Congressional Record, Volume 162 Issue 23 (Tuesday, February 9, 2016)

[Congressional Record Volume 162, Number 23 (Tuesday, February 9, 2016)]
[Senate]
[Pages S724-S725]
From the Congressional Record Online through the Government Publishing Office [www.gpo.gov]

THE PRESIDENT'S SPACE PROGRAM BUDGET

Mr. NELSON. Mr. President, I come to the floor to speak about the
President's proposal with regard to our space budget, the civilian
space program, and NASA. Of course we have many other space programs,
primarily national security, but now there is a commercial space
program. We are seeing the burgeoning commercial space industry in the
NASA budget. We are amazed by the rockets which can take the first
stage--instead of throwing it away when it lands in the Atlantic Ocean
after a launch from Cape Canaveral--under powered flight, even without
parachutes, can come back and land on a specific spot, just as SpaceX
did in its first stage in a launch about 2 months ago. We are seeing
commercial space.
The fact that these things we carry around in our pockets that we
loosely refer to as phones that know exactly where we are at any time
is as a result of a constellation of satellites up there called GPS
that triangulate and calculate exactly where we are. It is absolutely
amazing to me that my latest gadgetry acquisition--a Fitbit--can so
sensitively understand what my heart rate is at any moment, can measure
distance, and gives me all kinds of information about the functioning
of the human body.
Well, this didn't just accidentally appear. Where in the world did a
lot of this come from? It came from the space program. I wish to talk
about that, but first I want to underscore something. Other than its
pioneering, for example, of increased investments in aeronautics, which
is the first ``A'' in ``NASA''--the National Aeronautics and Space
Administration--there are other parts of the President's proposal that
have been left behind in the visionary appropriations bill we passed
back in the middle of December which has sent us on a course that we
are going to Mars. We are preparing to go to Mars, and that is a long
way. In order to sustain human life and go all the way there--land,
survive, reignite off the surface of Mars--and, by the way, I commend
the Matt Damon movie ``The Martian.'' The author of the book which the
movie came from actually consulted with a number of folks, including
one of my crewmates, on the propulsion, how to get to Mars a lot
quicker. That propulsion uses magnets and plasma as its fuel and thrust
to get us to Mars, and instead of the conventional 8 to 10 months, we
could get there in as little as 39 days. But those are to-be-developed
technologies.
Let me mention a couple of things we are developing. Folks often
argue about the NASA budget, which back in the lunar days the Apollo
Program was as much as 4 percent of the entire Federal budget. Now it
is about one-half of 1 percent. In the process of divvying up the
dollars out here, we pull and tug because people will ask: Why do we
need to go to Mars? Why do we need to go to an asteroid in preparation
to go to Mars? Why do we need a space program when we have so many
needs here on Earth? That is a legitimate question. What is the
legitimate answer? Do you appreciate the fact that we have MRIs and CT
scans? MRIs--magnetic resonance imaging--and CT scans--computer-aided
tomography--technologies that are used routinely today to help us so
much in a diagnosis of what is wrong or what is right in our own human
bodies and is part of this medical miracle that we know as modern
medicine--they came straight out of the space program.
In the 1960s, NASA had to find a safe landing spot for the Apollo
lunar lander amid all of that Moon surface and all of that dust. So
what happened was the engineers at JPL out in California developed a
digital scanning process using high-frequency sound waves, magnets, and
computers. In addition to making six successful Moon landings, this
technology was tweaked, adapted, improved, and it led to CT scans and
MRIs.
How about robots in the use of modern medicine? How about robots in
the use of the manufacturing process? Well, my colleagues will remember
the one thing on the space shuttle that had the name of another
country; it was the Canadarm. It was the robotic arm that was birthed
in the cargo bay of the space shuttle. It was used to deploy, maneuver,
and capture payloads. It has now been the forerunner of the neuroArm, a
surgical device that has successfully performed dozens of tumor
removals by robotic surgery.
Now, any of the males around here over the age of 50 ought to be
concerned about prostate cancer. They have a robot named DA Vinci that
is built in California, even though it is named after Leonardo da
Vinci, and this robotic device, with a small incision--six times--can
go in and, with some of this precise photography that was developed for
these cameras, robotically remove, in this case, the prostate cancer by
removing the prostate without damaging the nerves and without cutting
the human body open, which takes so much more time to heal, instead of
just sticking six holes in. That came directly out of the space
program. It is being used to develop an image-guided autonomous robot
for use in the early detection of breast cancer.
Let me give my colleagues another idea. When we get on a modern
airliner today and we look out the window and we look at that swept-
back wing, what do we see out there on the tip of the wing? The wing
doesn't just stop as it normally does; it curves up. This is called a
winglet. The winglets have these upturned features. They save billions
of dollars in fuel costs.
Now, with NASA technology at the Langley Research Center and now the
tests conducted at the Dryden Flight Center--now named, after the first
astronaut on the moon, the Armstrong Flight Center--this winglet
technology was released to Boeing, and it has saved the airline
industry more than 2 billion gallons of jet fuel, and it has saved more
than $4 billion in jet fuel costs and a reduction of almost 21.5
million tons of carbon dioxide emissions, just by the design of the
wing. That technology came directly out of NASA.
Here is another example. All of this is coming back to this: Why go
to space? Well, we go to space because our nature is that we are
explorers and adventurers. We go there because we haven't been there.
We go there to explore. Our nature is one of pioneers. The frontier is
now not westward, as it was in the beginning of this country, but
upward. So that is certainly a reason to have the space program, but
let me tell my colleagues more of how it applies to our daily lives.
How about fortified baby formula? Early 1980s research on
regenerative ecosystems led to a method of algae-based food supplements
that provide the long-chain polysaturated fatty acids that support
brain and eye development and function. So this led to a spinoff
product called Formulaid, which was patented in 1996. It can now be
found in over 90 percent of infant formula sold in the United States as
well as those sold around the world.
I will give another example: image sensors--image sensors to enhance
cell phone cameras. In the 1990s, a NASA team had been improving
digital image sensors in order to miniaturize cameras on spacecraft
while maintaining the scientific image quality. So this was spun off
into commerce, and the company that commercialized the technology has
shipped over 1 billion sensors for use in applications such as--now,
does this sound familiar--digital cameras, camera phones, web cameras,
automotive cameras. They are even developing something where you will
swallow a pill; only it is not a pill. It is an ingestible camera for
imaging the patient's gastrointestinal tract.

[[Page S725]]

Let me tell my colleagues about another one. I had a visit from
Tallahassee Community College today. They showed me what they could do
with a 3-D printer. I ask unanimous consent to show this in front of
the Senate.
The PRESIDING OFFICER (Ms. Ayotte). Without objection, it is so
ordered.
Mr. NELSON. We are doing this on the space station right now. We are
putting together tools so that if we don't have a tool in space or if
we were on the long journey to Mars and we did not have a tool that we
needed to repair something, we could send the messages up to the
spacecraft and 3-D print the tools that we need. So long-term space
missions like the one to Mars are going to benefit from this onboard
manufacturing capability.
Spare parts--what happens if we get up there and we don't have
enough? Well, we can print it. Engineers are even experimenting with
creating a completely 3-D printed high-performance rocket engine. Can
my colleagues believe that? So that would advance manufacturing
technologies that could benefit a number of us right here on the face
of the Earth.
So the excitement of this--even though some would look at the
President's request for NASA and see that it is $600 million over what
he requested last year, but it is actually almost flat-line to what we
actually appropriated. Don't be discouraged by that because in this
sense the excitement is gathering as we are about to launch humans--
Americans on American rockets. That is going to occur next year, as we
send crews to and from the International Space Station. As a result, we
therefore do not have to rely on the proven Russian Soyuz that gets our
crews to and from today. Now we will have the capability of not only
transporting cargo to and from but our American astronauts.
Even though the President's request falls short in some areas, I
think the President's request has been overcome with what we have done
here in the Congress, with a substantial increase in this current
fiscal year over and above last year and with the excitement of human
space flight again within our grasp on American rockets, as well as
this excitement of defining, creating, and manufacturing new
technologies for space flight that will benefit us here on the face of
the Earth.
If it sounds like I am a cheerleader, indeed I am a cheerleader. When
I see the miracles of modern medicine, when I see the increased
capabilities of exploring the heavens and now almost back to the
original light emitted from the big bang, and when we start to uncover
the new discoveries that expand our horizons, indeed, I am a
cheerleader. For that, I am grateful.
I commend the Senate to keep this space program going at a fast pace
as we increasingly get back into the total business, both manned and
unmanned, of space exploration.
Madam President, I yield the floor.
The PRESIDING OFFICER. The Senator from Arkansas.
(The remarks of Mr. Cotton pertaining to the introduction of S. 2123
are printed in today's Record under ``Statements on Introduced Bills
and Joint Resolutions.'')
The PRESIDING OFFICER. The Senator from Connecticut.

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