Detection of regions exhibiting irregular electrophysiological activity

What is claimed is: 1. One or more non-transitory computer-readable media having instructions executable by a processor, the instructions programmed to perform a method comprising: defining a plurality of spatial regions distributed across a three-dimensional geometric surface corresponding to a heart of a patient; detecting at least one wave front that propagates across the three-dimensional geometric surface based on electrical data representing electrophysiological signals for each of a plurality of nodes distributed on the three-dimensional geometric surface over at least one time interval; determining a duration that the wave front resides within at least one spatial region of the plurality of spatial regions during the at least one time interval; identifying slow conduction activity for the at least one spatial region based on comparing the duration that the wave front resides within the at least one spatial region relative to a duration threshold; and storing in memory conduction data representing the slow conduction activity identified for each spatial region. 2. The media of claim 1 , wherein the method further comprises generating a graphical map visualizing each region exhibiting slow conduction activity during the at least one time interval on a graphical representation of the three-dimensional geometric surface corresponding to anatomy of the heart based on the conduction data. 3. The media of claim 1 , wherein each of the plurality of spatial regions is defined to includes a set of the nodes residing within a predetermined spatial distance from a respective one of the plurality of nodes. 4. The media of claim 3 , wherein each of the plurality of spatial regions is defined as a circular region centered around the respective node and having a predetermined diameter that is twice the predetermined spatial distance. 5. The media of claim 3 , wherein the slow conduction activity for the at least one spatial region is further determined based on the predetermined spatial distance. 6. The media of claim 1 , wherein detecting the at least one wave front further comprises detecting each of a plurality of wave fronts that propagate across the three-dimensional geometric surface based on the electrical data, the method further comprising: determining a duration that each wave front of the plurality of wave fronts resides within a respective spatial region of the plurality of spatial regions over the at least one time interval; and identifying slow conduction activity for each of the plurality of spatial regions based on a comparing the duration that each wave front resides within the respective spatial region relative to the duration threshold; and storing the conduction data in the memory to represent the slow conduction activity identified for each of the plurality of spatial regions. 7. The media of claim 6 , wherein the method further comprises quantifying a relative amount of slow conduction activity for each of the plurality of regions. 8. The media of claim 6 , wherein determining the duration that each wave front resides within the respective spatial region further comprises: determining the duration that a given wave front of the plurality of wave fronts resides in each of the plurality of spatial regions; weighting each of the plurality of spatial regions according to an amount of time that the determined duration for the given wave front exceeds the duration threshold for that region; repeating the determining and weighting for each remaining wave front of the plurality of wave fronts; and aggregating the weighting for each of the plurality of spatial regions, such that the aggregated weighting quantifies a relative amount of slow conduction activity for each of the plurality of regions. 9. The media of claim 8 , wherein the method further comprises generating a graphical map visualizing the relative amount of slow conduction activity for each of the plurality of regions based on the conduction data. 10. The media of claim 1 , wherein the duration that the wave front resides within the at least one spatial region is a continuous duration of consecutive time frames within the at least one time interval. 11. The media of claim 1 , wherein the duration threshold is programmable in response to a user input instruction. 12. The media of claim 1 , wherein the electrophysiological signals at each of the plurality of nodes over the at least one time interval comprise unipolar signals on a body surface of the heart reconstructed from body surface electrophysiological signals measured non-invasively from the body surface. 13. The media of claim 1 , wherein the at least one time interval is selected, such that the electrophysiological signals include fibrillatory signals, the method further comprises: determining a cycle duration for the electrophysiological signals at each of the plurality of nodes over the at least one time interval; comparing each cycle duration to a short duration threshold to identify each short duration event for each electrophysiological signal; quantifying a number of short duration events at each of the plurality of nodes that occur during the at least one time interval; and generating a graphical map visualizing the number of short duration events that occur across a graphical representation of the heart. 14. The media of claim 13 , wherein determining the cycle duration further comprises: finding downward sloping signal segments for each of the electrophysiological signals at each of the plurality of nodes over the at least one time interval; identifying a feature in each of the downward sloping signal segments; and calculating the cycle duration as a corresponding time interval between the feature in consecutive the downward sloping signal segments for each of the electrophysiological signals. 15. A system comprising: memory to store machine readable instructions and data, the data comprising electrical data representing electrophysiological signals for a plurality of nodes distributed across a geometric surface over at least one time interval; at least one processor to access the memory and execute the instructions, the instructions comprising: code to detect at least one wave front that propagates across the geometric surface based on the electrical data, the geometric surface including a plurality of spatial regions; code to determine a duration that the at least one wave front resides within at least one spatial region of the plurality of spatial regions during the at least one time interval; code to identify slow conduction activity for the at least one spatial region based on the duration that the at least one wave front resides within the at least one spatial region being less than a duration threshold; and code to store in the memory conduction data to represent slow conduction activity for each of the plurality of spatial regions. 16. The system of claim 15 , wherein the instructions further comprises code to generate a graphical map visualizing an extent to which each region exhibits slow conduction events during the at least one time interval on a graphical representation of the geometric surface corresponding to the heart based on the conduction data. 17. The system of claim 15 , wherein each of the plurality of spatial regions includes a set of the nodes residing within a predetermined spatial distance from a respective node of the plurality of nodes. 18. The system of claim 17 , wherein each of the plurality of spatial regions is defined as a circular region centered around the respect