Comment by tzury
9 hours ago
There are 2 short segments in the video showing the actual performance and thus far it is a complete [1] failure [2].
The guy has a talent, and he put together a nice prototype based on OpenRocket [3], but with all due respect, this is not a rocket, and you are not going to win any war with this toy, even if all your enemy has are rocks thrown at you from pretty much similar distance.
The remix of computer games / Ukraine / Martin Luther King / Vietnam / David Koresh just adding more to the amateur spirit and confusion.
[1] https://youtu.be/DDO2EvXyncE [2] https://youtu.be/DDO2EvXyncE?t=280 [3] https://openrocket.info/
I'm surprised nobody else has pointed this out. The entire YouTube video has only two short clips of the actual rocket being fired, and in both cases the clips are very short and only show the rocket being fired and then following an erratic flight path, and then get cut before showing the rocket hitting anything.
For all the technical info given in the video, there is a curious lack of any data regarding the actual accuracy of the system. What percentage of rockets tested managed to hit anything and at what range?
I suspect a major problem is the quality and consistency of the propellant and getting a symmetric burn.
The video references "future tracking systems," so I don't think it aims at all yet.
> curious lack of any data regarding the actual accuracy of the system
No lack of entrackment data generated by [edit] d̶i̶g̶i̶t̶a̶l̶ ̶t̶w̶i̶n̶ github repo of "the system".
"digital twin"?
Is there a simulation that has been documented to have the identical behavior and flight characteristics as the real thing? Does not seem like it.
If there is a difference, it is not a twin.
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Yes, I don't think this project is a serious threat as a weapon, it's more interesting if viewed as a politically provocative stunt, to get people thinking about the relationship between technology and war.
I always wonder why rockets are millions of dollars each, that seems insane to me.
Part of it is the sophistication. Take the Tomahawk: assumed range of ~1000 miles , estimated accuracy of 30 feet. Can launch from above or below water. Etc.
The other part is the limited production runs. Until last month, the DoD was generally purchasing ~100 of these annually. There's no scale economy in making these, so those 100 missiles need to support the entire production & R&D of the product.
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Check out Joe Barnard's youtube channel BPS.Space where he's documenting his development of "high power" (hobby) rockets. Those are relatively small rockets still but nonetheless he's getting into performance regimes where the engineering starts to be tricky and the details really matter. The more extreme your rocket gets, the difficulty really ramps up quick.
It’s not a complete explanation, but I was awed by the precision of the shower screens used in modern rocket engines. In the 60s it might have sufficed to just spray fuel into the combustion chamber using some nozzles, but now we have highly precise matrices of micro-perforations that maximize combustion.
Also if you want to harden the rocket against EMP attacks you need an inertial guidance system, and those things also demand extreme precision.
It really depends on what kind of rocket you’re talking about. An unguided rocket propelled grenade mass produced with 1960s technology is a few hundred bucks. Stepping up to a simple TOW guided missile using 1970s technology quickly ramps that price up to $5-10k per round with a max range of 3-5km.
Once you add in modern electronics and guidance and reliability that cost quickly skyrockets, going up an order of magnitude at each step of complexity (advanced guided like the Javelin, cruise, ballistic, etc).
Fireworks rocket do not cost as much. But if you want high precision and high speed, that simply is expensive. Also the area is of course restricted making it more expensive as most states do not want DIY rockets everywhere.
They arent. Missiles cost millions. Rockets are cheap. Rockets are unguided. Missiles are guided. From a military perspective, spacelaunch rockets are techically "unguided" as they are not tracking a target but trying to stick to a fixed/programed trajectory. It is the seeker head that costs the millions, all the jamming/counter-jamming tech that drives up development costs.
This is a rather basic (passive) seeker head by modern standards.
https://en.wikipedia.org/wiki/File:R-27_missile_homing_head,...
Something far more interesting, you can find in this channel: https://m.youtube.com/@LafayetteSystems
I've been subscribed to this guy for some time. His work is much more impressive, and IIRC, he either works for a defense contractor or is studying for that.
I think there's lots of people talking past each other on this post. These kinds of designs won't be as reliable as the existing designs, and they may have a systemic flaw, for example, susceptibility to disabling with microwaves. And they aren't going to work after sitting in an ammo depot for 15 years in the desert or after being dropped from a plane.
But these designs will cost just a few dollars more than the equivalent dumb munition (and can possibly be retrofitted), and can be two orders of magnitude more effective in the short term. The threat here isn't "guy in garage makes MANPADS", it's "IRGC converts 100's of thousands of existing unguided cold-war rockets into guided S2A and S2S missiles for $20 each". Even if it doesn't hit any target, each aircraft has a limited number of countermeasures and has to return to base if they run out or risk being hit.
Guided munition at a dumb munition price is enough to invalidate many strategies.
"and you are not going to win any war with this toy, even if all your enemy has are rocks thrown at you"
I don't want to use it for war. I think it would be a pretty cool technical project (if it works).
This design is pretty clearly optimized for weaponry. Eg the foldable fins - necessary if you want to keep a magazine of these things stored compactly before firing. Totally unnecessary for funsies.
What nonviolent application are you imagining for a gps-guided rocket that is launched by pulling a gun trigger on a hand held mount?
Launching model rockets with a controlled landing (less likelihood of property damage or fires). Learning about the components. Folding fins make it easier to transport without snapping one (hopefully). Trigger vs button launch isn't that big of deal, although might have better safety options compared to standard model rocket launch buttons.
> What nonviolent application are you imagining for a gps-guided rocket that is launched by pulling a gun trigger on a hand held mount?
A launcher for a climbing rope or grappling hook. Have you ever tried getting a rope up over a branch on a very tall tree?
Not joking - I considered it as a hobby project years ago until I discovered how hard it would be to do legally.
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Ukraine needs more cheap weapons.
You don't need to win any wars with it if you can use them to sow confusion, obscure the firing of more serious rockets, and/or trigger a sufficiently more expensive response.
It clearly needs more work, but if an amateur can get this far at this low cost, odds are you'll see attempts at overwhelming attackers or defense systems by sheer volume with cheap decoys like this long before they become an actual threat in and of themselves.
Get the rocket a bit more stable, and force an attack to try to take out dozens of these because one of them might be a real threat, and you'll have created a problem.
With a 3D printer and some 'ordinary household chemicals' to quote a certain movie you can do pretty scary stuff.
People can do very scary things with a knife, a car, or petrol+matches.
We don't try to regulate those things out of existence like we do with new technology (drones and now 3D printers)
Kind of ridiculous that a country with more guns than people and 45k firearms deaths per year wants to regulate 3D printed plastic. Yet collecting and shooting actual guns is still an acceptable hobby in many states.
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McGuyver pouring sap on a pinecone
Hiya! (Grenade)
Exactly. Consider the current conflict in Iran. They have thousands of drones that cost $50k each. The US’s only real defense against one of these drones is to fire a million dollar missile at it. That assymmetry can win or lose a war.
It's not the only real defense. This works pretty well too https://en.wikipedia.org/wiki/Centurion_C-RAM
There's clearly a need for more cheap interceptor drones as well, but it's not like the US military won't start deploying those soon enough.
Regardless, he made a prototype rocket enclosure and he seems to have the software down… I think the propulsion system will be the easy part. Hardest part will be tuning the PID so that the rocket goes where he wants it to. Then incorporating his tracking system will be another challenge of itself but that’s because of the form factor. As long as his calculus and linear algebra is good I see than being successful. Either way I’d hire simply to be a prototype engineer. Either Anduril or CIA would hire him in a heartbeat for prototyping.
> I think the propulsion system will be the easy part.
Really? I think rocket science is still not easy. Just look at how much nation states are spending on maintaining their liquid and/or solid fuel rocket programs. If they even have one, let alone both.
This book might give some insights into the why https://library.sciencemadness.org/library/books/ignition.pd...
Quote: "All this sounds fairly academic and innocuous, but when it is translated into the problem of handling the stuff, the results are horrendous. It is, of course, extremely toxic, but that's the least of the problem. It is hypergolic with every known fuel, and so rapidly hypergolic that no ignition delay has ever been measured. It is also hypergolic with such things as cloth, wood, and test engineers, not to mention asbestos, sand, and water —with which it reacts explosively. It can be It has recently been shown that an argon fluoride, probably ArF2, does exist, but it is unstable except at cryogenic temperatures.
[...] kept in some of the ordinary structural metals — steel, copper, aluminum, etc. —because of the formation of a thin film of insoluble metal fluoride which protects the bulk of the metal, just as the invisible coat of oxide on aluminum keeps it from burning up in the atmosphere. If, however, this coat is melted or scrubbed off, and has no chance to reform, the operator is confronted with the problem of coping with a metal-fluorine fire. For dealing with this situation, I have always recommended a good pair of running shoes."
Granted this is about a fuel that is AFAIK not used for MANPADs, but the joke about the running shoes could be made about most aspects of rocket propulsion.
With all do respect I think your over complicating the problem. It’s not rocket science (no pun intended). It’s essentially a hobby rocket that can be weaponized and it’s all DIY. That’s the point simple and off the shelf. Not meant to travel towards the stratosphere or even long range. Quick and dirty way to cause havoc in a localized area.
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Taking a quick look at the BOM, it lacks the correct sensor selection.
Even if the correct sensor could be chosen (whatever it is), unlikely is attainable by consumers and the technology would definitely be export controlled in the US.
You'd be AMAZED what you can find on eBay.
I saw this pop up alongside its video thumbnail and nearly shit myself watching it and going "damn, that looks exactly like what's on those RU/UA drones going at each other"... https://www.ebay.com/itm/197224214645
"HS AI Vision Cube For Ultra-long-range Target Recognition tracking & Thermal" for as low as $175. I am feeling the potential ITAR violations straight through my screen.
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I think MEMS gyroscopes and accelerometers used in consumer drones should be just about good enough to measure orientation and acceleration, and those are cheap and easy to get.
You could integrate acceleration to get speed - the flight is short enough to make compounding errors easy to ignore.
I think thanks to drones and RC hobbyists, there's a generally nice body of knowledge on how to get good enough data from consumer hardware to keep things flying.
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Get connected with DARPA ASAP, just to let the overlords know you are on "the right side of the fence" - - before Homeland pays you a "very uncomfortable" visit
And that’s ok if it’s failing to do the job as intended, learning is acquired, and it looks fun to build, I am in the field and I find it great homemade concept.
Realistically, I doubt there’s ANY system out there will be able to counter small weaponized drones that are flown manually let alone with AI, you might have some workarounds, but never a real counter.
> Realistically, I doubt there’s ANY system out there will be able to counter small weaponized drones that are flown manually let alone with AI, you might have some workarounds, but never a real counter.
Weaponized drones (say D_A) can be countered by other weaponized drones (say D_B), equally cheap or cheaper than D_A because the D_A is usually targeting something larger (so more payload) and typically has a longer range. D_B only needs to wreck D_A at a shorter defensive range. That's what Ukraine is doing.
You can also use drone swarms with coordinated action so that each drone in the swarm is only targeting one other drone, and automatic re-targeting if one node misses. [1]
[1] https://en.wikipedia.org/wiki/Swarm_robotics
> equally cheap or cheaper
I doubt it, as D_A's target is stationary (and could be reduced to GPS coords) while D_B's target is moving.
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Couldn’t post earlier seems HN is rate limited :/
hardest issue as I mentioned in another comment is detection. Now on using other drones to counter a drone, there are other issues, as I built and tested some before, assuming you got the detection part done. The first one is guidance and correction mid-air, flying manually won’t really be practical due to the need for an extraordinary flying skills, which can’t be relied on in the field, the second part is the speed, you need to ALWAYS make sure the interceptor is faster to catch it up, third is the weight, I disagree about the payload part you mentioned, I have seen videos of light weight drones failing to wreck bigger ones, if you are relying on collision alone. Additionally, the telemetry/video/C&C for the interceptor, if jamming is already in place, your counter won’t work either.
The swarm will require a low latency comms link, centralized or decentralized, if the area is jammed, it won’t work. i have built a self-healing decentralized system using cellular in each drone, but that’s useless if the network is down to start with.
So they might work in a very specific use case, but not an ultimate solution to counter them.
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I don’t know if it will work, but here’s a startup that seems to be building an AI-controlled shotgun:
https://www.ycombinator.com/companies/9-mothers-corporation
Given the war in Ukraine, wanting to build such things is certainly understandable. But still, this is the stuff of nightmares.
David Suaez in Kill Decision had swarms of small single shot drones with the targeting intelligence of ‘00 camera. Identify a face, fly towards it, fire when close. It was an implementation of quantity has a quality all its own.
"Realistically, I doubt there’s ANY system out there will be able to counter small weaponized drones that are flown manually "
Why would lasers not work?
Those cheap drones are made from plastic, if you have a laser powerful enough and a target guidance system (like a camera and a PI) - then you would just need enough of them.
At long distances the small cross section of the drone requires tight focusing (expensive optics) or a high power, preferably pulsed laser (expensive laser) or both.
Not impossible but many times more expensive than the drone
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At very short distances and with a lot of power, perhaps. Despite what we see in movies laser beams diverge. And then with distance it’s harder to track moving objects precisely to hit the same spot long enough to melt it.
At that point might as well spend the money to use a kinetic weapon with basic tracking and ballistic calculations.
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The practicalities of using lasers are covered in some depth on the Naval Gazing blog. First part here:
https://www.navalgazing.net/Lasers-at-Sea-Part-1
Powerful enough laser and accurate enough targeting system is easy to say, but not easypeasy to do. Dumping thousands of Joules on a tiny moving target is much easier to do with explosives.
Lasers imo don't really have IRL advantages over machine guns and rockets, and their line of sight nature is a huge limitation.
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Lasers won’t effectively work, it’s a two part equation, detection and targeting. To neutralize a target using a ground-based laser, you need an enormous power, and still it won’t penetrate a high distance/altitude in the sky, environment factors also to be considered. The detection part is even harder, these small 8in drones are almost impossible to detect unless you can hear it, aka it’s over, because they can fly at 250km/h, too small to be visually detected, acoustic sensors will fail to detect them, and radar will miss it as a false negative since it’s the size of a bird. I have seen some systems trying to combine all that to detect them plus AI for flying pattern detection, but they are far from being reliable in practical applications.
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From what I can tell, Ukrainians are having some success with converting guns into automatic turrets that can track and shoot down drones via sensors, and the rifle-equivalent of birdshot.
"let alone with AI" what's falling into the AI category here perhaps is the key question, since microseconds counts, and LLM are very slow!
Even the fastest "real-time" LLM frameworks currently report sub-second latencies around 120ms. This is fine for high-level mission planning (e.g., "fly to the red house") but too slow to prevent a drone from hitting a tree at 50mph (80 KM/h)[1]
Whilst the Shahed-136 kamikaze drone typically flies at a maximum speed of around 185 km/h (roughly 115 mph or 100 knots).
[1] https://arxiv.org/html/2602.19534v1 [2] https://en.wikipedia.org/wiki/HESA_Shahed_136
> "let alone with AI" what's falling into the AI category here perhaps is the key question, since microseconds counts, and LLM are very slow!
LLMs (Large Language Models) are far from the only type of AI around. It's a pretty broad field, and there are real-time AI systems, for example, self-driving cars, which have the response times you're thinking of. [1]
[1] https://en.wikipedia.org/wiki/Artificial_Intelligence:_A_Mod...
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> Realistically, I doubt there’s ANY system out there will be able to counter small weaponized drones that are flown manually let alone with AI
What kind of systems are you thinking about? Jet airplanes for sure are completely safe from small drones.
"Jet airplanes for sure are completely safe from small drones."
That feels like a bold and unsupported assertion. Ask a pilot how they'd feel about takeoffs or landings through airspace filled with adversarial drones.
A flock of unlucky geese can knock out a jet turbine, how is this a "for sure" conclusion?
> Jet airplanes for sure are completely safe from small drones.
Until they land then, due to their cost, they become a very juicy target to aim for.
maybe in the air, but I seem to recall the Ukrainians being successful at attacking Russian planes on the ground.