According to the Apollo 11 narrative, the astronauts/Houston...
No, not Houston. Just the astronauts.
though relatively infrequently [...] checked to be sure there was no platform drift
Thank you for conceding that space navigation requires only infrequent verification of platform alignment. Earlier you insinuated that if Al Worden couldn't align the platform during the 23 minutes he was in full darkness, the guidance system would have been "lost."
The Apollo Guidance Computer does not "know" one way or the other if there is or is not drift.
Correct, hence the inability of an unmanned CSM to fly to the Moon. It would have no way of keeping its guidance platform within the tolerance required for such a mission. Your "unmanned military mission" scenario fails by your own evidence and is therefore rejected.
An element of the alleged protocol for determining as to whether drift has or has not occurred features the astronauts [...] CONFIRMING THE STARS' IDENTITIES in the context of a platform alignment check by way of pressing a button.
No. The mark establishes the star's
location after having finely manipulated the sextant's view angle relative to the platform chassis.
I see you've finally read O'Brien's chapter on sextant operation. Will you now retract (1) your insinuation that Collins could have used the sextant to search for the LM without accurate shaft and trunnion angles, and (b) your claim earlier that the AGC itself sighted the stars?
Yes, the entire process assumes that the marked star is actually the one the computer has been told to aim the sextant at. But as we'll see below, your handwaving attempts to play up the alleged inability to correctly identify that star are fairly preposterous.
My point is that the narrative as presented with reference to these star sightings must be bogus.
And my point is that you understand neither the nature of the process nor the factors that affect its success.
As we'll note below, you home in on contrived hypothetical case and suggest that this invalidates the whole process of celestial navigation. Once again, the fallacy of hasty generalization. You invent your one little straw man and posit it to be the
dictum simpliciter of the whole problem. I note that this is what your opponents in other threads accuse you of doing, even when it's a topic on which you claim special expertise.
A star floating isolated in the cislunar sky is NOT something Collins could identify as Menkent, Nunki, or any one of the other primary navigational stars.
No. The highlighted portion is where you misrepresent Collins.
Collins mentions two of the reference stars and says that, to him, they were difficult to locate with the naked eye. That is not an admission that
all the reference stars were similarly difficult to locate. In fact, Collins is here illustrating the operation of the optical and inertial references. His explanation is irrelevant if the stars he chooses for this example are not more difficult than the others to find.
The point he's trying to make is that the computer almost always knows where the stars
should be, in terms of their absolute locations on the celestial sphere, and therefore their expected location relative to the platform, and further where the computer would have to point the sextant relative to the platform in order to see them. If Collins, looking out the window or through the 1X telescope, can't find some of the more obscure ones, he can tell the computer to point the sextant to where they should be. The narrow field of view then brackets the star of interest.
If the platform is aligned properly with the universe, the star in the crosshairs is the one he had a hard time finding. If the platform is slightly misaligned, the star is in the field of view, but not centered. If the platform is wildly misaligned, then the star may be outside the sextant FOV.
In short, Collins is describing the relationship among the sextant, guidance platform, computer, and the universe for the lay reader by saying, "If I can't find a given star, here's how the inertial and optical systems work together to help." You're trying to twist that into saying, "If I can't find some given star manually, I have no way of navigating." That's not what Collins is trying to say at all.
If, in the context of an actual platform alignment, Collins has a hard time finding Nunki, a relatively dim star in the backwaters of the massive Sagittarius constellation, he can always use Vega, the blazing king of the Lyra constellation and one of the vertices of the iconic Summer Triangle. It's on the same side of the spacecraft and bereft of any nearby stars of similar magnitude. It's by far the brightest game in town, in its little neighborhood.
When traveling through cislunar space, around the moon's back side and what not, the star count would vary, assuming any of this were real.
The star count varies here on Earth. If I'm down on the valley floor, the city lights obscure almost all the stars. If I'm up in the mountains or out in the west desert, where I go every year to observe the Perseids, I can see a vast panorama of them including the Milky Way. This does not affect my ability to locate celestial objects.
Variation in star count alone is insufficient to discount the ability to navigate. Your premise commits the fallacy of limited scope, and is therefore rejected.
There would be times wherein any given constellation pattern would become unreadable due to the presence of too many stars...
Begging the question.
I have no problem identifying constellations as star count varies. And I'm only an amateur astronomer. The Apollo astronauts were trained in planetariums to become better-than-average astronomers. You cite individual isolated examples of difficulty in locating stars, but you again hastily generalize that to say that all stellar navigation was impossible. The premise is rejected.
Note that most of the MIT guys would have bought in. This is tricky and they would not have readily been fooled.
So here you claim that the MIT Draper lab was full of smart people. And then in the next sentence below you say that they were too stupid to realize that stars of different relative magnitudes might have different visibility depending on circumstances.
Really? You're actually going to float that contradiction as part of your argument?
What do the MIT AGC designers know about star variable visibility conditions in cislunar and perilunar space? Less than NOTHING!
Begging the question yet again. Your straw man "requires" MIT people to be ignorant,
ergo they must be ignorant. The question-begging premise is rejected.
You apparently know about Frank O'Brien's book. Now you need to go scare up Eldon Hall's book, where you'll find that MIT's Draper lab was chosen to develop Apollo's guidance system because they were the undisputed experts in inertial guidance systems using optical stellar fixes as a backup. Apollo's weren't the only ones that existed. And I'm surprised that your obsession over ICBM's hasn't led you to some others.
In addition your premise commits the fallacy of limited scope and is therefore rejected.
...no one at NASA is going to tell them that it hardly makes any sense
It's a good thing that MIT's expertise didn't depend on NASA's. Just the opposite, in fact. NASA needed MIT's expertise. Fallacy of inverse causation (
cum hoc), and the premise is rejected.
The point is that when Collins checks to be sure if the platform is aligned or not aligned in the Apollo 11 narrative, HE, COLLINS, MUST...
[whole lot of hysterical handwaving snipped]
how would Collins know anything? Answer......Collins doesn't know anything...
You leave out the part where Collins claims to have navigated successfully to and from the Moon. If you're going to cite him as an authority on the details of how that's done, then you are highly dishonest when you omit his authority on whether or not it was nevertheless possible to do.
Congratulations on having dismembered your straw man. Now let's look at the real world.
You note above, correctly, that platform checks were done infrequently. You imply above, correctly, that only in few cases did these checks require correction. The "verify more often than you correct" procedure is meant to assure that platform drift is unlikely to cause the reference stars to drift out of the FOV. When that condition is made to prevail, it is unnecessary to locate the reference stars first with the naked eye.
You wrongly suggest that the difference in naked-eye visibility affects how the sextant is used. That violates a well-known principle of restricted fields of view, such as in telescopes. Further, you make a big deal out of recognizing stars in context, but there is only a very narrow context available anyway through the sextant. The point is to recognize the star through the
sextant. Everything else is largely irrelevant.
Three star sightings typically occur in the alignment check and correction procedure. The only constraint is that the greater the angular separation among them, the more accurate the reading. However, because of the geometric degrees of freedom, only two sights are strictly necessary. This is intended first to refine the solution, and second to allow the navigator to misidentify one of the stars.
However that's not as likely to happen as you make it out to be. Out of an overabundance of caution, far more reference stars were provided in the computer than would be practically necessary. The reference stars cover a substantial expanse of the celestial sphere, spread out geometrically. The pilot only has to find two or three of them, out of the dozen in the hemisphere visible from the sextant side of the ship.
And if for any reason the platform has drifted more than a couple of degrees, and if the navigator cannot manipulate the sextant field of view to find the reference star, then there is always the coarse alignment procedure, which is performed anyway when the IMU is turned on after periods of disuse. That's accurate enough to put the stars back in the FOV.
And if the coarse alignment procedure fails, there is the cage-and-restart procedure that "homes" the stable member.
And if all that fails, there is the
other guidance system that uses a completely different kind of inertial reference.
Collins could not reliably identify stars under these circumstances...
False. Collins says two of his reference stars were more difficult than the others to locate by the naked eye, which he uses to illustrate for layman's use the operation of the optical and inertial references. You try to parlay that statement into a completely unrealistic straw man of celestial navigation.
...nor could Armstrong, nor could Aldrin.
Assumes facts not in evidence. Rejected.
Star identities could NOT be reliably determined by this less than laughable system PERIOD!
Straw man. You cite Al Worden's case (which is clearly anomalous and has a built-in solution) and Micheal Collins' example (which is an irrelevant transposition). You are not describing navigation as a whole. The premise is therefore rejected as a hasty generalization.
The view of the firmament would be inconsistent, the stellar patterns would be inconsistent, and as such, not recognizable.
Assumes that the view through the sextant is analogous to the view according to the naked eye, which is the commonality in your cases in evidence. It has been explained to you why that does not hold. Since you've been directed to that explanation three times, I conclude you have no answer for it. As such, the premise is rejected.
This whole thing is way fake and this is so easy to see now, so so so easy to see.....
Of course it's "easy to see" when you don't even have a passing familiarity with reality, and you ignore everything that doesn't fit your preconceived belief, and you remain uninformed regarding the underlying sciences.
Since you claim your arguments are logical, I've given you a running account of the fallacies you've committed. Please feel free to explain how you can fall into those fallacies and yet claim your arguments are logical.
