Multiple wellbore hydraulic fracturing through a single pumping system

What is claimed is: 1. A method for conducting a hydraulic fracturing job on a plurality of wellbores in a subterranean formation using the same pump, the method comprising: selecting a fluid pump of known operating pump capacity, wherein the operating pump capacity is measurable in barrels per minute; fluidly connecting the pump with each of a plurality of cased wellbores in a subterranean formation for providing pumped fracturing fluid to each of the wellbores, wherein each of the plurality of wellbores has at least one perforation through a casing of the wellbore and each perforation has a known rate range within which fracturing fluid is required to be provided to the perforation to successfully fracture the subterranean formation outside the perforation, through the perforation; and configuring the wellbores that are fluidly connected to the pump, based on both the known rate range of each perforation and operation of the pump, so that the pump provides fracturing fluid to each of the plurality of wellbores on a per perforation cluster-basis to cause each of the perforations in a cluster to concurrently receive fracturing fluid within the known rate range of the respective perforation to successfully fracture the subterranean formation outside the perforation, while the pump provides fracturing fluid to the plurality of wellbores. 2. The method as recited in claim 1 , wherein configuring the plurality of wellbores fluidly connected to the pump is at least in part by either or both: selection of wellbores that have appropriately sized perforations that facilitate the pump's operation in a damage avoidance mode characterized by operating the pump on the per perforation cluster-basis to cause each of the perforations in a respective cluster to concurrently receive fracturing fluid within the known rate range of the respective perforation; and preparation of perforations in the wellbores that are appropriately sized to facilitate the pump's operation in the damage avoidance mode. 3. The method as recited in claim 1 , wherein a rate range of fracturing fluid for successfully fracturing the subterranean formation through a respective perforation is known because the respective perforation has been designed to that rate range. 4. The method as recited in claim 1 , wherein a duration of the fracturing job of the plurality of wellbores is one of: a period of time measured from when fracturing fluid is first provided to all of the plurality of wellbores simultaneously by the pump and continues as long as fracturing fluid is being provided simultaneously by the pump to all of the plurality of wellbores; a period of time measured from when fracturing fluid is first provided to any of the plurality of wellbores by the pump and continues as long as fracturing fluid is being provided to any of the plurality of wellbores; and a period of time measured from when fracturing fluid is first provided to all of the plurality of wellbores simultaneously by the pump and continues as long as fracturing fluid is being provided by the pump to any of the plurality of wellbores. 5. The method as recited in claim 1 , wherein the perforations are configured so that at least a majority of the pump's known operating capacity is utilized to successfully fracture the subterranean formation through the perforations during a duration of the fracturing job. 6. The method as recited in claim 1 , wherein the pump's known operating capacity occurs at a sustainable operating speed of the pump specified by the pump's manufacturer. 7. The method as recited in claim 6 , wherein the sustainable operating speed of the pump is less than a peak operating speed of the pump specified by the pump's manufacturer. 8. The method as recited in claim 1 , wherein the perforations in each wellbore are created in clusters of any one of: (i) one, (ii) two, (iii) three, (iv) four, (v) five or (vi) six perforations per cluster. 9. The method as recited in claim 1 , wherein, at any time during a duration of the fracturing job, either: the perforations in any one of the plurality of wellbores are configured to require only a portion of the pump's known operating capacity in a damage avoidance mode and achieve successful fracture of the subterranean formation through each of those perforations, wherein the damage avoidance mode is characterized by operating the pump on the per perforation cluster-basis to cause each of the perforations in a respective cluster to concurrently receive fracturing fluid within the known rate range of the respective perforation; or the perforations in the plurality of wellbores are configured to collectively require at least a majority of the pump's known operating capacity in the damage avoidance mode. 10. The method as recited in claim 1 , further comprising creating the perforations in at least one of the wellbores using wireline-free actuation. 11. The method as recited in claim 1 , further comprising creating a predominance of the perforations in the wellbores using wireline-free actuation and thereby enabling substantially continuous operation of the fluid pump to be conducted during one of: a predominance of a duration of the fracturing job; as much as seventy percent of a duration of the fracturing job; as much as ninety percent of a duration of the fracturing job; as much as ninety-five percent of a duration of the fracturing job; or a substantial entirety of a duration of the fracturing job. 12. The method as recited in claim 1 , further comprising utilizing at least one of the following wireline free actuation techniques in the creation of at least a portion of the perforations in the wellbores: (i) sliding sleeves, (ii) casing-conveyed perforating shaped charges, (iii) apertures plugged with water soluble material; (iv) apertures plugged with formation-fluid soluble material; and (v) apertures plugged with chemically dissolvable material. 13. The method as recited in claim 12 , wherein the casing-conveyed perforating shaped charges are mounted at an exterior of the wellbore casing. 14. The method as recited in claim 1 , wherein each wellbore has perforations configured to collectively require less than about forty barrels per minute of pressured fracturing fluid to be provided by the pump to the wellbore for successful fracture of the subterranean formation through the perforations thereby avoiding fluid friction loss in the wellbore which facilitates operation of the pump in a damage avoidance mode characterized by operating the pump on the per perforation cluster-basis to cause each of the perforations in a respective cluster to concurrently receive fracturing fluid within the known rate range of the respective perforation. 15. The method as recited in claim 1 , wherein each wellbore has perforations configured to collectively require less than about fifty barrels per minute of pressured fracturing fluid to be provided by the pump to the wellbore for successful fracture of the subterranean formation through the perforations thereby avoiding fluid friction loss in the wellbore which facilitates operation of the pump in a damage avoidance mode characterized by operating the pump on the per perforation cluster-basis to cause each of the perforations in a respective cluster to concurrently receive fracturing fluid within the known rate range of the respective perforation. 16. A single pumping system for conducting a hydraulic fracturing job on a plurality of wellbores in a subterranean formation, the single pumping system comprising: a fluid pump of known operating pump capacity, wherein the operating pump capa