Aerial vehicle with differential control mechanisms

The invention claimed is: 1. An aerial vehicle comprising: a fuselage having: a nose end, and a tail end; a first wing member extending from the fuselage in a first direction, the first wing member comprising: a first drive motor coupled to a first rotor, a second drive motor coupled to a second rotor, and a third drive motor coupled to a third rotor, wherein, in a second direction perpendicular to the first direction, the first wing member and the third drive motor are positioned between the first drive motor and the second drive motor; a second wing member extending from the fuselage substantially opposite the first wing member; a first wing rotation motor coupled to rotate the first wing member about a first axis substantially perpendicular to a fuselage axis extending from the nose end to the tail end; a second wing rotation motor coupled to rotate the second wing member about a second axis substantially perpendicular to the fuselage axis; and a controller circuit configured to; differentially actuate the first motor and the second motor; detect a rotation failure of the second wing member based on one or more sensors that generate a signal based on a position of the second wing member; and responsive to the detecting of the failure, determine a combination of rotor speeds for the first, second, and third rotors and rotation positions for the first wing member that brings about a desired thrust vector and/or moment of torque for the aerial vehicle. 2. The aerial vehicle of claim 1 , wherein the controller circuit is further configured to rotate the first wing member and the second wing member to generate a thrust vector towards the nose end of the fuselage while the fuselage axis is substantially parallel to a horizon. 3. The aerial vehicle of claim 1 , wherein the controller circuit is further configured to: operate the aerial vehicle in a first control mode when the aerial vehicle is above a threshold altitude; and operate the aerial vehicle in a second control mode when the aerial vehicle is below the threshold altitude, wherein the first wing rotation motor and the second wing rotation motor are maintained at a substantially constant revolution rate in the second control mode. 4. The aerial vehicle of claim 1 , wherein the second wing member extends from the fuselage in a third direction, and wherein the second wing member comprises: a fourth drive motor coupled to a fourth rotor; a fifth drive motor coupled to a fifth rotor; and a sixth drive motor coupled to a sixth rotor; wherein, in a fourth direction perpendicular to the third direction, the second wing member and the sixth drive motor are positioned between the third drive motor and the fourth drive motor. 5. The aerial vehicle of claim 4 , wherein the controller circuit is further configured to: energize the first drive motor and the fourth drive motor to maintain the first rotor and the fourth rotor at a constant revolution rate; and energize the first wing rotation motor or the second wing rotation motor to generate a thrust vector that changes an attitude of the aerial vehicle. 6. The aerial vehicle of claim 1 wherein the controller circuit is further configured to: determine the position of the second wing member based on a current position of the second wing rotation motor. 7. The aerial vehicle of claim 1 , wherein the controller circuit is further configured to energize the first wing rotation motor or the second wing rotation motor to generate a vertical thrust vector with the fuselage axis not parallel to a horizon. 8. The aerial vehicle of claim 1 , further comprising a stationary tail coupled to the fuselage. 9. An aerial vehicle comprising: a fuselage having: a nose end, and a tail end; a first wing member extending from the fuselage in a first direction, the first wing member comprising: a first drive motor coupled to a first rotor, a second drive motor coupled to a second rotor, and a third drive motor coupled to a third rotor, wherein, in a second direction perpendicular to the first direction, the first wing member and the third drive motor are positioned between the first drive motor and the second drive motor; a second wing member extending from the fuselage substantially opposite the first wing member; a first wing rotation motor coupled to rotate the first wing member about a first axis substantially perpendicular to a fuselage axis extending from the nose end to the tail end; a second wing rotation motor coupled to rotate the second wing member about a second axis substantially perpendicular to the fuselage axis; and a controller circuit configured to differentially actuate the first wing rotation motor and the second wing rotation motor, wherein the first wing member is coupled to the first wing rotation motor by bevel gears configured with a gear ratio such that expected aerodynamic forces on the first wing member do not cause the first wing member to rotate absent input from the first wing rotation motor.