- Nektar-users - imperial.ac.uk

New collections functionality
by David Moxey 23 Apr '15

23 Apr '15

Dear all, This morning we merged some new functionality into master that you should be aware of. There is a new library, called Collections, which essentially has been formulated to apply operators such as BwdTrans and IProductWRTBase across multiple elements at once, leading to significant performance boosts in some cases. This is like the global optimisation parameters, but more configurable, easier to use and across many elements at once. Collections are enabled by default, but in their default mode will just replicate the functionality that you see in ExpList, so your simulation results should not change. However, if in your session file, you add the tag: <COLLECTIONS DEFAULT="auto" /> inside the main NEKTAR tag, then the collections library will attempt to figure out what the quickest scheme is at runtime. If you use the '-v' command line option, you will see the auto-tuning results, which is a table of the timings for each strategy. This takes 10-60 seconds to run, depending on problem size. You can do some more advanced setup and manual selection of schemes in the XML file, which is documented in the user guide. Note that certain schemes require increased memory usage. Also, this isn't magic: some solvers, particularly those that are heavily solver-bound such as the incompressible NS equations, aren't likely to see huge benefits. However, DG-based solvers such as the APESolver and CompressibleFlowSolver can observe quite large speedups in certain cases. Let us know via this mailing list if you run into problems or encounter any errors. Cheers, Dave -- David Moxey (Research Associate) d.moxey(a)imperial.ac.uk | www.imperial.ac.uk/people/d.moxey Room 363, Department of Aeronautics, Imperial College London, London, SW7 2AZ, UK.

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Nektar++ workshop invitation, 7-8th July 2015 at ICL
by David Moxey 22 Apr '15

22 Apr '15

Dear all, This email is being sent to invite you to a workshop that we are organising for users and developers of Nektar++ (www.nektar.info) as well as anyone that is interested in seeing some of the applications of our high-order framework in a variety of subject areas. The workshop is being held across two days, Tues 7th and Wed 8th July 2015, here at the South Kensington campus of Imperial College London. Further details about exact times and locations will be sent out closer to the date. Tentatively, the schedule is: - Tues 7th July: a series of casual, short-format presentations from users and developers, with dinner in the evening. - Wed 8th July: a general group session for discussing long-term goals, new features and implementation challenges/bugs that you are finding within the current structure. If you're interested in attending, I'd request that you fill in the doodle poll that we have set up for the event so that we know the number of people to expect: http://doodle.com/iyigwkek7bhddu4b You can choose to attend either or both days, depending on what you find most useful. Please feel free to send this email across to anyone else you think might be interested in attending the workshop. Also, we will be looking for volunteers for presentations on applications involving Nektar++, so please email me if you feel that you will be able to present! They will be around 15-20 minutes with questions, depending on the number of presenters we have on the day. Finally, if you are currently a user or developer of Nektar++ and have not registered for our users mailing list, through which you can get some support for the framework, I'd encourage you to do so here: https://mailman.ic.ac.uk/mailman/listinfo/nektar-users Many thanks, Dave -- David Moxey (Research Associate) d.moxey(a)imperial.ac.uk | www.imperial.ac.uk/people/d.moxey Room 363, Department of Aeronautics, Imperial College London, London, SW7 2AZ, UK.

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Womersley velocity profile
by Kamil ÖZDEN 19 Apr '15

19 Apr '15

Dear All, I want to implement the Womersley solution below for inlet velocity boundary condition. where A is the amplitude of pulsation and is the non-dimensional Womersley number. These are equal to 0.667 and 7.5 respectively. Is there any way to implement this profile in Nektar++ (any extension code etc.) ? Regards, Kamil

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Generating curved edge in ICEM CFD for Nektar++
by Kamil ÖZDEN 03 Apr '15

03 Apr '15

Dear All, I found such a way to generate my meshes to use in Nektar++: 1) First I create my mesh in ICEM CFD. 2) Then I export that mesh from ICEM CFD as a Nastran file (with *.dat extension). 3) After that I open that *.dat file in Gmsh and save it as a *.msh file. 4) Finally I generate my *.xml file from that *.msh file. This works in Nektar++ but I have a problem about generating curved edges in ICEM CFD. There is no such option or I couldn't find how to succeed this. Is there any one who use this method to generate mesh for Nektar or can inform me about generating high order edge in ICEM CFD? NOTE: I've tried to generate curved edge in Gmsh with the imported *.dat file but it didn't work. Regards, Kamil

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Parabolic velocity profile for inlet boundary condition
by Kamil ÖZDEN 31 Mar '15

31 Mar '15

Dear All, In a stenosed pipe flow problem, I specify parabolic velocity profile u=2*(1−(r^2)), where r=sqrt(y^2+z^2) as seen below. /*<BOUNDARYREGIONS>*//* *//* C[7] *//* *//* C[9] *//* *//* C[8] *//* *//* </BOUNDARYREGIONS>*//* *//* *//* <BOUNDARYCONDITIONS>*//* *//* <REGION REF="0">*//* *//* <D VAR="u" VALUE="2*(1-(rad(y,z)^2))" />*//* *//* <D VAR="v" VALUE="0" />*//* *//* <D VAR="w" VALUE="0" />*//* *//* <N VAR="p" USERDEFINEDTYPE="H" VALUE="0" />*//* *//* </REGION>*//* *//* <REGION REF="1">*//* *//* <N VAR="u" VALUE="0" />*//* *//* <N VAR="v" VALUE="0" />*//* *//* <N VAR="w" VALUE="0" />*//* *//* <D VAR="p" VALUE="0" />*//* *//* </REGION>*//* *//* <REGION REF="2">*//* *//* <D VAR="u" VALUE="0" />*//* *//* <D VAR="v" VALUE="0" />*//* *//* <D VAR="w" VALUE="0" />*//* *//* <N VAR="p" USERDEFINEDTYPE="H" VALUE="0" />*//* *//* </REGION>*//* *//* </BOUNDARYCONDITIONS>*//**/ However, since u=0 at wall of the pipe due to no slip boundary condition definition, the calculated value of parabolic velocity profile at the wall (u = 1.5 ) can not be achieved. Is there any way to overcome this problem? Regards, Kamil

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Interest in potential Nektar++ workshop
by David Moxey 20 Mar '15

20 Mar '15

Dear all, As our user base is growing, we are considering arranging a workshop, where users and developers can present their work with Nektar++, as well as provide a forum for discussing long-term goals, feature requests and implementation challenges/bugs that you are finding within the current structure. The purpose of this email is to see if there is sufficient interest to arrange such a workshop. Probably it would take place over summer this year, across one or two days, and take the format of short-form presentations and some general discussion and support sessions. Please let us know by replying to the mailing list if you're interested! Also, if you are aware of any users who are not subscribed to this list, feel free to pass this email on (and encourage them to subscribe!) Cheers, Dave -- David Moxey (Research Associate) d.moxey(a)imperial.ac.uk | www.imperial.ac.uk/people/d.moxey Room 363, Department of Aeronautics, Imperial College London, London, SW7 2AZ, UK.

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Defining kinematic viscosity
by Kamil ÖZDEN 08 Mar '15

08 Mar '15

Dear All, I've a question about defining kinematic viscosity. In general I'm defining kinematic viscosity parameter in a non-dimensional way by taking both diameter and inlet velocity as 1 by dividing dimensional values of these parameters with reference velocity and length values. So kinematic viscosity becomes equal to 1/Re. However, in aortic blood flow tutorial kinvis is calculated by taking D=3.32 mm and mean inlet velocity=1 (there is no unit specified). Is there any inconsistency in terms of units of diameter and velocity? Could you please explain how Kinvis parameter is defined in this tutorial? Is my logic true in defining Kinvis non-dimensionally? Regards, Kamil

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Solution of Navier Stokes equation with steady-state solver
by Kamil ÖZDEN 05 Mar '15

05 Mar '15

Dear All, I want to solve a constricted pipe flow problem (for Re=100) using Navier Stokes equation with steady-state solver of Nektar++. By reading the user guide of Nektar++ I prepared solver info and parameters part of my xml file for this purpose as seen below: /* <SOLVERINFO>*//* *//* *//* *//* *//* *//* *//* *//* *//* *//* </SOLVERINFO>*//* *//* *//* *//* <PARAMETERS>*//* *//* ControlCoeff = 1 *//* *//* FilterWidth = 1 *//* *//* TOL = 10e-9 *//* *//* Kinvis = 0.1 *//* *//* </PARAMETERS>*/ When I tried to run an analysis I got such an error: /*Fatal : Level 0 assertion violation*//* *//*EquationSystem 'SteadyLinearisedNS' is not defined.*//* *//*Ensure equation name is correct and module is compiled.*/ I also tried other equation types (Steady Stokes, Unsteady NS etc.) What is the source of this error? I also want to ask if it is possible to write a history file for steady solutions? Regards, Kamil

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Defining time dependent velocity boundary condition
by Kamil ÖZDEN 03 Mar '15

03 Mar '15

Dear all, I wonder if it is possible to define a time dependent function for velocity boundary condition at the inlet in Nektar++? Like ramp function which gives U(t=0) = 0 and U(t=1) = 1? Regards, Kamil

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Boundary Conditions at Outlet
by Kamil ÖZDEN 24 Feb '15

24 Feb '15

Dear All, I've several questions about outflow boundary conditions for boundary regions and conditions specified below for a pipe flow problem: */<BOUNDARYREGIONS>/**/ /**/ C[2] /**/ /**/ C[3] /**/ /**/ C[1] /**/ /**/ </BOUNDARYREGIONS>/**/ /**/ /**/ <BOUNDARYCONDITIONS>/**/ /**/ <REGION REF="0">/**/ /**/ <D VAR="u" VALUE="0" />/**/ /**/ <D VAR="v" VALUE="0" />/**/ /**/ <D VAR="w" VALUE="1" />/**/ /**/ <N VAR="p" USERDEFINEDTYPE="H" VALUE="0" />/**/ /**/ </REGION>/**/ /**/ <REGION REF="1">/**/ /**/ <N VAR="u" VALUE="0" />/**/ /**/ <N VAR="v" VALUE="0" />/**/ /**/ <N VAR="w" VALUE="0" />/**/ /**/ <D VAR="p" VALUE="0" />/**/ /**/ </REGION>/**/ /**/ <REGION REF="2">/**/ /**/ <D VAR="u" VALUE="0" />/**/ /**/ <D VAR="v" VALUE="0" />/**/ /**/ <D VAR="w" VALUE="0" />/**/ /**/ <N VAR="p" USERDEFINEDTYPE="H" VALUE="0" />/**/ /**/ </REGION>/**/ /**/ </BOUNDARYCONDITIONS>/* 1) What is the meaning of */<N VAR="p" USERDEFINEDTYPE="H" VALUE="0" /> /*and why do we specify such a BC at the wall of the pipe? What happens if I don't specify any pressure BC at the wall of the pipe?*/ /*2) Is there any other option to specify pressure BC at the outlet other than*//**/*/<D VAR="p" VALUE="0" />/*/* ?*/*//*/*For example is it possible to apply the pressure BC at the outlet given below which is specified in a paper (Direct numerical simulation of stenotic flows. Part 1. Steady flow, SONU S. VARGHESE, STEVEN H. FRANKEL AND PAUL F. FISCHER) ? /*In turbulent flows, it is possible to have vortices strong enough to yield a (locally) negative flux at the outflow boundary. Since no flow characteristics are specified on these boundaries, a negative flux condition typically leads to instabilities with catastrophic results. One way to ensure that the characteristics at the exit are always pointing outwards is to force the exit flow through a nozzle, effectively adding a mean axial component to the velocity field. In contrast, schemes based on viscous *//*buffer zones require knowledge of the anticipated space and time scales to ensure that vortical structures are adequately damped as they pass through the buffer zone.*//* *//*This nozzle effect can be imposed numerically without having to change the mesh geometry by imparting a positive divergence to the flow field near the exit (in the spirit of a supersonic nozzle). In the current study, this is done by identifying the layer of elements adjacent to the outflow and imposing a divergence function D(x) that is zero at the upstream end of the layer and ramps to a fixed positive value at the exit. Specifically, we set D(x)=C[1−(x⊥/L⊥)2], where x⊥ is the distance normal to the boundary and L⊥ is the maximum thickness of the last layer of elements. A net gain in mean velocity is obtained over the extent of the layer by integrating the expression for D from x⊥/L⊥=1 to 0. The constant C is chosen such that the gain is equal to the mean velocity prior to the correction.*//* */*/ /*Regards, Kamil

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