System, method, and apparatus for operating a high efficiency, high output transmission

What is claimed is: 1. A method, comprising: providing a first opposing pulse in a first closed volume that opposes movement of a progressive actuator of a transmission in a shift direction; providing a first actuating pulse in a second closed volume that promotes movement of the progressive actuator in the shift direction; determining a shift completion event that releases pressure in the first and second closed volumes; and commanding a position of the progressive actuator operationally coupled to a clutch based at least in part on an interpreted clutch torque profile that is interpreted by performing a clutch engagement position test. 2. The method of claim 1 , wherein performing the clutch engagement position test further comprises commanding a friction brake to bring an input shaft speed to zero. 3. The method of claim 2 , further comprising: interpreting, by a vehicle state logic, at least one vehicle operating condition; and providing, by a neutral enforcement logic, a first neutral command to the progressive actuator and a second neutral command to the progressive actuator, in response to the at least one vehicle operating condition indicating that vehicle motion is not intended; wherein the progressive actuator is responsive to selectively decouple a first gear mesh based on the first neutral command and a second gear mesh based on the second neutral command, wherein both gear meshes in the engaged position couple the input shaft of the transmission to drive wheels of a vehicle including the transmission, and wherein either gear mesh in a neutral position decouples the input shaft from the drive wheels. 4. The method of claim 1 , further comprising providing, by a launch characterization logic, an iteratively derived estimated vehicle mass value. 5. The method of claim 4 , wherein the iteratively derived estimated vehicle mass value is based at least in part on adjusting, by a model consistency logic, an adaptation rate of operations of a vehicle environment logic and a mass estimation logic. 6. The method of claim 5 , wherein the vehicle environment logic is configured to provide interpretations of a motive torque value, a vehicle grade value, and a vehicle acceleration value. 7. The method of claim 6 , further wherein a mass estimation logic is configured to: determine a plurality of correlations between the interpretations of the vehicle environment logic; and determine adaptations of an estimated vehicle drag value and an estimated vehicle effective inertia based on at least the plurality of determined correlations. 8. A computer product in a non-transitory memory, wherein the computer product configures a processor, when implemented from the memory, to: provide a first opposing pulse in a first closed volume that opposes movement of a progressive actuator of a transmission in a shift direction; provide a first actuating pulse in a second closed volume that promotes movement of the progressive actuator in the shift direction; determine a shift completion event that releases pressure in the first and second closed volumes; and command a position of the progressive actuator operationally coupled to a clutch based at least in part on an interpreted clutch torque profile that is interpreted by performing a clutch engagement position test. 9. The computer product of claim 8 , wherein the clutch engagement position test comprises commanding a friction brake to bring an input shaft speed to zero. 10. The computer product of claim 9 , wherein the processor is furthered configured to: interpret at least one vehicle operating condition; and provide a first neutral command to the progressive actuator and a second neutral command to the progressive actuator, in response to the at least one vehicle operating condition indicating that vehicle motion is not intended; wherein the progressive actuator is responsive to selectively decouple a first gear mesh based on the first neutral command and a second gear mesh based on the second neutral command, wherein both gear meshes in the engaged position couple the input shaft of the transmission to drive wheels of a vehicle including the transmission, and wherein either gear mesh in a neutral position decouples the input shaft from the drive wheels. 11. The computer product of claim 8 , wherein the processor is furthered configured to: provide an iteratively derived estimated vehicle mass value that is based at least in part on adjusting an adaptation rate of operations of a vehicle environment logic and a mass estimation logic. 12. The computer product of claim 11 , wherein the vehicle environment logic is configured to provide interpretations of a motive torque value, a vehicle grade value, and a vehicle acceleration value. 13. The computer product of claim 11 , further wherein a mass estimation logic is configured to: determine a plurality of correlations between the interpretations of the vehicle environment logic; and determine adaptations of an estimated vehicle drag value and an estimated vehicle effective inertia based on at least the plurality of determined correlations.