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OFFICE OF PUBLIC INFORMATION JET PROPULSION LABORATORY, CALIFORNIA INSTITUTE OF TECHNOLOGY NATIONAL AERONAUTICS AND SPACE ADMINISTRATION PASADENA, CALIFORNIA. TELEPHONE 354-5011 MARINER '69 FACT SHEET The National Aeronautics and Space Administration will launch two Mariner spacecraft, F & G, on fly-by missions to Mars in 1969. Project responsibility is assigned to the Jet Propulsion Laboratory of the California Institute of Technology. NASA's Lewis Research Center, Cleveland, is responsible for the launch vehicle. Tracking and communication will be provided by the Deep Space Net stations operated by JPL for NASA. The Mariner Mars '69 launch period falls between mid- February and mid-April. The spacecraft will arrive at Mars between the end of July and mid-August. The first spacecraft will be launched as early in the period as possible the second as late as possible. The arrival dates will not be less than five days apart. The launch vehicle for this mission is the Atlas/Centaur combination; the first time this combination has been used for planetary exploration. The spacecraft will weigh approximately 900 pounds compared with 575 pounds for the Mariner Mars '64 mission. All scientific experiments aboard the Mariner '69 are planet-oriented with particular emphasis on providing data on the atmosphere and surface of Mars. The experiments aboard Mariner '69 are as follows: -2- __________ _______ ______________________ Infrared Measure the infrared Dr. G. C. Pimentel Spectrometer spectral energy from the University of California lower atmosphere and Berkeley surface at 1.9 to 14.7 microns. Infrared Measure thermally emitted Dr. G. Neugebauer Radiometer energy from the surface California Institute of in the regions of 8.0 to Technology 12.0 and 18.0 to 25.0 microns. Ultraviolet Detect the presence and Dr. C. A. Barth Spectrometer scale height of atmos- University of Colorado phere constituents by Boulder, Colorado measurements in the 1100 to 4500 Angstrom region. Television Photograph planetary disc Dr. R. B. Leighton and surface California Institute of Technology S-Band Determined atmospheric Dr. A. J. Kliore Occultation surface pressure and den- Jet Propulsion Laboratory sity and variations with height and latitude. Celestial Refine accuracy of the Dr. J. D. Anderson Mechanics Earth and Mars orbits, Jet propulsion Laboratory Mars Mass, Earth-Moon mass ratio and the astronomical unit. On currently designed trajectories the two spacecraft will fly-by Mars at a closest approach distance of approximately 2000 miles. In the 1964 mission the closest distance was 6000 miles. The extremely close approach, which will occur when Mars is about 62 million miles from Earth, includes a 30,000 to 1 probability that the spacecraft will not impact and contaminate the planet Mars. -3- The two camera systems, wide-angle and narrow angle aboard each spacecraft will provide narrow angle photographs of the disc of Mars as it revolves in front of the approaching spacecraft during far-encounter, and both wide-and narrow-angle pictures of the planet's surface during the near-encounter fly-by. The best resolution of the full disc pictures will be about 1 1/2 miles; the resolution of the near-encounter pictures about 3000 yards for the wide angle camera and 300 yards for the narrow angle camera. The Martian moon Phobos may be visible in some of the approach pictures. A minimum of thirty-three TV pictures will be obtained by each spacecraft. At least eight of the pictures will be at a range which will show the entire disc of the planet (far-encoun- ter). (Optional sequences under consideration can provide additional far-encounter pictures). The remaining twenty-five pictures will be taken as the spacecraft fly past the planet, (near-encounter). The Infrared Radiometer (IRR), Infrared Spectrometer (IRS) and Ultraviolet Spectrometer (UVS) will scan the same areas photographed by the two cameras to allow correlation of data. They will also scan the planet's dark side. Data from the IRR, IRS and the UVS will yield information on temperatures in the atmosphere and at the surface and the composition of the upper and lower atmosphere. Mariner '69 design is based upon the successful Mariner missions to Venus 1962, Mars 1964, and Venus 1967. Comparison -4- between 1964, and Venus 1967. Comparison between 1964 and 1969 reflect the growth and improvements in the Mariner class spacecraft. ____________ ____________ Weight 575 lbs. 900 lbs. Transmitter 10 watts 20 watts Bits per second 8 1/3 270 and 16,200 Bits per picture 240,000 3,991,680 Record time per picture 24 sec. 42.24 sec. Weight of Science Instruments 60 lbs. 141.18 lbs. Closest approach 6118 miles 2000 miles Mariner 1969 has been designed to provide a number of options in the operation of the two spacecraft after launch if in-flight performance and the availability of ground tracking facilities permit. The options will allow enhancement of mission results. Encounter of the two spacecraft with Mars will be designed to allow one spacecraft to fly-by the Southern polar cap and the other near the Equator. The point of closest approach will occur over the tracking and communication station of the Deep Space Net Station at Goldstone, California. Program Manager for Mariner Mars '69 is N. W. Cunningham, of the Office of Space Science and Application, NASA, Washington. Harris M. Schurmeier, is Project Manager for the Mars mission for the Jet Propulsion Laboratory. ### 472/5/15/68