Propeller blade leading edge serrations for improved sound control

What is claimed is: 1. An aerial vehicle comprising: a first motor configured to rotate a propeller such that the propeller generates a lifting force; the propeller including: a hub that is coupled to the motor so that the motor can rotate the propeller; a propeller blade extending from the hub, the propeller blade including: a leading edge; a tip; a trailing edge; and a plurality of serrations protruding from the propeller blade along at least a portion of the leading edge of the propeller blade; a controller coupled to at least some of the plurality of serrations and configured to move the at least some of the plurality serrations while the propeller blade is rotating, the controller including an adjustment arm that extends along the propeller blade, contacts the at least some of the plurality of serrations, and moves between a first adjustment arm position and a second adjustment arm position; and a sensor configured to monitor a sound generated around the aerial vehicle; and wherein the controller moves the adjustment arm between the first adjustment arm position and the second adjustment arm position based at least in part on the sound. 2. The aerial vehicle of claim 1 , wherein: when the adjustment arm is in the first adjustment arm position, the at least some of the plurality of serrations are in a first serration position, and when the adjustment arm is in the second adjustment arm position, the at least some of the plurality of serrations are in a second serration position that is different than the first serration position. 3. The aerial vehicle of claim 2 , wherein: the at least some of the plurality of serrations cause the propeller blade to: generate a first sound when the at least some of the plurality of serrations are in the first serration position and the propeller blade is rotating at a first speed; and generate a second sound when the at least some of the plurality of serrations are in the second serration position and the propeller blade is rotating at the first speed; and the controller moves the adjustment arm from the first adjustment arm position to the second adjustment arm position when the second sound is less than the first sound. 4. The aerial vehicle of claim 1 , wherein: at least one of a first length or a first curvature of a first serration of the plurality of serrations is different than at least one of a second length or a second curvature of a second serration of the plurality of serrations. 5. A propeller blade, comprising: a hub; a tip; a surface area that extends between the hub and the tip, the surface area having an upper side, a lower side, a leading edge that extends from the hub to the tip, and a trailing edge; a plurality of serrations coupled to the leading edge of the propeller blade; and a controller configured to alter a position of a first set of serrations of the plurality of serrations between a first position and a second position, the controller including: a communication component configured to receive a wireless communication that indicates whether the first set of serrations is to be in the first position or the second position; and an actuator in contact with each serration of the first set of serrations and configured to move each serration of the first set of serrations between the first position and the second position based at least in part on the indication included in the wireless communication. 6. The propeller blade of claim 5 , wherein the propeller blade generates a first sound when rotating and the first set of serrations is in the first position and generates a second sound when rotating and the first set of serrations is in the second position. 7. The propeller blade of claim 6 , wherein the first set of serrations includes at least one serration of the plurality of serrations. 8. The propeller blade of claim 6 , wherein: when each serration of the first set of serrations is in the first position, each serration is retracted behind the leading edge of the propeller blade; and when each serration of the first set of serrations is in the second position, each serration extends beyond the leading edge of the propeller. 9. The propeller blade of claim 6 , wherein: the controller is configured to alter a position of a second set of serrations of the plurality of serrations between a third position and a fourth position; the propeller blade generates a third sound when rotating and the first set of serrations is in the first position and the second set of serrations is in the third position; and the propeller blade generates a fourth sound when rotating and the first set of serrations is in the second position and the second set of serrations is in the fourth position. 10. The propeller blade of claim 5 , further comprising: a power supply included in the propeller blade and configured to provide power to the actuator. 11. The propeller blade of claim 10 , wherein the power supply is at least one of a fuel cell, a battery, or a solar panel. 12. The propeller blade of claim 5 , wherein at least some of the plurality of serrations vary in at least one of a size, a shape, a length, a diameter, a curvature, or a material. 13. An aerial vehicle, comprising: a frame; a motor coupled to the frame; a propeller coupled to and rotatable by the motor; a first plurality of serrations positioned on the propeller, wherein a sound generated by the propeller when the propeller is rotating is altered based at least in part on a position of each of the first plurality of serrations; a second plurality of serrations positioned on the propeller, wherein the sound generated by the propeller when the propeller is rotating is further altered based at least in part on a position of each of the second plurality of serrations; a sensor configured to measure a sound generated by the aerial vehicle; and a controller configured to send instructions to alter a position of at least one of the first plurality of serrations or the second plurality of serrations; and wherein the instructions are based at least in part on the sound measured by the sensor. 14. The aerial vehicle of claim 13 , wherein: the second plurality of serrations are positioned toward a tip of the propeller and alter sound generated by a tip vortex resulting from the rotation of the propeller; and the first plurality of serrations are positioned along a leading edge of the propeller and alter sound generated by air passing across the propeller. 15. The aerial vehicle of claim 13 , wherein the first plurality of serrations are formed of a fibrous material that flexes during rotation of the propeller. 16. The aerial vehicle of claim 13 , wherein the controller is configured to cause a position of the first plurality of serrations to be altered while the propeller is rotating. 17. The aerial vehicle of claim 13 , further comprising: a flexible fringe extending from a trailing edge of the propeller, the fringe configured to disrupt air passing the propeller and alter a sound generated by the air passing the propeller as the propeller rotates; and a sound dampening material affixed to at least one of an upper side of the propeller or a lower side of the propeller and configured to absorb sound generated by air passing the propeller as the propeller rotates.