Actuator with brushless DC motor

The invention claimed is: 1. An aircraft fuel system comprising: a plurality of fuel tanks fluidly connected to a crossfeed manifold; a valve configured to regulate fuel transfer between the fuel tanks through the crossfeed manifold; an actuator for the valve, the actuator comprising: a brushless DC motor, a rotary output device including a disc drive gear configured to turn the valve between open and closed positions, a reduction system driven by the brushless DC motor and engaging the disc drive gear to turn the disc drive gear and thereby turn the valve; a housing enclosing the reduction system, wherein the housing includes a front plate and a back plate and a sidewall between the front plate and the back plate; a shaft coupling the disc drive gear to the valve extends through the front plate of the housing; a contactless position sensor configured to sense a rotational position of the rotary output device, an indicator on the disc drive gear which is visible through a window in the back plate of the housing when viewed from outside of the actuator, wherein the indicator indicates a rotational position of the drive shaft; an electronic controller coupled to the contactless position sensor and to the brushless DC motor, wherein the electronic controller is configured to produce an electric drive signal for commutating windings of the brushless DC motor based upon a sensor signal from the contactless position sensor; an electrical connector for receiving a valve position command signal, wherein the electrical connector includes two command discrete pins, and energising one of the two command discrete pins drives the valve to an open position, and energising the other of the two command discrete pins drives the valve to a closed position, wherein the electronic controller is arranged to continuously provide a discrete electrical signal to the two command discrete pins to indicate the state of the valve irrespective of whether the actuator is powered; wherein the brushless DC motor is a first brushless DC motor and is mounted to the sidewall of the housing, and the actuator further comprises a second brushless DC motor mounted to the sidewall opposite to the first brushless DC brushless motor, wherein both the first and second brushless DC motors are configured to drive the reduction system; and wherein the electrical connector is a first electrical connector and is mounted to the sidewall of the housing and parallel to the first brushless DC motor, and the actuator further comprises a second electrical connector mounted to the sidewall opposite to the first electrical connector and parallel to the second brushless DC motor. 2. The aircraft fuel system according to claim 1 , wherein the reduction system includes a worm gear driven by the brushless DC motor, wherein the worm gear engages the disc drive gear. 3. The aircraft fuel system according to claim 1 , wherein the brushless DC motor is external to the housing. 4. The aircraft fuel system according to claim 1 , wherein the contactless position sensor includes a Hall effect sensor, and the Hall effect sensor is arranged to directly measure a rotational position of the rotary output device. 5. The aircraft fuel system according to claim 1 , wherein the electronic controller includes one or more of: a microcontroller, an FPGA, or an ASIC. 6. The aircraft fuel system according to claim 1 , wherein the electronic controller includes an FPGA having multiple redundant modules within the same FPGA, wherein the redundant modules each include control and voting components. 7. The aircraft fuel system according to claim 1 , wherein the electronic controller includes a PID controller implemented in hardware for controlling motor torque and motor speed. 8. The aircraft fuel system according to claim 1 , wherein the electronic controller includes an FPGA, wherein the FPGA is partitioned into at least two sections, wherein one of the at least two sections is configured to operate at Design Assurance Level different than a Design Assurance Level at which operates another of the at least two sections. 9. The aircraft fuel system according to claim 1 , further comprising a non-transitory storage device configured to store one or more parameters of the actuator, wherein the storage device is coupled to or forms part of the electronic controller. 10. The aircraft fuel system according to claim 9 , wherein the storage device forms part of the electronic controller and data gathering and storage functions of the electronic controller are partitioned within the electronic controller from actuator control hardware. 11. The aircraft fuel system according to claim 9 , wherein the actuator parameters include one or more of: current, voltage, motor speed or data relating to a signal from the contactless position sensor. 12. The aircraft fuel system according to claim 9 , wherein the storage device includes non-volatile memory. 13. The aircraft fuel system according to claim 9 , wherein the electronic controller is configured to sample and store one or more parameters of the actuator at a variable rate in dependence upon one or more events. 14. The aircraft fuel system according to claim 13 , wherein the electronic controller is configured to sample and store one or more parameters of the actuator at a high sample rate in event of a short lived electrical transient during active operation of the motor, and at a low sample rate in the event of standby operation of the motor. 15. The aircraft fuel system according to claim 9 , wherein the storage device is coupled to an interface for retrieving data from the storage device. 16. A valve assembly in combination with an aircraft fuel system; the aircraft fuel system comprising a cross-feed manifold between fuel tanks in an aircraft; the valve comprising: a valve connected to the cross-feed manifold, wherein the valve is configured to be turned to open and close fuel flow through the cross-feed manifold, and an actuator configured to turn the valve, wherein the actuator includes: a housing including a front plate, a back pate opposite to the front plate and a sidewall between the front plate and the back plate; a brushless DC motor mounted to the side wall of the housing; a rotary output device including a disc gear within the housing, wherein the disc gear is coupled to drive a shaft extending through the front plate of the housing, and the shaft is coupled to the valve such that as the disc gear turns the shaft and valve turn, and the disc gear includes a side facing a window in the back of the housing; a reduction system within the housing and driven by the brushless DC motor, wherein the reduction system engages an outer rim of the disc gear to turn the disc gear, wherein the reduction system turns the disc gear which turns the shaft and valve to regulate fuel flow, a contactless position sensor within the housing and configured to sense a position of the disc gear or shaft, an indicator on the side of the disc gear facing the window in the back plate of the housing, wherein the indicator is visible through the window from outside of the housing, and the indicator indicates a rotational position of the disc gear, the shaft and the valve; an electronic controller coupled to the contactless position sensor and to the brushless DC motor, and an electrical connector for receiving a valve position command signal, and wherein the electronic controller is configured to: produce an electric drive signal to be applied to commutating windings of the brushless DC motor; determine an actual valve position bas