Systems and methods for lighter-than-air high altitude platforms

What is claimed is: 1. A high altitude platform comprising: an inflatable body configured to contain a gas therein in an amount effective to provide lift such that the platform can reach a minimum altitude of 50,000 feet, wherein the body when inflated has a front with a first opening and a rear with a second opening at opposite ends of the body, wherein the distance from the front to the rear defines an inflated body length, and wherein the inflated body length is greater than a maximum width of the inflated body; a duct disposed through the body and having a plurality of cross-sectional areas, the duct having a length extending at least from or near the first opening at the front of the body to or near the second opening at the rear of the body, wherein the plurality of cross-sectional areas decreases from the first opening to a forward portion of an intermediate region of the duct, wherein the intermediate region is located closer to the first opening than to the second opening, and wherein the plurality of cross-sectional areas increases from a rearward portion of the intermediate region to the second opening; and a first propeller positioned in the duct between the first and second openings, wherein the body when inflated has a surface area drag coefficient of about 0.002 in a freestream flow having a speed relative to the body of twenty meters per second (m/s) and has a Reynolds Number of about 4.8×10 6 . 2. The high altitude platform of claim 1 , wherein the high altitude platform has a lifting capability of at least about 410 kg. 3. The high altitude platform of claim 1 , further comprising a solar panel coupled with the platform and configured in conjunction with an electrical energy store to provide electrical power to the platform. 4. The high altitude platform of claim 1 , further comprising a control surface configured to orient the platform such that the front faces a freestream flow. 5. The high altitude platform of claim 1 , further comprising a payload coupled with the platform, the payload comprising a communication system. 6. The high altitude platform of claim 1 , wherein the first propeller is positioned in the duct between the first and second openings at a position that is located at a distance of about 10% or less of the length of the duct from the forward portion of the intermediate region. 7. The high altitude platform of claim 1 , wherein a divergence angle of the duct from the intermediate region to the second opening is at least about 1.3 degrees. 8. The high altitude platform of claim 1 , further comprising a payload coupled with the platform, the payload comprising a surveillance system. 9. The high altitude platform of claim 1 , further comprising one or more additional propellers located in the duct near the first propeller, wherein the first propeller and the one or more additional propellers are configured such that the total angular momentum of the first propeller and the one or more additional propellers when operating generates a net torque on the platform that is within a control range of a control system of the platform. 10. The high altitude platform of claim 1 , wherein the body is formed of a thin-walled structure having an average thickness of less than about 0.1 inches. 11. A high altitude platform comprising: an inflatable body configured to contain a gas therein in an amount effective to provide lift such that the platform can reach a minimum altitude of 50,000 feet, wherein the body when inflated has a front with a first opening and a rear with a second opening at opposite ends of the body, wherein the distance from the front to the rear defines an inflated body length, and wherein the inflated body length is greater than a maximum width of the inflated body; a duct disposed through the body and having a plurality of cross-sectional areas, the duct having a length extending at least from or near the first opening at the front of the body to or near the second opening at the rear of the body, wherein the plurality of cross-sectional areas decreases from the first opening to a forward portion of an intermediate region of the duct, wherein the intermediate region is located closer to the first opening than to the second opening, and wherein the plurality of cross-sectional areas increases from a rearward portion of the intermediate region to the second opening; and a first propeller positioned in the duct between the first and second openings, wherein a drag force on the high altitude platform is less than 14 pounds (lbs) at an altitude of 65,000 feet in a freestream flow having a speed relative to the body of twenty meters per second (m/s). 12. The high altitude platform of claim 11 , wherein the high altitude platform has a lifting capability of at least about 410 kg. 13. The high altitude platform of claim 11 , further comprising a solar panel coupled with the platform and configured in conjunction with an electrical energy store to provide electrical power to the platform. 14. The high altitude platform of claim 11 , further comprising a control surface configured to orient the platform such that the front faces a freestream flow. 15. The high altitude platform of claim 11 , further comprising a payload coupled with the platform, the payload comprising a communication system. 16. The high altitude platform of claim 11 , wherein the first propeller is positioned in the duct between the first and second openings at a position that is located at a distance of about 10% or less of the length of the duct from the forward portion of the intermediate region. 17. The high altitude platform of claim 11 , wherein a divergence angle of the duct from the intermediate region to the second opening is at least about 1.3 degrees. 18. The high altitude platform of claim 11 , further comprising a payload coupled with the platform, the payload comprising a surveillance system. 19. The high altitude platform of claim 11 , further comprising one or more additional propellers located in the duct near the first propeller, wherein the first propeller and the one or more additional propellers are configured such that the total angular momentum of the first propeller and the one or more additional propellers when operating generates a net torque on the platform that is within a control range of a control system of the platform. 20. The high altitude platform of claim 11 , wherein the body is formed of a thin-walled structure having an average thickness of less than about 0.1 inches.