Trajectory optimization in radiotherapy using sectioning

The invention claimed is: 1. A method for radiation therapy treatment using a radiation delivery device, the method comprising: providing a patient model, dosimetric constraints, delivery motion constraints, and delivery coordinate space of the radiation delivery device, wherein the delivery coordinate space is represented as a mesh with vertices connected by edges, where the vertices correspond to directions of a beam eye view (BEV) of the radiation delivery device, where each BEV has corresponding area elements resulting from beam collimation; constructing BEV region connectivity manifolds from the patient model, the dosimetric constraints, the delivery coordinate space, and existing beam trajectories, wherein each of the BEV region connectivity manifolds represents connections between contiguous 2D target regions, wherein each of the 2D target regions is defined at each of the vertices of the delivery coordinate space; selecting beam trajectories based on region connectedness information in the BEV region connectivity manifolds, the dosimetric constraints, the delivery motion constraints, and the existing beam trajectories; and delivering radiation using the radiation delivery device in accordance with the selected beam trajectories. 2. The method of claim 1 wherein selecting beam trajectories is also based on a BEV dose section and a BEV score section, wherein the term “section” refers to a section of a BEV fiber bundle. 3. The method of claim 1 wherein selecting beam trajectories uses a max-distance function to select among trajectories found using a min-distance function. 4. The method of claim 3 wherein selecting beam trajectories maximizes angular spread and minimizes trajectory interference by including in the min-distance function and max-distance function a per-voxel angular flux defined to be the number of unique directions at which the beam hits a given voxel with some spherical binning scheme. 5. The method of claim 1 wherein constructing the BEV region connectivity manifold comprises: i) at each vertex, identifying contiguous 2D target regions using a binary selection criterion to identify apertures for treatment; ii) identifying connections between contiguous 2D target regions of neighboring vertices. 6. The method of claim 5 wherein constructing the BEV region connectivity manifold comprises: expanding regions whose voxels have low binary angular flux counts; and contracting regions whose voxels have high (non-binary) angular flux counts; wherein the angular flux counts are defined to be the number of unique directions at which the beam hits a given voxel with some spherical binning scheme. 7. The method of claim 5 wherein the binary selection criterion is based on a BEV dose section, a BEV score section, and existing beam trajectories. 8. The method of claim 1 further comprising generating a BEV dose section representing BEV dosimetrics for each area element of the BEV at each vertex in the delivery coordinate space; and generating a BEV score section representing a measure of goodness for treatment at each area element of each vertex in delivery coordinate space.