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Date: Sat, 12 Dec 92 05:07:08
From: Space Digest maintainer <digests@isu.isunet.edu>
Reply-To: Space-request@isu.isunet.edu
Subject: Space Digest V15 #534
To: Space Digest Readers
Precedence: bulk
Space Digest Sat, 12 Dec 92 Volume 15 : Issue 534
Today's Topics:
absolutely, positively overnight
DC info
dialog between D. Goldin and C. Sagan
Electronic Journal of the ASA (EJASA) - December 1992
Terminal Velocity of DCX? (was Re: Shuttle ...)
Welcome to the Space Digest!! Please send your messages to
"space@isu.isunet.edu", and (un)subscription requests of the form
"Subscribe Space <your name>" to one of these addresses: listserv@uga
(BITNET), rice::boyle (SPAN/NSInet), utadnx::utspan::rice::boyle
(THENET), or space-REQUEST@isu.isunet.edu (Internet).
----------------------------------------------------------------------
Date: 11 Dec 92 00:45:47 GMT
From: Anthony J Stieber <anthony@csd4.csd.uwm.edu>
Subject: absolutely, positively overnight
Newsgroups: sci.space
In article <1992Dec10.225826.12281@eng.umd.edu> sysmgr@king.eng.umd.edu writes:
>In article <1g89m0INN578@uwm.edu>, anthony@csd4.csd.uwm.edu (Anthony J Stieber) writes:
>But they didn't call the SR-71 the Recon-STRIKE-71 before LBJ's mangling for
>nothing.
Yep. And I also heard about the drone launch accident that downed both
the drone and the host SR-71. Are the speeds SR-71 craft fly at
considered hypersonic? In any case release of anything in an
atmosphere at high speeds is problematic.
I suppose that a DC could be used like an ICBM bus and release
ordnance while suborbital above the atmosphere. Physics packages, etc.
would reenter on their own. The DC would put some distance between
itself and the payload and either reenter as well or burn some fuel and
take an orbit or two, perhaps for another bombing run. Bomb deorbit
burn motors would make it easier for a bomber to loiter for days and not
burn fuel to put bombs in a reentry trajectory. Price is certainly
less than a B-2.
Hmmm, I can see why the Air Force is interested...
--
<-:(= Anthony Stieber anthony@csd4.csd.uwm.edu uwm!uwmcsd4!anthony
------------------------------
Date: Thu, 10 Dec 1992 23:27:48 GMT
From: Brad Whitehurst <rbw3q@rayleigh.mech.Virginia.EDU>
Subject: DC info
Newsgroups: sci.space
In article <1992Dec10.152231.8279@cs.rochester.edu> dietz@cs.rochester.edu (Paul Dietz) writes:
>
>Question about the RL-10: what intake pressure do its pumps require
>to avoid cavitation? Hudson emphasizes that reducing this pressure
>is important in designing an SSTO, as lower pressure tanks can be
>lighter.
>
> Paul F. Dietz
As a data point, I was flipping through the new Aerospace
America, which gave the rated thrust for the newest RL-10 at a
combustion chamber pressure of 1000 psi. I suppose one could hazard
some guesses on fuel pressures from that, although not knowing the
pump's pressure ratio, the inlet pressure is still unknown. Just FYI.
The same issue also notes that composite test tanks have been
built for the NASP effort. Liquid H2 inside, 250 degrees F on the
outside!
--
Brad Whitehurst | Aerospace Research Lab
rbw3q@Virginia.EDU | We like it hot...and fast.
------------------------------
Date: Thu, 10 Dec 1992 23:10:13 GMT
From: "Loren I. Petrich" <lip@s1.gov>
Subject: dialog between D. Goldin and C. Sagan
Newsgroups: sci.space
In article <1992Dec8.204847.11925@unocal.com> stgprao@st.unocal.COM (Richard Ottolini) writes:
>Scattered throughout the evening were references to national politics.
>Sagan joked about Republican party follies.
I'd like to see some examples.
--
/Loren Petrich, the Master Blaster
/lip@s1.gov
------------------------------
Date: Thu, 10 Dec 1992 22:24:17 GMT
From: Larry Klaes <klaes@verga.enet.dec.com>
Subject: Electronic Journal of the ASA (EJASA) - December 1992
Newsgroups: sci.astro,sci.space,sci.space.shuttle,sci.misc,alt.sci.planetary
THE ELECTRONIC JOURNAL OF
THE ASTRONOMICAL SOCIETY OF THE ATLANTIC
Volume 4, Number 5 - December 1992
###########################
TABLE OF CONTENTS
###########################
* ASA Membership and Article Submission Information
* Further Analysis of EVA Self-Rescue Data - Adam R. Brody
* Transparency Films for Astrophotography - Brian G. Segal
###########################
ASA MEMBERSHIP INFORMATION
The Electronic Journal of the Astronomical Society of the Atlantic
(EJASA) is published monthly by the Astronomical Society of the
Atlantic, Incorporated. The ASA is a non-profit organization dedicated
to the advancement of amateur and professional astronomy and space
exploration, as well as the social and educational needs of its members.
ASA membership application is open to all with an interest in
astronomy and space exploration. Members receive the Journal of the
ASA (hardcopy sent through United States Mail - Not a duplicate of this
Electronic Journal) and the Astronomical League's REFLECTOR magazine.
Members may also purchase discount subscriptions to ASTRONOMY and
SKY & TELESCOPE magazines.
For information on membership, you may contact the Society at any
of the following addresses:
Astronomical Society of the Atlantic (ASA)
c/o Center for High Angular Resolution Astronomy (CHARA)
Georgia State University (GSU)
Atlanta, Georgia 30303
U.S.A.
asa@chara.gsu.edu
ASA BBS: (404) 564-9623, 300/1200/2400 Baud.
or telephone the Society Recording at (404) 264-0451 to leave your
address and/or receive the latest Society news.
ASA Officers and Council -
President - Don Barry
Vice President - Nils Turner
Secretary - Ingrid Siegert-Tanghe
Treasurer - Mike Burkhead
Directors - Bill Bagnuolo, Eric Greene, Tano Scigliano
Council - Bill Bagnuolo, Bill Black, Mike Burkhead, Frank Guyton,
Larry Klaes, Ken Poshedly, Jim Rouse, Tano Scigliano,
John Stauter, Wess Stuckey, Harry Taylor, Gary Thompson,
Cindy Weaver, Bob Vickers
ARTICLE SUBMISSIONS
Article submissions to the EJASA on astronomy and space exploration
are most welcome. Please send your on-line articles in ASCII format to
Larry Klaes, EJASA Editor, at the following net addresses or the above
Society addresses:
klaes@verga.enet.dec.com
or - ...!decwrl!verga.enet.dec.com!klaes
or - klaes%verga.dec@decwrl.enet.dec.com
or - klaes%verga.enet.dec.com@uunet.uu.net
You may also use the above addresses for EJASA back issue requests,
letters to the editor, and ASA membership information.
When sending your article submissions, please be certain to include
either a network or regular mail address where you can be reached, a
telephone number, and a brief biographical sketch.
Back issues of the EJASA are also available from anonymous FTP
at chara.gsu.edu (131.96.5.29)
DISCLAIMER
Submissions are welcome for consideration. Articles submitted,
unless otherwise stated, become the property of the Astronomical
Society of the Atlantic, Incorporated. Though the articles will not
be used for profit, they are subject to editing, abridgment, and other
changes. Copying or reprinting of the EJASA, in part or in whole, is
encouraged, provided clear attribution is made to the Astronomical
Society of the Atlantic, the Electronic Journal, and the author(s).
Opinions expressed in the EJASA are those of the authors' and not
necessarily those of the ASA. This Journal is Copyright (c) 1992
by the Astronomical Society of the Atlantic, Incorporated.
FURTHER ANALYSIS OF EVA SELF-RESCUE DATA
IAA-92-0385
Adam R. Brody
Senior Aerospace Engineer/Experimental Psychologist
Sterling Software
NASA Ames Research Center
Moffett Field, California, U.S.A.
Copyright (c) 1992 by Sterling Software. Published
by the International Astronautical Federation (IAF),
with permission.
Abstract
A means for rescuing a stranded Extra-Vehicular Activity (EVA)
astronaut is necessary to ensure future safe space station operations.
One promising device is a hand-held thruster similar to the Hand-Held
Maneuvering Unit (HHMU) from the GEMINI and SKYLAB programs of the
1960s and 1970s.
A study was performed in the Virtual Interactive Environment
Workstation (VIEW) at NASA Ames Research Center. Three Initial
(Separation) Velocities (0.5, 1.0, and 1.5 m/s) were crossed with five
Initial Spin Velocities (0, #177#0.1, #177#0.3) to yield 15 different
trials. An Attitude Hold system was also modeled, which, when
combined with the 15 combinations of separation and spin velocity,
provided 30 distinct trials.
Recent examinations of the data reveal that Initial (Separation)
Velocity and Initial Spin Velocity each produced main effects and
combined to produce an interaction effect on Solution Time. Solution
Time increased with Initial Velocity and absolute Initial Spin
Velocity. Final Roll Angle also increased Initial Spin Velocity.
Attitude Hold Fuel increased with absolute Initial Spin Velocity.
Interaction effects revealed that main effects were less pronounced
at the lowest Initial Velocity level.
Introduction
There are a number of organizations in the United States
developing devices to be used to return a stranded EVA astronaut to
a space station after an accidental separation. Some of the devices
merely extend the reach of the stranded crewperson with a pole or
other apparatus. These will only work when the separation velocity is
so small that the crew can unstow and operate the rescue tool before
s/he drifts further than the instrument's maximum operational range.
Once this maximum range is exceeded, propulsive techniques must be
used.
One possible propulsive device is the Hand-Held Maneuvering Unit
(HHMU) initially used in the United States' GEMINI program. Three
different models (varying by propellant type, total delta-v, and other
attributes) were developed and used. Experimentation continued in the
SKYLAB program.
The device simulated in the current series of experiments is
analogous to the HHMU. However, neither the thruster configuration
nor the propellant is specified. The amount of thrust is recorded as
a thrusting duration. The thrust force multiplied by the duration
yields the impulse, which when divided by the system mass, yields the
change in velocity or delta-v. This value for delta-v may then be
used to determine propellant mass for any combination of propellant
specific impulse and thruster configuration.
The current study was performed in the Virtual Interactive
Environment Workstation (VIEW) laboratory at the NASA Ames Research
Center. This simulator facility provided the user with a stereoscopic
visual image of the space station from which s/he has become separated.
The visual scene was altered not only by the equations of motion
governing orbital flight, but also by the changes in orientation and
position of the operator's head. In this way, an effective EVA
simulation was realized.
This study demonstrated the viability of using VIEW as an EVA
simulation facility. It also revealed separation velocity to be the
most important factor characterizing a separation scenario with fuel
consumption, maximum range, and time to reach maximum range increasing
linearly with separation velocity. In addition, no significant
benefits from an attitude hold capability were uncovered (although a
null effect cannot be proven). EVA trainers at the Johnson Space
Center in Houston, Texas, were sufficiently impressed with the study
that they considered using the facility for astronaut EVA rescue
training. This collaboration was precluded by lack of funding.
Many of the results of this study were presented elsewhere.
[1, 2, 3] Space limitations prevented inclusion of all the results;
additional results are described here. Also, the stated result that
no statistically significant solution time effects were found was
incorrect. These effects will also be discussed here.
Method
One highly-trained subject was used in this study. The subject,
situated in the VIEW, experienced sudden separations from the virtual
space station to which he was previously tethered. Using hand gestures,
which commanded the fore and aft firings of a virtual hand-held thruster,
he effected his returns to the station. The subject was trained until
he was able to recover consistently from a variety of separation
scenarios.
The subject was presented with an assortment of failure scenarios
with varying initial velocities, and rotation rates. The opportunity
to use attitude hold was allowed on only half the trials. Since
preliminary investigations revealed starting location to have less
of an effect on rescue performance than other input parameters, all
separations began at the center of mass of the space station. Motion
began in the direction of the minus velocity vector.
Three initial (separation) rates (0.5, 1.0, and 1.5 m/s) were used
in the study. These values were selected as appropriate based upon
separation dynamics tests performed on the KC-135 aircraft. In these
tests, test subjects were assisted in achieving the maximum separation
rates possible; a maximum separation rate of 1.5 m/s (4.5 ft/s) was
achieved. The maximum rotation rates were found to be 4.5 RPM (0.47
rad/s) in roll, 10.1 RPM (1.06 rad/s) in pitch and 5.8 RPM (0.61
rad/s) in yaw. [4] The five rotation rates (-0.3, -0.1, 0, 0.1, 0.3
rad/s) in this study were crossed with the translation rates to yield
a trial set of 15 different trials. Initial rates were the same
about all axes. Both negative and positive values were used because
preliminary testing suggested a handedness effect might be present.
The capability to use attitude hold was added as another factor
raising the number of distinct trials to 30. The subject was
presented with 2 different random orders of these 30 trials in groups
of 5. Dependent variables included: Mission duration, total velocity
increment, impact velocity, and maximum range from the station along
all three axes.
The subject was allowed one attempt at a rescue per trial. The
trial was aborted if he passed the station. These aborted missions
were immediately reflown.
The hand-held thruster fired an 8.9 N (2-pound) force along the
direction of the hand in either the fore or aft direction. All
thrusts that were not directed precisely through the center of mass of
the subject, which was located in the center of the subject's back,
added rotational motion along one or more axes.
An 8.9 N (2-pound) thruster requires 31 seconds to accelerate the
simulated crew mass of 274 kilograms to 1 m/s. This thrust must be
through the center of mass to avoid adding rotational motion. This
is virtually impossible, so achieving a velocity of 1 m/s typically
requires more than 31 seconds. [3]
The simulated space station was located in a 270 nautical mile
circular orbit around the planet Earth. Since it was impractical to
keep up with the rapidly changing design of space station FREEDOM,
the station was represented by two intersecting 5-meter trusses. The
horizontal dimension was 50 meters and the vertical dimension was 100
meters. [5]
Results
A data entry error prevented the discovery of several solution
time effects that were indeed present. Initial (separation) velocity
and initial spin velocity each produced statistically significant main
effects on solution time. They also combined for an interaction effect.
These effects were statistically significant at the five-percent level
and are discussed here.
Solution time increased monotonically with initial velocity as
described in Figure 1. This effect is intuitive and fits with similar
effects on fuel consumption, final axial velocity, and maximum range.
[1, 2, 3]
This effect was non-linear, however. Tripling the separation rate
from 0.5 to 1.5 m/s quadrupled the solution time, for example. This
was because the ratio of thrusting time to solution time was lower at
the two highest separation rates than at 0.5 m/s. Since proportionately
less time was spent thrusting at the higher rates, those missions took
longer than a simple multiple of the fastest response would predict.
There was more of a "thrust and wait" strategy with the longer missions
than with the shortest one. Proportionately more time was spent
verifying progress at the higher velocity separations than at the
lower velocity separations.
Figure Descriptions
Figure 1: Initial velocity effect on solution time. A solution
time effect was also observed with Initial Spin Velocity as the
independent variable. The plot appears as Figure 2. Fuel consumption
also increased with initial spin velocity as did maximum range. [1, 2,
3] Trials with higher initial spin velocities were more difficult
from which to recover.
Figure 2: Initial spin velocity effect on solution time.
Separation velocity and spin velocity combined to produce an
interaction effect on solution time as described in Figure 3.
Separations at a rate of 0.5 m/s were not affected by spin velocity
as much as separations at the two higher rates. Rapid response times
precluded greater impact of initial spin rate. The asymmetries in the
plots are due to a handedness effect. The thruster commands were sent
with the right hand only.
Figure 3: Separation and spin velocity interaction. Initial spin
velocity also produced a main effect on final roll angle. Interaction
effects with attitude hold, and separation velocity x initial spin
velocity, and separation velocity x initial spin velocity x attitude
hold interactions were also present.
Final roll angle increased with initial spin velocity as described
in Figure 4. Since final roll velocity (V spin Xf) remained close to
initial spin velocity [1, 2, 3] and solution times were greater for
higher initial spin rates than for lower rates, final roll angle was
proportional to initial spin velocity. The more time the subject spun
at a given rate, the greater the final angle was.
Figure 4: Final Roll Angle verses Initial Spin Velocity Two
interaction effects were observed in the final roll angle data.
Attitude hold and separation velocity were the disturbing factors
leading to inconsistent main effects. When the subject had the
capability of using attitude hold, the final roll angle was much
closer to zero than when attitude hold was unavailable. This effect
is described in Figure 5.
Figure 5: Attitude Hold x Initial Spin Velocity Interaction.
A two-way interaction between separation velocity and initial spin
velocity was also discovered. This effect appears in Figure 6.
Again, the curve for the 0.5 m/s separation velocity data is more
shallow and less pronounced than the other curves. At higher
separation velocities, the effect of initial spin velocity is
more prominent.
Figure 6: Initial Spin Velocity x Separation Velocity
Interaction. A second-order interaction of Separation Velocity x
Initial Spin Velocity x Attitude Hold was also revealed by the data.
The effects appear as Figures 7a and 7b for the disabled and enabled
Attitude Hold conditions respectively. The use of attitude hold
greatly reduced the final roll angle. Again, the curve for the
0.5 m/s data was shallower than those for the other two.
Figure 7a: Second order interaction with Attitude Hold Disabled.
Figure 7b: Second order interaction with Attitude Hold Enabled.
The data from trials in which Attitude Hold was available were
looked at separately to determine if there were any effects regarding
number of attitude hold commands or attitude hold fuel used along any
particular axis. The Pitch Attitude Hold data appear as a U-shaped
plot in Figure 8. More pitch attitude hold fuel was used at greater
initial spin rates.
Physically, more fuel is needed to eliminate higher initial spin
rates than lower rates. The moment of inertia for the pitch axis
was 108 kg-m2. An 8.9 N thruster at the end of a 1-meter moment
arm produces a torque of 8.9 N-m. These values yield an angular
acceleration of 0.08 rad/s2. At this rate, 1.25 s of thrust are
required to produce a spin rate of 0.1 rad/s. Similarly, 3.75 s
are needed to produce a rate of #177#0.3 rad/s.
The data in Figure 8 reveal actual (simulator) values to be fairly
close to theoretical values. In some cases, the subject reduced some
of the pitching himself, thus reducing the amount of time the pitch
attitude hold was needed. In other cases, the subject contributed to
the rotational motion and the attitude hold system had to work harder
to make up for this addition.
Figure 8: Pitch Attitude Hold Fuel. An interaction effect with
Separation Velocity and Initial Spin Velocity was also uncovered with
these data. Again, the 0.5 m/s data produced the shallowest curve.
Pitch Attitude Hold fuel increased with separation velocity.
Figure 9: Initial Spin Velocity x Separation Velocity Interaction
for Pitch Attitude Hold Fuel.
Discussion
In every interaction effect involving Initial Velocity discussed
here, and all cases (except final out-of-plane velocity) listed
elsewhere, [1, 2, 3] the curve for the lowest Initial Velocity was the
shallowest of the three. The lower solution times associated with the
lowest separation velocity (average = 51 s) prevented the curves from
taking a shape similar to those representing the higher velocity data.
The solution times were too short to let some of the effects come
through. Shorter solution times precluded the development of certain
effects in other studies also. [6, 7] There is a qualitative
distinction between self-rescue from a separation velocity of 0.5 m/s
and rescue from higher rates. More research is needed to better
quantify these effects.
Preliminary simulation results indicate that a hand-held thruster
is capable of serving as an EVA self-rescue device. Its utility is
greater than any physical extension of the crewmember's body since it
has a greater range of operation. Further study, including a flight
experiment on Space Shuttle Mission STS-49 (May of 1992), will reveal
more about the capabilities and deficiencies of such a system.
Other parameters to be examined include thruster magnitude and
system geometry. Motion-base carriage and air bearing floor facilities
can also contribute as described elsewhere. [1, 2, 3] This is a field
of study in its infancy and more attention and funding is encouraged.
References
1. Brody, Adam R., R. Jacoby, and S. R. Ellis, "Simulation of
Extra-Vehicular Activity (EVA) Self-Rescue", SAE Technical Paper
911574, Warrendale, Pennsylvania, July 1991.
2. Brody, Adam R., R. Jacoby, and S. R. Ellis, "EVA Self-Rescue
Simulation in the Virtual Interactive Environment Workstation
(VIEW)", Space Safety and Rescue 1990-1991, Science and Technology
Series, American Astronautical Society, San Diego, California,
in press.
3. Brody, Adam R., R. Jacoby, and S. R. Ellis, "EVA Self-Rescue Using
a Hand-Held Thruster", JOURNAL OF SPACECRAFT AND ROCKETS, in press.
4. Porter, S., "Separation Dynamics Tests," 1989.
5. Brody, Adam R., R. Jacoby, and S. R. Ellis, "Man Overboard! What
Next?", International Academy of Astronautics IAA-91-584, Paris,
France, October 1991.
6. Brody, Adam R., S. R. Ellis, A. J. Grunwald, and R. F. Haines,
"Interactive Displays for Trajectory Planning and Proximity
Operations", JOURNAL OF SPACECRAFT AND ROCKETS, in press.
7. Brody, Adam R. and S. R. Ellis, "Effect of an Anomalous Thruster
Input During a Simulated Docking Maneuver", JOURNAL OF SPACECRAFT
AND ROCKETS, Volume 27, Number 6, 1990, pages 630-633.
About the Author -
Adam R. Brody received S.B. and S.M. degrees in Aeronautics and
Astronautics from the Massachusetts Institute of Technology (MIT) in
Cambridge, Massachusetts, and a diploma as a member of the founding
conference of the International Space University (ISU). Adam also
received his M.A. degree in Psychology from San Jose State University
in California.
Adam is a senior aerospace engineer/experimental psychologist
for Sterling Software, Palo Alto, California. Among the NASA Ames
Research Center organizations with which he has worked are the
Centrifuge Facility Project Office, Human Interface Research Branch,
EVA Systems Branch, and the Aerospace Human Factors Research Division.
Adam is the author of over thirty-five research papers on various
topics relating to performance aspects of humans in space. Adam
pioneered a comprehensive study of the human factors and manual
control aspects of orbital flight and he developed the Space Station
Proximity Operations Simulator at Ames for his studies. He also
initiated a research program to quantify EVA rescue requirements, and
created of an orbital trajectory planning tool for the Macintosh
computer system.
Adam's research interests include the human factors and manual
control requirements of space station proximity operations and other
manned space flight operations. Recent work includes development
and simulation of an EVA self-rescue technique using the Virtual
Interactive Environmental Workstation (VIEW). Currently, he serves
as the human factors expert on the systems engineering staff of the
Centrifuge Facility Project Office at Ames, where he developed the
Payload Resource In Space Monitor (PRISM) for tracking resources on
the FREEDOM space station. He is currently using object-oriented
rapid prototyping to develop software requirements for the space
station facility.
Adam is a member of the Space Operations and Support Technical
Committee of the American Institute of Aeronautics and Astronautics,
where he is chairman of the Human Factors, Automation and Robotics
Sub-committee. He is also a member of the National Air and Space
Museum, the Union of Concerned Scientists, a founding sponsor of the
CHALLENGER Center, and a charter member of the Technology Center of
Silicon Valley. His biography is listed in Personalities of America,
the Dictionary of International Biography, Who's Who of Emerging
Leaders in America, Who's Who Among Young American Professionals,
and Who's Who in the West.
Adam is the author of "Soviet Spacecraft Docking Experience",
published in the October 1992 issue of the EJASA.
Adam may be reached through the Internet at either:
adam_brody@qmgate.arc.nasa.gov or brody@eos.arc.nasa.gov
TRANSPARENCY FILMS FOR ASTROPHOTOGRAPHY
by Brian G. Segal
Reprinted with permission from the March-April 1991 issue of
NOVA NOTES, the Newsletter of the Halifax Centre of The Royal
Astronomical Society of Canada (RASC).
The thought of tools for astrophotography usually brings to mind
images of huge apertures, fluorite elements, exotic guiders, freezing
cold cameras bathed in dry ice (usually redundant in Canada), dead
accurate drive systems, the soft red glow of reticules and tired eyes
- not to mention those supportive, understanding spouses condemned to
yet another night of just sitting there in the dark!
However, given a decent array of hardware, the most important
consideration facing the aspiring cosmic snapshooter is the choice of
"weapons", otherwise known as film. There is a kind of decision
tree that one must work through: Black and white or color; print or
transparency; fine and slow or grainy and fast; Kodak, Fuji, Konica,
Illford, etc..
Not surprisingly, many astro-shooters tend to specialize. Given
the time it takes to make astronomical images (other than the Moon or
Sun) and the number of opportunities for total, partial, or incidental
SNAFUs, simplification is a good strategy.
Consequently, my astrophotographic odyssey has been mostly
confined to the use of various transparency (slide) films. They
are my medium of choice. Different ones are suitable for different
applications. I have done considerable work with EKTACHROME 400,
KODACHROME 64, and FUJICHROME 50, 100, 400, and 1600. I have also
shot FUJICHROME 400 at an effective exposure value of ISO 800 and
had it push processed.
The slower films have been used exclusively for solar photography
and some lunar when the Moon is at least at first quarter phase. The
only limiting factor in this situation is the mechanical stability of
your system. The exposures have to be made on the long side, compared
with the focal length of the lens. A prime focus shot of the Sun taken
on an unstable 2000 mm scope will blur at the slightest vibration unless
you can shoot at 1/2000th of a second, which is unlikely. If you are
looking at shutter speeds of from one second to 1/500th of a second,
you had better have a real solid mount and lock up your camera's mirror
if it is an SLR system.
I have had good results with KODACHROME 64 and both FUJICHROME 50
and 100 when shooting the Sun with a Thousand Oaks full aperture solar
filter. Effective focal lengths of up to 25,000 mm through eyepiece
projection have yielded surprisingly good results on calm days.
Naturally at the higher magnifications various factors come into play,
including the amount of glass in the system, the seeing, and the care
taken by the photographer.
I have also used both EKTACHROME 400 and FUJICHROME 400 for this
type of photography. The trade off is a cooler color cast and a lot
more grain, especially during the longer exposures. Generally, we are
told, slow films have better reciprocity characteristics than faster
ones: There seems to be some substance to that claim. However, you
do achieve between a two to three-stop advantage, which translates to
faster shutter speeds and less camera shakes - in theory, anyway!
I have also used pushed FUJICHROME 400 for lunar shots using a
1000 mm f/11 Maksutov. The results were surprisingly good and allowed
me to photograph an almost full Moon without a drive.
Deep sky work is a very different challenge. All but the
brightest objects require relatively long exposures (to a daytime
photographer, anything longer than a few seconds is very long). Even
with the very fast print films (ISO 3200), ten minutes would be a
minimum exposure for the majority of diffuse and faint objects. As
film speed decreases, exposure length grows exponentially. Each stop
represents a doubling of exposure time as the ISO value is reduced.
Each doubling of exposure time increases the risk of any number of
problems, from the gradual accumulation of dew or frost to unfortunate
happenstance - like sneezing your head into the eyepiece, resulting in
possible eye damage and shaking the optics.
As any slide presentation will demonstrate, various emulsions have
very different characteristics. There are some factors which will
influence the choice of films. While EKTACHROME 400 tends to bring
out certain red nebular emissions very effectively, it suffers from
a lower contrast than its FUJICHROME 400 cousin. In fact, the sky
background tends to a kind of purplish cast while the FUJI retains
very black skies over fairly long exposures.
Naturally the seeing and general sky conditions have to be
comparable, but certainly my experience over a range of targets and
nights has confirmed this situation. I do find, however, that the
FUJI requires more exposure for certain objects, particularly
planetaries.
FUJICHROME RSP 1600 is the fastest transparency film in the FUJI
line. Its optimum rated value is ISO 1600, although it can be pulled
to ISO 800 or pushed to ISO 3200. Although KODAK makes EKTACHROME
P800/1600, a film that makes similar claims, in fact its optimum
rating is ISO 800 with a one or two-stop push possible. The fact that
the FUJI product is "comfortable" at 1600 means that the one-stop push
to 3200 is asking less of the film. As push processing does have both
color shift and granular effects on the final image, the less push,
the better.
I have used the RSP 1600 in daylight as well as night time
photography and can attest to its quality. It has surprisingly fine
grain characteristics and although rather high in contrast compared to
a slower chrome film, its color response is quite good. The higher
contrast level is a plus in astrophotography. The skies in exposures
of up to forty minutes stay quite blue-black with very good color
range in the stars and gasses. You will have to be careful of
several things, though:
GUIDING: Very sensitive emulsions gather light at an alarming
speed. Any deviations in guiding are preserved obviously and
mercilessly for all time within seconds. With ISO 400 films a bit of
wander due to periodic drive error or distractions of one sort or
another can be recovered from with little or no evidence. However, a
quick glimpse at a meteor at the wrong moment with ultra-fast film can
leave a lasting memory on the emulsion.
FOGGING: Ultra-high speed films are very susceptible to ambient
light, whether from city lights, celestial background light, or that
yard light your neighbor has installed across the valley just to make
your observing that much more of a challenge! The message is to be
in a dark place and wait *patiently* for astronomical twilight to
surrender to real night!
With any transparency processing it is a good idea to write those
three important words "DO NOT CUT" on the envelope. Although I always
take the precaution of exposing the first frame in daylight to give
the processors a reference frame, I much prefer to cut and mount my
own slides for two reasons:
1 - I use a mini-cassette recorder for note-taking during a
session. All of the data is subsequently preserved frame by frame.
Thus, when the film comes back, I simply turn on the tape and review
the strip of film to my own commentary. As I cut and mount the
slides, the information is recorded in indelible ink on the mount.
You cannot count on the processor to sequentially mount your slides:
They do screw up at times!
2 - There are, alas, always shots that do not make it. Why
bother having them mounted?
Another transparency material that is often overlooked is black
and white negative film. A negative tonal "slide" can be quite
dramatic and add another dimension to projectable images.
Whatever the application you may have planned for your
astrophotography, transparency films offer a variety of choices and
possibilities. If you decide that you have an image that simply must
be printed, you can always go the route of reversal printing and have
a large internegative made. Thus, the versatility of transparency
films makes them an attractive option for astrophotography.
Related EJASA Articles -
"Astrophotography the Easy Way", by Harry Taylor - October 1991
"Telescopes: A Novice's Guide", by Steven M. Willows - March 1992
About the Author -
Brian G. Segal is a visual artist living in Antigonish, Nova
Scotia, Canada, where he has operated a ceramic design studio with
his wife, Julia, for the past sixteen years. In addition, Brian is
a professional commercial photographer specializing in still life
and product, architectural, and corporate/industrial photography.
Brian's hobby is astrophotography, which he tackles with a twenty-
centimeter (eight-inch) Meade SCT, a bunch of hardware, various slide
films, and the clear, very dark skies of his rural location - whenever
it decides to clear up, that is! Brian is also a member of the
Executive Committee of the Halifax Centre of the Royal Astronomical
Society of Canada (RASC).
Brian's Internet address is: astro@esseX.stfx.ca
THE ELECTRONIC JOURNAL OF THE ASTRONOMICAL SOCIETY OF THE ATLANTIC
December 1992 - Vol. 4, No. 5
Copyright (c) 1992 - ASA
------------------------------
Date: 11 Dec 92 01:31:58 GMT
From: Pat <prb@access.digex.com>
Subject: Terminal Velocity of DCX? (was Re: Shuttle ...)
Newsgroups: sci.space
In article <Bz0svx.KEA@news.cso.uiuc.edu> jbh55289@uxa.cso.uiuc.edu (Josh 'K' Hopkins) writes:
>gary@ke4zv.uucp (Gary Coffman) writes:
>
>>I support the DC-X tests. The data developed may be useful in later
>>vehicles and the cost is not excessive. Like the X-15, however, I
>>doubt it's design will scale to commercial products. How many airliners
>>are derived from the X-15? The SR71 is the only manned vehicle that vaguely
>>resembles the X-15 and it's flight systems are entirely different. And
>>it's being retired as not cost effective for it's mission.
>
>Actually, I think shuttle derived a fair amount of value from the X-15 research
>even if it doesn't look the same. In addition saying that the SR-71 is being
I imagine that the X-15, set up a huge amount of data for the NASP as well
as the STS. the X-15 also probably provided test data for the ICBM
re-entry vehicle design. i think NASA programs such as SABER?, HL-20,
... pulled data from the X-15. the X -15 also procided a lot of data
on RCS systems, redundant system design and thermal stress design.
The only reason commercial products did not come out of the entire plane
was that we decided to run away from space during the Nixon administration.
Goldin was just on TV, talking abou;the X-15, and how 25 years ago we
stepped away from the cutting edge. now if we had kept pushing forward,
instead of deciding that attacking small asian countries was a more
noble purpose for the US, we would have regular trips to mars by now.
------------------------------
End of Space Digest Volume 15 : Issue 534
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