Method for determining distinct alternative paths between two object sets in 2-D and 3-D heterogeneous data

1. A method for assessing reservoir connectivity in a subsurface region for the purpose of planning and managing production of hydrocarbons from the subsurface region, comprising:

• (a) creating a geologic cellular model in a computer of at least a portion of the subsurface region, said model containing a value of a selected geophysical property for each cell of the model;
  
  (b) determining a front propagation speed for each cell as a function of the selected geophysical property;
  
  (c) selecting a source object and a target object in the model, wherein source object is associated with one or more source cells and the target object is associated with one or more target cells;
  
  (d) for a plurality of cells in the model excluding source and target cells, calculating arrival time for a front beginning at the source object to reach one of the cells in the plurality of cells in a computer, then calculating the arrival time for a front beginning at the target object to reach the one of the cells in the plurality of cells in a computer, then adding the two calculated times together and creating a two-way total arrival time for the one of the cells in the plurality of cells, said arrival time being calculated using the determined front propagation speed;
  
  (e) determining one or more distinct paths connecting source and target objects by calculating and using gradients of the two-way total arrival times and/or curvatures of the two-way total arrival times at the plurality of cells, wherein determining one or more distinct paths by using gradients of two-way total arrival times at the plurality of model cells comprises;
  
  (i) forming, using, and updating a current candidate cell list consisting of cells from the plurality of cells that have gradient magnitude value of zero to within a selected tolerance;
  
  (ii) selecting a cell from the current candidate cell list and determining an optimal path from the selected cell to the source object and another optimal path from the selected cell to the target object, and combining the determined optimal paths to form an optimal path associated with the selected cell; and
  
  (iii) accepting the optimal path associated with the selected cell as a distinct path if it passes through or touches at least a pre-determined number of cells having zero gradient within a selected tolerance, such cells being located within a predetermined proximity to the selected cell;
  
  (f) assessing reservoir connectivity between source and target objects using the one or more distinct paths; and
  
  (g) planning or managing production of hydrocarbons from the subsurface region using the reservoir connectivity assessment.