The Portuguese Space Agency (yes, there is one, Go Portugal) recently ran a competition for teens to fly with Air Zero G. Thirty kids, including my son (majority were girls), shipped out today for the Air Force base at Beja. They fly on Friday.
Congratulations for him and his peers for having the opportunity to experience this. I can imagine that this will have a long lasting effect on their minds. It would be great to know what it did with him and the others in 10 years.
I’d guess not mechanical? Look at the dashboard top, lower left over the first minute or so: There’s a screw head that keeps popping in and out of existence which suggests some kind of heavy software correction to me.
I didn't know it's possible using an unmodified airplane. My first thought was: wouldn't this maneuver simultaneously set off all the alarms bells in the cockpit, as if the plane is crashing to the ground? After a quick search on YouTube, it indeed does, but not really a big deal...
> 2:43 - This parabolic manoeuvre isn't the normal kind of thing that you do in an Airbus, and the software in this plane hasn't been modified because to do so would be a huge effort to re-qualify it. With the normal software, you have the normal alarm saying, "This doesn't seem like a very good idea, guys," and one of the pilots that isn't too busy on the other two axes is turning off the alarms that we don't need to worry about and keeping track of the ones we might need to worry about.
I wonder if there isn't an easy way to automate the parabolic flight - the autopilot should be clever enough to do it by itself without needing human intervention.
The real question is "does it cost more to certify the autopilot to do this than it does to pay for an extra two pilots", and with my understanding of aerospace costs that answer would be "very, very much yes".
I could imagine the autopilot could do a much better job.
In the ideal 'zero-g' flight, you can release a ball at the start, and it should stay stationary (relative to the cabin) for the whole flight.
That means the plane body must be to within a few inches of the exact perfect location in the sky 30 seconds later.
I haven't flown planes, but I imagine that making sure they follow precisely a path with an accuracy of an inch in all three dimensions while travelling at 600 mph is no easy feat. But an autopilot with a fast control loop might be able to do it.
All the autopilots in the world aren't keeping a plane to within an inch in all three dimensions. It'd be nice, but turbulence is a thing :)
More importantly, actual position isn't that important - you care about relative acceleration being as close to 0g as you can.
And with the 3-pilot setup the A310 zero g flights have, they maintain +/- 0.02g. Now you add to that the fact that developing an autopilot you can trust in that situation costs a good chunk of money, the fact that it's a specially modified plane (so it's more or less a one-off effort), and the fact that pilot costs are negligible compared to the rest of the flight cost.
At this point, you can get a minimal increase in precision for a large expenditure up front. You'll still have the 3-pilot setup (you want to be able to recover on malfunction), so operational costs aren't reduced.
At that point, the question becomes "why would you"
The “easy” way to do it is to mandate autopilots to have the capability for precise ballistic trajectories. This would need better positioning, accelerometers, and meteorological radars and would also enable fully autonomous landings (if the plane can be aware of air densities and speeds around it, it can nail the landing even with wind gusts).
Wait what? If your landings are a ballistic trajectory, kindly step away from that stick ;)
And that's kind of the point - nobody except the few planes that fly parabolic trajectories needs this. So good luck mandating something affecting all of aviation with no practical use except for a handful of flights.
Autoland already exists. And can handle crosswinds up to 25kts. It's just that using them is an incredibly intense task - your reaction time to fix mistakes is a bit short.
That's why most landings are still manual, unless visibility is so bad that you have no choice.
(Also, the idea that meteorological radar could give you enough info about air density to preemptively handle air gusts is... a bold future)
Most passenger airliners flying today can land automatically, but are only allowed to do so when visibility is so bad that it's the only option. It's called CAT III Autoland.
There isn't much turbulence, wind gusts etc. at altitude - these are more of an effect of the bumpy and uneven, alternative hot and cold surface at ground level - the bumps are usually all smoothed out by the time you are high up in the air.
(besides large storms, of course)
EDIT: Turns out there is sometimes some turbulence at altitude, caused by large mountains, storms and the jet stream - but these are all predictable and avoidable.
This doesn’t need AI. The physics are very well understood. All that’s needed is a better autopilot with better awareness of surrounding conditions and more precise control of the aircraft.
FTA "To fly a parabola takes 3 pilots working in concert. Two pilots sit in front of the control columns and a third sits in the center jump seat to manage the engines. When flying a parabola, one pilot is responsible for the pitch of the aircraft and the other for the roll. The pilot responsible for the roll of the aircraft actually has a modified control column in order to put as little pressure on the yoke as possible, allowing the pitch pilot to focus on the correct parabola timing." I think precise timing requires many pilots. Lots to keep track of in the name of science.
Yeah doing a parabola is relatively easy. Doing a nearly perfect one to maximize weightlessness without overstressing something is harder, so having one pilot for each aspect makes sense.
Another for radio and another for “general everything watching; the captain” makes sense.
My aviation family has a long history all the way back to training pilots for WWII (already highly experienced - too much so for combat) so my hunch is accuracy and redundancy.
Under normal conditions, sure it’s a one time maneuver, within limits, etc. This is much more of a risk-laden undertaking with the repeated stress on the airframe, the human body, and so having individual attention on important individual tasks - with experience and brain computing speed machines still can’t match for a brilliant stick and yoke pilot in unexpected conditions - this is for safety.
Also considering my background with French culture, I imagine the discussion went something like “we could do it with fewer personnel, but why? This works.”
I imagine it's for an abundance of caution, as they are flying these planes way outside what their normal operations manual recommends. I assume a 320 NEO or a 737 MAX would slap the hand of the pilot if they attempted to go for a +50 degree climb and scream expletives in the voice alert system.
Okay you just gave me a mental image of an Airbus autopilot system so angry at you it starts swearing in French. Totally agree with safety and ‘normal use case this is not’ situation.
I did one of these with https://www.gozerog.com/ a few years back. Not cheap, but memories that'll last a life-time. Started with lunar and mars gravity, before going full zero g. Like the article says, just make sure you have your ass pointed at the ground before they bottom out!
My pilot friend did this maneuver in a light plane (Cesena 172?) with me once or twice. It was cool to see my camera floating in front of my face for a few moments.