Aerodynamically Efficient Lightweight Vertical Take-Off And Landing Aircraft With Pivoting Rotors And Stowing Rotor Blades

What is claimed is: 1 . An aerial vehicle adapted for vertical take-off and horizontal flight, said aerial vehicle comprising: a main vehicle body; a right side wing, said right said wing coupled to a right side of said main vehicle body, said right side wing comprising a forward swept wing, one or more right side rotor assemblies, said one or more right side rotor assemblies comprising a propeller and a motor, wherein one or more right side wing rotor assemblies are attached to said right side wing, and wherein said one or more right side wing rotor assemblies protrude forward of the leading edge of said right side wing along a middle section of the wing span, and wherein the centers of mass of each of the one or more right side rotor assemblies are forward of the leading edge of said right side wing when in a forward flight configuration; a right side wingtip rotor assembly, said right side wingtip rotor assembly comprising a propeller and a motor, wherein said right side wingtip rotor assembly is attached to the outboard tip of said right side wing; a left side wing, said left side wing coupled to a left side of said main vehicle body, said left side wing assembly comprising a forward swept wing; one or more left side rotor assemblies, said one or more left side rotor assemblies comprising a propeller and a motor, wherein one or more left side wing rotor assemblies are attached to said left side wing, and wherein said one or more left side wing rotor assemblies protrude forward of the leading edge of said left side wing along a middle section of the wing span, and wherein the centers of mass of each of the one or more left side rotor assemblies are forward of the leading edge of said left side wing when in a forward flight configuration; a left side wingtip rotor assembly, said left side wingtip rotor assembly comprising a propeller and a motor, wherein said left side wingtip rotor assembly is attached to the outboard tip of said left side wing. 2 . The aerial vehicle of claim 1 wherein said one or more right side wing rotor assemblies are attached to said right wing by a deployment mechanism adapted to deploy said one or more right side wing rotor assemblies from a forward facing horizontal flight configuration to a vertical take-off configuration, and wherein said one or more left side wing rotor assemblies are attached to said left wing by a deployment mechanism adapted to deploy said one or more left wing rotor assemblies from a forward facing horizontal flight configuration to a vertical take-off configuration. 3 . The aerial vehicle of claim 1 wherein said motor of each one or more right side wing rotor assemblies is an electric motor, and wherein motor of said right side wingtip rotor assembly is an electric motor, and wherein said motor of each one or more left side wing rotor assemblies is an electric motor, and wherein motor of said left side wingtip rotor assembly is an electric motor. 4 . The aerial vehicle of claim 2 wherein said right side wingtip rotor assembly is attached to said right wingtip by a deployment mechanism adapted to deploy said right side wingtip rotor assembly from a forward facing horizontal flight configuration to a vertical take-off configuration, and wherein said left side wingtip rotor assembly is attached to said left wingtip by a deployment mechanism adapted to deploy said left side wingtip rotor assembly from a forward facing horizontal flight configuration to a vertical take-off configuration. 5 . The aerial vehicle of claim 3 wherein said right side wingtip rotor assembly is attached to said right wingtip by a deployment mechanism adapted to deploy said right side wingtip rotor assembly from a forward facing horizontal flight configuration to a vertical take-off configuration, and wherein said left side wingtip rotor assembly is attached to said left wingtip by a deployment mechanism adapted to deploy said left side wingtip rotor assembly from a forward facing horizontal flight configuration to a vertical take-off configuration. 6 . The aerial vehicle of claim 1 further comprising: one or more right rear rotor assemblies, each of said one or more right rear rotor assemblies attached to the rear of said vehicle body by a deployment mechanism adapted to deploy each of said one or more right rear rotor assemblies from a forward facing horizontal flight configuration along the right side of said vehicle body to a vertical take-off configuration, each of said one or more right rear rotor assemblies comprising an electric motor; and one of more left rear rotor assemblies, each of said one or more left rear rotor assemblies attached to the rear of said vehicle body by a deployment mechanism adapted to deploy each of said one or more left rear rotor assemblies from a forward facing horizontal flight configuration along the left side of said vehicle body to a vertical take-off configuration, each of said one or more left rear rotor assemblies comprising an electric motor. 7 . The aerial vehicle of claim 2 further comprising: one or more right rear rotor assemblies, each of said one or more right rear rotor assemblies attached to the rear of said aerial vehicle by a deployment mechanism adapted to deploy each of said one or more right rear rotor assemblies from a forward facing horizontal flight configuration along the right side of said aerial vehicle body to a vertical take-off configuration, each of said one or more right rear rotor assemblies comprising an electric motor; and one of more left rear rotor assemblies, each of said one or more left rear rotor assemblies attached to the rear of said aerial vehicle by a deployment mechanism adapted to deploy each of said one or more left rear rotor assemblies from a forward facing horizontal flight configuration along the left side of said aerial vehicle body to a vertical take-off configuration, each of said one or more left rear rotor assemblies comprising an electric motor. 8 . The aerial vehicle of claim 5 further comprising: one or more right rear rotor assemblies, each of said one or more right rear rotor assemblies attached to the rear of said aerial vehicle by a deployment mechanism adapted to deploy each of said one or more right rear rotor assemblies from a forward facing horizontal flight configuration along the right side of said aerial vehicle body to a vertical take-off configuration, each of said one or more right rear rotor assemblies comprising an electric motor; and one of more left rear rotor assemblies, each of said one or more left rear rotor assemblies attached to the rear of said aerial vehicle by a deployment mechanism adapted to deploy each of said one or more left rear rotor assemblies from a forward facing horizontal flight configuration along the left side of said vehicle body to a vertical take-off configuration, each of said one or more left rear rotor assemblies comprising an electric motor. 9 . The aerial vehicle of claim 4 wherein said right side wingtip rotor assembly is attached to said right side wingtip with a deployment mechanism which pivots said right side wingtip rotor assembly from a forward facing horizontal flight configuration to a vertical take-off configuration, and wherein said left side wingtip rotor assembly is attached to said left side wingtip with a deployment mechanism which pivots said left side wingtip rotor assembly from a forward facing horizontal flight configuration to a vertical take-off configuration. 10 . The aerial vehicle of claim 7 wherein said right side wingtip rotor assembly is attached to said right side wingtip with a deployment mechanism which pivots said right side wingtip rotor assembly from a forward facing horizontal flight configurati