Nonlinear Static Analysis
This solution sequence performs static nonlinear analysis. Static inherently implies that a process occurring in real-time is being simulated infinitely slowly.
This allows the equilibrium equation to be satisfied at each step and inertia, momentum effects are ignored. Therefore, the possibly dynamic problem can be solved as a static problem (static).
Nonlinearity Sources
Geometric Nonlinearity
In analyses involving geometric nonlinearity, changes in geometry as the structure deforms are considered in formulating the constitutive and equilibrium equations. Many engineering applications require the use of large deformation analysis based on geometric nonlinearity. Applications such as metal forming, tire analysis, and medical device analysis. Small deformation analysis based on geometric nonlinearity is required for some applications, like analysis involving cables, arches and shells. Such applications involve small deformation, except finite displacement or rotation.
Material Nonlinearity
Material nonlinearity involves the nonlinear behavior of a material based on current deformation, deformation history, rate of deformation, temperature, pressure, and so on.
Constraint and Contact Nonlinearity
Constraint nonlinearity in a system can occur if kinematic constraints are present in the model. The kinematic degrees-of-freedom of a model can be constrained by imposing restrictions on its movement. In OptiStruct, constraints are enforced with Lagrange multipliers.
In the case of contact, the constraint condition is based on inequalities and such a constraint generally does not allow penetration between any two bodies in contact.
Follower Load
Applied loads can depend upon the deformation of the structure when large deformations are involved. Geometrically, the applied loads (Forces or Pressure) can deviate from their initial direction based on how the model deforms at the location of application of load. In OptiStruct, if the applied load is treated as follower load, the orientation and/or the integrated magnitude of the load will be updated with changing geometry throughout the analysis.
Nonlinear Static Analysis Types
The following analysis types are available in the Static Analysis domain within OptiStruct to solve nonlinear models.
Small displacement analysis cannot handle all the nonlinearities specified in the previous section. In such cases, Large displacement analysis can be used. Currently, small displacement analysis is used by default and large displacement analysis can be activated (LGDISP), if required.
Small Displacement Analysis
In small displacement analysis the sources of nonlinearity are restricted to contact, GAP elements, and MATS1 elastic-plastic material. Geometric nonlinearities, follower loads, and large strain elasto-plasticity cannot be handled by small displacement analysis. As a typical guideline, small displacement analysis should be limited to small strains (some 5 percent strain) in both translation and rotation. There is no update of gap/contact element locations or orientation due to the deformations. They remain the same throughout the nonlinear computations. The orientation may change, however, due to geometry changes in optimization runs.
Large Displacement Analysis
Large Displacement Nonlinear Static Analysis (LGDISP) is used for the solution of problems wherein the load response relationship is nonlinear and large structural displacements are involved. The source of this nonlinearity can be attributed to multiple system properties, for example, materials, geometry, nonlinear loading and constraints. Currently, in OptiStruct the large displacement capabilities include large strain elasto-plasticity (MATS1), hyperelasticity of polynomial form (MATHE), contact with small tangential motion, deformation dependent loads (follower loads), and rigid body constraints.
Nonlinear Solution Method
Nonlinear problems are generally history dependent. In order to achieve a certain level of accuracy, the solution must be obtained in a series of small increments.
For this purpose you need to solve the equilibrium equation at each increment and a corresponding increment size is selected. Newton's method is used to solve the nonlinear equilibrium equation in OptiStruct. If the solution is smooth, quadratic of rate of convergence may be achieved when compared with other methods. This method is also very robust in highly nonlinear situations.
Choosing a suitable time increment is very important. In OptiStruct, an automatic time increment control is available. It should be suitable for a wide range of nonlinear problems and, in general, is a very reliable approach. In future OptiStruct versions, additional user control options to set up automatic time increments may be provided.
The automatic time increment control functionality measures the difficulty of convergence at the current increment. If the calculated number of iterations is equal to optimal number of iterations for convergence, OptiStruct will proceed with the same increment size. If a lesser number of iterations is required to achieve convergence, the increment size will be increased for next increment. Similarly, if it is determined that too many iterations are required, the current increment will be attempted again with a smaller increment size.
This form is readily produced by adding ${K}_{n}$ ${u}_{n}$ to both sides of Newton's equation, and has certain advantages in practical implementations.
Incremental Loading
This procedure, known as incremental loading, helps to keep the consecutive iterations closer to the true load path, thereby improving the chances of obtaining a final, converged solution (though usually at the expense of an increased total number of iterations).
Nonlinear Convergence Criteria
In order to assess whether the nonlinear process has converged, a number of convergence criteria are available. These criteria and respective tolerances can be selected on the NLPARM Bulk Data Entry card.
The basic principle in assessing nonlinear convergence is to compare an error measure of the solution with a pre-determined tolerance level. When the error falls below the specified tolerance, the problem is considered converged. In a case of multiple, simultaneous convergence criteria, all criteria need to be satisfied for the solution to be converged.
Relative Error in Displacements
Where, $A$ is a normalizing vector consisting of square roots of diagonal elements of stiffness matrix $K$, ${A}_{i}=\sqrt{{K}_{ii}}$
$k=\frac{q}{1-q}$ for small displacement nonlinear analysis and the value of $q$ is calculated as:
$k=1$ for large displacement nonlinear analysis.
Relative Error in Terms of Loads
The load vector $f$ in this formula includes nodal reactions due to specified displacements.
Relative Error in Terms of Work
Problem Setup
Small Displacement Nonlinear Analysis
The setup for the small displacement nonlinear solution is shown below. The static loads and boundary conditions are defined in the Bulk Data Entry section of the input deck. They need to be referenced in the Subcase Information Entry section using an SPC and LOAD statement in a SUBCASE. Each SUBCASE defines a load vector. Loads or enforced displacements are not mandatory for nonlinear quasi-static solutions, if GAP or CONTACT elements are present in the model.
To indicate that a nonlinear solution is required for any subcase, a Subcase Information Entry command NLPARM needs to be present for the subcase. This command, in turn, points to the Bulk Data Entry NLPARM that contains the convergence tolerances and other nonlinear parameters.
SUBCASE 10
SPC = 1
LOAD = 2
NLPARM = 99
.
.
BEGIN BULK
NLPARM 99 12 UPW+1.1e-5
.
- Nonlinear gap and contact analysis are also supported in optimization.
- Inertia relief is supported for nonlinear static analysis. Any nonlinearity (contact, geometry and material) can be included in nonlinear static analysis with inertia relief.
- Plasticity is supported with membrane elements (first and second order) for small and large displacement nonlinear static analysis. Among the available hardening rules in the MATS1 entry, isotropic, kinematic and mixed hardening types are supported with membrane elements.
Large Displacement Nonlinear Analysis
- PARAM, LGDISP,1 is used to activate large displacement analysis for all subcases containing the NLPARM Subcase Information Entry in the model. Subcase-specific Large Displacement Analysis can be activated via NLPARM(LGDISP)=SID, wherein, SID references a NLPARM Bulk Data Entry.
- To indicate that a nonlinear solution is required for any subcase, the NLPARM Subcase Information Entry should be included in the corresponding subcase.
- This Subcase Information Entry, in turn, references a NLPARM Bulk Data Entry that contains the convergence tolerances and other nonlinear parameters.
- NLADAPT Bulk/Subcase Entry can be used to control the number of cutbacks, MAX/MIN time increment. With NLADAPT, you can also add the contact status change in convergence criteria and activate the linear extrapolation in Newton-Raphson method.
- If constraints or contacts are defined in the model, the matrix profile may be updated over time, so it is recommended that hash assembly is used for nonlinear analysis. This is activated using PARAM,HASHASSM,YES.
- Loads can be treated as Follower loads by using the
FLLWER Bulk Data Entry and FLLWER
Subcase Information Entry. Additionally, PARAM,
FLLWER can be used for global activation/deactivation
of Follower Loads. Follower Loads can only be activated for Large
Displacement Nonlinear Analysis, consequently,
PARAM,LGDISP,1
(or subcase-specific
NLPARM(LGDISP)=SID)
should be added to the input file. If a large displacement nonlinear subcase
contains a FLLWER Subcase Information Entry while
PARAM,FLLWER is present in the
deck, the follower force calculation parameters defined by the
FLLWER Bulk Data Entry (referenced by the
FLLWER command) overrides the global follower force
settings of
PARAM,FLLWER,<-1,
0, 1, 2,
3> for this subcase.
Follower Forces:
FORCE1/FORCE2 Bulk Data Entries can be used to define follower forces. The OPT field on FLLWER Bulk Data Entry/value on PARAM, FLLWER can be used to control the follower force configuration.
Follower Pressures:
The PLOAD, PLOAD2, and PLOAD4 Bulk Data Entries can be used to define follower pressure. For the case of PLOAD4, if the continuation line is not used, the initial pressure is always directed along the element normal. The OPT field on FLLWER Bulk Data Entry/value on PARAM, FLLWER can be used to control the follower pressure configuration.
Directional Follower Pressure:
The CID, N1, N2, N3 continuation line on PLOAD4 can be used to define directional pressure loading. If directional pressure loading is defined within a follower load case, a local coordinate system, aligned with the material coordinate axis, is constructed. If OPT=1 or 3 is specified, the pressure holds its initial direction in the local coordinate system. If OPT=2 is specified, the pressure holds its initial direction in the basic coordinate system.
If OPT=1 or 2, for a given PLOAD4 entry, the pressurized area is calculated on the deformed configuration. Otherwise, the pressurized area is calculated on the initial configuration.PARAM,LGDISP,1 PARAM,FLLWER,1 PARAM,HASHASSM,YES SUBCASE 10 SPC = 1 LOAD = 2 FLLWER = 31 NLPARM = 99 BEGIN BULK FLLWER,31 +,LOADSET,-1,101 +,LOADSET,0,102 +,LOADSET,1,103 +,LOADSET,2,104
- The NLOUT Bulk Data Entry and NLOUT Subcase Information Entry can be used to control incremental output in Small Displacement Nonlinear and Large Displacement Nonlinear Analysis.
- PARAM,SHELLLG,YES is available to activate an alternative 1^{st} order shell element for Nonlinear Large Displacement Analysis. This can be used for sensitive models.
- Large displacement nonlinear analysis is supported for Solid elements,
Shell (first order only) elements, CBUSH,
CBEAM, CBAR,
RROD, CELAS1,
CWELD, CFAST,
CONROD, RBAR,
RBE2, and RBE3 Bulk Data
Entries. Also, MPC is supported. Composites using
PCOMP, PCOMPG, and
PCOMPP entries are now supported with large
displacement nonlinear analysis.
SPC can be applied to the dependent grid on the RBE3 Bulk Data Entry for large displacement analysis.
- Direct Matrix Input (using the DMIG Bulk Date Entry) is currently not supported in Large Displacement Nonlinear Analysis, but DMIG is assumed to be small displacement.
- Linear Buckling Analysis and Preloaded Analysis are not supported with Large Displacement Nonlinear Analysis.
- Adaptive load increment technique with the expert system (PARAM, EXPERTNL) is currently not supported with Large Displacement Nonlinear Analysis. However, the stabilization with PARAM,EXPERTNL,CNTSTB is supported for large displacement analysis.
- Nonlinear Heat Transfer Analysis is currently not supported with large displacement nonlinear analysis.
- Large Displacement Nonlinear Analysis is not supported in conjunction
with the following elements:
- Gasket elements can exist in the model, but they will be resolved using small displacement nonlinear theory (equivalent to ANALYSIS=NLSTAT with plasticity). If large translations or rotations are expected on these elements, the results may not be accurate.
- The following elements are allowed in LGDISP, but will be
resolved using small displacement nonlinear
theory:
CGAP, CGAPG, CSEAM, and CSHEAR
- The RBE1 element is not allowed in LGDISP, and OptiStruct will error out if it is present.
- Large strain formulation for shells is supported in Large Displacement Nonlinear Analysis.
- Inertia relief is supported for nonlinear static analysis. Any nonlinearity (contact, geometry and material) can be included in nonlinear static analysis with inertia relief.
- Plasticity is supported with membrane elements (first and second order) for small and large displacement nonlinear static analysis. Among the available hardening rules in the MATS1 entry, isotropic, kinematic and mixed hardening types are supported with membrane elements.
- For large displacement nonlinear analysis, the local coordinate system of bush elements moves with the deformation.
Convergence Considerations for Small Displacement Nonlinear Analysis
For small displacement nonlinear analysis, the Newton's method is a reliable tool for the solution of nonlinear problems and can provide a fast quadratic convergence rate.
However, convergence is not guaranteed under all circumstances.
Problem Setup
Make sure that the nonlinear problem represents a realistic physical situation for which a feasible solution exists. In particular, special care needs to be taken in selecting the proper orientation of gap elements. This is especially important when using a specified gap coordinate system. See the description of the CGAP and CGAPG elements for more details.
Sufficient Support
Since gap/contact elements only provide one-way support, it is possible to formulate the problem in such a way that the individual components will have rigid body freedom under certain loading conditions. This will manifest as zero pivot in the solution process. To avoid such situations, it is advisable to provide sufficient support to all components so that, even without gap/contact elements, there are no rigid body modes. If "solid" supports are not feasible for all parts (the part needs to move), a very weak set of springs can be used to prevent the part from "flying away" when gap/contact elements are not engaged. The stiffness of such auxiliary springs can be selected so as to allow for large motion of the part, compatible with the overall size of the model. If the gap elements and contact interfaces are properly set up, such weak springs will exert virtually no effect when the solution has converged.
Reasonable Gap Stiffness
Where, $$E$$ is the typical value of elastic modulus and $$h$$ is the typical element size in the area surrounding the gap elements. Such range will generally keep the gap penetration below one thousandth/one millionth of the element size, respectively. A good value for $$KT$$ is of the order of $$0.1\cdot KA$$.
- Option $$KA$$=AUTO determines the value of $$KA$$ for each gap element using the stiffness of surrounding elements. Additional options SOFT and HARD create respectively softer or harder penalties. SOFT can be used in cases of convergence difficulties and HARD can be used if undesirable penetration is detected in the solution.
- Option $$KT$$=AUTO automatically calculates the value of $$KT$$. If MU1>0, the result here is the same as with blank $$KT$$ -- its value is calculated as $$MU1\cdot KA$$. However, if MU1=0 or blank, $$KT$$=AUTO produces a non-zero value of $$KT$$, calculated as $$KT$$=$$0.1\cdot KA$$. Therefore, $$KT$$=AUTO can be used to specify enforced stick conditions.
Friction
The presence of friction, due to its strong nonlinear, non-conservative nature, may cause difficulties in nonlinear convergence, especially when sliding is present. Therefore, solving the problem without friction can often provide convergence in otherwise failing problems. Or, in cases when presence of frictional resistance is necessary and minimal sliding is expected, enforcing a stick condition may be a viable solution, and will often lead to a better convergence than Coulomb friction (refer to the PGAP and PCONT Bulk Data Entries for details). In cases of larger sliding motions, the stick condition may lead to divergence through a "tumbling" mode.
Gap Offset
In order to provide theoretical correctness, friction produces bending moments in gap/contact elements of non-zero length (this results from the transfer of frictional force from the contact surface to the end nodes). This offset operation can, however, cause convergence problems and counter-intuitive results. In problems with friction, it may be advisable to turn off the offset operation via a parameter:
GAPPRM,GAPOFFS,NO
This will produce more intuitive results in the presence of friction. However, it may violate the rigid body balance of the body, and should therefore be used with caution, especially for problems without full SPC support. Refer to the PGAP and PCONT Bulk Data Entries for details.
Incremental Loading
If the nonlinear procedure diverges, in spite of taking the measures described above, the incremental loading procedure (applying the total load in a number of increments) can be used to achieve convergence. Refer to the NLPARM Bulk Data Entry for details. Note, however, that if the problem is incorrectly formulated (the solution exhibits excessive deformations, free rigid body motions, an ill-conditioned stiffness matrix, extremely high nonlinear error, etc.), incremental loading cannot be counted on to provide a converged solution.
Nonlinear Expert System
In some difficult to converge cases, an expert system can be used to achieve convergence:
PARAM,EXPERTNL,YES
The expert system will try to adjust the load increment and other nonlinear parameters to achieve convergence. However, if the problem is incorrectly formulated (the solution exhibits excessive deformations, free rigid body motions, an ill-conditioned stiffness matrix, extremely high nonlinear error, etc.), expert system cannot be counted on to provide a converged solution.
Moreover, in some cases it can lead to long computational times without success. This may be due to using very small load increments or re-running the solution with modified nonlinear parameters.
Option | Controlled By | Affected by EXPERTNL AUTO/YES |
---|---|---|
DT, NINC | NLPARM | NO, these only control the initial increment size. |
MAXITER | YES, MAXITER will be overridden by PARAM, EXPERTNL, AUTO/YES. | |
MAXLS, LSTOL, TTERM | NO |
PARAM, EXPERTNL, AUTO/YES does not affect any of the options in NLADAPT and TSTEP (in case of nonlinear transient analysis).
Arc-Length Method
The arc-length method is available for post-buckling problems in nonlinear static analysis. This can be activated via the NLPCI Bulk Data Entry.
Plot Convergence During Analysis
The convergence plot can be obtained for all nonlinear iterations across all subcases for nonlinear static and nonlinear transient analysis, using the Altair Compute Console (ACC).
The progress can also be monitored for all the optimization iterations.
For more details, refer to Plot Convergence During Analysis in the Runtime Monitoring section.