Nowadays,
comparative verification of numerical methods is getting more and more
in-demand in science and technology. Usually, the comparative verification is
conducted on a class of problems that have an exact or numerical solution,
acknowledged as reference, or experimental data.
This
paper constitutes the part of investigations on comparative verification of
numerical methods, held with the help of building up a generalized
computational experiment. Generalized computational experiment is computational
technology, built on synthesis of mathematical modeling approaches, parallel
computations and visual analysis of multi-dimensional data. Methods of making
the generalized computational experiment are extensively described in works [1,
2]. Implementation of the generalized computational experiment helps to obtain
and process the numerical solutions not only for one particular problem, but
also for the class of problems, which is set in the area of space of
determining parameters. This turned out to be quite a useful feature in
organizing the comparative verification of numerical methods. The
investigations dedicated to comparative verification of numerical methods with
the help of the generalized computational experiment, are presented in works [3–6].
Presently, the
methods of numerical modeling find expanding applications as addition to the
experiment and as research techniques replacing the experiment in different
academic fields [7].
In
solving evolutionary problems the three classes of numerical methods of
modeling are widely used: finite-difference methods,
finite element
methods
and particle methods [8].
Particle
methods are actively used in modeling the problems of gas dynamics. The model
of continuous media is replaced with discrete model, assembly of particles.
Each particle has a set of attributes, such as mass, speed, position in space.
The condition of the physical system is defined by the set of attributes of a
finite number of particles, and evolution of the system is defined by the laws
of particles’ interaction.
There
are three basic types of particle methods distinguished in scientific
literature [9]: particle-particle (PP), particle-mesh (PM) and particle-particle-particle-mesh
(P3M).
PP
methods use the Lagrangian approach, where the particles move together with the
medium. The the PM methods use Eulerian-Lagrangian approach. The computational
domain is divided with a fixed mesh (Euler approach), but the particles which
move through Eulerian mesh are also taken into consideration (Lagrangian
approach). Particles serve for defining liquid’s parameters (mass, energy, speed),
and Eulerian mesh is used for defining field parameters (pressure, density,
temperature).
In
PP methods the force influencing each single particle is calculated by means of
summing up the forces from the side of all other particles, in the PM methods
the force is a field’s value and is approximated on a mesh. The P3M methods is
a hybrid of PP and PM, where for nearby particles (till some preset distance)
the force is defined the same way as in PP methods, and for more distant ones, the
same way as in PM methods.
In
PP methods the condition of the physical system is described by the set of
positions and speeds of particles. With transition to a new time layer these
values recounted with the use of interaction forces and motion equations. Such
methods are computationally expensive, in the context of PM and P3M.
In
PM methods the field values, which fill the entire space of the physical
system, are approximately presented as values in regularly positioned mesh
nodes. As a result, the force is calculated more economically and quickly, but
way less precisely rather than with the usage of PP method.
The
smoothed particle hydrodynamics (SPH) [10], particle finite element method
(PFEM) [11] and discontinuous particle method [12, 13] are referred
to as the first type. The second type includes the particle-in-cell method
(PIC) [14], large-particle method [15], grid-characteristic methods [16,
17].
As
it was shown in articles [12, 18], the discontinuous particle method enables
the calculation of discontinuities with high precision, which is extremely
important for nonlinear equations in partial derivatives of hyperbolic type.
Suppose
there are
material
points that are at the initial moment in time in coordinates
and moving at
speeds
. This verbal
formulation corresponds to the Cauchy problem:
|
|
(1)
|
The
article [10] shows the transition from (1) to the transfer equation in
differential form:
|
|
(2)
|
That
is, if the coordinates of the points change according to the system of
equations (1), then the density
is a
generalized solution to the Cauchy’s problem for the transport equation (2).
Let's
describe the modification of the discontinuous method with a new variant of
density correction, previously presented in [19]. The particles selected for
correction will be called interacting, and the correction process will be
called interaction. Let's introduce a uniform grid in time with a step
. We consider
the system as a set
macroparticles.
To describe the particles, we introduce the following notation:
is the
coordinate of the center of the
i-th particle at the
k-th moment
of time,
is the
speed of the particle,
is the height
(density) of the particle. Also each particle has a time invariant mass, which
indicates that the method is conservative. If in the past we used the width of
the particle
(Fig. 1), then
the new algorithm is based on the conservation of the mass between the
particles.
Figure
1
– Approximation
of the function by a set of rectangular particles
The
mass between the coordinates of the particles is equal to the half-sum of the
particle masses, and, in the absence of diffusion, it should also remain
constant. Let’s introduce a notation
is the trace of
the mass located between the (i-1)-th and
i-th particles. We
calculate the trace of mass
as the area of
trapezoids:
|
|
(3)
|
Figure
2
– Introduction
of the mass trace
Remember
the values
at the initial
point of time
. Let's perform
the procedure of initializing the parameters of the particles at the initial
point in time. Let be given the initial density
. The
coordinates of the particles
can be evenly
arranged on the design region, where
.
|
|
(4)
|
As
shown in [10], the coordinates of the particles in solving the Hopf’s equation
must satisfy the system of equations:
|
|
(5)
|
Recall that the algorithm of the particle method is built as a
predictor-corrector. First, we solve the system of ordinary differential
equations by Euler's explicit method:
|
|
(6)
|
After
the particles shift, the distances between them change, which leads to a change
in the area of the trapezoid. Therefore, at the stage of the corrector, it is
necessary to change the heights of the particles so that the mass between the
particles remains constant. Consider the possible cases of particle interaction
(Fig. 3):
Figure
3
– Particle
interaction options
1.
A
particle with a higher density runs over a particle with a lower density, which
leads to a decrease in the trapezoidal area between the particles. In this case,
in order to preserve the area of the trapezoid, we will increase the height of
the particle with a lower density.
2.
A
particle with a higher density moves away from a particle with a lower density,
which results in an increase in the trapezoidal area between the particles. In
this case, to preserve the area of the trapezoid, we will reduce the height of
the particle with a higher density.
Using
these rules of particle rearrangement and selection criteria and as a result of
the interaction of the particle with one of the neighbors, the area of the
trapezoid with another neighbor for which correction has already been made can
change, which indicates the error of the algorithm. The particle interactions
that arise in this way are not taken into account.
The
corrector changes the height of the
i-th particle
so that the
trapezoidal area between the particles remains constant:
|
|
(7)
|
Therefore, the height of the i-th particle
in the new
step in time
is defined as:
|
|
(8)
|
The
equations of gas dynamics are expressions of the general laws of mass,
momentum, and energy. Following [20, 21] let's write down a system of equations
for the two-dimensional case in Euler’s variables:
|
|
(9)
|
Perfect
gas,
.
,
,
,
,
is density,
and
-components of
velocity, pressure and total energy.
The
algorithm for solving a two-dimensional problem is similar to a one-dimensional
case. The heights of the particles are found from the initial condition, functions
,
,
,
calculated at the
centers of particles bases (the points
,
).
First,
as in the one-dimensional case, we solve the systems of ordinary differential
equations for the coordinates of 4 types of particles by the Euler’s method.
In
the two-dimensional case, the partner for interaction is chosen by minimizing
the "impact" parameter — the angle
between the
vector of relative velocity and the vector connecting the centers of the
particles (algorithmically maximizing the cosine of this angle).
Let
be a
vector connecting the centers of particles
i
and
j,
and
be the
velocity vector of the particles. Then (Fig. 4):
|
|
(10)
|
Figure
4
– Finding the impact
parameter
Selecting
the
j-th particle for interaction, we proceed to the one-dimensional
problem (Fig.5).
Figure
5
– Transition
to a one-dimensional
problem
Next,
with the help of a corrector, we change the height of the
i-th particle
similarly (7) so that the trapezoidal area between the particles remains
constant:
|
|
(11)
|
From
here we find the preliminary height (so far without taking into account the
pressure forces):
|
|
(12)
|
The
next step of the algorithm is to take into account the forces of pressure. The
difference in pressures to the left and right of the particle leads to a change
in the momentum and energy of the particle, that is, to an increase in the
volume of the corresponding particles. Similarly [10], we obtain calculation
formulas:
The
density, momentum, and energy values calculated in the previous step make it
possible to determine the pressure at the center of the particle. To do this,
you need to use the equation of state.
To
determine the values of the pressure and velocity at the boundary of the
particle, a pressure account scheme based on the "interaction" of the
particles is used. If at step in time at one of the boundaries of the particle
an interaction occurred (in accordance with the criteria described above for a
one-dimensional configuration), then the value of the pressure and velocity at
this boundary was assumed to be equal to the pressure and velocity of the
particle that caused the rearrangement. If no interaction occurred, the
pressure at the boundary was supposed to be the same pressure as the center of
the particle.
Thus,
the volume of
,
and
further
increases.
We
will compare the discontinuous particle method (Particles) with the solvers of
the open source software package OpenFOAM [22]: rhoCentrlFoam (rCF), pisoCentralFoam
(pCF), QGDFoam (QGDF). To do this, by all methods we will solve the classical
two-dimensional non-viscous problems in modeling the oblique shock with all
methods.
The
general flow scheme is presented in Figure 6. A supersonic gas flow with Mach
number
Ì
falls on a flat plate at an angle of β. Before the start
of the plate, an oblique shock S occurs [21]. This problem is considered within
the system of the Euler equations and has an analytical solution [23].
Figure
6
– Flow diagram
At
the input boundary, the parameters of the unperturbed incoming flow are
specified. On the part of the lower boundary corresponding to the flat plate, a
non-flow condition is specified. At the output boundary, the boundary
conditions are set equal to zero of the derivatives of gas-dynamic functions at
the normal to the boundary. At the upper boundary for the velocity components,
the boundary conditions are set similarly to the conditions for the input
boundary. For the remaining gas-dynamic functions of the upper limit, the
boundary conditions are set to zero of the derivatives of the gas-dynamic
functions at the normal to the boundary. At the upper boundary for the velocity
components, the boundary conditions are set similarly to the conditions for the
input boundary. For the other gas-dynamic functions at the upper boundary, the
conditions are set similarly to the conditions for the output boundary.
Fig.
7 shows the established solution for the pressure field. Angle of incidence of
the incoming flow
β
= 10°,
Mach number
M
= 2. As a result of the steadying, a qualitative
picture of the flow was obtained, corresponding to the analytical solution. It
should be noted that the particles are presented in the form of circles for
ease of perception.
Figure
7
– Pressure
distribution
Figure
8 shows an animation of how the particle method works. It can be seen that in
the region of large gradients, the particle size decreases, which corresponds
to the thickening of the grid for grid methods.
Figure
8
– Animation of
the solution of the problem of supersonic flow around a wedge by the particle
method
Carefully
consider the behavior of gas-dynamic functions in the vicinity of the oblique shock.
Figure 9 shows a comparison of all solvers in the form of pressure distribution
along the horizontal line AA1 crossing the design area at a distance from the
lower boundary of
y
= 0.15 (see Fig. 6). The exact solution is
shown by the dotted line. Numerical methods are indicated by different colors
shown in the corresponding table in Fig. 9.
Figure
9
– Pressure
distribution along the horizontal line
The
presented figure allows you to judge the degree of smearing of the shock wave
front for all the methods considered. The particle method smears the gap into
the smallest number of cells, but the shock wave front is shifted towards the
area with increased density. Of the remaining methods, the best result is given
by the solver rhoCentralFoam. The solver QGDFoam smears the front of the shock
wave, and the resulting oscillations are also noticeable at the top of the
shock wave.
Also,
to assess the deviation of the obtained numerical results from the known exact
solution in the entire calculated area, we use an analogue of the norms of L2:
|
|
(14)
|
Here
ym
is the pressure
p
of the particle
m,
Sm
is the area of the particle. All calculations were carried out when setting the
following parameters: flow angle β is
6°, 10°, 15°, 20°,
Mach number
M∞
varies
from 2 to 3 in increments of 0.5.
Thus, the solution was implemented in the region
of the space of the determining parameters. In the incoming flow, the following
gas-dynamic parameters were set: pressure P∞
= 101325
Pa, temperature T∞
= 300 K. The set of calculations
with variable parameters is part of the generalized computational experiment
described in the works [2–6], where the results of comparative verification of
numerical methods implemented in the solvers of the open source software
package OpenFOAM [21] were presented. Tables 1–3 show the result of calculating
the error rate for pressure.
Table
1
–
Deviation from the exact
solution, U=2M
|
Angle
|
Particles
|
rCF
|
pCF
|
QGDF
|
|
6
|
0.012982
|
0.013287
|
0.013744
|
0.014393
|
|
10
|
0.019326
|
0.020839
|
0.021740
|
0.021850
|
|
15
|
0.029315
|
0.029893
|
0.031227
|
0.028868
|
|
20
|
0.037731
|
0.038307
|
0.040417
|
0.032726
|
Table
2
–
Deviation from the exact
solution, U=2.5M
|
Angle
|
Particles
|
rCF
|
pCF
|
QGDF
|
|
6
|
0.014283
|
0.015357
|
0.016346
|
0.018502
|
|
10
|
0.023192
|
0.025023
|
0.026259
|
0.029376
|
|
15
|
0.035997
|
0.036192
|
0.037452
|
0.042189
|
|
20
|
0.046724
|
0.045692
|
0.047210
|
0.051230
|
Table
3
–
Deviation from the exact
solution, U=3M
|
Angle
|
Particles
|
rCF
|
pCF
|
QGDF
|
|
6
|
0.017582
|
0.017717
|
0.018736
|
0.022639
|
|
10
|
0.030211
|
0.029721
|
0.030812
|
0.037448
|
|
15
|
0.046274
|
0.043788
|
0.045160
|
0.055111
|
|
20
|
0.057836
|
0.055751
|
0.057216
|
0.068286
|
Figure
10 shows the error surfaces in the L2
norm for all four methods involved
in the comparison. Calculations for the QGDFoam solver were made with a selected
value of α = 0.1.
It
can be seen that the error surfaces of the solvers rhoCentralFoam and
pisoCentralFoam are very close, that is, the methods have similar
characteristics. At β = 10° and
M
= 3, the
particle method gives less accuracy than the solver rhoCentralFoam. At
β = 15°, the particle method gives less accuracy than the solver
QGDFoam at
M
= 2 and less accuracy than the solvers rhoCentralFoam
and pisoCentralFoam at
M
= 3. At β=20°, the particle
method gives less accuracy than the solvers rhoCentralFoam and pisoCentralFoam
at
M
= 3. In other cases, the discontinuous particle method is
more accurate than the other compared methods.
Figure
10
– Error
surfaces
Fig.
11 shows a close-up of Fig. 10. The error surface of the QGDFoam solver is
hidden, as it is very different from other surfaces, which is noticeable in the
figure without magnification. As can be seen, the particle method for a large
Mach number and angle of attack is only slightly worse in accuracy than the
rhoCentralFoam solver.
Thus,
the generalized computational experiment suggests that the discontinuous
particle method is suitable for solving problems with a strong gradient. Not as
high accuracy as in solving one-dimensional problems is due to the fact that
although the particle method smears the shock wave front much less (as can be
seen from Fig.9), the front is shifted, which negatively affects the accuracy
of the method. However, there is a great potential for using the discontinuous
particle method to solve practical problems of mathematical modeling.
Figure
11
– Close-up of
Figure 10
With
the help of the discontinuous shapeless particle method, the problem of gas
dynamics on the formation of an oblique shock is solved. The results obtained
were compared with the exact solution in the L2
norm. Also, the
results were processed using scientific visualization tools. It can be seen
that the gap is smeared into 2-3 cells relative to the front of the oblique shock,
which is less than the smearing of the gap with a solver rhoCentralFoam on
comparable grids. Together, this suggests that the discontinuous particle
method solves two-dimensional problems of gas dynamics, is especially well
suited for solving two-dimensional problems with emerging shock waves. The
obtained result is very interesting from the point of view of implementing
comparative verification of numerical methods on a reference solution using a
generalized computational experiment [1–6].
Historically,
the particle method has been used in the problems of finding the interfaces of
media, gas-dynamic problems of flowing around bodies, and problems of dynamics
of multiphase media. The developed method should increase the computational
efficiency of the application of particle methods in these traditional areas,
for which research is to be done on comparative verification and evaluation of
the effectiveness of the method.
Calculations
were carried out using the hybrid supercomputer K100, installed in the
Supercomputer
Center for Collective Use of the Keldysh Institute of Applied Mathematics RAS.
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