Three direct solvers and one iterative solver are available for the solution of the set of equations.
In finite element analysis, a problem is represented by a set of algebraic equations that must be solved simultaneously. There are two classes of solution methods: direct and iterative.
Direct methods solve the equations using exact numerical techniques. Iterative methods solve the equations using approximate techniques where in each iteration, a solution is assumed and the associated errors are evaluated. The iterations continue until the errors become acceptable.
The software offers the following choices:
| Automatic |
The software selects the solver based on the study type,
analysis options, contact conditions, etc. Some options and conditions
apply only to the Intel Direct Sparse or FFEPlus solver. |
| FFEPlus
(iterative) |
The FFEPlus solver uses advanced matrix reordering
techniques that are more efficient for large problems. In general,
FFEPlus is faster in solving large problems and it becomes more
efficient as the problem gets larger (up to the maximum memory
available). For every 2,000,000 degrees of
freedom, you need 1GB of RAM. In general, the FFEPlus solver
requires less RAM than the Intel Direct Sparse
solver.
|
| Large
Problem Direct Sparse |
By leveraging enhanced memory-allocation algorithms,
the Large Problem Direct Sparse solver can handle simulation problems
that exceed the physical memory of your computer. When the size of the model exceeds the maximum memory
available, the Large Problem Direct Sparse is the most efficient
solver.
The Large Problem Direct Sparse
and Intel Direct Sparse solvers are more efficient than the FFEPlus
solver at taking advantage of multiple cores.
|
| Intel
Direct Sparse |
The Intel Direct Sparse solver is available for static,
thermal, frequency, linear dynamic, nonlinear studies, and topology
studies. By leveraging enhanced memory-allocation
algorithms and multicore processing capability, the Intel Direct
Sparse solver improves solution speeds for simulation problems that
are solved in-core.
The Intel Direct
Sparse solver is more efficient at taking advantage of multiple
cores.
|
Choosing a Solver
The Automatic choice for a solver is the default option for Static,
Frequency, Buckling, and Thermal studies.
In the case of multiarea contact problems, where the area of contact is found
through several contact iterations,
the
Intel Direct Sparse solver is preferred.
While all solvers are efficient for small problems (25,000 DOFs or
less), there can be big differences in performance (speed and memory usage) in
solving large problems.
If a solver requires more memory than available on the computer, then
the solver uses disk space to store and retrieve temporary data. When this situation
occurs, you get a message saying that the solution is going out of core and the
solution progress slows down. If the amount of data to be written to the disk is
very large, the solution progress can be extremely slow. In these cases (for static
and nonlinear studies), use the Large Problem Direct Sparse.
The following factors help you choose the proper solver:
| Size of the problem |
In general, FFEPlus is faster in
solving problems with degrees of freedom (DOF) over 100,000. It
becomes more efficient as the problem gets larger. |
| Computer resources: Available RAM
and number of CPUs (core or processors) |
The Large Problem Direct Sparse leverages multicore
processing capability and improves solution speed for static and
nonlinear studies. |
| Material properties |
When the moduli of elasticity of
the materials used in a model are very different (like Steel and
Nylon), then iterative methods could be less accurate than direct
methods. The direct solvers are recommended in such cases. |
| Analysis features |
Analysis with No Penetration
contacts and Bonded contacts enforced using constraint equations
will typically solve faster with the direct solvers. |
Depending on the study type, the following recommendations apply:
| Static |
Use the Intel Direct Sparse and Large Problem Direct
Sparse when you have enough RAM and multiple CPUS for solving:
- Models with contact interactions, especially
when you turn on the friction effects.
- Models with parts that have widely different
material properties.
- Mixed-mesh models
For a
linear static analysis, the iterative FFEPlus solver is
less demanding on memory as it requires 1GB of RAM for
every 2,000,000 degrees of freedom (dof).
|
| Frequency and Buckling |
Use the FFEPlus solver to calculate
any rigid body modes. A body without any restraints has six
rigid body modes.
Use the Intel Direct Sparse solver for:
- Considering the effect of loading on the
natural frequencies
- Models with parts that have widely different
material properties.
- Models where independent mesh is bonded using constraint
equations.
- Adding soft springs to stabilize
inadequately supported models (buckling studies).
Simulation uses the Subspace iteration method
as the eigenvalue extraction method for the Intel Direct
Sparse solver, and the Lanczos method for the FFEPlus and
Large Problem Direct Sparse solvers. It is more efficient to
use Lanczos with iterative solvers like FFEPlus.
Subspace can utilize the back and forth
substitution of the Intel Direct solver within its iteration
loop to evaluate the eigenvectors (only needs to decompose
the matrix once.) That is not possible with iterative
solvers.
|
| Thermal |
Thermal problems have one degree
of freedom (DOF) per node, and hence their solution is usually much
faster than structural problems of the same number of nodes. For
very large problems (larger than 500.00 dofs), use the FFEPlus
solver. |
| Nonlinear |
For Nonlinear studies of models
that have more than 50,000 degrees of freedom, the FFEPlus solver is
more effective in giving a solution in a smaller amount of time. The
Large Problem Direct Sparse solver can handle cases where the
solution is going out of core. |
Solver Status
The Solver Status window appears when you run a study. In addition to progress information, it displays:
- Memory usage
- Elapsed time
- Study-specific information such as degrees of freedom, number of
nodes, number of elements
- Solver information such as solver type
- Warnings
The Intel Direct Sparse solver does not provide a solver progress report status.
All studies that use the FFEPlus (iterative) solver (except frequency and
buckling) let you access the convergence plot and solver parameters. The convergence
plot helps you visualize how the solution is converging. The solver parameters let
you manipulate the solver iterations so that you can either improve accuracy or
improve speed. You can either use the solver's preset values or change:
- Maximum number of iterations (P1)
- Stopping threshold (P2)
To improve accuracy, decrease the stopping threshold value. In slowly converging
situations, you can improve speed by increasing the stopping threshold value or by
decreasing the maximum number of iterations (with the understanding that the results
accuracy can be affected.)
Multicore Processing
The table lists the multicore processing specifications of
simulation solvers for each Simulation license.
| Solvers |
Simulation Licenses - Limited to Maximum of 8
Physical Cores |
Simulation Licenses - No Limit on Number of
Physical Cores |
- FFEPlus
- Intel Direct
Sparse
- Large Problem
Direct Sparse
|
- Simulation Xpress
FFEPlus is the only solver option for Simulation
Xpress.
- Simulation in SOLIDWORKS Premium
- SOLIDWORKS Simulation Standard
|
- SOLIDWORKS Simulation Professional
- SOLIDWORKS Simulation Premium
|