Photo-sensor array to adjust alignment of optical receiver

I claim: 1. A balloon system comprising: an optical receiver configured to receive an optical signal at a balloon; a plurality of alignment sensors comprising at least a first and a second alignment sensors, wherein the first and the second alignment sensors are positioned so as to detect the optical signal at a first and a second location, respectively, and wherein the first location and the second location are proximate to opposite sides of the optical receiver; and a control system configured to: receive first light data that is indicative of the optical signal as received at the first alignment sensor; receive second light data that is indicative of the optical signal as received at the second alignment sensor; analyze the first and second light data to detect an intensity difference between: (a) the optical signal as received at the first alignment sensor and (b) the optical signal as received at the second alignment sensor; determine a desired horizontal movement of the balloon; receive altitudinal wind data; determine a desired altitude based on the desired horizontal movement and the received altitudinal wind data such that wind at the desired altitude contributes to the desired horizontal movement of the balloon; and in response to detection of the intensity difference and determination of the desired altitude, initiate a process to control positioning of the optical receiver based on the intensity difference and the desired altitude, wherein the process comprises moving the optical receiver towards the desired altitude via at least one of the following: (a) a change in the altitude of the balloon and (b) a change in position of the optical receiver with respect to the balloon. 2. The balloon system of claim 1 , wherein the optical receiver comprises a first photodetector, and wherein the plurality of alignment sensors comprises a plurality of second photodetectors. 3. The balloon system of claim 2 , wherein plurality of second photodetectors comprise a plurality of photodiodes. 4. The balloon system of claim 1 , wherein the optical receiver comprises a photodetector, and wherein the first location is to a first side of the photodetector, and wherein the second location is to a second side of the photodetector, wherein the second side is opposite to the first side. 5. The balloon system of claim 1 , wherein the optical receiver comprises a photodetector, wherein the first location is left of center with respect to the center of the photodetector, and wherein the second location is right of center with respect to the center of the photodetector. 6. The balloon system of claim 1 , wherein the optical receiver comprises a photodetector, wherein the first location is above the photodetector, and wherein the second location is below the photodetector. 7. The balloon system of claim 1 , wherein the optical receiver comprises a photodetector, wherein the first location is above center with respect to the center of the photodetector, and wherein the second location is below center with respect to the center of the photodetector. 8. The balloon system of claim 1 , further comprising a third alignment sensor and a fourth alignment sensor that are positioned so as to receive the optical signal at a third and a fourth location, respectively. 9. The balloon system of claim 8 , wherein the optical receiver comprises a photodetector, wherein the first and the third location are both to a first side of the photodetector, and wherein the second and the fourth location are both to a second side of the photodetector, wherein the second side is opposite to the first side. 10. The balloon system of claim 8 : wherein the optical receiver comprises a photodetector; wherein the first location is left of center with respect to the center of the photodetector; wherein the second location is right of center with respect to the center of the photodetector; wherein the third location is above center with respect to the center of the photodetector; and wherein the fourth location is below center with respect to the center of the photodetector. 11. A computer-implemented method comprising: receiving first light data that is indicative of an optical signal as received at a first of a plurality of alignment sensors, wherein the plurality of alignment sensors comprises at least the first and a second alignment sensor, wherein the first and the second alignment sensor are positioned so as to detect the optical signal at a first and a second location, respectively, and wherein the first location and the second location are proximate to opposite sides of an optical receiver of a balloon; receiving second light data that is indicative of the optical signal as detected at the second alignment sensor; analyzing the first and second light data to determine an intensity difference exists between: (a) the optical signal as detected at the first alignment sensor and (b) the optical signal as detected at the second alignment sensor; determining a desired horizontal movement of the balloon; receiving altitudinal wind data; determining a desired altitude based on the desired horizontal movement and the received altitudinal wind data such that wind at the desired altitude contributes to the desired horizontal movement of the balloon; and in response to detecting the intensity difference and determining the desired altitude, positioning the optical receiver based on the intensity difference and the desired altitude, wherein positioning the optical receiver comprises moving the optical receiver to the desired altitude via a process that comprises at least one of the following actions: (a) changing the altitude of the balloon and (b) changing a position of the optical receiver on the balloon. 12. The method of claim 11 , wherein analyzing the first and second light data to determine an intensity difference exists comprises: determining a first intensity value corresponding to the optical signal as detected at the first alignment sensor; determining a second intensity value corresponding to the optical signal as detected at the second alignment sensor; and determining a difference between the first intensity value and the second intensity value. 13. The method of claim 12 , wherein analyzing the first and second light data to determine an intensity difference exists comprises determining that the difference between the first intensity value and the second intensity value is greater than a predetermined threshold. 14. The method of claim 11 , further comprising repeating the method of claim 11 until the intensity difference is less than a predetermined threshold. 15. The method of claim 11 , wherein the first and the second alignment sensor are arranged horizontally opposite one another, and wherein positioning the optical receiver based on the intensity difference comprises moving the optical receiver horizontal to the ground. 16. The method of claim 11 , wherein the first and the second alignment sensor are arranged vertically opposite one another, and wherein positioning the optical receiver based on the intensity difference comprises changing the altitude of the optical receiver. 17. A non-transitory computer readable medium having stored therein instructions executable by a computing device to cause the computing device to perform functions comprising: receiving first light data that is indicative of an optical signal as received at a first of a plurality of alignment sensors, wherein the plurality of alignment sensors comprises at least the first and a second alignment sensor, wherein th