This seems very odd to me. The other booster burns are clearly closed loop, both for engine-out on ascent, and landing. So surely the booster could do the same for the entry burn, and I would expect it to. However, the telemetry indicates that it did not do so. Anyone got any suggestions as to why?
Here's something that's been bugging me about the L19 failure:I've always assumed the re-entry burn was a closed loop burn under guidance control, ending when the booster (assuming normal rest-of-landing trajectory) was on a path to meet the landing ship. So if an engine fails (as it did here) the remaining two engines would burn for longer until the target trajectory is met, just like on ascent. Of course this would not guarantee mission success, since the longer burn has more gravity losses and eats into the fuel reserves, but the opposite seems like sure failure (if your trajectory does not intersect the barge, you are doomed anyway).So I would have expected that when one engine failed during re-entry, the remaining two would have fired longer until the same final velocity was attained. But looking at the circled area in the telemetry below, this was not the case - the remaining engines may have fired a second or two longer (not completely clear since they started a second or so later), but the final velocity was higher than in a normal mission, so the entry burn did not fully compensate.This seems very odd to me. The other booster burns are clearly closed loop, both for engine-out on ascent, and landing. So surely the booster could do the same for the entry burn, and I would expect it to. However, the telemetry indicates that it did not do so. Anyone got any suggestions as to why?
Quote from: LouScheffer on 03/10/2021 01:17 amThis seems very odd to me. The other booster burns are clearly closed loop, both for engine-out on ascent, and landing. So surely the booster could do the same for the entry burn, and I would expect it to. However, the telemetry indicates that it did not do so. Anyone got any suggestions as to why? Propellant budget for the landing burn? - Ed Kyle
Quote from: LouScheffer on 03/10/2021 01:17 amHere's something that's been bugging me about the L19 failure: [...]This seems very odd to me. The other booster burns are clearly closed loop, both for engine-out on ascent, and landing. So surely the booster could do the same for the entry burn, and I would expect it to. However, the telemetry indicates that it did not do so. Anyone got any suggestions as to why?The answer may lie just to the right of your circle: the velocities quickly converge. The drag depends on velocity squared, so the faster rocket slows down more until they are both at terminal velocity.The re-entry burn isn't to bleed off speed as much as it is to control heating. So the failed burn leaves the stage with more heating, but you don't have to burn longer to make it up, the heat damage has already been done. Just do the best you can, let the atmosphere take care of the rest, and cross your fingers that your structure has enough margin to take the extra heat. And as Ed says, don't blow your propellant margin trying to close the barn door after the heat horse is already out.I am not a rocket engineer, just my opinion, etc.
Here's something that's been bugging me about the L19 failure: [...]This seems very odd to me. The other booster burns are clearly closed loop, both for engine-out on ascent, and landing. So surely the booster could do the same for the entry burn, and I would expect it to. However, the telemetry indicates that it did not do so. Anyone got any suggestions as to why?
There are at least two different ways to close a loop.One way is to have a nominal trajectory and close the loop to keep on the nominal trajectory.Another method, which is usually more efficient in physical resources, but more computationally expensive, is to continual recalculate the best trajectory from where you are* to where you want to end up. If you follow this rule perturbations may not be immediately corrected. After a perturbation the actual trajectory may not converge to the nominal trajectory until right at the end. It's possible for the the corrected trajectory to be radically different from the nominal one (e.g. Hiten)* In phase space, not just position.
Quote from: Barley on 03/10/2021 04:25 amThere are at least two different ways to close a loop.One way is to have a nominal trajectory and close the loop to keep on the nominal trajectory.Another method, which is usually more efficient in physical resources, but more computationally expensive, is to continual recalculate the best trajectory from where you are* to where you want to end up. If you follow this rule perturbations may not be immediately corrected. After a perturbation the actual trajectory may not converge to the nominal trajectory until right at the end. It's possible for the the corrected trajectory to be radically different from the nominal one (e.g. Hiten)* In phase space, not just position.The problem is that they did not follow either of these two sensible strategies.They did not follow the nominal trajectory, since they ended up with a higher velocity, which they could have fixed by burning the two remaining engines longer. And I can't believe they used the "optimize from here on out" strategy, since they did nothing different after one engine failed. Whatever the optimum strategy is after losing 1/3 of your thrust, just doing the same thing minus one engine is not it.My current thinking is that they simply don't have the software to account for an engine loss during re-entry burn. Landing is single-string anyway, so perhaps the extra software work was deemed not worth the effort. How often will this particular case happen? Not often at all, I suspect, and even if it does it does not affect their primary mission. So maybe they have some "simple" algorithm with (say) an orientation, a delta-V target, and a time limit for backup. So they lose an engine during the burn, and then time out before reaching their delta-V target.
Technically the boot is part of the heat shield.
Quote from: cscott on 03/11/2021 07:34 amTechnically the boot is part of the heat shield. Oh you're right it just seems to me the damage might've been a bit more damaged than just an engine cover having a hole in it.
If the rocket was coming straight down, your answer makes perfect sense. Then the applied delta-V does not affect targeting, so just take off as much velocity as you can, and hope the heating is OK.However, the rocket is coming in at something like a 45 degree angle. So if you don't slow it enough, the higher velocity will take it further downrange until terminal velocity kicks in, and you'll overshoot the barge.
You might be able to do something using the altitude, rate of change of altitude and speed to place some limits on what the directions actually are. We can certainly see that at the start of the reentry burn the angle of the velocity to the horizontal is far less than 45 degrees. (The ratio of the minimum speed at the top of the arc to the speed at the start of the burn is less than sqrt(2) ).
Quote from: LouScheffer on 03/10/2021 05:20 pmMy current thinking is that they simply don't have the software to account for an engine loss during re-entry burn. Landing is single-string anyway, so perhaps the extra software work was deemed not worth the effort. How often will this particular case happen? Not often at all, I suspect, and even if it does it does not affect their primary mission. So maybe they have some "simple" algorithm with (say) an orientation, a delta-V target, and a time limit for backup. So they lose an engine during the burn, and then time out before reaching their delta-V target.But is that “the SpaceX way”?After the first stage failure on CRS-7, (IIRC). Musk stated that the software would be modified to deploy the parachutes in any similar event in the future. That’s a low gain remedy for a low probability event, but Musk said they would work on it. Recovering a first stage after an engine failure at entry burn seems more value and higher probability.
My current thinking is that they simply don't have the software to account for an engine loss during re-entry burn. Landing is single-string anyway, so perhaps the extra software work was deemed not worth the effort. How often will this particular case happen? Not often at all, I suspect, and even if it does it does not affect their primary mission. So maybe they have some "simple" algorithm with (say) an orientation, a delta-V target, and a time limit for backup. So they lose an engine during the burn, and then time out before reaching their delta-V target.
The company is also working on future upgrades to the control systems on Falcon 9 that will help the vehicle land even in the event of an engine shutdown during flight like the one that occurred Feb. 15, Reed said.
From SpaceX lost a rocket in the ocean last month. Here's why.:QuoteThe company is also working on future upgrades to the control systems on Falcon 9 that will help the vehicle land even in the event of an engine shutdown during flight like the one that occurred Feb. 15, Reed said.
In terms of going from there. We apply, well, here's where we need to do more inspections, here's where [garbled] kind of components we need to replace, and here's where we can actually upgrade the systems, the algorithms on the vehicle to even further detect and control what the vehicle needs to do. And that's what we're doing as we move forward.
Quote from: Comga on 03/10/2021 08:06 pmQuote from: LouScheffer on 03/10/2021 05:20 pmMy current thinking is that they simply don't have the software to account for an engine loss during re-entry burn. Landing is single-string anyway, so perhaps the extra software work was deemed not worth the effort. How often will this particular case happen? Not often at all, I suspect, and even if it does it does not affect their primary mission. So maybe they have some "simple" algorithm with (say) an orientation, a delta-V target, and a time limit for backup. So they lose an engine during the burn, and then time out before reaching their delta-V target.But is that “the SpaceX way”?After the first stage failure on CRS-7, (IIRC). Musk stated that the software would be modified to deploy the parachutes in any similar event in the future. That’s a low gain remedy for a low probability event, but Musk said they would work on it. Recovering a first stage after an engine failure at entry burn seems more value and higher probability. Yes, apparently it is the SpaceX way: From SpaceX lost a rocket in the ocean last month. Here's why. :QuoteThe company is also working on future upgrades to the control systems on Falcon 9 that will help the vehicle land even in the event of an engine shutdown during flight like the one that occurred Feb. 15, Reed said.
