Hierarchical inflatable structures and methods

What is claimed is: 1. An inflatable structure comprising: multiple variable chambers including a first variable chamber and a second variable chamber; a first boundary envelope defining the first variable chamber; a second boundary envelope defining the second variable chamber, the first and second boundary envelopes separating the first variable chamber from the second variable chamber; an inflation system configured to inflate the first variable chamber to a first pressure and to inflate the second variable chamber to a second pressure higher than the first pressure for a higher stiffness of the second boundary envelope as compared to the first boundary envelope; and a base configured as an interface between the inflation system and the first and second variable chambers, the base including a first nozzle in fluid communication with the first variable chamber and a second nozzle in fluid communication with the second variable chamber; wherein the first and second variable chambers are defined by an operative scale that differs by an order of magnitude between the first and second variable chambers; wherein the operative scale is volume with the first variable chamber defining a first volume when fully inflated and the second variable chamber defining a second volume when fully inflated, the second volume smaller than a first volume by the order of magnitude. 2. The inflatable structure of claim 1 , comprising a controller configured to: monitor, by a first pressure sensor, a first pressure inside the first variable chamber; and monitor, by a second pressure sensor, a second pressure in the second variable chamber. 3. The inflatable structure of claim 2 comprising: a valve disposed to control inflation of the first variable chamber, wherein the controller is configured to: access a design pressure; and close the valve when the first pressure sensor indicates the first pressure equals a predetermined design pressure selected to maintain pressure and shape of the first variable chamber. 4. The inflatable structure of claim 1 wherein the second variable chamber is configured to be inflated before the first variable chamber so that the inflatable structure inflates to a substantially deployed state more quickly than if the first variable chamber were inflated first. 5. The inflatable structure of claim 1 wherein the inflatable structure is stored in a first state and is deployed in a second state, and wherein when in the first state the inflatable structure has a size that is compact relative to the second state. 6. The inflatable structure of claim 1 comprising: a third variable chamber; and a third boundary envelope defining the third variable chamber wherein the second and third boundary envelopes are in contact with the first boundary envelope. 7. The inflatable structure of claim 6 wherein the first chamber has a length and the second and third variable chambers both have helix shapes wrapped around the first variable chamber, the helix shapes of the second and third variable chambers wrapped along the length. 8. The inflatable structure of claim 6 wherein the first variable chamber extends along an axis, the second variable chamber is wrapped at a first angle relative to the axis, and the third variable chamber is wrapped at a second angle relative to the axis that differs from the first angle. 9. The inflatable structure of claim 1 comprising: a third variable chamber; and a third boundary envelope defining the third variable chamber, wherein the second and third boundary envelopes are fixed to the first boundary envelope so that when the second or third variable chamber is pressurized, the first variable chamber extends or contracts. 10. The inflatable structure of claim 1 wherein the first boundary envelope comprises a material that is stretchable so that the first boundary envelope is expanded when pressurized, and the second boundary envelope comprises a material that is non-stretchable so that the second boundary envelope is substantially non-expanded when pressurized. 11. A method of deploying an inflatable structure comprising: constructing the inflatable structure with multiple variable chambers including a first variable chamber and a second variable chamber, a first boundary envelope defining the first variable chamber; and a second boundary envelope defining the second variable chamber; constructing an inflation system to inflate the first variable chamber to a first pressure and to inflate the second variable chamber to a second pressure higher than the first pressure for a higher stiffness of the second boundary envelope as compared to the first boundary envelope; adding a base as an interface between the inflation system and the first and second variable chambers, the base including a first nozzle in fluid communication with the first variable chamber and a second nozzle in fluid communication with the second variable chamber; separating the first variable chamber from the second variable chamber by the first and second boundary envelopes; and defining the first and second variable chambers by an operative scale that differs by an order of magnitude between the first and second variable chambers, wherein the operative scale is volume with the first variable chamber defining a first volume when fully inflated and the second variable chamber defining a second volume when fully inflated, the second volume smaller than a first volume by the order of magnitude. 12. The method of claim 11 comprising: inflating, by an inflation system, the first variable chamber to a first pressure; and inflating, by the inflation system, the second variable chamber to a second pressure wherein the second pressure is higher than the first pressure so that the second boundary envelope is stiffer than the first boundary envelope and the second variable chamber supports the first variable chamber. 13. The method of claim 12 comprising: inflating the second variable chamber before inflating the first variable chamber so that the inflatable structure inflates to a substantially deployed state more quickly than if the first variable chamber were inflated first. 14. The method of claim 11 comprising: connecting a base with the first and second variable chambers, the base having a first nozzle open to the first variable chamber and a second nozzle open to the second variable chamber; and selectively connecting a pressure source, by an inflation system, with the first and second nozzles. 15. The method of claim 11 comprising: storing the inflatable structure in a first state; and deploying the inflatable structure in a second state wherein when in the first state the inflatable structure has a size that is compact relative to the second state. 16. The method of claim 11 comprising: providing a third variable chamber of the inflatable structure; and constructing the second and third variable chambers with helix shapes wrapped around the first variable chamber. 17. The method of claim 16 comprising: constructing the first variable chamber to extend and contract along an axis; and constructing the second and third variable chambers so that the helix shape of the second variable chamber is wrapped at a first angle relative to the axis, and the helix shape of the third variable chamber is wrapped at a second angle relative to the axis that is different than the first angle. 18. The method of claim 16 comprising: staging the second and third variable chambers along the first variable chamber in non-overlapping positio