Electromechanical linear actuator

1 . A linear actuator comprising: an actuator housing; a plurality of motors providing linear movement along a motor drive axis wherein the motor drive axes are parallel, and wherein the motors are within the housing, each motor comprises: a stator for applying an electromagnetic force; and a rod movable within the stator, wherein the electromagnetic force from the stator drives the rod to extend from and retract into the stator along the motor drive axis of that motor. 2 . The linear actuator of claim 1 and further comprising a plurality of displacement sensors, wherein each displacement sensor is associated with a different one of the rods, and wherein each displacement sensor produces a displacement signal that is a function of a position of its associated rod relative to the actuator housing. 3 . The linear actuator of claim 2 , wherein the displacement sensors are variable differential transformers. 4 . The linear actuator of claim 2 and further comprising a plurality of controllers, each controller associated with a different one of the motors, a different one of the rods, and a different one of the displacement sensors, wherein each controller provides a drive signal to its associated motor as a function of the displacement signal from its associated displacement sensor and a command signal. 5 . The linear actuator of claim 4 , wherein the controllers are connected to communicate between each other to synchronize movement of their associated rods. 6 . The linear actuator of claim 1 and further comprising a plurality of force sensors, wherein each force sensor is associated with a different one of the stators, and wherein each force sensor produces a force signal that is a function of the electromagnetic force applied by its associated stator. 7 . The linear actuator of claim 6 , wherein the force sensors are bi-directional load cells. 8 . The linear actuator of claim 7 , wherein each of the bi-directional load cells are disposed between an end of the actuator housing and its associated stator. 9 . The linear actuator of claim 6 and further comprising a plurality of controllers, each controller associated with a different one of the motors, a different one of the rods, and a different one of the force sensors, wherein each controller provides a drive signal to its associated motor as a function of the force signal from its associated force sensor and a command signal. 10 . The linear actuator of claim 9 , wherein the plurality of controllers are connected to communicate between each other to synchronize movement of their associated rods. 11 . The linear actuator of claim 6 and further comprising a plurality of displacement sensors, wherein each displacement sensor is associated with a different one of the rods, and wherein each displacement sensor produces a displacement signal that is a function of a position of its associated rod relative to the actuator housing. 12 . The linear actuator of claim 11 and further comprising a plurality of controllers, each controller associated with a different one of the motors, a different one of the rods, a different one of the stator, a different one of the force sensors, and a different one of the displacement sensors, wherein each controller provides a drive signal to its associated motor as a function of its force signal from its associated force sensor, its displacement signal from its associated displacement sensor, and a command signal. 13 . The linear actuator of claim 12 , wherein the plurality of controllers are connected to communicate between each other to synchronize movement of their associated rods. 14 . A method for driving a linear actuator having a plurality of motors arranged within a common housing so that motor drive axes of the motors are parallel, the method comprising: receiving a command signal for each motor; using a plurality of controllers, each controller associated with a different one of the motors, to produce a drive signal to be sent to the associated motor of each controller based on the command signal for that motor; sending the drive signal to a stator of each motor from its associated controller; and driving a rod of each motor along one of the motor drive axis of that motor based on electromagnetic force produced by the stator in response to the drive signal. 15 . The method of claim 14 , further comprising: receiving a displacement signal that is a function of position of each rod relative to the linear actuator; receiving a load signal that is a function of the electromagnetic force applied to each rod by its stator; and producing the drive signal based on the command signal, the displacement signal, and the load signal.