Introduction
This examples demonstrates how to build a 3-story,3-bay frame. The nodes and elements are specified one by one.
Input
Model Building
The following tasks are performed when building the model
- define units
- define model
- define recorders for output
- define & apply gravity
Elastic Element
Files
Notes
- Effective axial and flexural stiffnesses are defined at the element level
- elasticBeamColumn elements
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Distributed Plasticity Element, Uniaxial Section
Files
Notes
- Axial and flexural stiffnesses/strength are defined independently at the section level
- uniaxial inelastic section (moment-curvature)
- nonlinear beam-column elements
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Distributed Plasticity Element, Fiber Section
FiberSection -- Standard AISC W-Section
Files
Notes
- The section is broken down into fibers where uniaxial materials are defined independently.
- The program calculates flexural and axial stiffnesses/strength by integrating strains across the section.
- Standard AISC W-section
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FiberSection -- Reinforced Concrete Section
Files
Notes
- The section is broken down into fibers where uniaxial materials are defined independently.
- The program calculates flexural and axial stiffnesses/strength by integrating strains across the section.
- Rectangular Reinforced-Concrete Section
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Lateral-Load Analysis
The following tasks are performed in the analysis
- define lateral-load parameters
- analyze
Static
Static Pushover
Files
Notes
- One-directional monotonic displacement-controlled static loading
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Static Reversed Cyclic
Files
Notes
- One-directional displacement-controlled static loading
- Displacement cycles are imposed in positive and negative direction
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Dynamic EQ Ground Motion
Dynamic Uniform Sine-Wave Ground Motion
Files
Notes
- Sine-wave acceleration input
- Same acceleration input at all nodes restrained in specified direction
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Dynamic Uniform Earthquake Ground Motion (typical)
Files
Notes
- Earthquake (from file) acceleration input
- Same acceleration input at all nodes restrained in specified direction
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Dynamic Multiple-Support Sine-Wave Ground Motion
Files
Notes
- Sine-wave displacement input
- Different displacements are specified at particular nodes in specified directions
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Dynamic Multiple-Support Earthquake Ground Motion
Files
Notes
- Earthquake (from file) displacement input
- Different displacements are specified at particular nodes in specified directions
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Dynamic Bidirectional Earthquake Ground Motion (typical)
Files
Notes
- Earthquake (from file) acceleration input
- Different ground motion in two directions
- Same acceleration input at all nodes restrained in specified direction
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Run
The model and analysis combinations for this example are numerous. The following are an small subset, for demonstration purposes:
- To run Elastic Mode, Static Pushover Analysis:
puts " -------------Elastic Model -------------"
puts " -------------Static Pushover Analysis -------------"
source Ex5.Frame2D.build.ElasticSection.tcl
source Ex5.Frame2D.analyze.Static.Push.tcl
- To run Uniaxial Inelastic Section, Nonlinear Model, Uniform Earthquake Excitation
puts " -------------Uniaxial Inelastic Section, Nonlinear Model -------------"
puts " -------------Uniform Earthquake Excitation -------------"
source Ex5.Frame2D.build.InelasticSection.tcl
source Ex5.Frame2D.analyze.Dynamic.EQ.Uniform.tcl
- To run Uniaxial Inelastic Material, Fiber Section, Nonlinear Model, Dynamic Bidirectional Earthquake Ground Motion
puts " -------------Uniaxial Inelastic Material, Fiber Section, Nonlinear Model -------------"
puts " -------------Dynamic Bidirectional Earthquake Ground Motion -------------"
source Ex5.Frame2D.build.InelasticFiberSection.tcl
source Ex5.Frame2D.analyze.Dynamic.EQ.bidirect.tcl
Notes
Return to OpenSees Examples Manual -- Structural Models & Analyses
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