3.3 Navigator Nodes
Navigator Nodes are the icons and text that represent the analysis tools or spreadsheet viewers that you are using or have used in your work. Double clicking a Navigator Node causes the associated Viewer window to be displayed. Each Navigator Node is given a default name when it is created, but it can be renamed by right clicking on the Node and selecting Rename Node from the context menu Fig. or by single clicking on the Navigator Node’s name.
Navigator Nodes can also be deleted by right clicking on the Node and selecting Delete Node from the popup menu. Note that when deleting a Node, all of the Node’s children will also be deleted, as well as all documentation and notes about those Nodes in the Node Change Log and Edit Annotations windows.
![[Picture]](renameNodePT.png)
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3.3.1 Viewer Windows
Each data analysis tool is opened in a Viewer window. Spreadsheet Viewers let you view and select data for analysis, while other viewers analyze the data and provide helpful visualizations of data.
Under certain circumstances, Viewer windows automatically generate a duplicate Navigator Node. For example, if a spreadsheet node has a Histogram Node as a child, because the histogram is directly dependent on the state of it’s spreadsheet parent, any change in the state of the spreadsheet causes Optimus RP to duplicate the spreadsheet node (but not its children) and make the change in the duplicate leaving the original spreadsheet unchanged. This technique of duplicating parent Navigator Nodes with dependent children helps maintain the integrity of the historical documentation associated with each Navigator Node, making it easier to track changes and produce accurate reports.
There are two types of Viewer windows, a simple viewer and a tabbed viewer. Simple Viewers are associated with a single Navigator Node. Tabbed Viewers are associated with multiple Navigator Nodes. Tabbed Viewers are created for Navigator Nodes that my be duplicated for integrity reasons as described above. For example, by zooming in on a matrix plot a new Navigator Node is created and a tab is added to the bottom of the viewer, titled "Zoom 1". A tabbed viewer has one or more tabs on the bottom of the Viewer that correspond to each of the previously created Navigator Nodes. Clicking on the tabs changes which Navigator Node viewer is displayed. Another example for tabbed viewers occurs when you create ten subset spreadsheets for a given data set, one tabbed viewer is created with ten tabs (a tab for each spreadsheet), and ten Nodes are created in the Project Navigator window. When you double click on one of the ten Spreadsheet Nodes, the tabbed viewer will open with the correct tab selected showing the spreadsheet data for the selected node.
3.3.2 Types of Navigator Nodes and Their Associated Viewers
There is a Navigator Node type for each analysis action that takes place. Except for the Project Node and a Dataset Node, every node can be doubled clicked for its specific Viewer to be displayed. Each type of Navigator Node is described briefly below:
3.3.2.1 The Project Node
![[Picture]](projectIcon.png)
The Project Node is the root node that displays the project’s name. The tree of Navigator Nodes descends, either
directly or indirectly, from the Project Node. It does not open any Viewer, nor can it be deleted.
3.3.2.2 The Dataset Node
![[Picture]](datasetIcon.png)
The Dataset Node represents data that has been imported into the project. Its function is to visually identify the data
you are analyzing. Every imported data set automatically creates a child Spreadsheet Node. To view a Dataset Node, Double
clicking on the child Spreadsheet Node, not the Dataset Node. See chapter 4, Importing Data, for a complete description of
the Dataset Node.
3.3.2.3 The Spreadsheet Node
![[Picture]](spreadsheetIcon.png)
A Spreadsheet Node represents either all or a subset of a data set. Double clicking on a Spreadsheet Node displays a
Spreadsheet Viewer. Using the Spreadsheet Viewer you can select portions of the data set and generate Tree Analysis Nodes
for recursive partitioning analysis (see Chapter 7, Interactive Tree Analysis) and for predictions (see Chapter 8, Prediction
Recipes).
Only a spreadsheet view has the ability to export data out of Optimus RP. All spreadsheet views have a CSV output option. There is also an option that allows you to export to SAS, EXCEL and most common databases. See Chapter 6, Using the Spreadsheet Viewer, for an explanation of working with a spreadsheet view of the data.
3.3.2.4 Tree Analysis Node
![[Picture]](treeIcon.png)
A Tree Analysis Node opens a previously created Tree Viewer when double clicked. The Tree Viewer is the main
tool for doing the advanced recursive partitioning analysis provided by Optimus RP. See Chapter 7, Interactive Tree Analysis,
for a detailed explanation.
3.3.2.5 Multitree Model Node
![[Picture]](multitreeIcon.png)
The Multitree Model Node represents a number of trees that have previously been generated with randomly defined
splits. Double clicking a Multitree Node displays a Multitree Viewer. The Multitree Viewer is a powerful analysis tool. It is
fully described in Chapter 9, Random Tree Generation. For details on doing predictions with the Multitree Viewer,
see Chapter 8, Prediction Recipes. The Multitree Viewer has several outputs that generate child Spreadsheet
Nodes:
- View Average Tree Predictions,
- View All Tree Predictions,
- View Usage of Selected Variables, and
- View Frequencies of Selected Variables.
3.3.2.6 Applied Tree Node
![[Picture]](appliedtreeIcon.png)
The Applied Tree Node represents a list of trees that were created as a result of using a Multitree
Model to make predictions on some data. Double clicking on the Applied Tree Node displays an Applied
Tree Viewer where you can view the prediction trees. See Chapter 8, Prediction Recipes for details of doing
predictions. This Viewer also the same outputs as the Multitree Model Node to generate child Spreadsheet
Nodes:
3.3.2.7 Histogram Node
![[Picture]](histogramIcon.png)
A Histogram Node represents a previously generated histogram. Double clicking on a Histogram Node causes its
Histogram Viewer to be displayed. See Chapter 11, Histogram Node Analysis, for a description of the Histogram
Viewer.
3.3.2.8 Observation Distance Matrix Node
![[Picture]](distancematrixIcon.png)
An Observation Distance Matrix Node represents a previously generated observation distance matrix graph. Double
clicking on an Observation Distance Matrix node causes an Observation Distance Matrix Viewer to be displayed. See Chapter
12, Viewing the Observation Distance Matrix for more details.
3.3.2.9 Correlation Interaction Node
![[Picture]](correlationinteractionIcon.png)
The Correlation Interaction Node represents a previously generated correlation interaction graph. Double clicking
on a Correlation Interaction Node causes a Correlation Interaction Viewer to be displayed. See Chapter 13, The Correlation
Interaction View.
3.3.2.10 P Value Node
![[Picture]](pvalIcon.png)
The P Value Node represents a previously created P Value Plot. Double clicking on this node will display the P
Value Plot Viewer.
3.3.2.11 Text Node
![[Picture]](metaInfoIcon.png)
The Text Node represents a collection of textual information. Double clicking on this node will open a Text
Viewer.