Talk:Ethiopian Airlines Flight 302/Archive 2

This is an archive of past discussions. Do not edit the contents of this page. If you wish to start a new discussion or revive an old one, please do so on the current talk page.

Archive 1

Archive 2

Archive 3

Archive 4

Additional comments, Prelim Report

"We need someone else to draw the conclusion from Boeing manuals to avoid it being original research afik. Thoughts??"

I agree that we need WP:RS cites for any informational statements put in the article. It takes a lot of time to find good sources on the Internet that can be used, but I don't have excess time of my own to do that research, so it will have to be done by other editors. When I comment about how such systems work, I do so to help other editors to know what to look for in their research quiries, which is required to satisfy the WP:RS rule.

"I think we are all seeing that overspeed is a key factor here. Whether it turns out to be a primary or contributing cause remains to be seen."

I agree, the excessive high speed greatly reduced their ability to get the HS back to where it should have been, for normal flight. However, as to that pilot error (to properly control the speed) being classified as Primary or Contributing, we will have to wait for the final report. I do not recommend any editor inserting statements like that even if a WP:RS source can be found prior to the Final Rpt being released, since it would be irresponsible for any press article to make statements like that, EVEN IF the source is one that has traditionally been treated as a Wiki RS for other issues.

"...could find no reference to position of the "arm" switch or anything else about airspeed and AT other than the original text quoted, after left Autopilot was engaged, "at 05:39:42, Level Change mode was engaged. The selected altitude was 32000 ft. Shortly after the mode change, the selected airspeed was set to 238 kt." From the data both left and right N1% seem to stay above 90% as best I can eyeball it until the final sharp dive commences. The more I have looked into this it seems the most glaring issue - was the AT in fact on or off (and when), did the pilots know the AT actual state, and if it was on why did it not throttle back when 238kt was exceeded? Sounds like this needs to be addressed. I don't see any obvious edits to the article (since it would be original research) so if anyone has any ideas please say. Otherwise, we wait. Greenbe (talk) 00:52, 25 April 2019 (UTC)"

The AT switches HAVE TO BE IN THE 'armed' position for the ATs to be engaged. If those switches are in the off position, then all thrust changes can only come from manual movement of the thrust levers by the pilots.

IF the ATs were in the TOGA mode originally, they would have remained in that mode "IF" the button was not punched after the pilot dialed in the airspeed of 238kts. THAT is one possible explanation. The other is that they selected the "Level Change" VNav mode, to command the plane to climb to FL 320. IMHO, that was improper because that mode is a "pitch" mode, not a speed mode. The result is that the ATs did not pull back at all, since there still was no command to reduce thrust.

"Six seconds after the autopilot engagement, there were small amplitude roll oscillations accompanied by lateral acceleration, rudder oscillations and slight heading changes. These oscillations continued also after the autopilot was disengaged."

Those lateral movements could come ONLY from the pilot moving the rudder pedals (though yaw dampers can move the rudders, their authority is very limited and usually only comes into play at cruise altitudes, IN RESPONSE TO detected yawing which can occur in all swept-wing aircraft at high MACH speeds). The APs are NOT connected to the rudder during regular, normal AP operations. ONLY when the two or three APs are ON and BOTH FCCs are engaged and comparing data, during a CAT III AP approach, will the APs command rudder movements too.

"I presume he had difficulty reaching even the column trim switches, as he later asks the copilot to try trimming: At 05:41:46, the Captain asked the First-Officer if the trim is functional. (Likely he meant column trim, but this is not confirmed.)"

I think neither of the yoke trim switches worked then, because that was AFTER they had turned off the two pedestal switches, and BEFORE they had turned them back on again. Once they turned them back on again, they COULD HAVE saved the plane "IF" they had continuously trimed ANU until the HS was back to the proper position, AND THEN turned those switches OFF again, while manually pulling the thrust levers back to idle trust position. Why they did not do that is a mystery to me. If it was because of "pilot overload," then I would attribute that to a great deficiency in proper training of how to deal with a "runaway stabilizer" emergency, regardless of why it was happening. IMHO, the MANUAL trim would not work because of the excessive high-speed air load on the HS.

"Before Mcas activated, they already had AP induced oscillations..."

How can anyone know that was caused by the AP?

"Struggling to fly straight and level, the pilots became overloaded or startled. Misleading and contradicting warnings confused them and they lost overview of the situation."

I think that is a reasonable speculation. The most important question then, is "WHY?" My answer is that their sim and ground school training was terribly deficient. The more experience and training a pilot gets, as to possible emergency situations and how to handle them properly, the less likely they will be overwhelmed and unable to make proper decisions at critical times, even when the pressure piles on them. BOTH of the MAX crashes would not have happened, IMHO, if those pilots had been properly and thoroughly trained on how to handle that kind of emergency. EditorASC (talk) 18:18, 27 April 2019 (UTC)

"About why the overspeed warning went unnoticed, I can only guess any of: 1) panic and fatigue caused tunnel vision 2) stick-shaker and repeated nose-down pitching suggesting low speed, thus ignoring airspeed as unreliable 3) reliance on AT, expecting it to be engaged."

Why do you think it went "unnoticed?" That is an assumption which won't stand for pilots that have considerable experience in flying jet aircraft. As the actual speed increases, noise level in the cockpit also increases. If a pilot suspects his IAS is giving erroneous information, that does not mean he thinks the plane is at low speed while the cockpit sound level has increased significantly, consistent with very high ACTUAL speed.

"Repeated nose-down pitching suggesting low speed."

Not to an experienced jet pilot. To the contrary, the speed effect of gravity on jet aircraft is incredibly powerful. That is why pilots can keep increasing the speed during descent from a cruise altitude simply by lowering the nose by only 2 degrees AND -- even though the thrust of all engines has been reduced to flight idle.

The overspeed clacker sounded for over two minutes, until the end of the FDR recording; the left IAS reached 458 kts & the right IAS read 500 kts.

"reliance on AT, expecting it to be engaged."

Since N1 of both engines remained at 94% the entire flight, either it WAS still engaged in the TOGA mode, OR the pilots had advanced the thrust levers manually to TO thrust, and never adjusted the thrust levers after that.EditorASC (talk) 19:49, 28 April 2019 (UTC)

@EditorASC:

"I think neither of the yoke trim switches worked then, because that was AFTER they had turned off the two pedestal switches, and BEFORE they had turned them back on again."

I should have cited the line before the cut-out: "At 05:40:27, the Captain advised the First-Officer to trim up with him.". This 10 second trim ends with the cut-out.

"Once they turned them back on again, they COULD HAVE saved the plane "IF" they had continuously trimed ANU until the HS was back to the proper position, AND THEN turned those switches OFF again, while manually pulling the thrust levers back to idle trust position. Why they did not do that is a mystery to me."

Note: there is agreement that the cut-out happened, as the cvr recorded the correct procedure: "At 05:40:35, the First-Officer called out “stab trim cut-out” two times. Captain agreed and First Officer confirmed stab trim cut-out.", but the pilots turning the cut-out back on is only a "likely" scenario, based on circumstancial evidence: "At 05:43:04, the Captain ... said that pitch is not enough. At 05:43:11, two momentary manual electric trim inputs are recorded in the ANU direction."

There were longer inputs before, so these two inputs seem irrational. Did the pilot's thumb switches fail? He asked the copilot to trim before for some reason. Or the trim motor was stalled, and he gave up trying? 5 seconds later the Mcas activation caught them off-guard, 5 more seconds and they fly up from their seats, column back-pressure decreases. A lot happened in these 10 seconds that decided the fate of the airplane, and there is very little information about it.

This was much more than a runaway trim. The Mcas failure is different in crucial points:

Runaway Trim is stopped by the TRIM COLUMN CUTOUT switch in the 737 NG when the pilot pulls enough on the yoke^[1], giving time to resolve the issue. Mcas overrides this switch by design: it's purpose is to increase the necessary back-pressure to pull back the yoke when AoA is high (and the lift generated by the big engine nacelles create significant pitch-up force). Sources I read also say "in turns", therefore the weird name of "Manouvering Characteristics" and not "Pitch" or "Stall Characteristics". There is no software failsafe built in to limit or disable Mcas with extreme column forces.
Runaway Trim is continuous, easy to identify. Mcas can confuse the pilot: stops after 10 seconds or electrim trim inputs, but starts again after a delay of 5 seconds.
Speed Trim System present in the 737 NG operates the trim at low speed (0.6 degrees per second) when flaps are up. Mcas always at high speed (2.5/s), regardless of flaps, airspeed, altitude, pitch. It takes 40 seconds from level flight to nose-down, with the effect slowly building up, delaying reaction.
The 737 NG has separate trim cut-out switches for electric trim (pilot) and automatic trim (AP/STS, Mcas on the Max). A mistrim can potentially be fixed without re-enabling the faulty automated system.

The runaway trim was only the second issue, preceded by "flight control problems" that started a minute earlier. The report only states "small amplitude ... oscillations", and the articles I read do not go into detail either. Based on the acceleration graphs from the FDR I think the pilot had serious trouble controlling the plane even before the trim runaway. After the runaway was stopped it took about a minute to counter the oscillations with both pilots holding the yoke.

This was a failure mode possibly unknown even to Boeing. I believe experienced pilots, who have been in a real emergency, or very difficult simulator trainings, thus able to keep composure would have been able to save these planes, but many pilots would become the victim of this emergency. Not all pilots are fighter pilots.

"How can anyone know that was caused by the AP?"

Right. I've rewritten to express more explicitly the whole interpretation is one possibility/speculation.

"The most important question then, is "WHY?" My answer is that their sim and ground school training was terribly deficient."

Another answer is that one of the primary design targets of the Max was minimal pilot training costs, thus no simulator training or documentation for Mcas failure modes, which have less failsafes, but many times more authority than AP/STS trim. This design principle goes even deeper: many design compromises led to the creation of Mcas in this way. It uses a critical flight control just to make it harder to pull on the yoke, instead of safer alternatives: The Elevator Feel Shift module or a stick pusher. Mcas would not even be necessary if the landing gears were taller and the engines under the wing, but that would require a re-design of the fuselage and possibly different type certificate. There's a series of causes, some of which affect more passengers than the training procedures of one airline.

For me the important question is how the "human-machine interface" can be safer for resolving such situations. While researching this accident I was surprised to realise if some instrument fails there is no logic in the FCC to identify the source of the fault. All it does is disconnect the AP, and leave the pilot with confusing readings. In these accidents the confusion was compounded with misleading disagree lights (the raw airspeed and ALT readings were the same on both sides, only the ADIRU computed values differed), and the lack of the real cause, the AoA disagree light (economic decision). With proper checks in the FCC these misleading warnings can be eliminated. In many cases (like ET302) the failing sensor can be identified from the impossible jump of the value. The pilot should be able to switch over to the other sensor, thus disabling the erroneous stick shaker, reducing stress significantly.

Going further, I could hardly believe how the Mcas behaves. From the top of my head I've listed 7 safety constraints in a previous answer, all of them missing from the original Mcas... The software update statement^[2] mentions only one (disagree) of these, and 2 more I did not list.

There's a lot that can be done to prevent this accident in design and training as well.

"Why do you think it went "unnoticed?"" [the overspeed warning]

The report doesn't show either the pilot or the copilot calling out speed readings or the overspeed clacker, but it shows the copilot noticed Master Caution: "At 05:42:51, the First-Officer mentioned Master Caution Anti-Ice.", a more subtle warning. Why overspeed is not mentioned, then? The report skipped many parts of the CVR, but if there was an overspeed callout, I would expect it to be included, unless left out intentionally. Is this a sign of tunnel-vision caused by the overload or shock of pilots? Or they haven't been in an overspeed simulation, and did not recognize the meaning of the clacker?

— Aron Manning (talk) 03:27, 30 April 2019 (UTC)

"I just came across this ^[3] I downloaded a copy before it too "disappears"."

@Greenbe: You can read the original article^[4] on linkedin. Well written and thorough, but rushes to a judgement, while ignoring the unexplained mysteries, the human factor, and most importantly an engineering review of the erroneous Mcas system and the brand new sensors that failed. He is a B787 pilot, thus his loyalty to Boeing is understandable. He also "provides investment research and analytic support for investors in the airline and related industries"^[5] at "Ionosphere Capital", so there is a conflict of interest. The gaps he jumps over might reveal great lessons on the "Human-Machine Interface", pilot workload limits and cockpit psychology. Apart from that the timeline is a valuable work. It's also worth to look at the comments for more balanced interpretations.

IMHO talking about the mistakes of pilots is acceptable and respectful as long as it is not a judgment. To make mistakes is human, especially in a life-threatening situation. Judging these mistakes from our comfort would be pretentious and disrespectful, but understanding them is necessary to learn the lessons. The problem with the phrase 'pilot error' is: it's strongly attached to a final judgement that ignores all other errors. It reflects a very limited view on reality, as all accidents are an accumulation of errors. Ignoring the non-pilot errors would be unjust, and dangerous for future flights, as these errors will resurface sooner or later, when all the contributing factors are present.

"What I was trying to get at is whether the overspeed situation was a result of the plane's automation fighting with itself or the pilot's actions (or inaction)."

@Greenbe: IMO the simplest - but possibly not the right -, answer for the uncontrolled speed is mental overload, or shock. As I imagine the cockpit environment, the pilots were fighting for survival, and all their focus was concentrated on leveling an erratically flying plane. Possibly the copilot wanted to enable A/T SPD mode after selecting 238 kts, but was distracted or did not push the button properly as the cockpit was quite bumpy. Throughout the flight it was hard to judge the speed with the unreliable airspeed indicator, the up-down fluctuation, and the stick shaker's rattle shadowing the overspeed clacker. Possibly the pilots 1) did not notice the warning, or 2) ignored it as unreliable. For me the question is 1) what events caused such tunnel vision and why they lost awareness of speed, or 2) what did they see on the instruments, and what they read into it. The prelim report curiously lacks any communication concerning speed, possibly only the final report will reveal more.

"The lack of speed control is very troubling and would seem to have fallen victim to inattention due to pilot distraction/workload. The pilot not flying (pilot monitoring) should have been alerting the pilot flying repeatedly over the excessive speed, yet this report makes no mention of this advice, and even when overspeed."^[6]

"When a pilot experiences a stall warning like a stick shaker, his reaction is to lower the nose and increase the speed. He wants to build a margin to an eventual stall. If he simultaneously has “Unreliable airspeed” warning, the built margin will be larger. In both of these cases, the pilots are flying faster than normal at the low altitudes they flew (5,000ft pressure altitude for JT610, 9,000ft for ET302). This is to build a safety margin while sorting out stall warning and flight control problems."^[7]

"The throttles are left at 94% thrust for the whole flight. This is higher than normal but this is a high takeoff. At 7,600ft it is a full 2,200ft higher than Denver, which is the US Benchmark for high takeoffs. And with Stick Shaker and IAS disagree you keep high thrust and fly a slow climb ..."^[8]

A Senior Captain commented on the article Greenbe mentioned: "why do we move so quickly to seek retribution from the front line operators who constitute the last line of defense. That’s where all the readily available data is recorded, CVR, FDDR etc. If we had recorders from the manufacturer design workshops and executive boardrooms perhaps the playing field would level out a little."^[9]

To level the field I'd add that the uncontrolled speed might not bear that much weight in the investigation. The safety assessment and certification of Mcas is scrutinized:

It is widely known (obvious from the FDR data) that it has no checks for sensor failure, yet it has unlimited authority over the stabilizer, operates the trim motor at fast speed (2.5 degree / 9.26 sec, 4 times faster than a Runaway Trim with flaps up).
Peter Lemme pointed out Mcas overrides the primary safety switch for Runaway Trim ("aft column cutout" / "COLUMN TRIM CUTOUT"), which stops a nose-down trim when the pilot pulls back the yoke. Lemme emphasized this difference (which would have saved both planes) "is not highlighted in the FAA Airworthiness Directive. It even implies that it will work".^[10]
Additionally the 737 NG has a separate Auto Pilot "STAB TRIM CUTOUT" switch between the wheels, which can disable AP and STS trim runaway without disabling the pilots trim thumb switches. In the Max this switch became a backup "B/U" for the other switch, thus both switches disable both the pilot and automatic trim by cutting power to the trim motor.^[11] I don't believe this was mentioned in the 2 hour differential course.
Stabilizer authority greatly increases with airspeed, but Mcas ignores this in the formula, commanding fast and long trim movements even at high speed. JT610 pitched from level flight to unrecoverable nose-dive in 30 seconds, ET302 in 10 seconds as a result.

These reports paint a picture of a critical system that lacks redundancy, multiple safety layers, and was not prepared for the whole flight envelope. This design slipped through multiple levels of the company, and the FAA certification. Boeing refutes any claims this design is unsafe, and does it's best to prove it's the pilots' responsibility to disable this "system", although it's existence and potential was not disclosed, even the EAD only hints of its existence, without describing its dangers.

To augment this picture:

The failure of multiple relatively new sensors does not happen by chance. Lemme shows design weaknesses of the AoA sensor on diagrams^[12] and a youtube tinkerer "AvE" disassembled a similar sensor^[13] although from a different aircraft type.
The Lion Air plane had more sensor issues, this can point to a signaling unreliability.
Lemme speculates Mcas runs in one instance, like STS does. Both being FBW "augmentations" using a critical control, safety requirements would necessitate that 2 independent implementations run at the same time and validate output consistency. Doubt this is part of the software update.
One non-critical sensor's failure caused incorrect, misleading and overwhelming warnings, unreliable critical instruments, unnecessary stress and workload. The failing sensor was automatically identifiable by the impossible jump to 74.5 degrees in 3/4 sec. Sensor failures are many times identifiable from erratic readings with moderately complex logic. By switching to the backup with pilot confirmation all the confusion is avoided. In this price category it is a naturally occurring thought that such safety features are undoubtedly part of the design, but this is not the case. There is room to make the planes safer, more resilient to failures, and more survivable in emergencies.

References

^ https://avherald.com/h?article=4c534c4a/0052&opt=0. {{cite web}}: Missing or empty |title= (help)
^ https://www.boeing.com/commercial/737max/737-max-software-updates.page. {{cite web}}: Missing or empty |title= (help)
^ https://leehamnews.com/wp-content/uploads/2019/04/Cordell-Case-for-Pilot-Error.pdf
^ https://www.linkedin.com/pulse/boeing-737-max-8-crashes-case-pilot-error-vaughn-cordle-cfa/
^ linkedin profile
^ www.satcom.guru/2019/04/what-happened-on-et302.html
^ https://leehamnews.com/2019/03/22/bjorns-corner-the-ethiopian-airlines-flight-302-crash-part-2/
^ https://leehamnews.com/2019/04/05/bjorns-corner-et302-crash-report-the-first-analysis/
^ https://www.linkedin.com/pulse/boeing-737-max-8-crashes-case-pilot-error-vaughn-cordle-cfa/
^ www.satcom.guru/2018/11/737-mcas-failure-is-option.html
^ www.satcom.guru/2019/04/stabilizer-trim-loads-and-range.html
^ satcom.guru/2019/03/aoa-vane-must-have-failed-boeing-fix.html
^ https://youtube.com/watch?v=NhZ0D-JRtz0