Autonomous aerial vehicle hardware configuration

What is claimed is: 1. An aerial vehicle comprising: a body that extends along a longitudinal axis from a forward end to an aft end, the body having a port side and a starboard side on opposite sides of the longitudinal axis; a first rotor assembly extending from the port side of the body proximate to the forward end, the first rotor assembly including: a first image capture device on a top side of the first rotor assembly; and a first rotor on a bottom side of the first rotor assembly; a second rotor assembly extending from the starboard side of the body proximate to the forward end, the second rotor assembly including: a second image capture device on a top side of the second rotor assembly; and a second rotor on a bottom side of the second rotor assembly; a third rotor assembly extending from the port side of the body proximate to the aft end, the third rotor assembly including: a third image capture device on a bottom side of the third rotor assembly; and a third rotor on a top side of the third rotor assembly; a fourth rotor assembly extending from the starboard side of the body proximate to the aft end, the fourth rotor assembly including: a fourth image capture device on a bottom side of the fourth rotor assembly; and a fourth rotor on a top side of the fourth rotor assembly; a fifth image capture device on a top side of the body proximate to the aft end; and a sixth image capture device on a bottom side of the body proximate to the forward end. 2. The aerial vehicle of claim 1 , wherein the first image capture device, second image capture device, and fifth image capture device collectively comprise a plurality of upward-facing image capture devices, the plurality of upward-facing image capture devices arranged relative to the body so as to enable trinocular stereoscopic image capture in a first plurality of directions substantially above the aerial vehicle; and wherein the third image capture device, fourth image capture device, and sixth image capture device collectively comprise a plurality of downward-facing image capture devices, the plurality of downward-facing image capture devices arranged relative to the body so as to enable trinocular stereoscopic image capture in a second plurality of directions substantially below the aerial vehicle. 3. The aerial vehicle of claim 2 , wherein at least one of the plurality of upward-facing image capture devices and at least one of the plurality of downward-facing image capture devices have overlapping fields of view. 4. The aerial vehicle of claim 1 , further comprising: a computer system configured to: process images captured by any one or more of the first image capture device, second image capture device, third image capture device, fourth image capture device, fifth image capture device, or sixth image capture device; generate a planned trajectory for the aerial vehicle through a physical environment based on the processing of the images; and control any one or more of the first rotor, second rotor, third rotor, or fourth rotor to autonomously maneuver the aerial vehicle along the planned trajectory. 5. The aerial vehicle of claim 1 , further comprising: a seventh image capture device coupled, via a mechanical gimbal, to the body of the aerial vehicle proximate to the forward end, the mechanical gimbal configured to adjust an orientation of the seventh image capture device about at least one axis of rotation relative to the body of the aerial vehicle. 6. The aerial vehicle of claim 1 , wherein at least one of the first image capture device, second image capture device, third image capture device, fourth image capture device, fifth image capture device, or sixth image capture device has a field of view of at least 180 degrees. 7. The aerial vehicle of claim 1 , wherein at least one of the first rotor assembly, second rotor assembly, third rotor assembly, or fourth rotor assembly includes: a support arm that extends from a wall of the body to a rotor housing. 8. The aerial vehicle of claim 7 , wherein at least a portion of the support arm, the wall of the body, and the rotor housing are formed as a unitary part in the construction of the aerial vehicle. 9. The aerial vehicle of claim 1 , wherein the aerial vehicle is an unmanned aerial vehicle (UAV). 10. An aerial vehicle comprising: a central body extending from a forward end to an aft end and having a port side opposite a starboard side; and a plurality of rotor assemblies coupled to the central body, the plurality of rotor assemblies including: a first rotor assembly extending from the port side of the central body proximate to the forward end, the first rotor assembly including a first image capture device arranged on a top surface and a first powered rotor arranged on a bottom surface; and a second rotor assembly extending from the port side of the central body proximate to the aft end, the second rotor assembly including a second image capture device arranged on a bottom surface and a second powered rotor arranged on a top surface; a third rotor assembly extending from the starboard side of the central body proximate to the forward end, the third rotor assembly including a third image capture device arranged on a top surface and a third rotor arranged on a bottom surface; a fourth rotor assembly extending from the starboard side of the central body proximate to the aft end, the fourth rotor assembly including a fourth image capture device arranged on a bottom surface and a fourth powered rotor arranged on a top surface; a fifth image capture device arranged on a top side of the central body proximate to the aft end; and a sixth image capture device on a bottom side of the central body proximate to the forward end. 11. The aerial vehicle of claim 10 , wherein the first image capture device, third image capture device, and fifth image capture device collectively comprise a plurality of upward-facing image capture devices, the plurality of upward-facing image capture devices arranged relative to the central body so as to enable trinocular stereoscopic image capture in a first plurality of directions substantially above the aerial vehicle; and wherein the second image capture device, fourth image capture device, and sixth image capture device collectively comprise a plurality of downward-facing image capture devices, the plurality of downward-facing image capture devices arranged relative to the central body so as to enable trinocular stereoscopic image capture in a second plurality of directions substantially below the aerial vehicle. 12. The aerial vehicle of claim 10 , further comprising: a seventh image capture device coupled, via a mechanical gimbal, to the central body of the aerial vehicle proximate to the forward end, the mechanical gimbal configured to adjust an orientation of the seventh image capture device about at least one axis of rotation relative to the central body of the aerial vehicle. 13. The aerial vehicle of claim 10 , wherein the first image capture device and second image capture device have overlapping fields of view. 14. The aerial vehicle of claim 10 , wherein at least one of the first image capture device and the second image capture device have a field of view of at least 180 degrees. 15. The aerial vehicle of claim 10 , further comprising: a computer system configured to: process images captured by the first and second image capture device; generate a planned trajectory for the aerial vehicle through a physical environment based on the processing of the images; and control any one or more of the first powered rotor or second