PUBLIC INFORMATION OFFICE
JET PROPULSION LABORATORY
CALIFORNIA INSTITUTE OF TECHNOLOGY
NATIONAL AERONAUTICS AND SPACE ADMINISTRATION
PASADENA, CALIF. 91109.  TELEPHONE (818) 354-5011

Contact: James H. Wilson

FOR IMMEDIATE RELEASE                   December 9, 1992

     Thirty years ago, Dec. 14, 1962, the first successful
interplanetary traveler reached Venus after a 108-day journey
from Earth.  Named Mariner 2, it was a 200-kilogram (450-pound)
machine carrying six scientific instruments, a two-way radio, a
solar power system and assorted electronic and mechanical
devices.  Its crew, numbering roughly 75, stayed behind at NASA's
Jet Propulsion Laboratory.  

     The Mariner planetary spacecraft series began in 1960 as a
group of mission studies at JPL; by 1975 there had been 10
Mariner flights, seven of them successful explorations of the
inner Solar System.  Mariner 2 became the model for planetary
space flights,  one that emphasized good and copious scientific
data collection, utilizing remote sensing of planets and in-situ
measurement of the space environment; all of is this supported by
high-quality engineering. 

     The resulting program eventually led to close observation of
all the planets but Pluto, planetary orbiters and landers,
international cooperative missions and flights right out of the
Solar System.       What became the Mariner 2 mission was
authorized by NASA in August 1961, less than a year before the
first launch window.  The limited capacity of Atlas/Agena, the
largest available launch vehicle, severely restricted launch
opportunities and spacecraft size.  The first launch, Mariner 1,
was aborted when its launch vehicle strayed from the safe flight
corridor and was destroyed by the Range Safety Officer.  

     Mariner 2 was successful, however; since that trailblazer
mission, there have been about four dozen U.S., Soviet and other
flights -- the majority successful -- reaching every planet from
Mercury to Neptune, plus comets and an asteroid, and one joint
U.S.-European mission (still underway) to the poles of the Sun. 
These are in addition to dozens of lunar spacecraft and the
manned lunar flights of Project Apollo.

                             Liftoff

     A few minutes before 2 a.m. on Aug. 27, 1962, Mariner 2
lifted off the pad at Cape Canaveral aboard its Atlas-Agena
rocket.  It was nearly as much an experiment for the rocket and
spacecraft engineers as for the space scientists intent on
observing interplanetary space and the planet Venus.   

     During its three-and-a-half-month odyssey of some 290
million kilometers (180 million miles), reaching a third of the
way around the Sun to Venus, Mariner 2 transmitted coded signals
continuously to the Earth, mixing scientific measurements of
interplanetary dust, magnetism, cosmic rays and solar plasma with
engineering data on the health and performance of the spacecraft.

     As Earth turned beneath the feeble radio transmissions,
three great steerable antennas (now the Deep Space Network)
captured Mariner's signals in turn, first in California, then
Australia, Africa and California again.

     Mariner 2 suffered and survived a number of unanticipated
events during the flight.  It lost its attitude orientation; one
of the solar panels failed; many temperature readings rose
ominously as Mariner approached Venus; and, just before the Venus
encounter, the computer/sequencer became erratic.  But Mariner
automatically recovered its orientation, survived solar heating,
and, as sunlight grew more intense, one solar panel did the work
of two.  When the flight engineers saw the sequencer faltering,
they started the encounter sequence by radio commands from Earth.

     On Dec. 14, 1962, Mariner's infrared and microwave
radiometers scanned back and forth across the planet, capturing
data that would prove Venus's surface to be fire-hot -- about 425
degrees Celsius or 800 Fahrenheit -- warmed in part by a runaway
greenhouse effect in the thick carbon dioxide atmosphere.  About
three weeks after its historic Venus flyby, Mariner 2 went off
the air.  Its signal was last received on Jan. 3, 1963.

     The ability of Mariner's crew and equipment to overcome in-
flight problems, and simply to complete the flight to the planet
Venus, constituted major technical advances in addition to the
scientists' discoveries about Venus and the Solar System.  The
spacecraft design proved robust, and the attitude-stabilized
spacecraft concept feasible for long-term exploration. 

                             To Mars

     Two years later -- Nov. 28, 1964 -- a second-generation
Mariner set forth -- this time on an eight-month journey to Mars. 
Mariner 4, like its predecessor, survived the loss of a twin and
the rigors of an alien environment.  Also like the earlier
Mariner it was extremely light in weight, solar-powered, fully
stabilized, automated, in constant contact with a team of
engineers and scientists back on Earth and bristling with
instruments.  

     Unlike Mariner 2, this machine could see: a TV camera and
tape recorder caught the first close-up pictures of the surface
of Mars, revealing moon-like craters, some of them topped with
frost.  The navigators sent Mariner 4 behind Mars, letting the
radio link with Earth serve as a probe of the atmospheric density
and revealing a surface pressure less than 1 percent of Earth's.

     Following the pattern set by Mariner 2 and Mariner 4,
NASA/JPL sent spacecraft back to Venus and Mars, into Mars orbit
and to Mercury.  The latter flight, made by Mariner 10 in 1973-
74, used the gravitational field of Venus to boost it inward to
the orbit of Mercury.  In the 1970s, various USSR spacecraft
orbited Venus, entered its thick atmosphere, even landed.

     In 1976, two NASA scientific stations landed on Mars,
remaining in operation for several years. This Viking mission,
encompassing two large Mars-orbiting spacecraft as well as the
two landers, conducted a comprehensive, long-term mapping survey
of the entire planet, spot investigations of special areas
(including the moons Phobos and Deimos), and atmospheric studies.
Viking also produced biological, chemical, meteorological,
physical and image data collected at the landing sites.

                          A Grand Tour

     A year later two spacecraft were launched on what became the
grand tour of the outer planets: the Voyager mission to Jupiter,
Saturn, Uranus, Neptune and -- still going -- beyond the Solar
System to interstellar space.  Voyager 1 used Jupiter's
gravitational field to speed it on to Saturn and then, after tens
of thousands of images of the two planets and their many
satellites, it left the plane of the ecliptic.  Voyager 2 also
flew past Jupiter (1979) and Saturn (1981), but its path was
designed to use additional gravity assists to sling it onward to
Uranus (1986) and Neptune (1989). 

     The two Voyagers took a total of well over 100,000 images of
the outer planets, rings and satellites, as well as millions of
chemical spectra, magnetic and radiation measurements.  They
discovered rings around Jupiter, volcanoes on Io, shepherding
satellites in Saturn's rings, new moons around Uranus and
Neptune, geysers on Triton.  The last imaging sequence was
Voyager 1's portrait of the Solar System, showing Earth and six
other planets as sparks in a dark sky lit by a single bright
star, the Sun. 

     Two spin-stabilized Pioneer spacecraft had preceded the
Voyagers to Jupiter, and one of them went on to Saturn, before
heading out of the System.  Thus, four NASA spacecraft are now
actively searching, in different directions, for the frontier
between solar and interstellar space; at least one is expected to
detect it in the next quarter-century.

                             New Era

     Shortly before Voyager 2's Neptune encounter, a new
generation of planetary exploration began.  Magellan set out for
Venus in 1989 to map the surface from orbit using imaging radar. 
A Pioneer spinning spacecraft had been orbiting Venus for more
than a decade, completing a low-resolution radar topographic map
and many other planetary and solar studies; the Soviets compiled
radar images of the northern part of Venus, landed more cameras
and deployed balloons into the atmosphere.  Magellan mapped 99
percent of the surface at high resolution, parts of it in stereo,
and is presently mapping the gravitational field.

     In October 1989, NASA/JPL's Galileo spacecraft began a
gravity-assisted journey to Jupiter, where it will place a probe
in the atmosphere and observe planet and satellites from orbit
for two years.  On the way, Galileo performed gravity-assist
encounters with Venus and the Earth and made the first close
flyby of asteroid Gaspra in 1991.

     In a joint mission with the European Space Agency, NASA
launched the Ulysses spacecraft in 1990 on a flight over the
poles of the Sun.  To achieve high orbital inclination, the
spacecraft did a gravity-assist flyby of Jupiter, measuring the
magnetosphere as it did so.

     In September 1992, Mars Observer was launched to Mars.  It
is scheduled to go into orbit around the planet in August 1993
and make many observations during a period of one Martian year.

     As 1992 rounded out three decades of scientific growth and
achievement in observing and understanding the Solar System and
the development of highly sophisticated spacecraft and missions,
NASA began to look anew to the small, purposeful, higher-risk
kind of mission represented by Mariner 2 thirty years ago. 

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