary layer resolving, Rotated hybrid Riemann solver, JCP, 2008. [3] Y X Ren, A robust shock capturing schemes based on rotated Riemann solvers, Comput and Fluids, 2003. [4] 'Applied computational fluid dynamics techniques', R. Lohner, 2nd edition, Wiley, 2008. [5] M Berger, M J Aftosmis, S M Murman, Analysis of slope limiters on unstructured grids, 43rd AIAA Aerospace meetings, 2005. ugurtan666 likes this. Last edited by SangeethCFD; October 7, 2017 at 09:05. Reason: added information about time accuracy