I'm wearing someone else's shoes every day so I can give you a quick feedback of my experience. I'm trans, blonde, pass relatively well and on the feminine side. I have seen a drastic shift in messages I get from people online. I regularly get mansplained obvious things about aviation, tech, coding on social media. People don't assume I'm the CEO of my company or that I have anything to do with engineering anymore.
Glad we hired someone else to do support for us...
It's an everyday occurrence during the development of our app (Infinite Flight).
We often get customers complaining about a misplaced sticker on a livery, a missing exit door in a particular variant of a the 737-900... That type of stuff is easily verifiable. But for things like the airplane not behaving in a way they expect in certain conditions, or perhaps a wrong approach speed or angle, discussions usually start with:
"We tuned the airplane based on information available to us at the time we built the airplane. We are happy to make any changes based on an actual report from one or more pilots flying on this airplane, or better yet, the aircraft manual if you can get your hands on one."
The discussion usually ends there :)
One we get often is about why it's possible to do a barrel roll in a jet liner in Infinite Flight. We simply point them to the video of that test pilot who did one in a 707 ;-)
Since a properly executed barrel roll can be a 1-G maneuver, it's technically possible in any aircraft.
The reason most aircraft are incapable of flying upside down isn't usually due to stresses on the airframe, it's because the fueling system relies on some form of force pushing the fuel through the bottom of the aircraft. A 1-G barrel roll does exactly that.
There's some interesting trickery done with carbureted aerobatic aircraft to let them fly upside down for an extended period of time, including special valves which shut off fuel flow to the bowls when gravity isn't in the direction they expect it to be, so the aircraft won't lose that fuel back into the fueling system (or out the top of the engine) and can run for a bit on that fuel in the carburetor bowls until the plane is righted.
>Since a properly executed barrel roll can be a 1-G maneuver, it's technically possible in any aircraft.
Although it's a low positive G maneuver it's not 1G, only straight and level flight is 1G, everything else requires a deviation from that to change direction. Wikipedia says it will vary between 0.5 to 3G throughout the maneuver which should be possible in almost all aircraft as it keeps fuel flowing and isn't a major stress on the airframe. It's probably even possible to do it at no more than 1.5G if you do it large enough so that it's even comfortable and not particularly noticeable for the passengers that don't look out the window.
That demonstrates that there are no negative G forces. It doesn't demonstrate that it's 1G.
I'm a private pilot who has done aerobatics, exactly 1G doesn't work - and it's completely unnecessary (though you can stay pretty close to it, so that someone with their eyes closed would not know they were rolled).
But just about the video as "proof of 1G":
As long as you stay positive you are fine, even psychologically with passengers not used to it. The real turning point, in real effects as well as psychologically, is when you approach 0G, the feeling only starts at less than 0.5G when you begin to feel more and more weightless.
When you go even slightly negative it becomes a completely different matter, both in terms of real effects (fuel, oil, lose stuff flying around the cabin) as well as psychologically: Even though you made the harness extra tight with as much force as you could muster in preparation for an aerobatic flight with negative G forces, when you get here it feels as if you hang upside down in the harness and the seat is miles away from you, as if you dropped a few centimeters and now literally just hang in the airplane.
I (in my small and somewhat underpowered aircraft) go below 1G when I get close to the top, because if I tried to maintain 1G the nose of the airplane would have to drop (towards the earth in that position), and I want to keep that at a minimum, so that I don't end the roll with the nose in too much of a nose-down attitude from which I will have to pull out.
EDIT: (after reading some comments) To me a roll is over when the airplane is back to straight and level, after 360 degrees. So my statements are for that interpretation of the word "roll". And my frame of reference for g-forces are the people on board the aircraft.
But as the video demonstrates quite well, the first phase of a barrel roll requires pitching up into a gentle climb. This is physically impossible without exceeding 1g at any point.
I love that video. I've got an autographed pencil sketch of Bob's P-51 (autographed by both the artist and Bob!). And while watching him fly, the only explanation I could come up with that explains how effortless he makes it look is that he was actually a bird in an earlier lifetime.
Physicist here. There is no law of the universe that prevents flying an absolutely perfect 1G barrel roll. Maybe those numbers are assuming perfectly steady thrust and a constant angle of attack, or true circular motion? That's the best I can think of.
If you maintain exactly 1 gee, then the moment your lift vector deviates from vertical you'll begin to accelerate downward, since the vertical component of your lift vector will no longer cancel out all gravitational acceleration. At the end of the maneuver you're going straight and level again, which means the vertical velocity you built up needs to be eliminated. The only way to do this is by accelerating at more than one gee for some period of time.
You can stay arbitrarily close to 1 gee, given unlimited time and altitude, but you can't stay exactly at one gee throughout a barrel roll.
Here's the difference, once the plane's wings are level with the horizon, the roll is considered to have been completed. The rest (regaining a stable pitch) is recovery.
Yes, you are correct that the aircraft's velocity is not maintainable after the maneuver has been completed, and must incur positive G forces to regain level flight, but it's not technically part of the barrel roll.
EDIT: As I noted in another response (in which I go into a lot more detail), the pilot probably doesn't even have to take any action to negate the downward velocity component; the change in the angle of attack (the angle at which the wing intersects with the airflow) would naturally increase the amount of lift being generated by the wing, at the cost of more drag.
I don't think that's quite right. A barrel roll is supposed to be entered and exited in level flight. But I think we both understand what's going on, so that's just a dispute over where to draw an arbitrary line!
I suppose it's high-school-physics possible to fly a 1 gee helical path (the "barrel roll") centered around an orbital zero-gee trajectory...
Imagine for a moment a zero gee orbital trajectory at a low enough altitude that you can still generate aerodynamic lift from the atmosphere. (Here we handwave away all the pesky frictional heating, because we're deep in the thought experiment world of perfectly spherical cows of uniform density.) Now imagine a helical "coil spring" shaped path with that orbital trajectory running through the center. "All" you need to do is get the diameter and spacing of those helical coils right so your acceleration around the coils needs to be 1G, while your averaged out path coincides with the orbital zero gee trajectory.
<grin>
(An aircraft with sufficient speed, fuel capacity, heat shielding, and whatever else I've glossed over - is left as an exercise for the reader...)
I just thought of an easier (and probably achievable) thought experiment.
Imagine a fighter jet flying circles around an airliner as it follows it along - with the fighter pilot flying at just the right radius and speed that it's accelerating at 1 gee for the turn (so they'd be "feeling" 2 gee as they pass under the airliner, and zero gee as they loop over the top of the airliner) using a helical "barrel roll" path - and at the same time "keeping up" with the airliner along it's path, so if you were sitting in the airliner looking out it'd look like the fighter was flying circles around the long axis of the fuselage.
Now imagine the fighter pilot does the same trick following the vomit comet - as it flies its parabolic arcs which gives it's occupants 20-30 secs or so of "zero gee".
However, if you keep flying 1G after exiting that parabolic barrel roll, you're going to make a hole in the ground. The vomit comet usually does a 3G pull up afterwards. You've got to exceed 1G, either to enter the parabolic arc from level flight, or to leave it to regain level flight, or more likely, both.
You're neglecting two potential sources of upward acceleration. One, the turn itself, or in other words air resistance: if you stop turning when you're pointed straight up, clearly you're going to go up, not down (at least to start with), which means the turn accelerated you upward. And two, any forward acceleration provided by the engine while "forward" isn't horizontal.
(I don't know enough about aerodynamics to actually determine how a barrel roll actually works, though, only enough to contradict your post :)
I'm not addressing any sources of acceleration. I'm only looking at the final acceleration vector. If the magnitude of that vector is 1 gee, then there are only two possibilities. One is that it perfectly opposes gravity, resulting in zero net acceleration. The other is that it doesn't perfectly oppose gravity, resulting in downward vertical acceleration. It is not possible for a 1 gee acceleration vector to result in upward vertical acceleration, regardless of what causes the acceleration.
Given that "1G" is here defined as "in the vertical plane of the aircraft", no it's not, unless you're willing to accept a permanent vertical delta-V (which, as a pilot, you aren't.)
You know of a path that keeps the acceleration 1G and pointing downwards at all times? Or you mean 1G in total acceleration that can point in any direction? I'd be curious to see a reasonable path for the second and don't see how the first can be possible (and 1G usually means more than just an acceleration vector of length 1 otherwise we wouldn't talk about negative G).
Nobody is talking about a gravity vector pointing towards the center of the earth during the entire maneuver. The implied assumption, I believe, is 1G towards the floor of the plane at all times.
This is quite easy to do when you realize that the plane can (and will) lose altitude and transfer ground-relative horizontal momentum for the vertical.
>Nobody is talking about a gravity vector pointing towards the center of the earth during the entire maneuver. The implied assumption, I believe, is 1G towards the floor of the plane at all times.
I mean downwards towards the floor of the plane of course, not the center of the earth. mikeash has already explained much better than I could why you can't keep 1G from the point of view of the passenger and do a normal barrel roll from/to level flight. It seems easy to have a path that does it if you allow it to finish in descending flight.
Maneuvers are always from the reference frame of the passenger. If a passenger is feeling subjectively to be in 0G, it doesn't matter what their acceleration is compared to any fixed reference frame.
The second is an aileron roll done purely with the ailerons, engine and tail, not using the lift generated by the wings. Not all planes can do it because the engine needs to be very powerful to support horizontal flight, and the wings need a neutral airfoil shape to provide lift when upside down.
Trying to come up with a better explanation for the first.
EDIT: Try this on for size:
Given - the force imparted by the wings is 1G (enough to cancel the force of gravity), and will always be pointed straight through the roof of the aircraft. The pilot takes no action to increase the amount of lift. The G's are measured from the frame of reference of the passengers in respect to the aircraft. Rotational forces are not considered - most people are unable to kinesthetically perceive any rotation which occurs at less than 5 degrees per second, and don't realize that they could be upside down and still feeling like they're right side up. It's why instrument training involves so much instruction and reminders to trust the instruments, not your body.
The maneuver is initiated by rolling the plane (clockwise, with respect to the pilot) with the ailerons. Since no effort is made to change the amount of force being generated by the wings, the downward component of that thrust (as measured from an external reference point) will lessen, allowing the aircraft to start accelerating downwards while also accelerating to the right. The force felt by the passengers is still exactly 1G - the force created by the wings, and it is still pointed vertically through the plane. Since the downward component affects the passengers and plane equally, there is no measurable effect on the G forces with respect to the passenger's frame of reference.
The aircraft reaches 90 degrees, and is accelerating to the right at 1G, and downwards at 1G. The downward force is not felt by the passengers, again because their entire frame of reference is accelerating at the same speed, only the force pushing them into their seats.
The aircraft reaches 180 degrees, and is now accelerating at 2Gs downwards. Passengers are still feeling only 1G of pressure from the seat.
270 degrees - the acceleration to the left cancels out the previous acceleration to the right, passengers are still being just pushed into their seats.
360 degrees - the maneuver is complete. The plane is significantly lower and some distance to the "right" of its original position. Their velocity now includes a significant downwards component.
Now here's where things perhaps become a matter of semantics - pilots would consider the barrel roll to be completed at this point, and they simply need to recover from their new orientation. Of course, this will probably require little to no input from the pilot, it will simply happen naturally due to the changed angle of attack induced by the downward motion increasing the lift generated by the wing.
It depends on your frame of reference. If you're on the space station, are you falling down with 1G of force? Yes, but so is everything else around you, so we consider this to be effectively weightlessness.
An aircraft which is freefalling will be experiencing 0G's in that downward direction, but if the aircraft's wings are creating 1G of force perpendicular to the force of gravity, the only forces experienced within the frame of reference of the aircraft is that 1G sideways.
I read something similar in John Boyd's biography (highly recommended) about the barrel roll as well. I assume they mean it can be done while keeping the plane in a 0.9-1.1G window or something along those lines. In other words in can be done in a way that if you closed the blinds on all the windows and did it in a commercial flight full of passengers no one would complain or even be able to tell.
I had a beer with a B-1 Lancer pilot who was here on exercises many years ago. He said that on low level flight infiltration exercises, his normal method to go over ridge lines and small hills is to pull the aircraft gently up, roll it inverted and pull back while cresting the ridge, then roll upright once over.
He said he is experienced enough to maintain 1.0 to 1.5G throughout the manoeuvre, and the most of the time, the weapons guys in the back of the plane who are usually 'heads down' and don't have big windows to look out of, don't even realise they were inverted for 10 to 15 seconds.
He said he has a standing wager with them when they land, and if the back seaters can accurately tell him how many ridgelines they crested inverted correctly, he buys them a beer. He told me he hardly ever has to buy.
We humans are pretty funny. The sensitivity comes a lot from what the eyes see, the hands feel and what we expect to happen from what the experience tells us (stick movement and such). Only a small ammount of it comes from the inner ear balance sense.
Try standing on one leg. Then close your eyes. Or try walking in a very dark but not completely black room. And then close your eyes. Your balance sense might tell you very strange things and if you haven't trained for this, you might fall.
Below a certain threshold, somewhere near 5 degrees a second, your inner ear can not sense the rotation. It's why you need instruments when flying without visual cues.
Oh, it can also tell you you're tumbling wildly when you are actually going completely straight. Really disorienting.
> everything else requires a deviation from that to change direction
Well, kinda. The trick is that you have 1G downwards constantly, which can be reduced by initiating a descent at the same time you introduce other directional changes. Rotation (the major component of a barrel roll) does not impart G forces, as recognized by the term.
I'm sure few to zero pilots who can keep it at 1G exactly throughout the maneuver, but it is at least theoretically possible (so long as you don't mind losing altitude via the maneuver).
>Well, kinda. The trick is that you have 1G downwards constantly, which can be reduced by initiating a descent at the same time you introduce other directional changes.
This isn't possible. In straight and level flight you are experiencing 1G acceleration. To be able to change the plane's orientation in any way you need to impart some acceleration to it and thus deviate from the 1G. For example initiating a descent requires an acceleration downwards which will be felt by the passengers as less than 1G. If you finesse it enough and do it big and wide enough you can probably maintain it within a tolerance for what we consider to be 1G but it's not possible to stay at 1G exactly.
In any realistic scenario it's of course only possible to stay within some threshold around 1G. But why would it be theoretically impossible? If I drop the nose down slightly I reduce downward forces to say 0.95G. In the same manouver I accelerate left with 0.31G. Since 0.95^2 + 0.31^2 = 1^2, I still have a net force of 1G on the aircraft. In theory it should be possible to compute a path that keeps me at exactly 1G at all times.
You can indeed, in theory, start a descent while maintaining exactly 1 gee. But you can't stop that descent without exceeding 1 gee. The best you can do is to maintain your current vertical velocity.
I understand 1G as also requiring the vector to be pointing down on the aircraft. If you allow it to point in any direction as long as the vector has length 1 passengers will notice and not all mechanical parts will be guaranteed to work so the fact that it's technically 1G is not enough to guarantee any airplane can do it. I think that's not the usual definition of 1G either as we even talk about negative Gs (and airframes are particularly sensitive to them) which wouldn't make sense in that case.
But it would be cool to see if there's a theoretical path that we can recognize as a barrel roll than keeps exactly 1G of acceleration in any direction needed.
By smoothly transitioning into the turn as you roll. The simple act of rolling the aircraft doesn't change the amount of lift being generated towards the roof of the aircraft. In fact, if you don't increase that force intentionally, you will turn and lose altitude.
I don't think this is correct. There's a constant 1G force; you can adjust for the difference necessary in angular momentum as you turn. Sure you won't be perfectly level in the same way have a constant rotational velocity would be but it's still a barrel roll.
Of course, it would point in a different direction, but the magnitude would be 1G.
Hell, i think you could easily develop an intuition for it.
The 1G is from the frame of reference of the passenger. Gravity's effects are essentially nil for the passengers (and the aircraft itself), since everything in the aircraft is accelerating in the same way at the same time. You only really feel the force of the lift generated by the wings.
Electrical planes have a weight issue with the need for batteries (or humongous wings covered with solar panels). Petroleum products, for better or worse, still have a huge advantage in the energy/weight department.
How does the fuel get from the tank to the jet or fuel injected engine when the pickup is on the bottom of the now upside-down tank?
There are ways to ensure fuel delivery, but the problem certainly isn't unique to carbureted engines, only the particular issue of managing the fuel in the carburetor bowl.
In "toy planes" we (used to) use "clunk tanks", where the fuel pickup is a piece of flexible tube with a weight on the end, so no matter what orientation the airframe is in, the "sloshed fuel" and the fuel pickup end up in the same place (near enough). For aggressively aerobatic model planes (like control line combat wings) a pressurised fuel bladder was sometimes used (made, back in my childhood, we made these from baby pacifiers!)
Note: this is a couple or more decades old knowledge... Modern electric powered rc planes and builders don't have this problem to deal with.
The issue is a non issue. For ages in planes, race cars, etc we have had fuel cells. A few types exist, from just adding more baffles and pickups with vapor locks, to fuel bags (no air to make it to pickup) or the more modern foam matrices that use capilary effect.
As I said. There are ways to combat the problem, but the above comment that it did not apply to jet engines or fuel injected engines did not take into consideration the requirement that the entire fuel system be able to operate at low or negative G's
Boeing also did a near-vertical take off in the 787 during their initial tests (and a few times after at air shows) This video [1] from a past Paris air show, shows a 787 ready for a delivery to Vietnam Airlines doing a very aggressive & short (but not vertical take off). Pretty ballsy to do such a thing in such an expensive jet that's on its way to delivery to a client.
According to comments, it was nowhere near vertical, which is why they didn't show it from a side angle. Apparently indicator light goes off at 30 degrees, indicating imminent engine stall.
I'm assuming you mean angle of attack, not flight path angle. The aircraft could certainly be capable of a 60 degree climb until it slowed down enough that it couldn't maintain a low enough angle of attack. It probably could only sustain something less than a 30 degree climbing flight path angle (while empty), as that would be pushing the limit of the thrust to weight ratio. That being said cameras can be used in ways that make things look much more dramatic than they actually were.
As a side note, at 30 degrees AoA the aircraft will not be able to continue flying anyway, the wings will have stalled well before that, and the pilot would be made painfully aware of this fact through stick shakers, aural warnings, and very rough tail buffet.
I'm a flight test engineer, so this stuff is what I get to do for work! :)
The video is filmed from a distance using a long telephoto lens, compressing the perspective. The 2011 movie Tinker Tailor Soldier Spy used the trick in a similar scene to a great dramatic effect [1].
One of the characters is trying to get information out of the other by threatening him with being put on the plane, which, it's implied, would take him to an extremely disagreeable destination.
(Unintentionally reduced spoilers due to having forgotten many details of the film.)
Yes. The staring man (Smiley, played by Gary Oldman) is looking for a spy in his organization. The man being stared at is worried that Smiley is going to kill him (by putting him on the plane). The audience feels the same anxiety by proxy, because it appears that the actors are about to be hit by the propellers.
Look again at the actors. Smiley never stops studying the others' face, while the other looks scared, nervous, shifty, and guilty the entire time. Even without context you should be able to pick up that Smiley is cool as ice, and that the other man has something to hide.
I think you are referring to the "Pitch Limit Indicator". This is not exactly a light, it's two yellow bars superimposed on the artificial horizon.
The PLI is capped at 30 degrees pitch, but that does not mean that the plane would stall at 30 degrees. You could climb much steeper than that if you had enough speed:
> However, the PLI also is limited to 30 deg of pitch attitude, regardless of AOA. If AOA or AOA margin to stick shaker were to be used as the first and primary focus of the flight crew during windshear escape or terrain avoidance procedures, extremely high pitch attitudes could be reached before stall warning if the maneuver is entered with sufficient speed. Therefore, the PLI shows the lesser of either margin to stick shaker, or 30 deg of pitch. (http://www.boeing.com/commercial/aeromagazine/aero_12/attack...)
Boeing also released a video of the pilots rehearsing the routine. There's an overhead view of the takeoff - that's a lot steeper than 30 degrees, unless it's a perspective trick.
EDIT: 50-55 degrees seems to the actual pitch angle.
One of the videos I saw of the test planes appeared to be well above 60 degrees. Agreed, not vertical, but far more vertical than a standard airliner. Also, they only maintain the aggressive angle of attack for a very short time, which may lead credence to an engine stall, or an imminent engine stall.
Please state clearly and plainly that it is your assertion, as a claimed expert pilot and aerospace engineer, that a stock 787 as shown has enough thrust to achieve vertical flight, as you are strongly implying in your comment. Thank you.
The sub is actually already rigged to keep most loose things under control even under normal running... with any advance warning (most emergency blows are planned ;-) everyone has the time to secure things in lockers etc.
That said, standing on a vinyl tiled deck in the peak angle point of one is a trip!
If we get a strange claim like "The 737 at MLW should have a stable approach speed of 170kts, with 70% N1 and 5 degrees of pitch", then asking for a source of information seems pretty reasonable here...
They usually don't find it because it is based on "shower curtain" type of sources. ("my brother told me", or "this other sim behaves this way")
Tell that to a pilot who's had an autopilot failure where a servo went crazy all of a sudden. You better act quick, especially in low visibility situations, to turn it off, or pull the circuit breaker.
It might happen a bit slower than in a car, but the consequences can be much more dramatic.
How are the consequences much more dramatic while flying? I can think of plenty of scenarios while driving where you go from perfect autopilot conditions with no visible risks to death of passengers or pedestrians in <5 seconds.
Errm, I'm pretty sure the car equivalent of that would result in the vehicle swerving towards the side of a bridge at 70+ MPH, with very little chance of reacting quickly enough to turn it off. A car on the highway really doesn't have that much in the way of safety margins.
Even if the plane started falling down like a rock, you still have more time to react than a driver of a car where a tyre burst at 80mph and now the car is heading towards the incoming lane/rock face on the other side. You literally might have less than few seconds to impact and I imagine that if you weren't holding the steering wheel at the time, you won't be able to do anything.
Pilot here as well, unfortunately, it's a fight that won't be easy to win. If in the mind of people, Autopilot means self driving. It's going to be hard to change the global perception.
When I'm using the Autopilot, I feel like I'm in my airplane, always on guard, and in a practice of recovery from unusual attitude in flight.
There are a few times also where being an engineer has helped a lot. You can pretty much predict the situations where the car will run into issues and conflicts ahead of time, just by looking at the scenario in front of you.
It's something that the majority of population is not trained to do.
Now having said that, I used to own a BMW X5 with Adaptive Cruise Control, and that car was also doing some pretty stupid things at times, especially when cars in front were moving out of the way. The car would suddenly think the way was clear and floor the accelerator...
Have a RAV4 2016 SE. Great car, sonars and cameras everywhere but still very stupid driving at times. I don't mind it, because it keeps me alert to take over at moments notice.
I really want to hack the can bus and give it more smarts. What is the legality of that?
You are freed from continually making stupid rote inputs to match the speed of the driver in front, allowing you to apportion a bit more focus to the road further ahead.
Further, it makes the bulk of motorway driving less fatiguing. When you're not having to personally intervene to slow down when the driver in front chooses to go a few kays slower than you, it's nowhere near as irritating.
Agree with parent. Unfortunately for your profession "Airplane!" the movie ruined the perception. When I read "autopilot" I think robot guy driving airplane without any intervention meaning I can sleep from takeoff to landing.
Have you updated that phone regularly? I have one for testing here, and it's become so slow, I don't even know how one could use it every day... Even if they bring back removable batteries, software updates will take care of the deprecation. Just look at an iPad 2 with iOS9 today...
Same reaction here... they made me feel guilty about using adblock, I was nice enough to disable it, then that unrelated video kept on playing, and they popped up another message saying thanks...
Who's in charge of this? ugh...
So happy for Miguel and Nat. We worked with Xamarin when we ported Infinite flight from Windows Phone to iOS and Android. We wouldn't be there if it wasn't for them.
One thing I'm really looking forward to is efforts on the QA front. I'm scared to update every time as things are frequently broken, especially on the iOS side.
This is mostly the feeling I get from reading those articles about lousy sale on iOS.
It has become too easy to write those types of simple games, what are those guys expecting?
It's a known fact that if you write such a game in a few weeks, it will most likely not generate any money.
Yeah, I wrote this game Orb (http://joeblau.com/orb./) In 3 days for iOS and Android. I didn't put any money into marketing it, but I did promote it. I made my game to test the effectiveness of the Apple Store vs the Play Store vs the Amazon store for an app with minimal publishing. I've definitely learned a lot which I'll probably blog about soon.
Do you have more info about the airplane performance? I'm working on a flight simulator and this plane is one of the 747's we're going to add.
I'd love to get more details about the differences compared to a regular 747SP.
Many free apps on the store who can get away with charging outside do it. Uber, Banks, etc...
Why can they use Apple's IP for a flat $99/yr and others don't? It's not a fair system. Paid apps are essentially subsidizing the free ones.