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Displacement time-history records should be obtained from acceleration readings such that ground motion may be manually applied to specific structural supports. Otherwise, time histories are automatically applied to all supports. This article outlines the mathematical formulation for conversion from acceleration to displacement. Visuals are taken from Dr. Wilson’s text Static and Dynamic Analysis of Structures, available for sale through the link provided in the References section.{excerpt} \\ During [time-history|kb:Time-history analysis] analysis, an acceleration record is automatically applied to all [restraint|kb:Constraint] supports. {new-tab-link:http://www.csiberkeley.com/}CSI{new-tab-link} Software then uses d’Alembert’s principal to translate the time history into [acceleration loads|Acceleration load] which are applied to structural [joints|kb:Joint]. This process is explained further in the {new-tab-link:http://www.csiberkeley.com/}CSI{new-tab-link} [_Analysis Reference Manual_|doc:Analysis Reference Manual] (Acceleration Loads, page 304). To manually input ground motion at specific supports, rather than all supports, it is necessary to first convert the acceleration record into its corresponding *displacement time-history record*. Because displacement is piecewise linear, while velocity is piecewise constant, and acceleration is a series of impulse functions at each time step, users should mind [output accuracy|Time-history output-acceleration accuracy] by smoothing the displacement record. This refinement is accomplished by using a smaller time step, possibly one-tenth that of the acceleration record, when transferring ground motion into its corresponding displacement time-history record. \\ There are two basic approaches to conversion from acceleration time history to displacement. Users may follow an experimental approach, given as follows: * Create a simple [SAP2000|sap2000:home] model * Apply the acceleration time history using the given time step (perhaps 0.02) * Set the output time step to the refined value of one-tenth the input (0.002) * Extract the displacement results from a [restrained|kb:Constraint] joint * Correct for zero initial and final displacement and velocity (a + bt) * Use this smoothed displacement function as the ground-motion input for real model. Please note that analysis will be performed at the shorter time step, though output is reported (more accurately) only for each original time step. \\ Alternatively, users may implement the mathematical formulation which is summarized in Appendix J of Dr. Edward L. Wilson’s text {link-window:href=http://orders.csiberkeley.com/SearchResults.asp?Cat=2}{_}Static and Dynamic Analysis of Structures_ {link-window}, and outlined below: First, ground acceleration is idealized, within each time increment, as linear (Figure 1). \\ !Figure 4.png|align=center,border=1! {center-text}Figure 1 - Ground acceleration record{center-text} \\ At each time step, integration of acceleration and velocity then yields expressions for ground velocity and displacement (Figure 2). \\ !Figure 5.png|align=center,border=1! {center-text}Figure 2 - Expressions for a, v, and d, derived through integration{center-text} \\ Evaluation of these expressions at _t = ∆t_ yields a set of recursive equations, as shown in Figure 3: \\ !Figure 6.png|align=center,border=1! {center-text}Figure 3 - Recursive equations characterizing ground motion{center-text} \\ These expressions may then be used to translate a ground acceleration record into its corresponding displacement record. This double integration procedure should produce zero displacement at either end of the record. If non-zero displacement does exist, it is then necessary to apply a base line correction. Figure 4 presents a formulation for this process. \\ !Figure 7.png|align=center,border=1! {center-text}Figure 4 - Algorithm for zero displacement at record ends {center-text} \\ Once the displacement time-history record has been produced, users may continue to manually input ground motion at supports by following the process outlined in the [Multi-support excitation|Multi-support excitation] article. h1. References * Wilson, Dr. Edward L. _Static & Dynamic analysis of Structures_. 4th ed. Berkeley: Computers and Structures, Inc., 2004. Available for purchase on the {new-tab-link:http://www.csiberkeley.com/}CSI{new-tab-link} Products > {link-window:href=http://orders.csiberkeley.com/SearchResults.asp?Cat=2}Books {link-window} pagesection. |
When an acceleration record is specified for time-history analysis, the ground motion is automatically applied to all support restraints. CSI Software uses d’Alembert’s principle to then translate the time history into acceleration loads which are applied to structural joints. During formulation, since acceleration couples with mass, it is important that joints have mass. Acceleration loads are explained further in the CSI Analysis Reference Manual (Chapter XVII: Load Patterns, Acceleration Loads).
To manually input ground motion at specific supports, it is necessary to first convert the acceleration record into its corresponding displacement time-history record. During conversion, displacement is piecewise linear, velocity is piecewise constant, and acceleration is a series of impulse functions at each time step. Users should mind output accuracy by smoothing the displacement record. A smaller time step, possibly 1/10 that of the acceleration record, will refine the ground motion during conversion.
Experimental conversion
Two basic methods are available for conversion from Acceleration time history to displacement. First, an experimental approach is described as follows:
- Create a simple SAP2000 model.
- Apply the acceleration time history using the given time step (perhaps 0.02).
- Set the output time step to 1/10 of this value (0.002).
- Extract the displacement results from a support restraint.
- Correct for zero initial and final displacement and velocity using a + bt.
- Use this refined displacement function as the ground-motion input for the actual model.
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NOTE: Analysis proceeds according to the shorter time step, though output is reported (more accurately) only for each original time step. |
Mathematical conversion
As an alternative, mathematical conversion is summarized in Appendix J of Dr. Edward L. Wilson’s text Static and Dynamic Analysis of Structures. The conversion is given in Figure 3, and its formulation is described as follows:
Ground acceleration is idealized as linear within each time increment, as shown in Figure 1:
Figure 1 - Ground acceleration record
Acceleration and velocity are integrated at each time step to generate expressions for velocity and displacement, as shown in Figure 2:
Figure 2 - Expressions for a, v, and d, derived through integration
These expressions are evaluated at t = ∆t to produce the set of recursive equations shown in Figure 3:
Figure 3 - Recursive equations characterizing ground motion
An acceleration record is then translated into its corresponding displacement record using these expressions.
This double-integration procedure should produce zero displacement at either end of the displacement record. However, if nonzero displacement does exist, a base-line correction must be applied according to Figure 4:
Figure 4 - Algorithm for zero displacement at record ends
- Displacement ground motion is then input at specific support locations using the option for Ground Displacement Load. This process is described in the Multi-support excitation article.
See Also
- Ground motion at specific supports – Manual multi-support excitation
- Output accuracy – Time-history output-acceleration accuracy
References
- Wilson, E. L. (2004). Static and Dynamic Analysis of Structures (4th ed.). Berkeley, CA: Computers and Structures, Inc.
Available for purchase on the CSI Products > Books page