Hydraulic actuator system

We claim: 1. A system for hydraulically actuating at least one degree of freedom, said system comprising: a single prime mover for at least two actuation modules, wherein the prime mover produces rotary motion and is constituted by a battery powered electric motor, and each actuation module includes: (1) an over-center variable displacement pump, said pump having: (a) a power input connection configured to power the pump from said prime mover; and (b) a displacement varying input for varying the displacement of the pump; and (2) a displacement varying actuator configured to modulate the displacement varying input of the pump; (3) an output actuator in direct communication with the pump, said output actuator being configured to drive an object through a corresponding degree of freedom, wherein the output actuator is in communication with each of a first and second side of the pump; and (4) a feedback measurement that represents a force or motion of the output actuator, said feedback measurement being constructed from at least one sensor; and a controller configured to control the prime mover and the displacement varying actuator for each of said at least two actuation modules, wherein said controller further controls motion of the prime mover and uses the feedback measurement to regulate the force or motion of the output actuator by controlling the displacement varying actuator. 2. The system of claim 1 wherein said controller controls a speed of the rotary motion to maximize power transferred from said variable displacement pump wherein controlling the force or motion of the output actuator results in power being transferred from said variable displacement pump. 3. The system of claim 1 wherein the controller controls an angular speed of the prime mover to be constant. 4. The system of claim 1 wherein the output actuator has a limited travel. 5. The system of claim 1 wherein the controller controls the prime mover in three modes: (1) producing power when an angular speed of the prime mover is below a low set point, (2) producing no power when the angular speed of the prime mover is above said low set point but below a high set point, and (3) absorbing power when the angular speed of the prime mover is above said high set point. 6. The system of claim 1 wherein the system is incorporated into a device, the controller controls a rotational speed of the prime mover and receives a signal from the device, and, based on the signal, the controller changes the rotational speed of the prime mover between at least two different values wherein lower values correspond to the device being in a rest state and higher values correspond to the device being in an active state. 7. The system of claim 1 wherein the controller controls the prime mover to a rotational speed, the controller includes a model of power loss in the actuation system, and said controller establishes the rotational speed to minimize power loss. 8. The system of claim 1 wherein the controller controls the prime mover to a rotational speed and said controller establishes the rotational speed to maximize a life of the pump. 9. The system of claim 1 wherein the controller controls the prime mover to a rotational speed and said controller establishes the rotational speed to minimize acoustic volume. 10. The system of claim 9 wherein the acoustic volume is minimized over a specific range of frequencies. 11. The system of claim 1 wherein the controller controls the prime mover to a rotational speed and the controller establishes the rotational speed to maximize performance in regulating the force or motion of the output actuator. 12. The system of claim 1 wherein the controller controls the prime mover to a rotational speed and the controller establishes the rotational speed to minimize an amount of power consumed in regulating the force or motion of the output actuator. 13. The system of claim 1 wherein the controller controls the prime mover to a rotational speed, the system is incorporated into a device, and said device signals said controller which of several modes of optimization the controller should use in order to choose the rotational speed of the prime mover, said modes including at least two of the following: minimizing power loss, maximizing efficiency, maximizing pump life, minimizing acoustic volume, maximizing actuation performance, and minimizing system temperatures. 14. The system of claim 13 wherein the device is configured to receive input from a human operator on which of said modes of optimization should be chosen. 15. The system of claim 1 wherein the displacement varying actuator is backdrivable. 16. The system of claim 1 wherein the variable displacement hydraulic pump includes a rotating core that holds pistons or vanes, a translating housing, and a stationary body, said rotating core being driven by said prime mover to rotate within said housing, said housing being translated by the displacement varying actuator, and said housing being constrained to translate with respect to the stationary body with a flexural connection. 17. The system of claim 1 wherein moving parts of said variable displacement pump are submersed in working hydraulic fluid. 18. The system of claim 1 wherein the variable displacement pump comprises two rotating cores that hold pistons or vanes, two translating housings, a housing connection, and a pump body, and wherein each said core is located coaxially along a common shaft and rotates within one of the two translating housings, and the housing connection couples said two translating housings so that the displacement varying actuator moves both translating housings in opposite directions. 19. A system for hydraulically actuating at least one degree of freedom, said system comprising: a single prime mover for at least two actuation modules, wherein the prime mover produces rotary motion and is constituted by a battery powered electric motor, and each actuation module includes: (1) an over-center variable displacement pump, said pump having: (a) a power input connection configured to power the pump from said prime mover; and (b) a displacement varying input for varying the displacement of the pump; and (2) a displacement varying actuator configured to modulate the displacement varying input of the pump; (3) an output actuator in direct communication with the pump, said output actuator being configured to drive an object through a corresponding degree of freedom; and (4) a feedback measurement that represents a force or motion of the output actuator, said feedback measurement being constructed from at least one sensor; and a controller configured to control the prime mover and the displacement varying actuator for each of said at least two actuation modules, wherein said controller further controls motion of the prime mover and uses the feedback measurement to regulate the force or motion of the output actuator by controlling the displacement varying actuator, wherein the controller controls the prime mover to a rotational speed, and the controller chooses said rotational speed by: (1) dividing the flow required by each said output actuator by a maximum displacement of a corresponding variable displacement pump of that output actuator, producing a required prime mover speed for that actuation module, (2) computing a maximum speed that is the maximum of an absolute value of each of the said required prime mover speeds, and (3) establishing said rotational speed to be slightly larger than said maximum