Distributed electric and hybrid fans for distortion tolerance of turbofan engines

What is claimed is: 1. A gas turbine engine comprising a primary fan mounted for rotation about an axis of the gas turbine engine to provide thrust, the primary fan including a fan rotor, a plurality of fan blades that extend radially outward from the fan rotor, and an outer case that extend circumferentially around the axis of the gas turbine engine radially outward of the plurality of fan blades to define a portion of a flow path of the gas turbine engine, an engine core coupled to the primary fan and configured to drive the primary fan about the axis to cause the primary fan to push air to provide thrust for the gas turbine engine, the engine core including a compressor configured to rotate about the axis of the gas turbine engine to compress the air that flows from the primary fan, a combustor configured to receive the compressed air from the compressor, and a turbine coupled to the compressor and the primary fan and configured to rotate about the axis of the gas turbine engine in response to receiving hot, high-pressure products of the combustor to drive rotation of the compressor and the primary fan, and an auxiliary fan system including an auxiliary fan array located radially inward of the outer case and located axially forward or aft of the primary fan and a control unit coupled to the auxiliary fan array, the auxiliary fan array having a plurality of electric fans spaced apart around the axis of the gas turbine engine that are each configured to rotate about a fan axis, and the control unit configured to vary individually a rotation speed of each electric fan included in the auxiliary fan array in response to a pressure differential in the flow path of the gas turbine engine upstream of the engine core to minimize pressure and swirl distortions in the gas turbine engine. 2. The gas turbine engine of claim 1 , wherein the control unit includes a plurality of sensors arranged to measure pressure within the flow path of the gas turbine engine upstream of the engine core and a controller coupled to the plurality of sensors to receive pressure measurements from the plurality of sensors, the controller configured to increase the rotation speed of at least one electric fan included in the auxiliary fan array in response to the pressure measurement being above a predetermined threshold. 3. The gas turbine engine of claim 2 , wherein the controller is configured to decrease the rotation speed of at least one electric fan included in the auxiliary fan array in response to the pressure measurement being below the predetermined threshold. 4. The gas turbine engine of claim 3 , wherein the control unit further includes a memory coupled to the controller, the memory including a plurality of preprogrammed aircraft maneuvers that each correspond to a predetermined speed profile for the auxiliary fan array, and the controller is configured to detect a preprogrammed aircraft maneuver included in the plurality of preprogrammed aircraft maneuvers on the memory and direct the auxiliary fan array to change to the corresponding predetermined speed profile in response to detecting the preprogrammed aircraft maneuver. 5. The gas turbine engine of claim 3 , wherein the plurality of electric fans are each configured to pivot relative to the outer case of the primary fan and the controller is configured to direct at least one electric fan included in the plurality of electric fans to pivot in response to the pressure measurements from the plurality of sensors. 6. The gas turbine engine of claim 1 , wherein the control unit includes a controller and a memory coupled to the controller, the memory including a plurality of preprogrammed aircraft maneuvers that each correspond to a predetermined speed profile for the auxiliary fan array, and the controller configured to detect a preprogrammed aircraft maneuver included in the plurality of preprogrammed aircraft maneuvers on the memory and direct the auxiliary fan array to change to the corresponding predetermined speed profile in response to detecting the preprogrammed aircraft maneuver. 7. The gas turbine engine of claim 6 , wherein the plurality of electric fans are each configured to pivot relative to the outer case of the primary fan and the controller is configured to direct at least one electric fan included in the plurality of electric fans to pivot in response to detecting the preprogrammed aircraft maneuver. 8. The gas turbine engine of claim 1 , further comprising a plurality of struts that each extend between the outer case of the primary fan and the engine core and are spaced apart circumferentially around the axis, and wherein the auxiliary fan array is located axially aft of the primary fan and two or more electric fans included in the auxiliary fan array are arranged circumferentially between adjacent struts. 9. The gas turbine engine of claim 8 , wherein the auxiliary fan array is located axially aft of the plurality of struts. 10. The gas turbine engine of claim 8 , wherein the plurality of electric fans included in the auxiliary fan array are arranged around the engine core so that each electric fan included in the plurality of electric fans is located radially between the outer case and the engine core. 11. A gas turbine engine comprising a primary fan mounted for rotation about an axis of the gas turbine engine to provide thrust, an engine core coupled to the primary fan and configured to drive the primary fan about the axis, and an auxiliary fan system including an auxiliary fan array located axially forward or aft of the primary fan and a control unit coupled to the auxiliary fan array, the auxiliary fan array having a plurality of electric fans spaced apart around the axis of the gas turbine engine that are each configured to rotate about a fan axis, and the control unit configured to vary individually a rotation speed of each electric fan included in the auxiliary fan array in response to a pressure differential in a flow path of the gas turbine engine upstream of the engine core. 12. The gas turbine engine of claim 11 , wherein the control unit includes a plurality of sensors arranged to measure pressure within the flow path of the gas turbine engine upstream of the engine core and a controller coupled to the plurality of sensors to receive pressure measurements from the plurality of sensors, the controller configured to increase the rotation speed of at least one electric fan included in the auxiliary fan array in response to the pressure measurement being above a predetermined threshold and to decrease the rotation speed of at least one electric fan included in the auxiliary fan array in response to the pressure measurement being below the predetermined threshold. 13. The gas turbine engine of claim 12 , wherein the plurality of electric fans are each configured to pivot relative to the primary fan and the controller is configured to direct at least one electric fan included in the plurality of electric fans to pivot in response to the pressure measurements from the plurality of sensors. 14. The gas turbine engine of claim 11 , wherein the control unit includes a controller and a memory coupled to the controller, the memory including a plurality of preprogrammed aircraft maneuvers that each correspond to a predetermined speed profile for the auxiliary fan array, and the controller configured to detect a preprogrammed aircraft maneuver included in the plurality of preprogrammed aircraft maneuvers on the memory and direct the auxiliary fan array to change to the corresponding predetermined speed profile in response to detecting the preprogrammed aircraft maneuver. 15. The gas turbine