Differential assembly with axle torque vectoring

What is claimed is: 1. A vehicle, comprising: an engine; a differential operatively coupled to the engine; a first road wheel; a first half shaft drivingly coupling the differential to the first road wheel; a first electric machine having a first output shaft; a first planetary gear set having a first sun gear, a first planet carrier, and a first ring gear, the first sun gear being fixedly coupled with the first output shaft, the first planet carrier being fixedly coupled with the first half shaft; a first brake configured to selectively hold the first ring gear against rotation; a second road wheel; a second half shaft drivingly coupling the differential to the second road wheel; a second electric machine having a second output shaft; a second planetary gear set having a second sun gear, a second planet carrier, and a second ring gear, the second sun gear being fixedly coupled with the second output shaft, the second planet carrier being fixedly coupled with the second half shaft; and a second brake configured to selectively hold the first ring gear against rotation. 2. The vehicle of claim 1 , further comprising a controller configured to selectively control the first brake in a first brake engaged state with the first ring gear held against rotation and in a first brake disengaged state with the first ring gear not held against rotation, to selectively control the second brake in a second brake engaged state with the second ring gear held against rotation and in a second brake disengaged state with the second ring gear not held against rotation, to selectively control the first electric machine to provide drive torque and to provide resistive torque, and to selectively control the second electric machine to provide drive torque and to provide resistive torque. 3. The vehicle of claim 2 , wherein the controller is further configured to, in response to at least one sensor input corresponding to a torque boost condition or an emergency braking condition, control the first brake in the first brake engaged state, control the second brake in the second brake engaged state, and control the first electric machine and the second electric machine to provide torque and to rotate at a same speed. 4. The vehicle of claim 2 , wherein the controller is further configured to, in response to at least one sensor input corresponding to an electric drive condition, control the first brake in the first brake engaged state, control the second brake in the second brake engaged state, and control the first electric machine and the second electric machine to provide drive torque in the absence of drive torque from the engine. 5. The vehicle of claim 2 , wherein the controller is further configured to, in response to at least one sensor input corresponding to a parking assist condition or a redundant steering condition, control the first brake in the first brake engaged state, control the second brake in the second brake engaged state, and to control the first electric machine to rotate at a first speed and the second electric machine to rotate at a second speed, distinct from the first speed, to produce a speed differential between the first half shaft and the second half shaft. 6. The vehicle of claim 2 , wherein the controller is further configured to, in response to at least one sensor input corresponding to a targeted torque condition, control the first brake in the first brake engaged state, control the second brake in the second brake disengaged state, and to control the first electric machine to deliver drive torque to the first road wheel. 7. The vehicle of claim 2 , wherein the controller is further configured to, in response to at least one sensor input corresponding to a stability control condition, control the first brake in the first brake engaged state, control the second brake in the second brake disengaged state, and to control the first electric machine to deliver resistive torque to the first road wheel. 8. A differential assembly for a vehicle comprising: a differential; a prop shaft configured to drivingly couple the differential to a motive power source; a first half shaft configured to drivingly couple the differential to a first road wheel; a second half shaft configured to drivingly couple the differential to a second road wheel; a first electric machine having a first output shaft; a second electric machine having a second output shaft; a first gearing assembly configured to selectively impose a controlled speed ratio between the first half shaft and the first output shaft, the first gearing assembly including a first gearing element coupled to the first output shaft, a second gearing element fixedly coupled to the first half shaft, and a third gearing element; a second gearing assembly configured to selectively impose a controlled speed ratio between the second half shaft and the second output shaft, the second gearing assembly including a fourth gearing element coupled to the second output shaft, a fifth gearing element fixedly coupled to the second half shaft, and a sixth gearing element; a first brake configured to selectively hold the third gearing element against rotation; and a second brake configured to selectively hold the sixth gearing element against rotation. 9. The differential assembly of claim 8 wherein the first gearing element includes a first sun gear, the second gearing element includes a first planet carrier, and the third gearing element includes a first ring gear, and wherein the fourth gearing element includes a second sun gear, the fifth gearing element includes a second planet carrier, and the sixth gearing element includes a second ring gear. 10. The differential assembly of claim 8 , further comprising a housing, wherein the differential, the first half shaft, the second half shaft, the first electric machine, the second electric machine, the first gearing assembly, and the second gearing assembly are disposed at least partially within the housing. 11. The differential assembly of claim 8 , further comprising a controller configured to control the first gearing assembly to selectively operate in a first gearing assembly first mode with the controlled speed ratio between the first half shaft and the first output shaft and in a first gearing assembly second mode with no controlled speed ratio between the first half shaft and the first output shaft, and to control the second gearing assembly to selectively operate in a second gearing assembly first mode with the controlled speed ratio between the second half shaft and the second output shaft and in a second gearing assembly second mode with no controlled speed ratio between the second half shaft and the second output shaft. 12. The differential assembly of claim 11 , wherein the controller is further configured to, in response to a first set of operating conditions, control the first gearing assembly in the first gearing assembly first mode and control the second gearing assembly in the second gearing assembly first mode. 13. The differential assembly of claim 12 , wherein the first set of operating conditions includes a torque boost operating condition or an emergency braking operating condition, and wherein the controller is further configured to control the first electric machine and the second electric machine to rotate at a same speed and to provide torque. 14. The differential assembly of claim 12 , wherein the first set of operating conditions includes an electric drive operating condition, and wherein the controller is further configured to control the first electric machine and the second electric machine to rotate at a same speed and t