An example can include a pod detachably coupled to a hull. At least one thrust generator can be fixed to the pod. A power source can be mounted to the pod and slideable fore and aft. A power source actuator can be coupled between the pod and the power source to translate the location of the power source with respect to the pod. A sensor can be coupled to the pod to detect a pitch of the hull and provide a pitch signal. A controller can be coupled to one or more of the power source, the power source actuator, the first and second thrust generators and the sensor. The controller can maintain a pitch of the hull by translating the power source within the pod in association with the pitch signal.

An altitude movement device comprising of a ballonet within an outer envelope with the ballonet configured to control buoyancy and an apparent wind generating device combined with the altitude movement device to generate an apparent wind to propel the vehicle laterally with respect to the direction of the jet stream.

An altitude movement device comprising of a ballonet within an outer envelope with the ballonet configured to control buoyancy and an apparent wind generating device combined with the altitude movement device to generate an apparent wind to propel the vehicle laterally with respect to the direction of the jet stream.

A system enabling safe manned and unmanned operations at extremely high altitudes (above 70,000 feet). The system utilizes a balloon launch system and parachute and/or parafoil recovery.

A system enabling safe manned and unmanned operations at extremely high altitudes (above 70,000 feet). The system utilizes a balloon launch system and parachute and/or parafoil recovery.

A variable-volume aerostat, consisting of a flat gas envelope, joined to guide aerostat bodies. The flat gas envelope is typically deployed by rotation of cylindrical guide airships, or rollers suspended beneath guide aerostats. In its stowed configuration, the flat gas envelope is rolled, uninflated and relatively compact. As the invention ascends to high altitude, lifting gas expands out of the guide aerostats into the unrolling flat gas envelope. When fully deployed, the flat gas envelope is self-supporting, and has a horizontal surface area up-to 100 times larger than that of the guide aerostats. This is a major advantage in potential applications, including targeted Solar Radiation Management (SRM), and airborne solar power generation.

A variable-volume aerostat, consisting of a flat gas envelope, joined to guide aerostat bodies. The flat gas envelope is typically deployed by rotation of cylindrical guide airships, or rollers suspended beneath guide aerostats. In its stowed configuration, the flat gas envelope is rolled, uninflated and relatively compact. As the invention ascends to high altitude, lifting gas expands out of the guide aerostats into the unrolling flat gas envelope. When fully deployed, the flat gas envelope is self-supporting, and has a horizontal surface area up-to 100 times larger than that of the guide aerostats. This is a major advantage in potential applications, including targeted Solar Radiation Management (SRM), and airborne solar power generation.

An altitude movement device comprising of a ballonet within an outer envelope with the ballonet configured to control buoyancy and an apparent wind generating device combined with the altitude movement device to generate an apparent wind to propel the vehicle laterally with respect to the direction of the jet stream.

An altitude movement device comprising of a ballonet within an outer envelope with the ballonet configured to control buoyancy and an apparent wind generating device combined with the altitude movement device to generate an apparent wind to propel the vehicle laterally with respect to the direction of the jet stream.