| Can we create an unmanned aerial vehicle which | | | | said that). How about a sleeping potion or a gas |
| would convert its own wing structure into fuel for | | | | that puts the enemy into a hibernation state for a |
| the flight? What if that fuel were a polymer | | | | few hours or days? |
| solution which was a solid on takeoff, but then | | | | The engine in the rear might be made out of a |
| dissolved into a liquid once the flight operations | | | | clay type substance encased in cellophane which, |
| began? And what about the remaining structure | | | | once lit from the rear, would provide the thrust |
| inside the wing? | | | | like a small C-65 Estes rocket engine. Once the |
| The wing spars could be made of the same | | | | engine was burned out, it could fall to Earth in |
| types of plastics that surgeons use to expand | | | | cinders with a whistle on it so it made an |
| heart arteries during operations. We know these | | | | intimidating sound and another diversion; a dud, or |
| techniques work on metal, plastic, carbon fibers, | | | | perhaps a small charge. |
| resilient composite, rubber of all types even | | | | By using such strategies, we could create |
| (stretch Armstrong). We pick the lightest material | | | | single-mission non-return UAV swarms to |
| and go for it. | | | | overwhelm our enemies and prevail in victory |
| Nickel-titanium stints are also easily adaptable | | | | over the battlespace. I hope you will please |
| metal, and you would not need much. If you use | | | | consider this, because it is my belief that winning |
| nickel and poly fibers you could made a battery | | | | still matters against the Talaban in Afghanistan. |
| or find a suitable chemical reaction for fuel or | | | | We are not going to win anyone's heart or mind |
| propulsion or even poison gas on impact (forget I | | | | on that side of the game. |