Wagging the Moondoggie, Part XII
February 23, 2010
by David McGowan
“As launch windows open and close, the
next missions move
forward. Two test flights of the lunar landing vehicle, and then the
proposed
landing on the Moon. And plans are in the making now which include
fly-bys of
other planets; visits to what Dr. Bunche calls neighbors.”
From Debrief: Apollo 8, a NASA
promotional
film circa 1968
Just a few weeks ago, NASA Administrator
Charlie
Bolden boldly unveiled the agency’s new vision: “Imagine trips to Mars
that
take weeks instead of nearly a year, people fanning out across the
inner solar
system, exploring the moon, asteroids and Mars nearly simultaneously in
a
steady stream of firsts.” (“Launching a Broader Vision for NASA,”
Yeah, and then imagine visiting a distant
moon populated
by ten-foot-tall blue people, which is slightly more plausible than
NASA’s
grandiose dreams.
Bolden’s ambitious proclamation was intended
to put
a positive spin on NASA’s acknowledgment that the Constellation
Program, which
President George W. Jetson had promised was going to put us back on the
Moon by
2020, was being canceled. I’m sure we would have made it though were it
not for
the fact that President Blackbush doesn’t seem to want to fund the
effort.
Sure, he increased the agency’s budget for 2011, but he didn’t, you
know,
increase it enough. So the Constellation Program, which
taxpayers have
already reportedly shelled out at least $9,000,000,000 for, and which
will
reportedly cost another $2,500,000,000 to cancel, has been tossed on
the scrap
heap.
According to Bolden, things weren’t really
going all
that well anyway: “Currently, [Bolden] said, the 5-year-old
Constellation
program is burning through billions of dollars and falling further
behind
schedule. The program couldn’t get American astronauts back to the moon
until
at least 2028 … ‘So as much as we would not like it to be the case …
the truth
is that we were not on a path to get back to the moon’s surface,’
Bolden said.”
Well, were we at least on a path to put
together a
better simulation of landing on the Moon?
Taking into account that the Constellation
Program
was begun in 2005, and that the Apollo program allegedly landed men on
the Moon
in a mere eight years, it would appear that it wouldn’t actually take
twice as
long to get back to the Moon with today’s technology, as previously
advertised,
but would actually take at least three times as long! If, that
is, we
were able to man-up and follow through with the plan, which obviously
isn’t
going to happen.
But be assured that that’s only because we
don’t
have the money. Otherwise, we totally would have made it back to the
Moon.
Possibly in less than twenty years. By which time all the technology
that we
know and love today will be as obsolete as pagers and Betamax video
recorders,
and trips to the Moon will still be something that we only talk about –
sometimes nostalgically, as we fondly recall the fabled glory days from
a
decade few will remember, and sometimes with an eye to the future, a
oft-promised future that never seems to arrive.
In May of 1966, after spending five years
working on
the Apollo project, we were just a-year-and-a-half away from the launch
of the
first Saturn V. In 2010, after spending five years working on the
Constellation
project, NASA has nothing to present to us but a hefty bill – which
just goes
to show that lack of technological sophistication and space-flight
experience
can apparently be easily overcome with a little determination … and a
couple
rolls of duct tape.
I was thinking, by the way, that if the idea
of an
Apollo reenactment were properly pitched to the right ‘reality
television’
producers, we could probably make it back to the Moon in just a year or
so.
There was quite a bit of Apollo hardware that was left over after the
sudden
demise of the program, much of which is now in various aerospace
museums – and
aerospace museums tend to be run by aerospace geeks who would like
nothing more
than to see the
We’re going to need to assemble all our
donated
hardware, of course, and for that we can turn to the guys at Monster
Garage,
who should be able to slap it together for us in a couple of
afternoons. There
will undoubtedly be some missing and/or non-operational parts, but that
shouldn’t slow things down much; we can just give the guys over at American
Pickers a call and they’ll scour
Unlike girlie-men like Neil Armstrong and
Buzz
Aldrin, Bear would undoubtedly show us a few tricks that the Apollo
gang never
thought of – like fashioning a shelter out of Moon rocks, foraging for
the food
and water that others failed to find, building a roaring fire despite
the lack
of both air and combustible materials, and finding several new and
creative
uses for the urine bags that his predecessors tossed aside as space
trash. He
could also probably design and build his own lunar rover from parts
salvaged
from artifacts of the Soviet Luna program. And he could probably do it
all
without the need for a spacesuit.
Speaking of spacesuits, just a week before NASA shit-canned the Constellation Program, the agency announced that it had awarded a contract to Oceaneering International and the David Clark Company to design and build a brand-new, state-of-the-art spacesuit for use on future manned missions to the Moon and beyond (“NASA’s Next Space Suit,” Technology Review, January 25, 2010).
“If NASA returns to the moon in 2020 as
planned,
astronauts will step out in a brand-new space suit. It will give them
new
mobility and flexibility on the lunar surface while still protecting
them from
its harsh environment … The space agency has awarded a $500 million,
6.5-year
contract for the design and development of the Constellation space
suit.”
Astronauts performing EVAs these days currently use something known as
the
Extravehicular Mobility Unit: “It has a hard upper torso, layers of
material to
protect astronauts from micrometeoroids and radiation, a
temperature-regulation
system, and its own life support and communication system. The EMU
weighs over
300 pounds and has limited leg mobility – astronauts feet are normally
locked
in place on foot restraints while performing extravehicular tasks, and
during
Apollo missions, which used a different EMU suit, astronauts were
forced to
develop a bunny hop to traverse the lunar surface.”
I could, of course, point out once again the
absurdity of it taking about four times as long to develop a spacesuit
now than
it did back in the hi-tech 1960s, but I’m pretty sure I’ve already beat
that
particular horse damn near to death and then rubbed salt in the wounds.
I could
also point out that the Apollo suits somehow managed to perform all the
duties
of the current EMUs while weighing about 40% less, but that’s also
already
taken a pretty severe beating.
So instead, I’ll focus on the contention that
the
Apollo astronauts were “forced to develop a bunny hop to traverse the
lunar
surface,” which, as an alert reader pointed out, flies in the face of
numerous
past claims in which it was maintained that the ‘bunny hop’ was found
to be the
most effective means of locomoting in a reduced gravity environment,
not that
it was something forced upon the astronauts by the limitations of the
spacesuits. If I remember correctly, one of the Mythbusters
propagandists claimed that he had verified that it was the most
efficient means
of moving in reduced gravity, and he was, by his own admission, wearing
a
costume and not a pressurized spacesuit when he conducted his
experiment.
Someone, it would appear, is doing a little
lying
here. I am, needless to say, as shocked as all of you.
“‘When we went to the moon the first time, we were just trying to get there. Now astronauts need to be able to explore the surface, harvest resources, and do science,’ says Daniel Barry, vice president and director of research and development at David Clark Company, and head of the Constellation space suits project.”
So the Apollo missions, it turns out, were
just
about getting there. And the reason, I guess, why we allegedly
flew men
to the Moon eight times (including the alleged fly-bys by
Apollo 8 and
Apollo 13) was to, uhmm, prove that getting there the first
time was no
fluke. Sure, we were told that the boys were sent there to “do science”
and
that they took along a bunch of scientific testing equipment – and
even, on the
last flight, an actual scientist – but that apparently wasn’t really
the case. And
the lunar rovers allegedly flown to the Moon were not brought along to
enable
the astronauts to “explore the surface” and conduct additional science
projects.
This time, however, we’re going to do it
right … in
another 20+ years, that is … if we fast-track it.
What “resources,” by the way, are we planning
to
“harvest”? We’ve already allegedly brought back numerous samples of
Moon rocks,
which appears to be about the only resource readily available, other
than the
water NASA now claims can be found there. How much does it suck, by the
way,
for NASA to have to cancel the Constellation Program right after the
agency had
reported allegedly discovering loads of water on the Moon?
One ‘debunker’ claim that has been made
fairly
frequently over the years, it should be noted, is that NASA’s alleged
Moon
rocks contain no traces of water, proving that they are not of Earthly
origin
and could only have come from the surface of a waterless sphere like
the Moon …
which isn’t, NASA now claims, waterless. I have no doubt though that
those same
‘debunkers’ will be able to come up with some convoluted, hackneyed
explanation
for the apparent discrepancy.
Pictured below is the evolution of the
American
spacesuit. From left to right in the top row are the Mercury suit
(1961), the
Gemini suit (1965), and the pre-Playtex Apollo suit (1968); in the
lower row
are the famous Apollo magic suit (1969), the first space shuttle suit
(1981),
and the new suit being produced for the now-defunct Constellation
Program.
Below that, believe it or not, is an early prototype Apollo suit. While
it may
appear to be a still from some 1950s sci-fi flick, or a computer
generated
artist’s conception, it is, in fact, an actual suit being tested in the
Another thing Bear Grylls would undoubtedly
do is
bring us back some of those dazzling lunar starscapes that the Apollo
guys
neglected to capture. Presented below, by the way, is one of NASA’s
former astronomy
pics of the day. It carried with it the
following explanation: “If you could turn off the atmosphere’s ability
to
scatter overwhelming sunlight, today’s daytime sky might look something
like
this.” Below that is a shot from deep space, illustrating that stars in
outer
space maybe aren’t really as camera-shy as some would like us to
believe.
According to Bolden, NASA had “focused so
much of
our effort and funding on just getting to the moon, we were neglecting
investments … required to go beyond.” So while we don’t have the money
required
to get back to the Moon, you see, we do have the money to bypass the
Moon and
fly our guys to more distant locales, like Mars. No target date has
been set,
but I’m guessing that if we focus our attention on these bolder
objectives,
we’ll probably succeed by, like, 2050. Or maybe 2060. Or 2069, on the
100th
anniversary of the first alleged Moon landing.
As will be recalled, we set our sights a
little higher
in the 1960s. When Kennedy delivered his famous declaration back in May
of 1961
that we were going to the Moon, he gave the aerospace community less
than a
decade to make it happen. Engineers across the country, who were well
aware of
the fact that the nation hadn’t even taken its first baby-steps yet,
were
understandably dismayed.
The first Apollo contract was awarded just
two
months later, in July of 1961, for the sophisticated navigation system
that
would allegedly guide the spacecraft to the Moon. In an unusual move,
NASA
opted not to solicit bids for the guidance system; instead, the
contract was
handed directly to MIT, generating “immediate controversy,” as noted by
Moon
Machines. As one of the show’s talking-heads noted, “There was
actually a
budding industry out there that had developed guidance systems and
people from
industry were quite upset. They felt that they should have been given
the
chance to bid on the contract – and a university is not ordinarily what
the
government contracts out to build hardware for operational systems.”
There was, alas, nothing ordinary about the
Apollo
project.
The man NASA turned to first, long before
awarding
any of the other Apollo contracts, was one Charles Draper, who ran
MIT’s
instrumentation lab, which would later carry Draper’s name. Draper was
generally described as an eccentric, charismatic, colorful gent whose
background was in physics and, curiously, psychology. He is widely
considered
to be the father of the inertial guidance system.
Perhaps significantly, Bill Kaysing, the
first
Apollo skeptic to gain prominence, has claimed that it was MIT (in
conjunction
with DARPA) that provided NASA with the blueprint for how to plausibly
simulate
manned trips to the Moon. If true, then it of course makes perfect
sense that
NASA would have turned directly and immediately to MIT, and would have
done so
without taking any outside bids. Until MIT completed their work and
provided
the space agency with an outline of the project, it would seem, NASA
wouldn’t
have known what other contracts to award.
The fact that the project landed on the desk
of
Charles Draper is perhaps significant, given that the name ‘Draper’ is
a rather
notorious one in twentieth century American history – and one that is
closely
tied to the name ‘Bush.’ It is a name that appears more than once on
the
membership list of everyone’s favorite secret society, Skull &
Bones
(Herbert Draper Gallaudet [1898], Arthur Draper [1937], William Draper
III
[1950]). It is a name that was prominently featured in the American
eugenics
movement, with General William Draper, Jr. serving as founder and
chairman of
the Population Crisis Committee and vice-chairman of the Birth Control
League
(as Planned Parenthood was originally known). General Draper, a close
friend of
the Bush family, also helped finance the 1932 International Eugenics
Conference. Many years later, during the Apollo era, Draper advised LBJ
on
population reduction strategies.
The Draper family was also, not too
shockingly,
involved in the financing and maintenance of the Nazi regime. General
Draper
joined Dillon Read in 1927 and for many years was tasked with
personally
handling the account of Nazi industrialist/financier Fritz Thyssen. At
the
close of WWII, Draper was appointed Chief of the Economic Division of
the Joint
Allied Control Council for
One final note about General Draper (whose
son,
Bonesman William Draper III, served as the chief of fundraising for
George
Bush’s 1980 presidential campaign): he was a member of the Society of
American
Magicians. In other words, William Draper, Jr. considered himself to be
something of an expert in the art of illusion. Perhaps the same could
be said
of Charles Draper of MIT.
According to Moon Machines, Draper
and his
team got to work on the Apollo guidance system in the spring of 1962.
Given
that Moon Machines also contends that the contract was awarded
to MIT in
early summer of 1961, the question that is naturally begged is: why,
with the
clock ticking and with an absurdly short timeframe to pull the Apollo
project
together, would the MIT team have waited almost a year to get started?
Or did
they, in fact, spend that first year working on their real assignment –
mapping
out the key elements of the simulation?
If so, then they apparently spent a fair
amount of
time viewing an obscure German silent film by the name of Die Frau
im Mond
(The Woman in the Moon), as noted in the painfully long
documentary, What
Happened on the Moon? The German feature film, released by
filmmaker Fritz
Lang in 1929, provided the blueprint for the heavily ritualized launch
procedures that were adopted for the Apollo program. As can be seen in
the
screen caps below, all of the elements were there: the unnecessary
vertical
construction of the spaceship in a specially built hangar; the grand
opening of
the massive hangar doors; the excruciatingly slow roll-out of the
upright
rocketship from the hangar to the launch pad; the raucous crowds
watching the
spectacle live; the now ubiquitous countdown; even the shedding of two
stages
of the ship. In other words, the only elements of the performance that
the
public ever actually witnessed were all lifted directly from a
forty-year-old
silent film.
Fritz Lang’s technical adviser on the film
was
Herman Oberth, considered to be one of the three founding fathers of
rocketry.
Assisting Oberth on the film project, according to the previously
quoted Time-Life
book To the Moon, was one of his brightest students,
nineteen-year-old
Wernher von Braun. A decade-and-a-half later, both Oberth and von Braun
would
be scooped up through the Paperclip project and brought to America to
work on,
among other things, the Apollo program, whose choreography just
happened to
very closely match that of the fake Moon launch Oberth and von Braun
had
crafted forty years earlier.
Die Frau im Mond, by the way, was not the only Fritz Lang
film that proved to be rather prophetic. He followed it up in 1931 with
M,
the tale of a sadistic, pedophilic serial killer guided by voices in
his head.
I wonder how he came up with that plotline?
Before moving on, I should probably point out
here
yet another brazen lie the ‘debunkers’ like to tell – the one that
holds that
von Braun was only a Nazi because he had little choice in the matter,
what with
living and working in Germany during the days of the Third Reich and
all.
That’s a nice little fable, to be sure, but it is contradicted in a big
way by
at least one known photograph in which von Braun can be seen adorned in
the
elite Nazi regalia of the Black Order of the SS. As anyone who has
studied the
Nazi hierarchy is well aware, Himmler’s elite order had a ‘no weekend
Nazis
need apply’ policy.
Anyway, returning to MIT, the starting point
for
engineers was to develop a gyroscope-based guidance system. The problem
though
was that gyros could not be produced to MIT’s exacting standards,
resulting in
gyro after gyro being rejected. Another problem was that translating
data from
the gyros into flight instructions would require, as Moon Machines
noted, a “modern digital computer,” and putting such a beast in a
spaceship
“was an entirely new challenge.”
“Computers in the early 1960s,” you see,
“were huge.
The idea of squeezing such a monster into a spacecraft seemed
preposterous.”
But that wasn’t really going to be a problem since, as we have already
seen,
clearing seemingly insurmountable obstacles was something that the
aerospace
community was uniquely skilled at in the 1960s. The engineers working
on the
onboard computer utilized an entirely new technology known as the
silicon chip.
The technology was so new though that no one knew what it could
actually do.
And as with the gyros, it proved to be nearly impossible to produce
chips of
acceptable quality.
At the time, ‘software’ was a virtually
unknown
concept. As Moon Machines duly reported, “With nobody clear on
exactly
what the computer should do, the software engineers were free to write
almost
anything they liked.” One of those flight software developers, Alex
Kosmala,
made the following remarkable admission: “There were no specs. We made
it up.
Uhmm … and it’s always [been] amazing to me – why was I allowed
to
program something that hadn’t even been specified [but] that would be
critical
in assuring the success of the whole Apollo Program? I couldn’t
believe
it, but that’s the way it was. We made it up as we went along!”
I’m going to take a wild guess here and say
that
NASA probably wasn’t unduly concerned since the functioning of the
software
would only have mattered if the agency was planning to actually send
guys to
the Moon.
The most complicated aspect of the Apollo
missions
was the landing of the lunar modules, which made the software program
controlling that part of the mission the most difficult to design.
Amazingly
though, that aspect of the software design was not assigned until after
most of
the other programs were 2/3 complete – and it was assigned to a
twenty-two-year-old gent named Don Isles who had just recently started
his very
first job. According to Moon Machines, “the program without
which it
would be impossible to land on the Moon … had been written almost as an
afterthought by a junior engineer.”
It is rumored that MIT first tried to pawn
the job
off on a kid who flipped burgers at the local McDonalds, but he
apparently had
prior commitments.
By mid-1966, Draper’s dream of controlling
the
entire mission via an onboard computer had been dropped in favor of an
Earth-based control system with the Draper system along as back-up. MIT
allegedly produced a computer the size of a small fridge, which both
the
command module and the lunar module were outfitted with. Despite the
overwhelming obstacles faced by the MIT team, and the seemingly
lackadaisical
approach taken with the project, the Apollo guidance system, as would
be expected,
performed nearly flawlessly on every outing.
One final note here on Die Frau im
Mond before wrapping up this installment: the gatekeepers over
at the BAUT
forum appear to be in on the joke. Why else would the site's logo
contain not an image of NASA's lunar module sitting on the surface of
the Moon, but rather a rocketship that looks suspiciously like the
spaceship from Lang's film?
