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Vertex Variation

This tutorial shows you how to directly apply standard deviations to the coordinates of slope vertices in RocFall using the Edit Boundary Coordinates dialog . This allows the model to account for uncertainty in measurements or to simulate a pseudo 3-D rockfall analysis (i.e., to simulate minor variations in a slope profile).

Topics Covered in this Tutorial:

  • Constant seeder/slope properties
  • Editing slope coordinates
  • X, Y vertex variation

Finished Product:

The finished product of this tutorial can be found in the Tutorial 04 Vertex Variation data file. All tutorial files installed with RocFall can be accessed by selecting File > Recent Folders > Tutorials Folder from the RocFall main menu.

1.0 Model

1.1 OPEN THE TUTORIAL FILE

Let's start by opening the file for the tutorial:

Select: File > Recent Folders > Tutorials Folder and open the Tutorial 04 initial file. You should see the following model.

Image of model upon opening the

All slope and rock properties have already been defined, except for the vertex variation:

  • The Rigid Body rock shape is a 1000 kg sphere
  • Number of rocks = 50
  • The vertex variation has not been defined

Let’s first review the properties of this model.

1.2 SEEDER PROPERTIES

You can view the properties of the existing point seeder in the Seeder Properties dialog:

  1. Right-click the point seeder on the model (the blue cross at the top of the slope) and select Seeder Properties in the popup menu.
    Seeder Properties dialog
  2. Note the following:
    • Number of Rocks = 50
    • Initial Horizontal Velocity (m/s) = 3.5
    • No statistical distribution has been defined for the initial velocity, so all rocks will follow the same initial path
  3. Click Cancel to close the dialog.

1.3 SLOPE MATERIAL PROPERTIES

Next we'll look at the slope materials properties in the Slope Material Library dialog.

  1. Select Slope Material Library Slope Material Library icon on the toolbar or the Slope menu.
    Slope Material Library dialog
  2. Note the following:
      • A single material named No Deviation has been defined.
      • The Distribution of all parameters is set to None.
  3. Click Cancel to close the dialog.

2.0 Results

Now we'll switch to Results mode to run the analysis and then use the Animate Path option to view the rock fall.

  1. Click Results Results dialog on the toolbar.
  2. Select Animate Path on the toolbar or the Results menu.
  3. In the Animate Result dialog, click Play.
    You should see only a single rock path travel down the slope.

Image of model

Since there is no statistical variation (Distribution = None) in the rock's Initial Conditions, all 50 rocks have the same path so only that path is shown and animated.

3.0 Model Vertex Variation

Now we will demonstrate how to apply geometric variability to the slope coordinates by applying standard deviations to the slope vertices.

  1. Select Design Design icon on the toolbar.
  2. Select Edit Coordinates on the Slope menu or right-click on the slope and select Edit Slope Coordinates.
  3. For Point (Vertex) 3 (mean coordinates = 6.7, –12.2), enter X stdv = 0.05 and Y stdv = 0.10 as shown below.
    Edit Boundary Coordinates data table
  4. Click OK.

To keep things simple, we have only added standard deviation to a single vertex. This will make it easier to illustrate the effect of vertex variation in RocFall.

4.0 Results of Vertex Variation

Now we'll switch back to Results mode to view the results of the vertex variation.

  • Click Results Results icon on the toolbar.
    You should see the following.

Image of model

As you can see, all rocks follow the same initial trajectory since there is zero variation in the seeder initial conditions. However, when they reach the second segment of the slope, many diverging paths are created due to the variation we applied to Vertex 3.

Let’s zoom in again to see what is going on. Use Zoom In (F4) to zoom in on the first bounce location of to left of Vertex 3 until your screen looks similar to the following. You may also find Zoom Window and Pan in the View menu useful.

Image of model

This illustrates how the rocks can now bounce off slope segments above and below the mean slope segment orientation. The rock paths indicate the range of actual slope segments generated by the statistical variation we applied to Vertex 3. Effectively, a new slope is generated before each rock is thrown.

4.1 ANIMATE PATHS

Now we'll use the Animate Path option to view the rock fall.

  1. Select Animate Path Animate Path icon on the toolbar or the Results menu and zoom in if necessary.
  2. In the Animate Result dialog, click through each rock path using the forward arrow beside the rock ID number.

Image of model

NOTES:

  • Each time you view a new rock path, you can see the actual slope boundary segments generated for each rock throw.
  • For each rock throw, the coordinates of Vertex 3 are randomly generated according to the X and Y standard deviation you have entered. This results in the changing position of both boundary segments connected to vertex 3.

5.0 Sensitivity Analysis

When using vertex variation in RocFall, you may find it useful to change the standard deviation of only one vertex at a time (leaving all other vertices with a standard deviation of 0). This will allow you to determine the sensitivity of the simulation to the location of that particular vertex. If you change the standard deviation of many vertices at once, it may be difficult to determine which vertex has the most effect on the results and which have very little effect.

6.0 Summary

This simple example shows how to model geometric variability of your slope coordinates using the vertex variation method. You can apply vertex variation to any or all vertices in a RocFall analysis in the Edit Boundary Coordinates dialog. In conjunction with statistical variation of other model parameters (rocks, initial conditions, material properties), you can simultaneously apply variability to any combination of rock fall input parameters.

For other methods of modeling slope geometry variability, see Tutorial 05 - Slope Roughness in RocFall and Tutorial 06 - Crest Loss in RocFall.

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