h a l f b a k e r yContrary to popular belief
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[-] Use search engines to check whether or not what you're about to invent already exists. |
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GPS guided parachutes exist, but they're more commonly parafoils than bell shaped. Is there a unique advantage in your concept over the ones already in use? How do you plan to retrieve the guidance unit, assuming the reason for the airdrop was that it was for someplace you couldn't land? |
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If you have control you put it down where it's safest for the recipient. Terrain, weather, and encirclement can preclude vehicle use. If they can get the delivery they can also retrieve the unit. |
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The link misses several critical capabilities that the SD has: 1) Greater precision through finer control of the many airfoils. Not just opening and shutting off vents. 2) Capability to 'pilot' the drop unit remotely, from the drop ship or anywhere. The drop ship does all its calculations and lets their payload go without further control. 3) Fine control of true airfoils, not 'decelerators' which they use. Glide bodies can be used if you have greater control. |
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// The link misses several critical capabilities // |
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Whcih link? I gave you Google's list for "gps guided parachute" - how many of the hits did you actually read? |
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Edit to add - the third hit (for me) from Google looks a lot like yours (link). Precision, programmability, reusable: |
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Available in three payload configurations: Micro Onyx (0 to 20 lbs), Onyx 500 (0 to 500 lbs), and Onyx 2200 (500 to2200 lbs)
Accuracy of 100 m
Patented1 two-parachute ("hybrid") system uses a high-speed elliptical parafoil for autonomous guidance, and a round recovery parachute for a reliably soft landing Flocking/Swarming (formation flying) and active in-air Collision Avoidance for simultaneous deployment of up to 50 Onyx systems
Adaptive Control, an advanced self-learning method for flight control, enables gross variances in cargo weights to beairdropped
High glide ratio over 4.5:1 provides a horizontal standoff of 44 km from an altitude of 35,000 ft
Deployable from military fixed-wing and rotary aircraft up to 150 KIAS Ultra fast flight speed (80 kts) increases accuracy and reduces vulnerability to wind-induced errors and detection
Continuously dis-reefed guidance parafoil provides for lowest opening shock and high speed deployment capabilities
Rigger-friendly, fully-recoverable, modular, and reusable system |
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I regret that I have but one fishbone to give this idea. |
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Im curious where you found the illustration of the Smart Drop to make the comparison with your links. |
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Your link has many of the features of the Smart Drop but lacks compactness, simplicity, and the ability to control true airfoils, where the final drop speed can be controlled after much faster, far more evasive flight. The fine and gross control in the Smart Drop allows landings like the human parafoil experts do, standing up and virtually stationary. I propose control on the order of drone precision. The Smart Drop should be able to achieve a CPE of 5m after fast evasive flight, a feat the huge and complicated JPADS cannot do. Just look at that thing. What a target. |
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If you post an illustration of your concept I'll be happy to look at it. |
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Regarding compactness and simplicity, I didn't pick that up from your original description. But isn't the minimum size of going to be partly dictated by the mass of what you're trying to deliver? The heavier the load, the bigger the parachute/parafoil/drone swarm has to be. |
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And the faster it can fly evasively. |
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