>if you do as the pilots want and achieve very high aerodynamic stability through the air-frame instead of stability control systems (fly by wire essentially) it reduces the aerodynamic efficiency of the airliner
It's crazy to me that that would be an acceptable compromise.
Fly-by-wire means the control surface actuators are connected to cockpit controls electronically rather than with hydraulic lines or metal cables; it's not necessarily related to stability and control augmentation system.
With regard to the other point, I don't think anyone is advocating for very high aerodynamic stability. That would be a B52 carrying nuclear weapons. It was designed to be extremely stable and forgiving. That being said, you don't want to rely solely on stability augmentation for trimming an airliner.
It reminds me of Air Canada flight 143, the pilots lost both engines and power. yet they were able to land the plane safely on an abandoned airport. I'm not sure if that would be possible with a 737 Max.
Yes it would. There are backup systems to keep things working even with both engines dry (ram air turbine etc). In fact, if you really want to stretch our a glide, all those automated systems are probably a good things. They will keep the aircraft more perfectly trimmed for a glide than the pilots ever could by hand.
If the electrical failure is severe enough to lose control authority, it seems just as likely that a hydraulic system would have failed. These planes are just too large to operate the controls mechanically, so in practice there is just as much to fail in a hydraulic system as electrical control, since both require power.
That is what the RAT is for, alternative electrical power. If the entire electrical system is down, ie electrons no longer flow anywhere anyhow, then everyone is doomed. But that is up there with the tail falling off. The are no backups for the wings/tail either.
When I say stability control, we're not generally talking about unstable or "relaxed stability" airframes where the system failing would cause a pitching moment to accelerate rather than converge and the aircraft would tumble and disintegrate. From an efficiency and handling standpoint, this would be ideal, but it's only used in tactical military aircraft where the crew can bail if there's a problem.
In most cases, we're talking about preventing stall in a swept wing aircraft. Swept wings are necessary to cruise efficiently beyond ~300mph at high altitude so they have to stay obviously, however they have VERY poor stall characteristics. As such, we have to do some things to prevent the aircraft from stalling such as playing with trim, using a stick pusher, etc.
> Swept wings are necessary to cruise efficiently beyond ~300mph at high altitude
Layman here, but 737, 747, etc. don't have swept wings, right? So they all cruise inefficiently... but are in fact stable... which is the opposite of what you wrote earlier? Sorry, I'm just really confused.
You're picturing a fighter jet or something with severely swept wings. Do an image search - 737s, 747s, et al do indeed have gently swept back wings. They don't stick straight out at 90 degrees like aircraft from the piston era.
I like the LAX screensaver on Apple TVs—you can pick out the more organic/bird-like curve of the newer generation carbon fiber 787 planes from the old ones. I’ve never thought about it, but they do look less stable.
From a stability perspective there's likely no difference insofar as the stall response will be bad regardless. You can have complex wing geometry that stalls gracefully, for instance carbon general aviation aircraft have similar traits but require much cleaner stall response for certification generally.
BTW since it's been tossed around a lot, good stall response is when the whole wing stalls at the same time and both wings tend to stall together, therefore you get a clean lurch downward in a straight predictable line. Bad stall response is one part of one wing stalling before the rest such that the wing drops and the plane has to be fought to avoid a spin or if extreme enough, a tail slide or extreme side slip.
Obviously stability has to be achieved through fly by wire tech. Doing it through natural aerodynamic stability is a waste of resources of insane proportions as such airframes induce more drag and burn more fuel. If this sounds too scary for people in a forum of software developers it only puts a shame on our profession, from ourselves.
The software itself isn't necessarily the issue, though- it's also all the sensors and actuators involved.
Suppose, for instance, that an aircraft needs more yaw stability.
There's all sorts of design choices that could be made, but consider either A: a larger vertical stabilizer or B: automatic application of the rudder to damp oscillations.
The vertical stabilizer here is essentially a bit of metal. We know very, very well what can go wrong with bits of metal. Fatigue, corrosion, manufacturing defects, bad repairs... But, in 2019, we've pretty much figured out the failure modes of big bits of metal on an aircraft, and we generally know how to prevent and/or minimize them.
Now, the dynamic stabilization approach. We'll need gyroscope data (from the IRS, probably), a software model of flight dynamics (which almost certainly already exists and is running), and possibly faster servo valves for the rudder actuator.
This can work! We can formally verify that the control system we've created damps oscillations throughout all normal flight regimes. The gyroscopes are already redundant and well-tested. And you might not even need the faster servos.
Problem is, now avionics failures are even scarier. Will the stabilization here still operate when you get dropped into secondary mode? Probably not- so now, in unexpected situations, pilots need to keep in the back of their minds that yaw oscillations are more possible, that they may need to damp them manually, etc, etc.
Now you throw in some extra factors- turbulence, IMC (which would probably make detecting those oscillations manually that much more stressful), and trying to solve whatever problem dropped you into secondary mode in the first place... and you have something a bit concerning!
A bit of metal won't do that to you. We can make much better estimates of a bit of metal's reliability, and its failures are also less correlated- they aren't much more likely to crop up when you already have another problem.
Well military jets have been doing exactly that - maintaining stability through software on inherently unstable planes that would break up even in straight and level flight in a split second if computer crashes - for 40 years now. And Boeing builds both kinds of planes so they have the experience.
No one knows better than software engineers how difficult it is to make inherently reliable software and how much complexity can add to the difficulty of making reliable software.
That said, the cost of not using latest fuel efficient airplane would indeed be huge and the actual reliability of modern aircraft is very high and has been increasing over the years in which fuel efficiency also increased.
Sometimes, human can hit on a formula that produces objects that satisfy all the given parameters more fully rather than compromising on any of the requirement. But it's quite plausible that these formulas cannot be milked forever - thus the "Max" may be the point where tradeoffs stop working.
Could you clarify your assertion that it would be massively more expensive?
A quick look at the numbers suggests that a 737 MAX 8 is about 10% more efficient on fuel burn compared to a 737 300. That is not "massive" in my book and I'm more than happy to pay a little bit more per ticket if it means a higher safety margin.
Did you mean something older and less efficient than a 737 300?
such airframes induce more drag and burn more fuel
As a curious bystander, I assumed using fly by wire tech to achieve stability would involve using control surfaces, which increase drag by their nature. How would an airframe that's naturally stable and doesn't require control inputs burn more fuel?
It's more about preventing a stall with a swept wing which is needed to achieve high mach numbers.
That said, an easy (but different) case to visualize is a traditional tailplane. The center of gravity on an airplane is in front of the wing so it wants to pitch down slowly. The tail pushes DOWN in the back to keep the nose up. Nose heavy planes are stable and forgiving but you induce drag because the wing needs to supply some lift just to counteract the tail which is producing negative lift. If you move the CG backward, you get less stability because the airplane wants to pitch up/down more violently with a control input but you have less negative lift from the tail.
That’s a great explanation, even if it is oversimplifying.
We don’t build planes with training wheels anymore because the performance cost was too high. Planes are still the safest way to travel even without the training wheels.
I don’t think 737 MAX 8 pushes the envelope too far. I think they screwed up on re-training the disengage, and they may have screwed up on redundancy by only using a single AoA sensor, but I also am guessing the latest crash has absolutely nothing to do with trim.
There are two alpha vanes on 737s, including the MAX 8, that measure angle of attack. Also we don't know the exact source of the error (in the Lion Air case; in the Egyptian Airlines case we don't know at all). The vane itself could be the source or some other part of the system.
It's crazy to me that that would be an acceptable compromise.