One of the exciting new features in the Civil Site Design V26 and Stringer Topo V26 release is the Surface from LAS command. Often LiDAR and point cloud data is saved as a LAS file which previously required interpreting in another software prior to being imported to create a surface. This new command allows you to create a CSD surface directly from a LAS file without the need for any other programs. We foresee that this command will be used predominantly by AutoCAD and BricsCAD users, however it is also available to Civil 3D users.
Image: A Civil Site Design surface created from LiDAR data using the new Surface from LAS command
The Surface from LAS command is available in the Surfaces tab of the Ribbon and in the CSD Toolspace by right clicking on Surfaces. When you run the command, you will first be prompted to locate the LAS file you wish to import.
Image: Surface from LAS form
Next you have the option to downsample the data intelligently using voxel downsampling. This can reduce the total number of points being imported while maintaining a good representation of the original data and reducing the time and processing required to create and display the surface. The smaller the voxel size applied, the more points will remain.
Click Create Surface and give the new surface a name to create your Surface from LAS. If you receive an updated LAS file, you can repeat the import process and choose to update the LAS surface rather than create a new one.
The Surface from LAS command is available from the Ribbon and by right click on Surface Manager in the Toolspace.
Image: Surface from LAS icon in the Surfaces ribbon
Image: Surface from LAS Icon in the Surfaces ribbon (cropped)
Adaptive Decimate | Managing Large Surfaces
If you choose not to downsample when importing your LAS surface, the CSA surface engine may apply Adaptive Decimation. Very large input data files can exceed hardware limitations when processing the surface triangulation. Adaptive Decimate addresses this problem by detecting when the number of points could result in software instability and filters out points before creating the TIN surface.
To do this, Adaptive Decimate divides the surface into rectangular cells and assesses the elevation variation within the cell. If the elevation changes are small, this means the cell is relatively flat and the overall shape of the cell can be maintained with just four points in the outer corners. If the elevation variation is high, the cell is divided and checked again. The result is that the overall shape and accuracy of the surface is maintained whilst reducing the volume of data, to create an optimised surface with improved system performance.
The Stringer Topo V25.00 release will enable access to a Network version. Our adoption of a new Licensing system (QLM) allows us to reintroduce our popular Network version, which has been temporarily unavailable. For Stringer Topo customers who currently have Network licenses on software maintenance, you will be issued new Stringer Topo V25.00 Network license(s) […]
Modern survey equipment now stores more identifiers for a point than just a single integer value. Users can opt to identify the point using an alpha-numeric input. An alpha-numeric point is made up of a combination of alpha characters (eg : A, B, C) and numeric values (1, 2, 3, Etc). A common application of […]
“Civil Site Design: A Year in Review and a Glimpse into the Future,” recording is now available. We have dived into the transformative developments of the past year and shared some plans for the upcoming version V25. This session was led by one of our software developers, Andrew Banson, showcased the major enhancements and new […]
In conjunction with our partners Civil Survey Solutions, we are excited to announce the following upcoming training courses for our products Civil Site Design and Stringer Topo. The courses are delivered by our experts and the training team at Civil Survey Solutions. As an Authorised Autodesk Training Center and Application Developer, you can trust that […]
