FEMtools Optimization is a toolbox for solving general
optimization problems and more specifically for structural
design optimization. In combination with
FEMtools
Model Updating, it provides the unique possibility to
perform design optimization on validated and updated finite
element models.
Based on the acting loads, the design constraints, and the
required structural behavior, FEMtools Optimization computes the
optimal design parameters for the considered component or
structure. The state-of-the-art optimization techniques of
FEMtools Optimization enable to increase the performance of the
considered component considerably faster than conventional
development methods. FEMtools Optimization has an open
architecture providing virtually unlimited flexibility in the
problem definition and offering the possibility to solve the
optimization problem using your preferred FE-solver.
FEMtools Optimization contains modules for:
Sensitivity Analysis
Sensitivity analysis is a technique that allows an analyst to
get a feeling on how structural responses of a model are
influenced by modifications of parameters like spring stiffness,
material stiffness, geometry etc. Sensitivity analysis can be
used for the following purposes:
- What-If analysis - Study the effect of modeling
assumptions on the modal parameters or on other response
types.
- Variational Analysis
- Pretest analysis - Sensitivity analysis can be
used in pretest planning applications like studying the
effect of transducer mass loading on the modal parameters.
- Identify sensitive and insensitive areas of the
structure for given response and parameter combinations
- This will help the analyst to decide which parameters and
responses to include in the selection for model updating.
- Model updating - The sensitivity matrix is
inverted to find a gain matrix. This gain matrix is
multiplied with the difference between predicted and
reference response values to find the required parameter
change to compensate for this error.
- Design optimization - Find the optimal locations
to modify the structure in order to shift modal parameter
values or other response types.
- Acoustic sensitivities - Structural sensitivities
computed with FEMtools can be exported to acoustic analysis
packages where they are used for the calculation of acoustic
sensitivities.
Sensitivity coefficients quantify the variation of a response
value (e.g. resonance frequency or mass) as a result of
modifying a parameter value. The coefficients obtained for all
combinations of responses and parameters are stored in a
sensitivity matrix. Analyzing this matrix yields information on
the sensitive and insensitive zones of the structure. Color
graphics are available to visualize these different zones and
enable a fast optimization of the parameter selection.
Sensitivity analysis and model updating require that the user
select reference responses and parameters.
Sensitivity coefficients are computed internally by FEMtools
using a differential or finite difference method. The
possibilities depend on the parameter type and on the element
formulation. Alternatively, externally computed sensitivity
coefficients can be imported. For example, sensitivities
computed using SOL 200 in Nastran can be imported in FEMtools
for model updating.
Key Features
- Selection of all element material properties,
geometrical properties, boundary conditions, lumped masses,
and damping factors as parameters.
- Selection of mass, static and dynamic displacements,
resonance frequencies, modal displacements, MAC, FRFs, and
FRF correlation functions as responses
- Sensitivity for local and global parameters.
- Internal sensitivity analysis :absolute or normalized
sensitivities, finite difference and differential
sensitivities
- Pre- and postprocessing of external sensitivity analysis
(Nastran SOL 200)
- Sensitivity and gain matrix analysis.
Structural Responses
The following reference response types can be selected for
sensitivity analysis:
- Static displacements
- Resonance frequencies
- Individual modal displacements
- MAC-values
- Frequency Response Functions (FRF) values (amplitudes at
given frequency)
- FRF Correlation Functions values (signature and
amplitude correlation)
- Operational displacement, velocities or accelerations
Design Variables
The following parameter types can be selected for sensitivity
analysis:
- Material properties - Young's modulus (isotropic
or orthotropic), Poisson's ratio, shear modulus and mass
density.
- Geometrical element properties - Spring stiffness,
plate thickness and beam cross-sectional properties.
- Lumped properties - Lumped stiffness (boundary
conditions) and lumped masses.
- Damping properties - Modal damping, Rayleigh
damping coefficients, viscous and structural damper values.
Parameter can be selected at either the local or the global
level:
- Local parameters refer to an individual element.
- Global parameters refer to sets of elements
instead of an individual element.
Any arbitrary objective or constraint function can be used
for optimization by programming it using the FEMtools Script
language. There are no fixed limits on the number of
optimization parameters, objective functions or constraints.
Optimization Problems:
FEMtools Optimization is build around a powerful general
non-linear optimization solver the can handle the following
types of optimization problems:
- Constrained Optimization - Optimization
problems that include an arbitrary number of non-linear
constraints.
- Multi-Objective Optimization -
Optimization problems that include an arbitrary number of
objective functions.
- Least-squares distance - Optimization
problems that focus an minimizing the least-squares distance
with a set of reference data.
- Pareto Optimization
Size optimization allows optimizing the properties of
designable elements like bars, plates, etc.
- Easy selection of a wide range of sizing parameters..
- Fast gradient computation with the FEMtools sensitivity
module.
- Full flexibility in the problem definition by using the
FEMtools Script language.
The shape optimization module optimizes the shape of an
existing component.
Features:
The FEMtools shape optimization module offers the following
features:
- Modifying FE-models without requiring the underlying CAD
data.
- Possibility to handle large mesh deformations by using
mesh morphing technology.
- Full flexibility in the problem definition by using the
FEMtools Script language.
Mesh Morphing:
The shape optimization module offers three methods to deform
the mesh of the FE-model:
- Lattice-Based Free Mesh Deformation -
Deformation of the mesh based on a set of brick shaped
lattice cells. The mesh is deformed by moving the vertex
points of the lattice cells.
- Skeleton-Based Free Mesh Deformation -
Deformation of the mesh based on a set of control points
that are connected by a number of curves (line, spline or
circle). The mesh is deformed by moving the control points.
- Using a Shape Basis - The deformed mesh
is a linear combination of the shapes that define the shape
basis. Any arbitrary shape can be used as basis shape
Topometry optimization enables element-by-element size
optimization of FE-models.
Design Problems:
The topometry optimization module provides a solution for the
following design problems:
- Minimum static compliance design -
Provides the topometry that minimizes the static compliance
considering all the defined load cases.
- Maximum fundamental eigenvalue design -
Provides the topometry that maximizes the resonant frequency
of the first vibration mode.
- Minimum maximal FRF-level - Provides
the topometry that minimizes the compliance under a harmonic
load
Filters:
The topometry module offers the following filters:
- First order checkerboard filters.
- Second order checkerboard filters.
- Mesh independent filters.
Manufacturing Constraints:
- Symmetry constraints.
- Extrusion constraints.
- User-defined manufacturing constraints.
Topology optimization module can handle both 2D and 3D design
spaces.
Design Problems:
The topology optimization module provides a solution for the
following design problems:
- Minimum static compliance design -
Provides the topology that minimizes the static compliance
considering all the defined load cases.
- Maximum fundamental eigenvalue design -
Provides the topology that maximizes the resonant frequency
of the first vibration mode.
- Minimum dynamic compliance design -
Provides the topology that minimizes the compliance under a
harmonic load
Filters:
The topology module offers the following filters:
- First order checkerboard filter..
- Second order checkerboard filter.
Manufacturing Constraints:
The following constraints are available to improve the
manufacturability of the optimal design:
- Minimum member size constraints.
- Symmetry constraints.
- Extrusion constraints.
- Die-casting constraints.
- User-defined manufacturing constraints.
User Interface
-
All definition, editing and analysis
accessible via intuitive menus and dialog boxes or using
free format commands for batch processing and process
automation.
-
Complete electronic documentation.
-
Dedicated graphics viewers for model
inspection and results evaluation.
-
Point-and-click interactive selection.
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Direct access to FEA and test data.
-
Unlimited customization and extension using
FEMtools Script language.
Prerequisites
Options
-
FEMtools Model Updating.
-
NASTRAN interface and driver.
-
ANSYS interface and driver
-
ABAQUS interface and driver.
-
UNIVERSAL FILE interface and driver
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