Skip to end of metadata
Go to start of metadata

You are viewing an old version of this page. View the current version.

Compare with Current View Page History

« Previous Version 18 Next »

In this section:

Introduction

CUBE (Combined Uncertainty and Bathymetric Estimator) is an error-model based, direct DTM generator that estimates the depth plus a confidence interval directly on each node point. The CUBE library is developed by University of New Hampshire.

The implementation in Geocap Seafloor is modfied to work with echo sounder models which were not in the market when Cube was created. The latest release of the Cube library was in 2004.

 
The output of the command is a depth surface named cube_depth_surface. The surface can also contain additional attributes like UncertaintyDepthHypotheses and HypothesisStrength dependent on the selected options in the dialog.

 

The content of the menu

   

The CUBE dialog for multibeam data and CUBE for XYZ data in a Soundings folder.

 

Input Data

The Input data part of the dialog is where to select which data items to be gridded. The CUBE command works with both multibeam data (Survey Line)  and with XYZ data (Dataset). Select data items from the list.

The rows X, Y and Z are automatically updated with the minimum and maximum extensions of the coordinates from the selected files.

The Coordinate System field shows the type of coordinate system for the data.

 

Cube Algorithm Parameters

The Cube Algorithm Parameters part is where to specify parameters for the CUBE depth processing. The parameters to set:

  • Depth Estimation Algorithm
  • Grid increments
  • Error Distribution Model Algorithm

 

Depth Estimation Algorithm

The options for the depth estimation algorithm are:

  • Nodal estimate algorithm: This is the default algorithm for the implementation of Cube. It will create the depth surface and the operator can select to also create the Uncertainty attributes to the cube_depth_surface. 
  • Bined mean algorithm: This algorithm will create the surface based on the mean values in the bins (cells). No attributes can be created. 
  • Bined median algorithm:This algorithm will create the surface based on the median values in the bins (cells). No attributes can be created. 
  • HyperCUBE super-grid: The HyperCUBE super-grid is creating a grid based on several hypotheses from the depth data. In addition to the depth grid this algorithm can also create the attributes UncertaintyDepthHypotheses and HypothesisStrength as output in the cube_depth_surface. This depth estimation algorithm is implemented for multibeam data only. This algorithm is currently not available in Geocap Seafloor

 

Grid increments

Specify the increments:

  • X Increment (m): Specify the increments in X-direction (Easting) for the result grid.
  • Y Increment (m): Specify the increments in Y-direction (Northing) for the result grid.

The lower left corner and the upper right corner of the result grid will be rounded down and up to contain the increments. (A 5 meter grid increment result in a lower left corner starting on an integer value of 5 meter.)

 

Error Distribution Model Algorithm

Specify the type of the error distribution

  • FULL: Implemented for multibeam data only. Will use all information from the multibeam data's Vessel Configuration to estimate as accurate as possible the 
  • IHO: Implemented for multibeam data and XYZ data. When selected, the IHO order can be specified below.

The IHO Order (prediction model):

    • Special Order: Areas where under-keel clearance is critical.
    • Order 1a: Areas shallower than 100 meters where under-keel clearance is less critical, but features of concern to surface shipping may exist.
    • Order 1b: Areas shallower than 100 meters where under-keel clearance is not considered to be an issue for the surface shipping expected to transit the area
    • Order 2: Areas generally deeper than 100 meters where a general description of the sea floor is considered adequate.

 

Output

Select options for what output to create.

  • Depth Surface: The depth surface will always be produced in the cube_depth_surface result data.
  • Uncertainty Surface: When using the depth estimation algorithms Nodal estimate algorithm or HyperCUBE super-grid this option can be checked. The Uncertainty values will be an attribute in the cube_depth_surface.
  • Number of Hypotheses Surface: When using the depth estimation algorithms Nodal estimate algorithm or HyperCUBE super-grid this option can be checked. The DepthHypotheses values will be an attribute in the cube_depth_surface.
  • Hypothesis Strength Surface: When using the depth estimation algorithm HyperCUBE super-grid this option can be checked. The HypothesisStrength values will be an attribute in the cube_depth_surface. Since the algorithm HyperCUBE super-grid is currently not available, this output will not be possible.

 

The Results

After executing the volumetrics a dialog will pop up showing the parameters, result and volumes from the calculations. The report itself is saved in the project structure in a folder named Reports under the same folder as the command is executed from. The report itself is named as YYYYMMDD CUBE (the name of the executed command).

All reports from all runs will be saved in the Reports folder.

 

 

 

  • No labels