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Example Guide
The OptiStruct Example Guide is a collection of solved examples for various solution sequences and optimization types and provides you with examples of the real-world applications and capabilities of OptiStruct.
Topography Optimization
The examples in this section demonstrate how topography optimization generates both bead reinforcements in stamped plate structures and rib reinforcements for solid structures.
OS-E: 3005 Eigenvalue Maximization
An irregularly shaped plate is optimized to increase its natural frequencies.

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View new features for OptiStruct 2024.1.
Overview
OptiStruct is a proven, modern structural solver with comprehensive, accurate and scalable solutions for linear and nonlinear analyses across statics and dynamics, vibrations, acoustics, fatigue, heat transfer, and multiphysics disciplines.
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Discover OptiStruct functionality with interactive tutorials.
User Guide
This manual provides detailed information regarding the features, functionality, and simulation methods available in OptiStruct.
Reference Guide
This manual provides a detailed list and usage information regarding input entries, output entries, and parameters available in OptiStruct.
Example Guide
The OptiStruct Example Guide is a collection of solved examples for various solution sequences and optimization types and provides you with examples of the real-world applications and capabilities of OptiStruct.
- Nonlinear Small Displacement Analysis
  This section presents nonlinear small displacement analysis examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Nonlinear Large Displacement Analysis
  This section presents nonlinear large displacement analysis examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Nonlinear Transient Analysis
  This section presents nonlinear transient analysis examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Frequency Response Analysis
- Normal Modes Analysis
  This section presents normal modes analysis examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Complex Eigenvalue Analysis
  This section presents complex eigenvalue analysis examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Thermal and Heat Transfer Analysis
  This section presents thermal and heat transfer analysis examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Analysis Techniques
  This section presents analysis technique examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Topology Optimization
- Size (Parameter) Optimization
- Free-shape Optimization
- Shape Optimization
  This section presents shape optimization example problems, solved using OptiStruct. Each example uses a problem description, execution procedures and results to demonstrate how OptiStruct is used in shape optimization.
- Topography Optimization
  The examples in this section demonstrate how topography optimization generates both bead reinforcements in stamped plate structures and rib reinforcements for solid structures.
  - OS-E: 3000 Cross-section Optimization of a Spot Welded Tube
    A tube made of two sheet metal pieces is intended to carry a load in both bending and torsion. The cross-section of the tube may be of any shape, but due to manufacturing requirements, it must remain constant through the entire length.
  - OS-E: 3005 Eigenvalue Maximization
    An irregularly shaped plate is optimized to increase its natural frequencies.
  - OS-E: 3010 Multi-plane Symmetric Reinforcement Optimization for a Pressure Vessel
    A rectangular thin-walled box is to be used to store fluid. The outward bulging of the sides of the container (due to the pressure of the contents) is to be minimized. Additionally, the maximum outward displacement of the side panels must be below a given value.
  - OS-E: 3015 Rectangular Pressure Vessel
    This example involves a rectangular, thin-walled container used for storing fluid. The objective is to minimize the outward bulging of the sides of the container caused by the pressure of its contents. Additionally, the maximum outward displacement of the side panels must be below a given value.
  - OS-E: 3020 Two-Layer Stamped Control Arm
    An automobile control arm is manufactured by using two stamped plates joined at the seam.
  - OS-E: 3025 Optimization of the Modal Frequencies of a Disc using Constrained Beading Patterns
    Finding a good reinforcement pattern for a single modal frequency is difficult when dealing with beaded plates since adding stiffness in one direction often reduces stiffness in another direction.
  - OS-E: 3030 Plate in Torsion
    Demonstrates the power of topography optimization.
  - OS-E: 3035 Surface Optimization of a Control Arm
    Topography optimization has applications beyond creating beads in shell surfaces. Since the basic topography approach can be applied to any model containing large fields of shape variables, it lends itself to solid model applications, as well.
  - OS-E: 3040 Forge a Design Reference Out of a Solid Block
    Pattern grouping lends itself very well to applications where manufacturing conditions must be met. In this example, topography optimization is used to form a design concept out of a solid block. Manufacturing the design concept using a casting method is preferable.
- ESLM Optimization
  The examples in this section demonstrate how the Equivalent Static Load Method (ESLM) can be used for the optimization of flexible bodies in multibody systems.
- Multiphysics
  This section presents multiphysic examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Rotor Dynamics
- Response Spectrum
  This section presents response spectrum examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Nonlinear Explicit Analysis
  This section presents nonlinear explicit analysis examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
- Piezoelectric Analysis
  This section presents piezoelectric analysis examples generated using OptiStruct. Each example uses a problem description, execution procedures, and results to demonstrate how OptiStruct is used.
Verification Problems
This manual presents solved verification models including NAFEMS problems.
Frequently Asked Questions
This section provides quick responses to typical and frequently asked questions regarding OptiStruct.

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OS-E: 3005 Eigenvalue Maximization

An irregularly shaped plate is optimized to increase its natural frequencies.

Model Files

Before you begin, copy the file(s) used in this example to your working directory.

eigenplate.fem

Model Description

The plate is supported at ten bolt locations around its perimeter. The edge of the plate is turned downward to add stiffness.

top16 — Figure 1. Cover Plate Model with Constraints Shown

The red areas are excluded from the design domain. The blue area is open for OptiStruct to add a bead reinforcement pattern. The bead is drawn upward with respect to the plate orientation. The DTPG card used is as follows. Four different runs were made using different values for the draw height. The first run was made with a draw height of 20mm, the second with 40mm, the third with 60mm, and the fourth with 80mm.


(1)	(2)	(3)	(4)	(5)	(6)	(7)	(8)	(9)	(10)
DTPG	1	PSHELL	5
	20.0	60.0	YES	20.0	`NORM`			NONE

The optimization is set up to maximize the frequencies of the first six modes (minimizing the sum of the weighted inverse eigenvalues) and to ensure that the first three modes were above certain design constraints. This is accomplished by placing the following cards in the subcase definition:

DESOBJ(MIN): 1
DESSUB: 101

The following cards are placed in the Bulk Data section:


DRESP1	11	freq1	`FREQ`			1
DRESP1	12	freq2	`FREQ`			2
DRESP1	13	freq3	`FREQ`			3
DRESP1	1	wfreq	`WFREQ`
DCONSTR	101	11	400.0
DCONSTR	101	12	500.0
DCONSTR	101	13	600.0
DRESP2	1	wfreq	900

Results

Setting constraints on the first three modes results in separations between the frequency values of the modes and prevents OptiStruct from falling into local minimums when optimizing the modes. This approach ensures that a minimum performance criterion is satisfied.

Note: For the 40mm, 60mm, and 80mm draw height runs, the constrained frequencies are higher than those shown above.

The solutions generated for the plate runs are:

top17 — Figure 2. Solution for Plate with Draw Height Equal to 20mm

top18 — Figure 3. Solution for Plate with Draw Height Equal to 40mm

top19 — Figure 4. Solution for Plate with Draw Height Equal to 60mm

top20 — Figure 5. Solution for Plate with Draw Height Equal to 80mm

The reinforcement patterns have a similar shape, but runs with a higher maximum draw height use more levels of draws throughout the plate. All of the solutions made good engineering sense, connecting the weak areas of the plate with beads running primarily across the short span of the plate. These beads were fluidly connected across the long span of the plate allowing the beads to reinforce each other.