Method for controlling pressure in a hydraulic actuator

What is claimed is: 1. An electro-hydrostatic system comprising: a controller connected to an operator interface; a pump operable in a first direction for supplying pressurized fluid; an electric machine operated by the controller and connected to an electrical source through an inverter to drive the pump; and a hydraulic circuit having a first side fluidly connecting a first side of the pump to a first port for connection to a consumer, and a second side fluidly connecting the second side of the pump to a second port for connection to the consumer; wherein the controller is configured: to receive a user input for controlling the consumer and to supply hydraulic fluid in accordance therewith, to set the first side of the hydraulic circuit pressure limit to a reduced value pressure limit in response to the user input; to watch for a parameter, the parameter being indicative of pressure in the first side of the hydraulic circuit exceeding the reduced value pressure limit, and in response to the parameter indicative of the pressure exceeding the reduced value pressure limit, to restrict pressure in the first side of the hydraulic circuit until the pressure limit is increased, thereby delaying consumer motion unless a command to stop consumer motion is given and mimicking responsiveness in a conventional load-sense system, and to determine to increase the pressure limit based on receipt of the parameter indicative of the pressure exceeding the reduced value pressure limit. 2. The electro-hydrostatic system of claim 1 , further comprising valving fluidly connected between the pump and the ports, the valving controlled by the controller and operative to regulate the pressurized fluid between the pump and the consumer. 3. The electro-hydrostatic system of claim 1 , wherein the user command is a command for lowering an actuator. 4. The electro-hydrostatic system of claim 1 , wherein the consumer is a hydraulic cylinder and the first side of the hydraulic circuit is fluidly connected to a rod-side of the hydraulic cylinder. 5. The electro-hydrostatic system of claim 1 , wherein the controller is further configured to delay increasing the pressure limit after determining to increase the pressure limit based on receipt of the parameter indicative of the pressure exceeding the reduced value pressure limit. 6. The electro-hydrostatic system of claim 1 , wherein the parameter is pump speed. 7. The electro-hydrostatic system of claim 1 , wherein the parameter is a movement state of the consumer. 8. The electro-hydrostatic system of claim 1 , wherein the parameter is electric machine torque. 9. The electro-hydrostatic system of claim 1 , wherein the parameter is pressure in the first side of the hydraulic circuit. 10. The electro-hydrostatic system of claim 1 , wherein the controller is further configured to restrict pressure by setting a torque limit of the electric machine. 11. The electro-hydrostatic system of claim 1 , wherein the pump is a bi-directional pump operable in a first direction for supplying pressurized fluid through the first valve to the consumer for operating the consumer in one direction, and operable in a second direction opposite the first direction for supplying pressurized fluid through a second valve to the consumer for operating the consumer in a direction opposite the first direction. 12. The electro-hydrostatic system of claim 1 , further comprising: a hydraulic actuator to and from which hydraulic fluid is supplied and returned in opposite directions to operate the actuator in opposite directions. 13. The electro-hydrostatic system of claim 1 , further comprising: a boost system for accepting fluid from or supplying fluid to the hydraulic circuit of the hydraulic system, wherein the boost system includes: a boost pump for supplying fluid to a fluid make-up/return line that selectively is in fluid communication with the consumer, and a boost electric machine for driving the boost pump, the electric machine connected to a boost electric power source through a boost inverter. 14. The electro-hydrostatic system of claim 1 , wherein the valving includes a load-holding valve connected between the pump and the first port, the load-holding valve controlled by the controller and operative in a first position to allow flow to the consumer to operate the consumer against a load and operative in a second position to block load-induced return flow from the consumer to the pump. 15. A method of preventing over-actuation in an electro-hydrostatic system, the method comprising the steps of: receiving a requested consumer command; setting a maximum pressure limit of a first side of a hydraulic circuit fluidly connected to the consumer to a first value in response to the requested consumer command; controlling a pump and valving in the hydraulic circuit to achieve the requested consumer command; driving the pump via an electric machine connected to an electrical source through an inverter; monitoring a first system condition, the first system condition being indicative of pressure in the first side of the hydraulic circuit exceeding the first value; restricting pressure in the first side of the hydraulic circuit until the pressure limit is increased, evaluating the monitored system condition with a prescribed criteria in response to the requested consumer command; and determining whether or not to increase the maximum pressure limit based on the evaluation, thereby delaying consumer motion unless a command to stop consumer motion is given and mimicking responsiveness in a conventional load-sense system. 16. The method of claim 15 , wherein the consumer command is a command for lowering an actuator. 17. The method of claim 15 , wherein the consumer is a hydraulic cylinder and the first side of the hydraulic circuit is fluidly connected to a rod-side of the hydraulic cylinder. 18. The method of claim 15 , wherein the controller is further configured to delay increasing the maximum pressure limit after determining to increase the maximum pressure limit based on the evaluation. 19. The method of claim 15 , wherein the first system condition is pump speed. 20. The method of claim 15 , wherein the first system condition is a movement state of the consumer. 21. The method of claim 15 , further comprising controlling and driving the pump via an electric machine, wherein the first system condition is electric machine torque. 22. The method of claim 15 , wherein the first system condition is pressure in the first side of the hydraulic circuit. 23. The method of claim 15 , further comprising controlling and driving the pump via an electric machine, wherein setting the maximum pressure limit includes setting a torque limit of the electric machine. 24. The method of claim 15 , wherein the pump is a bi-directional pump operable in a first direction for supplying pressurized fluid through the first valve to the hydraulic actuator for operating the actuator in one direction, and operable in a second direction opposite the first direction for supplying pressurized fluid through a second valve to the hydraulic actuator for operating the actuator in a direction opposite the first direction. 25. The method of claim 15 , wherein the consumer is a hydraulic actuator to and from which hydraulic fluid is supplied and returned in opposite directions to operate the actuator in opposite directions. 26. T