Systems and methods to launch aircraft

What is claimed is: 1. An apparatus comprising: a body comprising a stow compartment, the stow compartment configured to store an aircraft; a launch arm configured to couple to the aircraft, the launch arm comprising: a shaft including a first end and a second end; a rotatable joint coupling the first end of the shaft to a floor of the stow compartment, the rotatable joint configured to rotate the shaft relative to the floor between a stowed position and a launch position, wherein the stowed position corresponds to the aircraft being in the stow compartment, wherein the shaft is substantially parallel with the floor of the stow compartment while in the stowed position, and wherein the shaft is non-parallel with the floor while in the launch position; a load cell configured to: autonomously generate load data indicative of a load exerted on the launch arm by the aircraft; and autonomously transmit the load data to a processor device; and a head configured to couple the second end of the shaft to the aircraft, the head configured to gimbal, while the launch arm is in the launch position, with respect to the launch arm to allow the aircraft to rotate on the launch arm, to pitch on the launch arm, and to yaw on the launch arm; and a release mechanism configured to release the aircraft from the head based on an autonomous determination, by the processor device, whether the load indicated by the load data satisfies a load threshold, wherein the processor device is configured to: in response to the autonomous determination that the load fails to satisfy the load threshold, autonomously transmit a signal to a thrust generator to cause the thrust generator to adjust a thrust vector of the aircraft, wherein the thrust generator is configured to increase a thrust output in response to the signal; and in response to the autonomous determination that the load satisfies the load threshold, autonomously cause a release of the aircraft from the head of the launch arm. 2. The apparatus of claim 1 , wherein the launch arm is configured to position a roll axis of the aircraft substantially parallel with the floor of the stow compartment while the shaft is in the stowed position, and wherein the launch arm is configured to position the roll axis of the aircraft to be non-parallel with the shaft while the shaft is in the launch position. 3. The apparatus of claim 2 , wherein the launch arm is configured to position the roll axis of the aircraft to be non-parallel with the floor while the shaft is in the launch position. 4. The apparatus of claim 1 , wherein the head is configured to position a roll axis of the aircraft to be parallel with a wind direction while the shaft is in the launch position. 5. The apparatus of claim 1 , wherein the stow compartment comprises a plurality of walls, each wall of the plurality of walls having a height larger than a height of the aircraft. 6. The apparatus of claim 5 , wherein a first wall of the plurality of walls is configured to be parallel with a roll axis of the aircraft while the shaft is in the stow position, and wherein the first wall has a first length greater than a second length of a portion of the aircraft corresponding to the roll axis. 7. The apparatus of claim 6 , wherein a second wall of the plurality of walls is configured to be perpendicular with the roll axis while the shaft is in the stow position, and wherein the second wall has a third length greater than a fourth length of a second side of the aircraft, the second side non-parallel with the first side. 8. The apparatus of claim 1 , wherein the body comprises a mobile vehicle. 9. The apparatus of claim 8 , wherein the mobile vehicle is configured to be pulled by a second mobile vehicle distinct from the mobile vehicle. 10. A system comprising: a mobile vehicle comprising: a first body comprising a stow compartment; a launch arm comprising: a shaft including a first end and a second end; a rotatable joint coupling the first end of the shaft to a floor of the stow compartment, the rotatable joint configured to rotate the shaft relative to the floor between a stowed position and a launch position, wherein the shaft is substantially parallel with the floor of the stow compartment while in the stowed position, and wherein the shaft is non-parallel with the floor while in the launch position; a load cell configured to: autonomously generate load data indicative of a load exerted on the launch arm; and autonomously transmit the load data to a processor device; and a head coupled to the second end of the shaft; and an aircraft coupled to the launch arm via the head, wherein the stowed position corresponds to the aircraft being in the stow compartment, the aircraft comprising: a second body configured to couple to the launch arm; a thrust generator configured to generate a force on the second body; and the processor device communicatively coupled to the load cell, the processor device configured to: determine, autonomously, whether the load indicated by the load data satisfies a load threshold; and transmit, autonomously, a signal: in response to a determination that the load indicated by the load data fails to satisfy the load threshold, to the thrust generator to cause the thrust generator to adjust a thrust vector of the second body; and in response to a determination that the load indicated by the load data satisfies the load threshold, to a release mechanism to release the second body from the head, wherein the head is configured to couple an end of the launch arm to the aircraft, and wherein the head is configured to, while the launch arm is in a launch position, gimbal with respect to the launch arm to allow the aircraft to rotate on the launch arm, to pitch on the launch arm, and to yaw on the launch arm. 11. The system of claim 10 , wherein the processor device is configured to communicate with a remote flight control system, wherein the remote flight control system is remote from the aircraft, and wherein the processor device is further configured to generate the signal in response to an input received from the remote flight control system, the input received in response to the load indicated by the load data not satisfying the load threshold. 12. The system of claim 10 , wherein the aircraft is coupled to the launch arm via a connector on a side of the aircraft facing the floor while the aircraft is couple to the launch arm. 13. The system of claim 10 , wherein, in response to the signal, the thrust generator is configured to increase a thrust output or adjust the thrust vector to compensate for at least one of gravity, wind force upon the aircraft, or environmental factors. 14. A method comprising: initiating rotation of an aircraft by rotating a single shaft of a launch arm relative to a mobile vehicle, the single shaft including a first end connected to a surface of the mobile vehicle by a rotatable joint and a second end connected to a head, the head coupled to the aircraft and configured to gimbal, while the launch arm is in a launch position, with respect to the launch arm to allow the aircraft to rotate and to pitch or yaw on the launch arm, wherein rotating the single shaft moves the aircraft from a stowed position to a launch position, wherein the stowed position corresponds to the aircraft being in a stow compartment of the mobile vehicle, wherein the single shaft is substantially parallel with a floor of the stow compartment while in the stowed position, and wherein the single shaft is non-parallel with the floor while in the launch position; determining load data indicative of a load exerted on the l