Vehicle lubrication flow control

The invention claimed is: 1. A hybrid vehicle powertrain comprising: a hybrid transmission having a plurality of fluid requiring components; a fluid pump in fluid communication with a fluid reservoir and with each of the plurality of fluid requiring components, the fluid pump configured to supply fluid to each of the plurality of fluid requiring components at an adjustable system flow rate; and a flow controller electrically connected to the fluid pump and configured to controllably modulate the operating speed of the fluid pump to adjust the system flow rate; and wherein the flow controller is further configured to: determine an operating speed and torque for each respective component of the plurality of fluid requiring components; select a component-required flow rate for each respective component of the plurality of fluid requiring components using the determined operating speed and torque for that component; set the system flow rate as the maximum component-required flow rate of the plurality of component-required flow rates; and command the fluid pump to supply fluid to each of the plurality of fluid requiring components at the system flow rate. 2. The powertrain of claim 1 , wherein the flow controller includes a plurality of two-dimensional look-up tables; and wherein the flow controller is configured to select each component-required flow rate from a respective look-up table of the plurality of two-dimensional look-up tables using the determined operating speed and torque for that component. 3. The powertrain of claim 1 , wherein the flow controller is configured to determine an operating speed and torque for each respective component by sensing the speed and torque using a sensor coupled with the respective component. 4. The powertrain of claim 1 , wherein the flow controller is configured to determine an operating speed and torque for each respective component by deriving each respective speed and torque using an operating parameter of a coupled electric traction motor. 5. The powertrain of claim 1 , wherein the plurality of fluid requiring components include a first planetary gear system, a second planetary gear system, and a third planetary gear system. 6. The powertrain of claim 1 , wherein the fluid pump includes an electric motor. 7. The powertrain of claim 1 , wherein the fluid pump is further in fluid communication with an electric fraction motor, and wherein the fluid pump configured to supply fluid to the traction motor at the system flow rate. 8. The powertrain of claim 1 , wherein the component-required flow rate for each respective component is selected such that a temperature rise of the fluid across the respective component does not exceed a predetermined amount. 9. A method of controlling a fluid pump to supply lubricating fluid at a system flow rate to a plurality of fluid requiring components in a hybrid vehicle powertrain, the method comprising: determining an operating speed and torque for each respective component of the plurality of fluid requiring components; selecting a component-required flow rate for each respective component of the plurality of fluid requiring components using the determined operating speed and torque for that component; setting the system flow rate at the maximum component-required flow rate of the plurality of component-required flow rates; and commanding the fluid pump to supply fluid to each of the plurality of fluid requiring components at the system flow rate. 10. The method of claim 9 , wherein selecting a component-required flow rate includes selecting the component-required flow rate from a two-dimensional look-up table using the determined operating speed and torque for that component. 11. The method of claim 9 , wherein determining an operating speed and torque for each respective component includes sensing the speed and torque using a sensor coupled with the respective component. 12. The method of claim 9 , wherein determining an operating speed and torque for each respective component includes deriving each respective speed and torque using an operating parameter of a coupled electric traction motor. 13. The method of claim 9 , wherein the plurality of fluid requiring components include a first planetary gear system, a second planetary gear system, and a third planetary gear system. 14. The method of claim 9 , further comprising supplying fluid to an electric traction motor coupled with the plurality of fluid requiring components at the system flow rate. 15. A hybrid vehicle powertrain comprising: an electric traction motor; a hybrid transmission having a plurality of fluid requiring transmission components; a fluid pump in fluid communication with a fluid reservoir, the traction motor, and with each of the plurality of fluid requiring components, the fluid pump configured to supply fluid to the traction motor and to each of the plurality of fluid requiring transmission components at an adjustable system flow rate; and a flow controller electrically connected to the fluid pump and configured to controllably modulate the operating speed of the fluid pump to adjust the system flow rate; and wherein the flow controller is further configured to: determine an operating speed and torque for the traction motor and for each respective component of the plurality of fluid requiring components; select a component-required flow rate for the traction motor and for each respective component of the plurality of fluid requiring components using the respectively determined operating speeds and torques; set the system flow rate as the maximum component-required flow rate of the plurality of component-required flow rates; and command the fluid pump to supply fluid to the traction motor and to each of the plurality of fluid requiring components at the system flow rate. 16. The powertrain of claim 15 , wherein the flow controller includes a plurality of two-dimensional look-up tables; and wherein the flow controller is configured to select each component-required flow rate from a respective look-up table of the plurality of two-dimensional look-up tables using the respectively determined operating speeds and torques. 17. The powertrain of claim 15 , wherein the flow controller is configured to determine an operating speed and torque for each respective fluid requiring component by sensing the speed and torque using a sensor coupled with the respective component. 18. The powertrain of claim 15 , wherein the flow controller is configured to determine an operating speed and torque for each respective fluid requiring component by deriving each respective speed and torque using an operating parameter of the traction motor. 19. The powertrain of claim 15 , wherein the plurality of fluid requiring components include a first planetary gear system, a second planetary gear system, and a third planetary gear system. 20. The powertrain of claim 19 , wherein the respective operating torque of each of the first, second and third planetary gear systems is a ring torque.