THE PASSING SIGHT DISTANCE TOOL

One of the most tedious steps in finishing a road design has been establishing the passing and no- passing zones for the permanent traffic control plan.   Since the adoption of painting the stripes on the pavement, many attempts have been made to develop a means by which to determine the passing and no-passing zones.   The most common is outlined in the AASHTO Green book . . . (the rolling straight edge method).   I've even heard of two guys, in different vehicles, trying to maintain the minimum passing distance between themselves and when they got out of sight of each other, they each threw a handful of flour out the window . . . wild, especially on a windy day in Wyoming!   The Federal Highway Administration had an application written for RDS that was quite good.   Once again, GEOPAK has come to ease your pain.

To use this application, the following files are necessary:

• The GPK file
• A TIN file that reflects your proposed design.
• Any 2D or 3D design file.   This file can be totally blank, but a proposed 3D model will allow you to see the passing site lines being drawn.

STEP 1.

Create a TIN file that reflects your proposed design:

The easiest way to do this is to open your proposed cross section file and invoke the XS Report Palette...

NOTE: This routine does not recognize vertical slopes in the cross section file, (a DTM problem).   Modify any vertical slopes so that they're not exactly vertical.

Invoke the XS Report Palette:

APPLICATIONS > GEOPAK ROAD > CROSS SECTIONS > CROSS SECTION REPORTS and Select... DTM Prop 3D.

This invokes the DTM Proposed 3D Report dialog box, and the sole purpose of this step is to create a .DAT file that will eventually create the .TIN file representing your proposed design.

Key in all appropriate information in the fields.   The default extension for the output file will be .COL, remember to change this to .DAT.
Click on Apply.

Now... to actually create the TIN file:

Open any 2D or 3D design file and invoke the DTM palette...

APPLICATIONS > GEOPAK ROAD > DTM TOOLS and select the icon... DTM Menu.   Next select Build > Triangles

Use the Files picker to select the .DAT file that you created.

Enter the path and name of the .TIN file to create.

Toggle Dissolve Option to Side.

Key in the Side Length.   (200 for English, 60 for Metric).

Click on Process.   Proceed to Final Step if Step 2 is skipped.

FINAL STEP.

To invoke the Passing Sight Distance dialog box:

APPLICATIONS > GEOPAK ROAD > 3D TOOLS > Passing Sight Distance

• Select the Tin file using the Files picker.   This is the TIN file that was created in Step 1 and/or Step 2 of these instructions.



• Key-in the Job Number.



• Select the Chain using the Select picker.



• The beginning and ending stations can be entered manually or by using the DP buttons and snapping to a graphical element in the design file.



• A normal sampling increment for an English design would be 50 ft.   This simply tells the program what frequency to check for sight distance.   Metric, maybe 15 m.

Under Parameters:

Click on Driver and Visible Vehicle Location:

Driver Location:

• Height Above TIN . . . AASHTO recommends using an average driver's eye height of 3.5 ft., (1.07 m).
• Direction of Stationing Offset . . . For a typical two lane highway, the driver would normally be approximately 4 ft., (1.22 m) from centerline.
• Opposite Direction of Sta. Offset . . . Again, for a typical two lane highway, the driver would normally be approximately 4 ft., (1.22 m) from centerline.

Visible Vehicle Location:

• Height Above TIN . . . AASHTO recommends using an average driver's eye height of 3.5 ft., (1.07 m).
• Direction of Stationing Offset . . . For a typical two lane highway, the driver would normally be approximately 4 ft., (1.22 m) from centerline.
• Opposite Direction of Sta. Offset . . . Again, for a typical two lane highway, the driver would normally be approximately 4 ft., (1.22 m) from centerline.

Still under Parameters:

Additional No Passing Distance . . . This is more or less a safety buffer that adds whatever distance is keyed in to each end of a no-passing zone.   For instance if the program determines that your design has a no-passing zone from 12+50 to 15+00 and you've keyed 25 in this field . . . a no-passing zone will be calculated from 12+25 to 15+25. If no additional distance is desired, key in 1, zero is invalid.

Minimum Passing Zone Length . . . AASHTO refers the marking of no-passing zones to the MUTCD manual.   The MUTCD manual states, "Where the distance between successive no-passing zones is less than 400 feet, the appropriate no-passing marking (one direction or two direction) should connect the zones."   FHWA will be using the 400-foot (122 m) distance as a minimum passing zone length.

Zone Designation:

When pressed this button invokes the Zone Designation Table.   This optional dialog is intended for designating certain areas to be treated specially.   In addition to specifying station ranges, there are two other options for more specific consideration:

Side . . . three options, Left, Right and Both

Class . . . three options, Passing, No-Passing, and Void.

For example, if the design was going through an area that was to be double yellow striped due to it being a heavy congested area, the user would key in the Beginning and Ending Station, toggle the Side toggle to Both, toggle the Class toggle to No-Passing and click on Add.   A series of station ranges and Side/Class options can be saved via the File pulldown and loaded again later for additional processing.

Sight Distance:

When pressed this button invokes the Sight Distance Table.   This is where the various design speeds are identified.   Rather than input the design speed the Minimum passing sight distance is entered.   This table allows the user to have multiple design speeds within the design and have each calculated according to its station range.   These ranges and passing sight distances can be saved via the File pulldown and loaded again later for additional processing.

The Draw Striping toggle and its Define button are now fully functional and actually draw the pavement markings in a design file.   When the Define button is pressed, the user keys in the appropriate data.   When either the Solid or the Skip button is pressed, the Design and Computation Manager is invoked and allows the user to select the appropriate pay item to be drawn in the 2D DGN file.

The Write Report toggle and its Files picker, are used for identifying the name of the output file and its path.   This is the ASCII output file that actually displays the passing and no-passing zones.   An example is shown below:

           Solid Left                      Skip Center                      Solid Right 
           ----------                      -----------                      -----------  
10+000.000 R 1 to 10+500.000 R 1 10+500.000 R 1 to 10+709.063 R 1 10+000.000 R 1 to 10+722.188 R 1
10+709.063 R 1 to 10+909.688 R 1 10+722.188 R 1 to 10+859.063 R 1 10+859.063 R 1 to 11+142.188 R 1
11+245.313 R 1 to 11+312.813 R 1 10+909.688 R 1 to 11+734.688 R 1 11+500.313 R 1 to 11+509.688 R 1
11+684.063 R 1 to 11+749.688 R 1 11+749.688 R 1 to 12+980.000 R 1 11+734.688 R 1 to 11+931.563 R 1
11+982.188 R 1 to 12+165.938 R 1                                  12+165.938 R 1 to 12+351.563 R 1
12+409.688 R 1 to 12+593.438 R 1                                  12+702.188 R 1 to 12+827.813 R 1
12+980.000 R 1 to 13+233.875 R 1                                  12+980.000 R 1 to 13+233.875 R 1

Total:       1455.13                         2401.25                           1776.69