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Structural Components
Elements
PERFORM-3D includes the following element types:
• Frame element for beams, columns and braces.
• Wall element for shear walls.
• Slab element for floors.
• Bar elements (with only axial stiffness) of various types.
• Buckling restrained brace.
• Gap elements.
• Seismic isolators of rubber and friction pendulum type.
• Fluid damper, with nonlinear relationship between force and deformation rate.
• Connection panel zone, to model shear deformation in beam-to-column connections.
• Infill panel, with only shear strength and stiffness.
• Deformation “gages” of various types. These elements have no stiffness . They are
used for calculating deformations, and hence deformation demand/capacity ratios.
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Components
In PERFORM-3D, most elements are made up of a number of components. For example, a beam element
might consist of several components.
Component Properties
All inelastic components have essentially the same force-deformation relationship. This is a basic tri-linear
relationship, with optional strength loss that can be captured in PERFORM-3D.
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Hysteresis Loops
The hysteresis loop for an inelastic component can be varied to account for stiffness degradation. The loop
can be plotted to check that it has the expected shape.
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Deformation Capacities
Deformation capacities can be specified for inelastic components, for calculating deformation
demand/capacity ratios. Deformation capacities can be specified for up to 5 performance levels.
Demand/Capacity Ratios
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PERFORM-3D includes a large number of components, both inelastic and elastic. During an
analysis, D/C ratios are calculated as follows:
• Deformation D/C ratios are calculated for inelastic components.
• Hence, components that are allowed to become inelastic can be checked to make sure
they have sufficient ductility.
• Strength D/C ratios are calculated for elastic components.
• Hence, components that are required to remain essentially elastic can be checked to
make sure they have sufficient strength.
Limit States
The number of components with D/C ratios can be very large. To simplify decision making, components
that have similar D/C measures can be grouped into Limit States. An example D/C measure is the concrete
tension strain in a shear wall. Each limit state has a “usage ratio”, which is the maximum D/C ratio for any
component in the limit state. For a structure to satisfy the performance requirements, the usage ratios for all
limit states should not exceed 1.0.
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Frame Structures
Simple frame structures consist of beam and column elements. Beam and column elements can be made up
of a variety of components, and may be elastic or inelastic. P-delta effects can be considered or ignored.
Shear Wall Structures
Shear walls are modeled using plane wall elements. Complex shear cores are made up of
plane elements. Wall elements can have inelastic behavior in bending and shear. Coupling
beams are usually modeled using beam elements, with inelastic behavior in either bending or
shear.
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Analysis
Types
PERFORM-3D can run the following analysis types:
• Mode shapes, periods, and effective mass factors.
• Gravity load.
• Static push-over.
• Response history for earthquake ground motion.
• Response history for dynamic forces.
• Response spectrum analysis (with limitations).
The nonlinear analysis strategies are very reliable, even when inelastic components
have negative stiffness, and when P-delta effects cause the structure to become
unstable.
Sequences
The most common analysis sequence is:
• Apply gravity loads.
• Run one or more static push-over analyses, with constant gravity load.
• Run one or more earthquake response history analyses, with constant gravity load.
This is a “standard” sequence. A “general” sequence can also be applied, for
example cyclic push-over as follows:
• Apply gravity loads.
• Add push-over loads to a specified drift in the positive direction.
• Add push-over loads to a specified drift in the negative direction.
• Etc., progressively increasing the specified drift in each direction.
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Series
An “analysis series” is a series of analyses, with a standard or general analysis sequence. For
each analysis series, the following structure properties can be changed:
• The mass distribution and magnitude. This can affect static push-over analysis as well
as dynamic response history analysis.
• The amount and type of damping for dynamic response history analysis.
• The strengths and stiffnesses of the structural components (within certain limits).
This allows you to change the structural properties without setting up a new
analysis model.
Behavior Check
Behavior Check Tools
PERFORM-3D includes a number of tools for processing the analysis results. One set of tools allows you
to study the behavior of a structure, and to check that the analysis look reasonable. These tools are as
follows:
• Deflected shapes. These can be animated, for both static push-over and dynamic
response history analysis.
• Time histories of many response quantities, including node displacements, velocities
and accelerations; element and component forces and deformations; and forces on
“structure sections” that cut through all or parts of the structure.
• Hysteresis loops for inelastic components.
• Moment and shear diagrams for beams, columns, and shear walls. These can be
animated.
• Energy balance, showing strain energy, kinetic energy, inelastic work, and damping
energy. This includes a comparison of external and internal work, which provides a good
indication of the numerical accuracy of the analysis.
These tools are not directly useful for making design decisions. For this, see the next section, Performance
Assessment
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Performance Assessment
Performance Assessment Tools
The results of an analysis are useful only if they are presented in a way that supports decision making for
design. PERFORM-3D includes powerful tools that assess the performance of a structure, and hence
support design. These tools are as follows:
• Target displacement calculation for push-over analysis. A number of methods can be
used, including those in ASCE 41 and FEMA 440.
• Usage ratio plots for single load cases. As the drift increases in a push-over analysis,
or time increases in a response history analysis, the usage ratios for the limit states
progressively increase. A usage ratio plot shows how the usage ratios vary for user-
selected groups of limit states.
• Usage ratio envelopes for load combinations. It is common practice to run response
history analyses for several earthquakes (often 7 or more), and to assess performance
based the mean values of the usage ratios. The tool implements this procedure.
• Deflected shapes with color coding based on D/C ratio. These can be used to identify
“hot spots” where the components are most heavily deformed.
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Processing of Results
• The PERFORM-3D analysis results are saved in a number of results files, each file
containing results of a specific type (for example, node displacements).
• If the performance assessment tools in PERFORM-3D do not meet your needs, you
can access the results files, and process the results in any way that you choose.
• You must, of course, write computer code to do the processing. You can use almost
any programming language.
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Import and Export
Supported Formats
Models can be imported to PERFORM-3D from SAP2000 or ETABS. These are partial
models, consisting mainly of nodes, elements, and loads. Component properties are not
included, because these properties are different in PERFORM-3D than in SAP2000 and
ETABS.
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