Morph Volume Panel

create morphvol (default)

Select the elements or nodes you wish the new volume to contain.

pick and enclose

Select nodes to indicate where you wish your new volume’s corner handles to be.

This method works in two different ways.

• Select a node for each of the eight corners of the new morph volume.
• If your model contains at least one morph volume, you can create a new volume adjacent to an existing one by selecting nodes on the face of the existing volume (and optionally designating the elements or nodes that you wish the new volume to contain). HyperWorks creates a new volume, joined to the first, which either contains those nodes/elements, or which extends outward a distance equal to the average length of the edges on the selected face.

Figure 2. . Notice the gray, highlighted elements.	Figure 3. . The new mvol conforms to the shape of the selection.

pick on screen

Draw the 2D boundaries of the new morph volume directly on-screen. The new morph volume will be given sufficient depth to enclose all the nodes selected within the window.

Figure 4.

In Figure 5, 3 of 4 lines have been laid down. When the 4th is laid, HyperWorks creates a new morph volume matching its shape and thick enough to enclose the relevant elements.

Figure 5.

reflect morphvols

Select one or more reflective symmetries, and create new morph volumes by reflecting existing ones.

Figure 6.

create matrix

Create a uniform matrix of connected morph volumes. As morph volumes are 3D, you can create a single-layer matrix of morph volumes (for example, nine volumes in a 3x3x1 matrix) or a multi-layer matrix (such as a 3x3x3 cube). Additionally, if you select a cylindrical coordinate system for the matrix, the matrix will be oriented around the central axis of the system.

Figure 7. Rectangular Matrix, with X,Y,Z Density of 3,3,3

Figure 8. Cylindrical Matrix with R, Theta, Z Density of 2,8,1

drag morphvols

Select existing morph volumes and drag their faces through a mesh, along a line or nodelist, along a vector, or about an axis.

Figure 9. Volumes Dragged along a Node List

Figure 10. Volumes Spun about an Axis

drag elements

Select shell elements and drag them through a mesh, along a line or nodelist, along a vector, or about an axis.

drag matrix (rect)

Create morph volumes in a rectangular configuration through a mesh, along a line or nodelist, along a vector, or about an axis.

drag matrix (cyl)

Create morph volumes in a cylindrical configuration through a mesh, along a line or nodelist, along a vector, or about an axis.

drag lines (rect)

Create morph volumes in a rectangular configuration with the outer profile matched to selected lines and drag them through a mesh, along a line or nodelist, along a vector, or about an axis.

Figure 11. Profile Lines Dragged along a Line to Create Morph Volumes

drag nodes (rect)

Create morph volumes in a rectangular configuration with the outer profile matched to a list of nodes and drag them through a mesh, along a line or nodelist, along a vector, or about an axis.

drag lines (cyl)

Create morph volumes in a cylindrical configuration with the outer profile matched to selected lines and drag them through a mesh, along a line or nodelist, along a vector, or about an axis.

drag nodes (cyl)

Create morph volumes in a cylindrical configuration with the outer profile matched to a list of nodes and drag them through a mesh, along a line or nodelist, along a vector, or about an axis.

along mesh

Drag the morph volume faces or elements along a line that runs roughly through the centroid of the selected nodes or elements.

along line

Drag the morph volume faces or elements along a line.

along nodelist

Drag the morph volume faces or elements along a line created from a list of nodes.

along vector

Drag the morph volume faces or elements in the specified direction. Use the toggle to select whether to drag for a specified distance or far enough to enclose the selected elements or nodes.

about axis

Spin the morph volume faces or elements about the specified axis. Use the toggle to select whether to drag through a specified angle or far enough to enclose the selected elements or nodes.

shrink depth

Shrink the morph volume only in the direction of the screen vector (the corners will remain at the positions you selected).

Note: Only available when the creation method is set to pick on screen.

no shrinking

Do not apply shrinking to the morph volumes upon creation, but you may shrink or fit them later using the shrink mvols or fit faces features in the update mvols subpanel, or you may adjust them manually by making the mvols inactive and then morphing their handles.

shrink mvols

Shrink the morph volumes, which are created, around the mesh to match the specified buffer % value. The implicit mode algorithm will be used to perform the shrinking.

slide faces

Slide the faces normal to their orientation, maintaining the orientation angles and shapes of the faces.

tilt faces

Change the orientation angles of the faces, but maintain the shapes.

fit faces

Change the shapes of the faces if there are mid-handles on the face edges, otherwise it will tilt the faces.

global system

Create the new morph volume with coordinates relative to the default global coordinate system.

local system

Add a syst selector to allow you to pick the desired local coordinate system to associate the new volume with.

Associate all nodes enclosed by the morph volume with that volume.

When registering nodes to multiple morph volumes or all morph volumes, nodes will only be registered to the morph volume that they are inside. This provides a convenient way to register masses of nodes rapidly. Nodes that are selected to be registered but that do not lie within a morph volume will still be registered to all morph volumes but will not be affected by any morph volume morphing. However, when switching from inactive to active status for morph volumes, all registered nodes are re-registered to the morph volumes, which allows for nodes to become registered to a new morph volume, or all morph volumes, depending on their location.

The process of registering nodes allows you to control which nodes are morphed by morph volumes and which are not (such as when you are matching one mesh to another), and allows you to make one morph volume dependent on another by registering its handle nodes to a morph volume that encloses it.

After morphing morph volumes while they are inactive, unregistered nodes may end up inside the morph volumes. These will not be automatically registered when the morph volume status is switched to active. You will need to register these new nodes manually.

For example: when creating a single-layer, 3 x 3 matrix of volumes around a 2D mesh, you might specify 3 for the X and Y densities and 1 for the Z density.

For a cylindrical matrix, the x density refers to the number of morph volume layers in the radial direction and the y density refers to the number of morph volumes in the outermost ring.

slide faces

Slide the faces normal to their orientation, maintaining the orientation angles and shapes of the faces.

tilt faces

Change the orientation angles of the faces, but maintain the shapes.

fit smooth

Smoothly curve the face to closely match the selected nodes

fit wavy

Fit a trigonometric shape to match the selected nodes.

fit approx

Smoothly curve the face to roughly match the selected nodes.

When performing a fit faces operation, choose to keep the current handles (use current) or specify a number of handles per edge after the volume faces are fitted (handles/edge).

implicit mode

Shrink morph volumes using internally calculated sensitivities.

This option is faster than explicit mode, however it usually requires twice as many iterations (30-50 is usually enough) to converge.

explicit mode

Shrink morph volumes using externally calculated sensitivities.

This option is slower than implicit mode, however it usually converges in 15 to 20 iterations.

Associate all nodes enclosed by the morph volume with that volume.

When registering nodes to multiple morph volumes or all morph volumes, nodes will only be registered to the morph volume that they are inside. This provides a convenient way to register masses of nodes rapidly. Nodes that are selected to be registered but that do not lie within a morph volume will still be registered to all morph volumes but will not be affected by any morph volume morphing. However, when switching from inactive to active status for morph volumes, all registered nodes are re-registered to the morph volumes, which allows for nodes to become registered to a new morph volume, or all morph volumes, depending on their location.

The process of registering nodes allows you to control which nodes are morphed by morph volumes and which are not (such as when you are matching one mesh to another), and allows you to make one morph volume dependent on another by registering its handle nodes to a morph volume that encloses it.

After morphing morph volumes while they are inactive, unregistered nodes may end up inside the morph volumes. These will not be automatically registered when the morph volume status is switched to active. You will need to register these new nodes manually.

If you are fitting to selected elements or nodes you are also given entity collectors to select them, as well as the option to register those nodes to the morph volumes being fit.

When performing a register nodes operation, only the registered nodes entity collector displays.

update mvols

Select morph volumes and update their handles or tangency.

join mvols

Combine two morph volumes, each of which is chosen with an individual morphvolume entity collector.

You can then:

join at midpoint

Stretch the two morph volumes that you choose equally to join at the midpoint between their closest faces.

first to second

Stretch the first morph volume that you choose to meet the second morph volume that you chose (the second volume will not stretch at all).

second to first

Stretch the second morph volume that you choose to meet the first morph volume that you chose (the first volume will not stretch at all).

equivalence

Join all of the morph volumes that you choose whose faces are within the specified tolerance at their respective midpoints.

Figure 12.

shrink mvols

Shrink selected morph volumes to more tightly fit their registered nodes.

fit faces

Curve or otherwise alter mvol faces to better fit the relevant elements.

Figure 13.

register nodes

Register nodes to a morph volume.

register connectors

Register connectors to their enclosing morph.

delete empty

Delete any morph volumes that have no registered nodes. This allows you to easily pare down large 3D matrices of morph volumes, retaining only the volumes that contain parts of your model.

by edges

Select the edge directly using the end node selector.

by nodes

Select node a and node b. These nodes should be the corner handles of the edge that you wish to free from tangency. Node a will be freed from tangency between its adjacent edges.

by mvols

Select one or two sets of morph volumes, and possibly also a vector or coordinate system depending on the option selected.

connect all edges

Connect all edges on the selected morph volumes which lie roughly in the same direction and meet at a common corner node.

connect edges between

Connect all edges on the first group of selected morph volumes to edges on the second group of selected morph volumes which lie roughly in the same direction and meet at a common corner node. Shared edges between the groups will not be connected.

connect along vector

Same as the connect all edges option except that it will only apply to edges which run roughly parallel to the specified vector. This allows you to connect edges running along the z-axis, for example.

connect radial edges

Same as the connect all edges option except that it will only apply to edges that run radially with respect to the specified system. This option works best with cylindrical type matrixes of morph volumes.

connect circum. edges

Same as the connect all edges option except that it will only apply to edges which run circumferentially with respect to the specified system. This option works best with cylindrical type matrices of morph volumes.

Free

Remove tangency from a selected edge, so that its shape is not affected by the edges attached to it.

Figure 14. No Correlation Between the Slopes of the Edges

Fixed

Fix one end of the edge so that the end’s slope is equal to a vector that you specify. For example, you can make one end of an edge begin with a flat slope.

Figure 15. Left End of the Curved Edge is Fixed Relative to the Y-Axis. The slope of the line is now enforced at one end and free at the other while still passing through the handles. When updating edge tangencies, the handles are not shown (for clarity) and tangency symbols are drawn at the ends of the edges where they apply.

Master/Slave

One edge (the master) is tangent to another edge (the slave) with the end of the slave edge being forced to meet the curvature at the end of the master edge. This is similar to setting one corner of the slave edge to be fixed (as for fixed tangency, above) but the corner’s slope is fixed relative to the slope of the master edge, instead of being fixed relative to a vector or axis. This is useful for keeping one morph volume (and the mesh inside) constant while still maintaining tangency between it and surrounding morph volumes.

Figure 16. Left Edge is Slaved to the Right Edge. The master edge is unaffected by the slave edge. The slave edge must remain tangent to the master edge.

Continuous

Create a consistent slope at a shared corner of two connected morph volumes.

Figure 17. Edges Form a Continuous Spline

Note: Tangency implies continuity between neighboring morph volumes, which means that morphing applied to one morph volume will affect all other morph volumes whose edges are connected through tangency. This is true for morphing in all directions.

Figure 18. Morph Volumes are Connected with Continuous Tangency. Notice how the mesh remains continuous across the boundary between the morph volumes regardless of the morph direction. For the lateral morphing case this means that elements in the lower morph volume will be shifted to the right when the upper morph volume is moved to the left. For the linear morphing case this means that the elements in the lower morph volume away from the boundary will be stretched and elements near the boundary will be compacted, which prevents an abrupt change in element size. Also notice the uneven distribution in compaction for the upper morph volume.

free all edges

Free any tangency condition for any edges on the selected morph volumes.

Note: For master-slave and continuous type tangencies, both edges must lie on the selected morph volumes.

free edges between

Free master-slave and continuous type tangencies where one edge of the tangency lies in the first group of selected morph volumes and the other edge of the tangency lies in the second group of selected morph volumes.

free along vector

Same as the free all edges option except that it will only apply to edges which run roughly parallel to the specified vector. This allows you to free edges running along the z-axis, for example.

free radial edges

Same as the free all edges option except that it will only apply to edges which run radially with respect to the specified system. This option works best with cylindrical type matrices of morph volumes.

free circum. edges

Same as the free all edges option except that it will only apply to edges which run circumferentially with respect to the specified system. This option works best with cylindrical type matrices of morph volumes.

mid-nodes on edge

Specify the number of desired mid-nodes. The graphics will display the positions of the new mid-nodes with X marks. The new positions will be evenly spaced along the edge.

Figure 19.

add mid-node

Specify the relative position (from 0 to 1) of the new mid-node, or you can click on the edge where you want the new mid-node to be, or you can click a node in the model and have the position of the new mid-node be aligned with that node. An X mark will appear to show you where the new mid-node will be created.

Figure 20.

Figure 21.

by nodes

Select a node a and a node b.

by edge

Click the edge you wish to split.

Clear this checkbox to create nodes, but not handles on the new volumes' edges.

If you clear this checkbox, the new (combined) morph volume's edge curvature will not affect or be affected by the edge curvature of the volumes adjacent to it.

single split

Specify the relative position (from 0 to 1) along the edge where you want the split to occur, click on the edge where you want the split to occur, or click a node in the model with which you want the split to be aligned.

For example, to split at the exact mid-point (creating two identical new volumes of half the original width), enter 0.5. By comparison, a value of 0.2 would still result in two morph volumes, but the one closest to node a would be only 1/5th as wide as the original distance between node a and node b. Instead of entering a value, you can click a spot on the edge, or a node in the model, to have HyperMorph calculate the distance ratio for you. An X marks the spot.

# of splits

Specify the number of split-lines to create.

For example, two split-lines will split a morph volume into three. HyperMorph places the number of split-lines that you specify equally-spaced along the length of the edge. HyperWorks marks each split location with an X.

Wireframe

Draw only the morph volume edges and handles. Do not color the face at all.

Transparent (1, 2, or 3)

Draw the faces semi-opaque; higher numbers mean more opacity.

Opaque

Set the morph volumes' transparency to zero.

Direct influence

Global handles directly affect each node.

Hierarchical influence

Global handles affect the individual domain handles within the global domain, and they in turn affect the nodes within their domains.

Mixed method

Global handles move the local handles, as for hierarchical, but they also apply the direct method to any nodes within the global domain's influence that are not part of a local domain. Such nodes otherwise would not morph at all when using the hierarchical method, causing mesh distortion at the local domain boundaries.

Spline (default)

Generally produces the best results.

Lagrange

A polynomial method, which may produce "wilder" curves for widely varying handle movements. For complicated curves the spline option is used even if this parameter is set to Lagrange.

Standard

Map the inner nodes to a position inside the morph volume and then use a reverse mapping process to determine where the nodes belong after the morph volume is morphed. Morph volume tangencies and edge curvature is respected.

Kriging

Apply the kriging algorithm for the morph volumes using only the handle positions as guides. Since the kriging algorithm is linear and morph volumes with tangencies have curved edges, the movement of the inner nodes may not match the shape of the morphed volumes. Increase the number of mid-side nodes if better correlation is desired.

mvols: inactive

Change the shape and size of morph volumes (on the morph panel) to better fit your mesh without actually altering/morphing the mesh itself. After adjusting the mvols, you can then return to the parameters subpanel to set them back to active and resume normal morphing behavior.

mvols: active / mvols: skin only

Automatically re-registers all currently registered nodes. HyperMorph will first try to register a node in its current morph volume; if that is unsuccessful it will register it to any morph volume. Unregistered nodes are unaffected, even if they now lie within a morph volume.

mvols: skin only

Delay the morphing of any nodes inside of a solid mesh until solve is clicked. This allows you to more rapidly morph your model if it contains a large number of nodes while still being able to see what affects your morphing is having on the model. To use this feature, switch the selector to mvols:skin only, make any number of shape changes to your morph volumes, and then click solve to morph the interior nodes.

register all inner connectors

Automatically register all enclosed connectors (displayed or undisplayed) when creating new morph volumes.

register displayed inner connectors

Automatically register displayed enclosed connectors only when creating new morph volumes. Undisplayed connectors will be unaffected even if enclosed by the new morph volumes.

don't register connectors

Connectors are not automatically registered to new morph volumes.