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This tutorial explains how to define horizontal and vertical *layout-line geometry*. [Layout lines|kb:Layout line] are broken into a number of segments between transition points, including point of tangent (PT), point of curvature (PC), point of vertical tangent (PVT), and point of vertical curvature (PVC). Each segment is defined using the parameters in the relevant menu.
h1. Layout line geometry
Plan and elevation views of the sample layout line used in this tutorial are presented with corresponding data sets below:
h2. Plan view
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!horizontal alignment.png|align=center,border=1!
{center-text}Figure 1 - Layout line plan view{center-text}
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!horizontal alignment table.png|align=center,border=1!
{center-text}Figure 2 - Plan view data{center-text}
h2. Elevation view
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{center-text}Figure 3 - Layout line elevation view{center-text}
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!vertical alignment table.png|align=center,border=1!
{center-text}Figure 4 - Elevation view data{center-text}
h1. Data to be entered in SAP2000
Data is entered using the Bridge Layout Line Data menu, shown in Figure 5:
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!baseline geometry in SAP2000.png|align=center,border=1!
{center-text}Figure 5 - Baseline geometry in SAP2000{center-text}
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Select Define Horizontal Layout Data to enter plan view geometry. Each row of the table in Figure 6 defines one segment of the layout-line plan as follows:
* Row 1 defines the initial bearing as N 90° 0′ 0″ E.
* Row 2 defines a straight segment, 100m long, which extends from the previous bearing (N 90° 0′ 0″ E).
* Row 3 defines the first curved segment, which has a constant radius of 100m. Since curvature is constant, there are no transition curves, meaning either radius or end bearing is sufficient for curve definition. If radius and end bearing do not represent a circular segment, the arc generated will be centered in the range specified. If this arc is shorter than the difference in stations, transition curves, varying linearly from _1 / R_ to zero, will connect the arc to end points.
* Rows 4-6 follow the same procedure as the previous three rows.
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!horizontal data in SAP2000.png|align=center,border=1!
{center-text}Figure 6 - Plan view data{center-text}
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Select Define Vertical Layout Data to enter elevation view geometry. Each row of the table in Figure 7 defines one segment of the layout-line elevation as follows:
* Row 1 defines the initial elevation and the initial grade.
* Row 2 defines a constant slope of 20% up to station 100.
* Row 3 defines a parabolic segment with an initial slope of \+20% and an end slope of \-20%.
* Row 4 defines a constant slope of \-20% to station 614.16.
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!vertical data in SAP2000.png|align=center,border=1!
{center-text}Figure 7 - Elevation view data{center-text}
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This procedure generates the layout line diagrammed and described in the [Layout line geometry|tutorials:Layout-line geometry#Layout line geometry] section. Info |
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This tutorial was written for SAP2000, but the same concept applies also to CSiBridge. |
This tutorial explains how to define horizontal and vertical layout-line geometry. Layout lines are broken into a number of segments between transition points, including point of tangent (PT), point of curvature (PC), point of vertical tangent (PVT), and point of vertical curvature (PVC). Each segment is defined using the parameters in the relevant menu.
On this page:
Layout line geometry
Plan and elevation views of the sample layout line used in this tutorial are presented with corresponding data sets below:
Plan view
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Figure 1 - Layout line plan view
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Figure 2 - Plan view data
Elevation view
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Figure 3 - Layout line elevation view
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Figure 4 - Elevation view data
Data to be entered in SAP2000
Data is entered using the Bridge Layout Line Data menu, shown in Figure 5:
Image Added
Figure 5 - Baseline geometry in SAP2000
Select Define Horizontal Layout Data to enter plan view geometry. Each row of the table in Figure 6 defines one segment of the layout-line plan as follows:
Row 1 defines the initial bearing as N 90° 0′ 0″ E.
Row 2 defines a straight segment, 100m long, which extends from the previous bearing (N 90° 0′ 0″ E).
Row 3 defines the first curved segment, which has a constant radius of 100m. Since curvature is constant, there are no transition curves, meaning either radius or end bearing is sufficient for curve definition. If radius and end bearing do not represent a circular segment, the arc generated will be centered in the range specified. If this arc is shorter than the difference in stations, transition curves, varying linearly from 1 / R to zero, will connect the arc to end points.
Rows 4-6 follow the same procedure as the previous three rows.
Image Added
Figure 6 - Plan view data
Select Define Vertical Layout Data to enter elevation view geometry. Each row of the table in Figure 7 defines one segment of the layout-line elevation as follows:
Row 1 defines the initial elevation and the initial grade.
Row 2 defines a constant slope of 20% up to station 100.
Row 3 defines a parabolic segment with an initial slope of +20% and an end slope of -20%.
Row 4 defines a constant slope of -20% to station 614.16.
Image Added
Figure 7 - Elevation view data
This procedure generates the layout line diagrammed and described in the Layout-line geometry#Layout line geometry section.
Metadata
Name: Layout-line geometry
Description: Guidelines for defining vertical and horizontal layout lines, also known as baselines.
Program: SAP2000
Program Version: 14.2.0
Model ID: na
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