Electro-hydrostatic brake control

What is claimed is: 1. An electro-hydrostatic brake system comprising: a motor in electronic control communication with a motor controller; a pump mechanically coupled to the motor; a hydraulic tank fluidly coupled with the pump; a hydraulic pressure rail fluidly coupled in fluid receiving communication with the pump; a brake actuator in fluid communication with the hydraulic pressure rail and configured to exert a braking force on a wheel, wherein the braking force is directly modulated by at least one of the motor and the pump; and a hydraulic return rail in fluid receiving communication with the brake actuator, wherein the hydraulic return rail is separate from the hydraulic pressure rail; wherein the brake actuator is a first brake actuator of a plurality of brake actuators in fluid communication with the hydraulic pressure rail and the hydraulic return rail, wherein the plurality of brake actuators is configured to exert the braking force on the wheel; wherein application of the braking force is directly modulated by the at least one of the motor and the pump without use of a hydraulic step down valve; and wherein there are no pressure reducing valves disposed between the pump and the plurality of brake actuators along the hydraulic pressure rail. 2. The electro-hydrostatic brake system of claim 1 , wherein the pump is a hydrostatic positive displacement pump. 3. The electro-hydrostatic brake system of claim 1 , wherein the hydraulic pressure rail is configured so that a hydrostatic pressure in the hydraulic pressure rail is substantially the same along its length, such that the hydrostatic pressure from the pump is substantially the same as the pressure in the plurality of brake actuators causing the application of the braking force. 4. The electro-hydrostatic brake system of claim 1 , further comprising a pressure sensor coupled to the hydraulic pressure rail and in electronic feedback communication with the motor controller. 5. The electro-hydrostatic brake system of claim 1 , further comprising a displacement sensor coupled to the brake actuator and in electronic feedback communication with the motor controller. 6. The electro-hydrostatic brake system of claim 1 , further comprising the motor controller, wherein: the motor controller is a first motor controller configured to receive a brake command and the electro-hydrostatic brake system further comprises a second motor controller configured to receive the brake command; the motor is a first motor and the electro-hydrostatic brake system further comprises a second motor in electronic control communication with the second motor controller; the pump is a first hydrostatic pump and the electro-hydrostatic brake system further comprises a second hydrostatic pump mechanically coupled to the second motor; the hydraulic pressure rail is a first hydraulic pressure rail and the electro-hydrostatic brake system further comprises a second hydraulic pressure rail fluidly coupled in fluid receiving communication with the second hydrostatic pump; the brake actuator is a first brake actuator, the braking force is a first braking force, and the electro-hydrostatic brake system further comprises a second brake actuator in fluid communication with the second hydraulic pressure rail that is configured to exert a second braking force on the wheel; and the hydraulic return rail is a first hydraulic return rail and the electro-hydrostatic brake system further comprises a second hydraulic return rail in fluid receiving communication with the second brake actuator. 7. An electro-hydrostatic brake system comprising: a motor controller; a motor in electronic control communication with the motor controller; a pump mechanically coupled to the motor; a hydraulic tank fluidly coupled with the pump; a hydraulic pressure rail fluidly coupled in fluid receiving communication with the pump; a brake actuator in fluid communication with the hydraulic pressure rail; a feedback sensor coupled in electronic feedback communication with the motor controller and coupled to at least one of the hydraulic pressure rail and the brake actuator; a hydraulic return rail in fluid communication with the brake actuator and the hydraulic tank; and a bleed valve coupled to the hydraulic return rail between the brake actuator and the hydraulic tank; wherein the motor controller comprises a processor; wherein a tangible, non-transitory memory is configured to communicate with the processor, the tangible, non-transitory memory having instructions stored thereon that, in response to execution by the processor, cause the electro-hydrostatic brake system to perform operations comprising: receiving, by the processor of the motor controller, a brake command; in response to the motor controller receiving the brake command, actuating the motor to deliver a hydrostatic pressure to the hydraulic pressure rail via the pump such that the brake actuator exerts a braking force on a wheel, wherein the hydraulic pressure rail is configured such that the hydrostatic pressure from the pump along the entire length of the hydraulic pressure rail to the brake actuator is substantially the same; receiving, by the processor of the motor controller, feedback from the feedback sensor; in response to the motor controller receiving the feedback, actuating the motor to change the hydrostatic pressure delivered to the hydraulic pressure rail via the pump such that the brake actuator changes the braking force; and in response to the motor controller receiving the feedback, actuating the bleed valve to decrease the hydrostatic pressure in the hydraulic pressure rail via the hydraulic return rail such that the braking force changes; and wherein there are no pressure reducing valves disposed between the pump and the brake actuator along the hydraulic pressure rail. 8. The electro-hydrostatic brake system of claim 7 , wherein the feedback sensor is a pressure sensor coupled to the hydraulic pressure rail, wherein receiving, by the processor of the motor controller, the feedback comprises receiving a feedback pressure from the pressure sensor. 9. The electro-hydrostatic brake system of claim 7 , wherein the feedback sensor is a displacement sensor coupled to the brake actuator, wherein receiving, by the processor of the motor controller, the feedback comprises receiving a feedback displacement from the displacement sensor. 10. A method of controlling a braking force of an electro-hydrostatic system, the method comprising: receiving, by a processor of a motor controller, a brake command; commanding, by the processor and in response to the motor controller receiving the brake command, actuating a motor mechanically coupled to a pump to deliver a hydrostatic pressure to a hydraulic pressure rail via the pump such that a brake actuator exerts a braking force on a wheel, wherein the hydraulic pressure rail is configured such that the hydrostatic pressure from the pump along the entire length of the hydraulic pressure rail to the brake actuator is substantially the same; receiving, by the processor of the motor controller, feedback from a feedback sensor; and in response to the motor controller receiving the feedback, actuating the motor to change the hydrostatic pressure delivered to the hydraulic pressure rail via the pump such that the brake actuator changes the braking force; wherein a hydraulic return rail is also fluidly coupled to the brake actuator and is separate from the hydraulic pressure rail; and wherein there are no pressure reducing valves disposed between the pump and the brake actuator along the hydraulic pressure rail. 11. The method of claim 10 , further comprising: