ALTERNATES AT 17 NOVEMBER 1989 NATIONAL SPACE COUNCIL MEETING

Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 ILLEGIB Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 FOR OEQCONLY Alternates at 17 November 1989 National Space Council Meeting White House Chief of Staff Office for Economic and Domestic Policy NASA J.R. Thompson, Aaron Cohen, Ken Pedersen, and John Young ICS State Treasury Commerce OMB Defense OSTP NSC Transportation JCS Fred Bernthal Richard Del Bello Robert Grady Doug Graham Judy Bostock Will Toby Brigadier General Jerome Jones DOE John Tuck FOR 0FL?tTSE ONLY STAT Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 +1, -t-AArylt (14-?1J\02.Adt4v4L CAX ebiAlArArAKW?A-4 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 , FOR OFFICIAL USE ONLY Attendees at 17 November 1989 National Space Council Meeting White House Chief of Staff Office for Economic and Domestic Policy Vice President Dan Quayle, Chairman Governor John Sununu Mr. Brad Mitchell NASA Vice Admiral Richard Truly DCI Judge William Webster State The Honorable Reginald Bartholomew Treasury The Honorable Sidney Jones Commerce The Honorable John Shaw OMB The Honorable Richard Darman Defense The Honorable Donald Rice OSTP The Honorable Allan Bromley NSC The Honorable Arnold Kantor Transportation Ms. Stephanie Lee-Miller JCS General Robert Herres DOE Admiral James Watkins FOR OFFICIAL USE ONLY Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 SUBJECT: (Optional) Point Paper for ROM: ROUTING AND RECORD SHEET 1 Space Council Meeting - 17 November 1989 (U) Acting Director, Intelligence Community Staff TO: (Officer designation, room number, and building) ? Executive Registry Rm 7E12, OHB - DATE 1 EXTENSION NO. ICS 4354-89 RECEIVED FORWARDED 1 6 NW 1989 DATE 16 November 1989 OFFICER'S COMMENTS (Number each comment to show from whom INITIALS to whom. Draw a line across column ,after each comment.) 4. Director of Central - - _ 10. 1 1 . 12. 13. 1 5. 4 FORM 610 1-79 USE PREVIOUS EDITIONS u'40, iftv er" /MALI 7- FOR OFFICIAL USE ONLY Declassified in Part - Sanitized Copy Approved for Release 2013/11/04 : CIA-RDP91B01306ROnnfInnn7nnn_7 Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91601306R000300070005-7 ' cek.:7 ? THE FOLLOWING DOCUMENTS ARE ATTACHED: (Please do not remove) el t-'/4'2 5R yq92/1 'OR 89- itc/92/2. 'ICS 4133,3 - 89 /Cs 4110 - 89 SUBJECT: NovemBER 17, 11 81 IWATIONAL SPACE covovcit. Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91601306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 FOR OFFICIAL USE ONLY ROUTING AND RECORD SHEET SUBJECT: (Optional) Point Paper for National Space Council Meeting - 17 November 1989 ? Acting Director, Intelligence Community Staff TO: (Officer designation, room number, and building) EXTENSION NO. ICS 4354-89 (U) 44-.41-71%qs'q4)TAT DATE DATE 16 November 1989 STAT RECEIVED FORWARDED OFFICER'S INITIALS COMMENTS (Number each comment to show from whom to whom. ?Draw a line across column after each comment.) . ER Rm 7E12, OHB 3. 4. 9. 10. 12. 13. 14. 15. ( EXEC Oct FORM 610 USE PREVIOUS 1-79 EDITIONS FOR OFFICIAL USE ONLY riE3 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 _ Declassified in Part - Sanitized Copy Approved for Release :2013/11/04: CIA-RDP91B01306R000300070005-7 Ed/1E24..1U 11 V Ed 0EA.,11E. 1 ttillt1 1 ROUTING SLIP TO: ACTION INFO DATE INITIAL 1 DCI X 2 DDCI X 3 EXDIR 4 D/ICS X 5 DDI 6 DDA 7 DDO 8 DDS&T 9 Chm/NIC 10 GC 11 IG 12 Compt 13 D/OCA 14 D/PAO 15 D/PERS 16 D/Ex Staff 17 18 19 20 21 A. git SUSPENSE Date Remarks To 4: As the DCI's surrogate for the Space Council, suggests you attend as 0ISTAT principal since DDCI will be on TDY. Also, select someone to attend with you. ER 89-4492 Executive Secretary 1 Nov 89 Date 3637 (10-81) Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306 R000300070005-7 Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 -?jALA.0 1 1 V I .A.AVE, 1 ./-11?1/-1.1 TO: ROUTING SLIP CTION INFO DATE INITIAL X 722.4C1 DCI -3 EXDIR 4 D/ICS X 5 DDI 6 DDA 7 DDO 8 DDS&T 9 Chm/NIC 10 GC 11 IG 12 Compt 13 D/OCA 14 D/PAO 15 D/PERS 16 D/Ex Staff 17 18 19 20 21 22 SUSPENSE Date Remarks To 4: As the DCI s surrogate for the Space Counci1 3uggests you attend as ouSTAT principal since DDCI will be on TDY. Also, select someone to attend with you. ER 89-4492 DCI EXEC REG Executive Secretary 1 Nov 89 Date 3637 (1041) Declassified in Part - Sanitized Copy Approved for Release 2013/11/04 : CIA-RDP91B01306 R000300070005-7 ? v en, r 14 4 Declassified in Part - Sanitized Copy Approved for Release 2013/11/04 : CIA-RDP91B01306R000300070005-7 r ' NATIONAL SPACE COUNCIL EXECUTIVE OFFICE OF THE PRESIDENT - WASHINOTON. D.C. 20500 November 1, 1989 MEMORANDUM FOR MR. J. STAPLETON ROY Executive Secretary Department of State MS. EMILY I. WALKER Executive Secretary Department of Treasury COL GEORGE P. COLE, JR. Executive Secretary Department of Defense MR. CRAIG R. HELSING Chief of Staff Department of Commerce MS. RUTH MOUSE Director, Executive Secretariat Department of Transportation GOV. JOHN H. SUNUNU Chief of Staff to the President SUBJECT: National Space ER 89-4492 MR. G. PHILIP HUGHES Executive Secretary National Security Council MR. FRANK HODSOLL Associate Director Office of Management and Budget DR. ALLAN BROMLEY Director Office of Science and Technology Policy BRIG GEN THOMAS WHITE Executive Assistant to the Chairman Joint Chiefs of Staff MS. JESSIE HARRIS Executive Officer National Aeronautics and Space Administration MR. H. LAWRENCE SANDALL Executive Secretary Central Intelligence Agency Council Meeting The Vice President will chair a one hour meeting of the National Space Council on November 17, 1989, beginning at 11:00 a.m., to receive a presentation from the Administrator of NASA and consider aspects of the President's space exploration initiative. The meeting will be in the Cordell Hull Conference Room, OEOB room 208. Attendance will be limited to principal, plus one. Please provide names of meeting attendees to Cynthia Chase at 395-61751 by noon, Wednesday, November 15. MARK J. ALBRECHT Executive Secretary nprlacRified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part - Sanitized Copy Approved for Release 2013/11/04 : CIA-RDP91B01306R000300070005-7 FOR OFFICIAL USE ONLY POINT PAPER FOR NATIONAL SPACE COUNCIL MEETING 17 NOVEMBER 1989 Time/Place o The meeting will be at 10:00 a.m. in the Cordell Hull Conference Room, 0E0B, Room 208. STAT o The AD/ICS, will accompany the DCI. Purpose of Meeting NASA Administrator, Vice Admiral Truly, will present NASA's results of its study on space exploration. (See meeting announcement Tab A.) o This is not a decision meeting. Discussion o In support of the President's space exploration initiative, NASA prepared a document, "Report of the 90-Day Study on Human Exploration of the Moon and Mars" (Tab B). o The report provides a data base for future Administration decisionmaking on the space exploration initiative. It considers five reference approaches and addresses questions of program objectives, schedules, technologies, and resource requirements. In addition, the report provides information regarding the benefits of the space exploration initiative, international participation considerations, and potential management enhancements. o Vice Admiral Truly gave a briefing at the National Space Council's Policy Implementation and Review Committee (PIRC) meeting on 15 November 1989. The briefing summarized and closely follows the 90-day study. Therefore, we suggest you try to read at least the Executive Summary prior to the meeting. o Several issues and comments did come up in the discussions which followed the briefing. The issues dealt with the costs of this initiative and releasability of the report. Both issues were discussed in the PIRC MFR, dated 15 November 1989 (Tab C). FOR OFFICIAL USE ONLY Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 FOR OFFICIAL USE ONLY o Anticipated Space Council attendees for the 17 November meeting (Tab D). Recommended Talking Points o No comments are required or recommended. Background Material o The background point paper (Tab E) for the last Space Council meeting provides information on the larger effort in support of the President's space exploration initiative. Attachments: A. National Space Council Memo, dtd 14 Nov 1989 B. NASA's Report of the 90?Day Study on Human Exploration of the Moon and Mars C. PIRC MFR, dtd 15 Nov 1989 D. Space Council Attendees, dtd 17 Nov 89 E. Background Point Paper for National Space Council Meeting, dtd 26 Oct 1989 FOR OFFICIAL USE ONLY Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 FOR OFFICIAL USE ONLY SUBJECT: Point Paper for National Space Council Meeting- 17 November 1989 (U) I CS/PPO, STAT (15 November 1989) Distribution: (ICS 4354-89) Orig - DCI 1 - ER 1 - AD/ICS 1 - D/PPO 1 - DD/PPO 1 - PPO Chrono 1 - PPO Subject (Fay) 1 - DD/PPO Chrono 1 - ICS Registry FOR OFFICIAL USE ONLY Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release, 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 TAB A NATIONAL SPACE COUNCIL EXECUTIVE OFFICE OF THE PRESIDENT WASHINGTON, D.C. 20500 November 141. 1989 MEMORANDUM FOR MR. J. STAPLETON ROY Executive Secretary Department of State MS. EMILY L. WALKER Executive Secretary Department of Treasury COL GEORGE P. COLE, JR. Executive Secretary Department of Defense MR. THOMAS MURRIN Deputy Secretary Department of Commerce MS. RUTH KNOUSE Director, Executive Secretariat Department of Transportation COV. JOHN H. SUNUNU Chief of Staff to the President MR. ROBERT MATHIAS Executive Assistant to the Secretary Department of Energy MR. G. PHILIP HUGHES Executive Secretary National Security Council MR. FRANK HODSOLL Associate Director Office of Management and Budget DR. ALLAN BROMLEY Director Office of Science and Technology Policy BRIG GEN THOMAS WHITE Executive Assistant to the Chairman Joint Chiefs of Staff MS. JESSIE HARRIS Executive Officer National Aeronautics and Space Administration MR. H. LAWRENCE SANDALL Executive Secretary Central Intelligence Agency SUBJECT: National Space Council Meeting The Space Council meeting, previously scheduled for Friday, November 17, at 11:00 a.m., has been moved to 10:00 a.m. The meeting will be in the Cordell Hull Conference Room, OEOB room 208. MARK J. ALBRECHT Executive Secretary Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 NATIONAL SPACE COUNCIL EXECUTIVE OFFICE OF THE PRESIDENT WASHINGTON, D.C. 20500 November 14, 1989 MEMORANDUM FOR THE POLICY AND IMPLEMENTATION REVIEW COMMITTEE SUBJECT: NASA Report to Admiral Truly on Human Space Exploration The PIRC meeting scheduled for tomorrow, November 15, and the subsequent National Space Council meeting on Friday, November 17, are convened to allow NASA to present the results of its study on space exploration. The study was prepared under the supervision of Dr. Aaron Cohen, Director of the Johnson Space Center, and submitted to the NASA Administrator. I attach copies of the study for your use prior to these meetings. The Vice President will be seeking independent views and analyses of human exploration alternatives in the weeks ahead. Within a few days, we will be asking for help in conducting such analyses. This process will support the Space Council deliberations in December and January. Please note that the Space Council meeting on Friday, November 17, previously scheduled for 11:00 a.m., has been moved to 10:00 a.m. Attachment MARE J. ALBRECHT Executive Secretary Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 NATIONAL SPACE COUNCIL EXECUTIVE OFFICE OF THE PRESIDENT WASHINGTON, D.C. 20500 November 14,. 1989 MEMORANDUM FOR MR. J. STAPLETON ROY Executive Secretary Department of State SUBJECT: MS. EMILY L. WALKER Executive Secretary Department of Treasury COL GEORGE P. COLE, JR. Executive Secretary Department of Defense MR. THOMAS MURRIN Deputy Secretary Department of Commerce MS. RUTH KNOUSE Director, Executive Secretariat Department of Transportation GOV. JOHN H. SUNUNU Chief of Staff to the President MR. ROBERT MATHIAS Executive Assistant to the Secretary Department of Energy MR. G. PHILIP HUGHES Executive Secretary National Security Council MR. FRANK HODSOLL Associate Director Office of Management and Budget DR. ALLAN BROMLEY Director Office of Science'and Technology Policy BRIG GEN THOMAS WHITE Executive Assistant to the Chairman Joint Chiefs of Staff MS. JESSIE HARRIS Executive Officer National Aeronautics and Space Administration MR. H. LAWRENCE SANDALL Executive Secretary Central Intelligence Agency National Space Council Meeting The Space Council meeting, previously scheduled for Friday, November 17, at 11:00 a.m., has been moved to 10:00 a.m. The meeting will be in the Cordell Hull Conference Room, OEOB room 208. MARK J. ALBRECHT Executive Secretary Declassified in Part - Sanitized Copy Approved for Release 2013/11/04 : CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 NASA National Aeronautics and Space Administration Washington, D.C. 20546 Reply to Attn 01 A Vice Admiral Richard H. Truly Administrator National Aeronautics and Space Administration NASA Headquarters Washington, DC 20546 Dear Admiral Truly: I am providing you the report resulting from our 90-day study to examine elements of the President's Human Exploration Initiative. This report represents the effort of teams from across the Agency. Each Program Associate Administrator developed functional and discipline assessments for the Initiative and participated in the integration of the overall study. NASA centers and JPL participated in the program office assessments and contributed members to the study team. A technical study group integrated the inputs of the center representatives and conducted detailed analyses and trade studies. Finally, a report assembly team worked with all involved to produce the enclosed report. Throughout the study, reviews were conducted by the Associate Administrators and center directors as well as a review team made up of senior agency officials. As described in the Preface, this report provides a data base for future Administration decision-making on the Human Exploration Initiative. It considers five reference approaches and addresses questions of program objectives, schedules, technologies, and resource requirements. In addition, the report provides information regarding the benefits of the Human Exploration Initiative, international participation considerations, and potential management enhancements. We believe this report represents a good starting point for Council deliberations and we plan to continue our efforts as the Human Exploration Initiative develops. The data base will permit the development of implementation options for use in the policy formulation process. Beyond providing this data base, NASA is also working with the Space Council on separate assessments of a number of critical issues including alternative approaches to schedule and technology development, and international cooperation. It is significant to note that the approaches are based on current and forecasted advances in technological capabilities. Should breakthroughs in any of several key technologies ? including propulsion, life support, and power ? cause these technologies to advance more rapidly than anticipated, increases in performance or reductions in cost could result. Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Throughout the effort to develop the report, I have had the opportunity to speak with a large number of people and I have been encouraged by the enthusiasm displayed and the thousands of hours so many people willingly contributed to the study. I am impressed not only with the capability available for the Human Exploration Initiative, but also with the dedication and excitement of individuals within the Agency as well as those outside the Agency. I feel the message is clear from those who participated in the 90-day study. NASA stands ready to support the Nation's decision to complete Space Station Freedom, to return to the Moon, this time to stay, and then press onward to Mars. Sincerely, Aaron Cohen Enclosure Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Preface In his speech on July 20, 1989, President Bush asked Vice President Quayle to lead the National Space Council in determining what is needed to chart a new and continuing course to the Moon and Mars and beyond: the necessary money, manpower, and materials, the feasibility of international cooperation, and realistic timetables with milestones along the way. To support this endeavor, NASA Administrator Richard H. Truly created a task force to conduct a 90-day study of the main elements of a Human Exploration Initiative. The Initiative described in this report encompasses robotic as well as human missions. It is, nonetheless, a distinctly human adventure in the broad- est sense involving not only human space travelers, but also extending into the solar system the skills, imagination, and support of many thousands of people who will never leave Earth. The information contained in this report describes study progress and serves as a reference point to assist the Council in its deliberations. Five reference ap- proaches are modeled building on past programs and recent studies to reflect wide-ranging strategies that incorporate varied program objectives, schedules, technologies, and resource availabilities. The five reference approaches presented reflect the President's strategy: First, Space Station Freedom, and next back to the Moon, and then a journey to Mars. The destination is, therefore, determined, and with that determination the general mission objectives and key program and supporting elements are de- fined. As a result, regardless of the implementation approach selected, heavy- lift launch vehicles, space-based transportation systems, surface vehicles, habi- tats, and support systems for living and working in an extraterrestrial environ- ment are required. As deliberations proceed, the task force is prepared to support the analysis of implementation options and option variations identified by the Administrator, the Vice President, and the members of the National Space Council. Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Contents Preface 1. Executive Summary 1-1 2. Introduction 2-1 3. The Human Exploration Initiative 3-1 Robotic Missions 3-7 Lunar Outpost 3-13 Mars Outpost 3-23 Planetary Surface Systems 3-31 4. Reference Approaches 4-1 Reference Approach A 4-1 Reference Approach B 4-5 Reference Approach C 4-6 Reference Approach D 4-7 Reference Approach E 4-7 5. Infrastructure 5-1 Earth-to-Orbit Transportation 5-1 Space Station Freedom 5-9 Telecommunications, Navigation, and Information Management 5-18 6. Meeting Human Needs In Space 6-1 7. Science Opportunities And Strategies 7-1 8. Technology Assessment 8-1 9. National And Institutional Impact 9-1 Resource Assessment 9-1 Enhancing Management Systems 9-2 International Participation 9-6 Conclusion 9-10 Report Transmittal Letter from the Study Director to the NASA Administrator 111 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Tables Number Page 4-1 Key Characteristics of Reference Approaches 4-2 5-1 Space Station Freedom Growth Elements for Human Exploration 5-13 Figures 3-1 Human Exploration Initiative 3-3 3-2 Mars Global Network Mission Vehicle Concept Using Landers 3-8 3-3 Sample Return Vehicle with Local Rover 3-9 3-4 Mars Site Reconnaissance Orbiter Concept 3-11 3-5 Long-Range Mars Rover 3-12 3-6 Lunar Mission Profile 3-13 3-7 Lunar Outpost Architecture 3-15 3-8 Lunar Heavy-Lift Launch Vehicle Options 3-16 3-9 Lunar Transportation System 3-18 3-10 Lunar Transfer and Excursion Vehicle Reference Engines 3-19 3-11 Lunar Transfer Crew Module Reference Concept 3-20 3-12 Lunar Excursion Vehicle 3-21 3-13 Mars Mission Profile 3-23 3-14 Mars Outpost Architecture 3-24 3-15 Mars Heavy-Lift Launch Vehicle Options 3-25 3-16 Mars Transportation System 3-26 3-17 Mars Transfer Vehicle Crew Module 3-28 3-18 Mars Excursion Vehicle 3-29 3-19 Initial Habitat and Laboratory Modules Conceptual Design 3-31 3-20 Constructible Habitat Concept Design 3-32 3-21 Photovoltaic/Regenerative Fuel Cell (Stationary) Power System 3-33 3-22 Nuclear Dynamic Power System (100 kilowatts) 3-34 3-23 Unpressurized Manned/Robotic Rover Design Concept 3-35 3-24 Transportation Vehicle Payload Unloader Design Concept 3-36 3-25 Lunar Liquid Oxygen Production Plant Design ? 3-37 3-26 Lunar Excursion Vehicle/Mars Excursion Vehicle Servicer and Thermal Tent 3-38 iv Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Figures (continued) Number Page 5-1 Expendable Launch Vehicles 5-4 5-2 Shuttle-Derived Heavy-Lift Launch Vehicles 5-5 5-3 Advanced Launch System-Derived Heavy-Lift Launch Vehicles 5-7 5-4 Space Station Freedom Assembly Complete Configuration 5-10 5-5 Transportation Node Configurations for Space Station Freedom Evolution 5-14, 5-15 5-6 Telecommunications Architecture for the Human Exploration Initiative 5-22 8-1 Exploration Technology Development Strategy 8-2 V Declassified in Part - Sanitized Copy Approved for Release 2013/11/04 : CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 ... And then a journey into tomorrow, a journey to another planet, a manned mission to Mars. And next, for the next century, back to the Moon, back to the future, and this time, back to stay. First, for the coming decade, for the 1990s, Space Station Freedom, our critical next step in all our space endeavor- _ - ??=.7"rf - 1 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 SECTION 1 Executive Summary On July 20, 1989, President Bush charted a new course for the human explo- ration of space: ". . . a long-range continuing commitment. First, for the coming decade, for the 1990s, Space Station Freedom, our critical next step in all our space endeavors. And next, for the next century, back to the Moon, back to the future, and this time, back to stay. And then a journey into tomorrow, a journey to another planet, a manned mission to Mars. Each mission should and will lay the groundwork for the next." With these words, the President provided specificity to the goal contained in the 1988 Presidential Directive on National Space Policy: to expand human pres- ence and activity beyond Earth orbit into the solar system. President Bush has answered the question "Where are we going?" We are going back to the Moon, and then we are going to Mars. The shape of human exploration of space is clear. Space Station Freedom, to be followed by a return to the Moon to stay, and a subsequent journey to Mars, will be rational extensions of the United States civil space program. From its very beginning, that program has expanded human activities in space. From Mercury and on through Gemini, Apollo, Skylab, the Space Shuttle, and now, Space Station Freedom, the United States has moved steadily into larger and more ambitious programs of ever-increasing complexity. Each has been a logical extension of what came before. Each built on past experience. The rationale for exploring and settling space mirrors the spirit that has com- pelled explorers through the ages: the human urge to expand the frontiers of knowledge and understanding and the frontiers where humans live and work. That is the basic reason people explore on land, sea, and in space, and has been since humans first walked on Earth. The imperative to explore is embedded in our history, our traditions, and our national character. Throughout the drama of American history, our forefathers, with resourcefulness, audacity, and ingenuity, explored a seemingly limitless continent, using the wealth of natural resources to sustain them along the way. Today, men and women have explored nearly every corner of the planet, even to the bleak center of remote Antarctica. Now, in the late 20th Century and the early 21st, men and women are setting their sights on the Moon and Mars, as the exploration imperative propels us toward new discoveries. S,1011?1101..? 1-1 Declassified in Part - Sanitized Copy Approved for Release 2013/11/04 : CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 The Human Exploration Initiative To enrich the human spirit, to contribute to national pride and international prestige, to inspire America's youth, to unlock the secrets of the universe, and to strengthen our Nation's technological foundation: human exploration of the Moon and Mars will fulfill all these aspirations and more. This document pro- vides a framework within which various approaches to meeting these national goals may be analyzed. The basic mission sequence is clear: begin with Space Station Freedom in the 1990s, return to the Moon to stay early in the next century, and then journey on to Mars. An end-to-end strategy for implementing the mission begins with robotic exploration to determine and characterize the lunar and martian environments in which spacecraft and crew must function. The next step is to build a permanent outpost on the Moon to support human presence for science and exploration. In addition to the benefits to be gained from lunar exploration for its own sake, the lunar outpost serves a vital parallel purpose. Just a 3-day journey from Earth, the Moon provides the ideal location to develop the systems and experience to prepare for the next step of the Initia- tive: an outpost on Mars. The mission objectives dictate a common profile for both outposts, beginning with the launch of crew and cargo from Earth, with the crew on the Space Shuttle and most of the cargo on new heavy lift launch vehicles. The destination is Space Station Freedom, where vehicles are assembled, fueled, and serviced for the next stage of the journey. Concepts have been developed for transfer ve- hicles that carry the crew and cargo from Freedom and to and from lunar and Mars orbit and for excursion vehicles that meet the crew and cargo in orbit and bring them to the surfaces of the Moon and Mars. Specialized concepts have also been developed for the systems that support human explorers as they live and work on the Moon and Mars. A combined habitation and laboratory module provides a comfortable environment for living, recreation, and scientific research. Power system concepts ranging from pho- tovoltaic to nuclear were developed to support increasing levels of activity and scientific research. For travel across planetary surfaces, various rovers will be used, some that crew members drive, and others that operate robotically. In situ resource utilization, which would increase outpost independence from planet Earth, may also be supported at the outposts. And finally, launch and landing sites have been designed for the vehicles that bring crew members to planetary surfaces and take them on the first leg of their journey home. 1-2 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Reference Approaches The Human Exploration Initiative provides a framework within which various elements of and approaches to human exploration of the Moon and Mars can be examined. In order to provide the data necessary to make these types of assess- ments, several reference approaches have been selected to determine which parameters drive such things as cost, schedule, complexity, and program risk. Five reference approaches were analyzed, each of which is characterized by a particular emphasis: (1) balance and speed; (2) the earliest possible landing on Mars; (3) reduced logistics from Earth; (4) schedule adapted to Space Station Freedom; and (5) reduced scale. The information generated through this process can be used as a data base for determining the appropriate scope, schedule, and ultimate approach to be used in implementing the program. The data generated by this process are intended to capture the range of possibilities based on our technical understanding today, and, consequently, can be used to develop im- plementation approaches for any number of options. Infrastructure The existing NASA infrastructure of Earth-to-orbit transportation systems, Space Station Freedom, and telecommunications, navigation, and information management systems will be an integral element of any human exploration program. In parallel with the development of the Initiative, current and pro- jected capabilities in these areas were assessed to determine where augmenta- tion might be necessary. In the area of Earth-to-orbit transportation, the Nation's current mixed fleet of Space Shuttles and expendable launch vehicles dearly requires enhancement. The Space Shuttle will be used to carry the crew to Space Station Freedom, but the massive cargo flights necessary to support extraterrestrial human explora- tion mandate launch vehicles with much greater lift capacity: approximately 60 metric tons for the lunar outpost, and about 140 metric tons for the Mars outpost. (The current Shuttle has a capability of 17.3 metric tons.) Various concepts for vehicles to accommodate these requirements range from Shuttle- derived vehicles to versions of the planned Advanced Launch System. New ground facilities will also be required to support the new vehicles. Space Station Freedom will serve a vital role in human exploration: it will provide the essential scientific and technological foundation for later human missions to the planets, and it will serve as a transportation node for the mis- sions of the Initiative. Space Station Freedom will serve as an on-orbit labora- tory for conducting research and developing technology that is required by the 1-3 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Initiative. Freedom is the ideal location for such studies and demonstrations because no terrestrial laboratory can adequately simulate the characteristics of the space environment. Research will determine acceptable long-term micro- gravity countermeasures and obtain data for the design of self-sufficient life support systems. Freedom can advance technology by serving as a test-bed for new lunar and Mars system developments. Further, the hardware, software, and other technologies used to assemble and operate Freedom can be applied to exploration vehicles and systems. A significant feature of Space Station Freedom's design is its capability to add pressurized laboratory and habitation modules, power generation equipment, truss extensions, and specialized facilities. This capacity allows Freedom to evolve gracefully as its requirements as a research facility and transportation node increase over the lifetime of the Initiative. Freedom will evolve sequeR- tially through four configurations to support four Human Exploration Initiative milestones: the verification flight of the lunar transfer vehicle, expendable lunar transfer vehicle operations, reusable lunar transfer vehicle operations, and orbital operations in support of Mars missions. The Human Exploration Initiative is also expected to stimulate new develop- ments in telecommunications, navigation, and information management. These enabling support functions monitor and control mission elements, acquire tel- emetered data from engineering and science measurements, provide radiometric data for navigation and video data for operations and science activities, and provide a capacity to communicate, receive, distribute, and process information. These functions must be provided efficiently, with human-related reliability. Several challenges must be met: incorporating highly unattended operations for many of the local Mars telecommunications and navigation functions, achieving a high Mars-Earth data rate, providing robust system connectivity for manned links, and providing an information management discipline, including stan- dards, for use in transferring data between system nodes. Meeting Human Needs in Space Exploring the frontier has always been risky to the lives of the men and women at its edges. Now, astronauts are preparing to venture for long periods of time into environments more harsh, albeit more challenging and fascinating, than any encountered on Earth. Fundamental differences between space and Earth?the lack of gravity, inadequate atmospheres, deep cold, and radiation hazards?challenge our ability to protect, nurture, and sustain the individuals who will be the pioneers of the solar system. 1-4 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Life scientists have major responsibilities under the Human Exploration Initia- tive: to the crew, to assure their health, productivity, and safety throughout the mission and the postflight rehabilitation period; to the mission, to provide a productive working environment; and to the scientific community, to advance knowledge and understanding of human adaptation to the space environment. Critical areas essential to support of human exploration include protection from the radiation hazards of the space environment, of the utmost importance both for journeying to and living on other planetary bodies Limits must be deter- mined, and protective measures, including shielding, storm shelters, and warn- ing systems, must be developed. Other important health-related areas include reduced gravity countermeasures, medical care, and life support systems. The final area that must be investigated is one about which we have very little data: behavior, performance, and human factors in an extraterrestrial environment. Science Opportunities and Strategies A long-standing policy goal of the U.S. civil space program is "to expand knowl- edge of the Earth, its environment, the solar system, and the universe." The Human Exploration Initiative will significantly advance scientific knowledge as we explore the Moon and Mars and learn to use their surfaces for observatories and laboratories. The act of exploration will provide new insights into the natural history of the bodies visited and may lead to their use for practical purposes. Many diverse scientific disciplines ? geology and geophysics, astron- omy and astrophysics, human and plant physiology, and evolutionary biology ? will be greatly enhanced. Exploring the Moon and Mars will help us in many ways to understand the past and to look into the future of our own planet, the solar system, and the universe. Our first stop as we move outward from Space Station Freedom into the solar system is the Moon, where we can find clues about the early days of Earth. Current scientific theory holds that the Moon formed when a Mars-sized body collided with Earth. By exploring lunar origins, we may understand not only the formation of Earth, but also other mysteries of our solar system, such as the tilt of Uranus and the rotational spin of Venus. The lunar surface also contains records of cratering processes, obliterated on Earth by erosion, which may contain clues about the extinction on Earth of entire species. Such break- throughs may lead to profound discoveries about how life, including human life, evolves. Studies of the Moon will also yield important information about its natural resources, which is a vital first step in becoming a multi-planet species. 01.1, Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 In addition to studying the Moon itself, from the lunar surface we will look outward. The Moon is a valuable platform for studying distant stars and galax- ies, the rest of the solar system, and Earth itself; its quiet, stable environment provides an excellent base for astronomy. From the Moon, we can make great strides in understanding the universe, strides that are currently impossible on Earth or using orbiting telescopes. And when men and women live there, scien- tists will learn about the long-term effects on humans of a low-gravity environ- ment; this is an essential step for longer-duration stays on Mars. We will not stop at the Moon, because the imperative to explore will lead men and women to Mars. The planet most like Earth, Mars offers many unique scientific opportunities, but perhaps the most intriguing question is whether life exists or has ever existed on Mars. Ancient river beds and channels indicate that water once flowed on Mars and that life could have formed there. Life may exist on Mars today in underground habitats where volcanic heating melts ground ice, producing a warm, wet environment protected from harsh surface conditions. Only scientists working on Mars can discover the answer to this age- old question. Studying Mars will also help us better understand changes on Earth, both natural changes and those that are caused by the presence of our species. By understanding the fascinating geological diversity on Mars, caused by drastic global climate change, we can understand more about our own changing planet. And exploration will not stop at the Moon and Mars. As with all pioneering ventures, the Human Exploration Initiative will open new vistas of discovery tomorrow that can only be imagined today. Technology Space is an infinite source of challenges. To send humans to explore it and use its resources, development must begin today of new technologies in many areas, including regenerative life support systems, aerobraking, advanced cryogenic hydrogen-oxygen engines, surface nuclear power systems, in situ resource utili- zation, radiation protection, and nuclear propulsion. Advancements in automa- tion and robotics, as incorporated into these and many other technologies, will significantly increase the effectiveness of operational systems. Perhaps the most tangible benefits of the Human Exploration Initiative, these developments will inevitably have spinoff applications that may profoundly affect our everyday lives and will certainly improve our position in the increasingly technological world economy. During the decade of exploration from the late 1960s to the late 1970s, the astronauts of Apollo and the machines of Viking began to explore the surfaces of 1-6 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 the Moon and Mars, achievements that were made possible by revolutionary advances in technologies and aerospace engineering capabilities. Innovative technological solutions to challenging engineering problems will also be one of the hallmarks of the coming era of exploration. Each step of the march to Mars ? sending robotic missions to the Moon and Mars, establishing a lunar outpost, staging initial expeditions of humans to Mars, and ultimately emplacing an outpost on Mars ? will drive technological and engineering expertise to greater heights and new standards of excellence. The Human Exploration Initiative will involve dozens of major systems and will span decades. Technology development will be a multifaceted process that tests the best scientists and engineers in the Nation, builds on the considerable base that NASA has accumulated over the years, and evolves as the Initiative pro- gresses. As mission objectives are crystallized, system concepts developed, and applicable technologies selected for pursuit, nearer-term advanced development programs will focus on creating individual operational systems. These advanced development programs will in turn feed into the design, development, test, and evaluation programs that will produce the flight hardware and software for specific Human Exploration Initiative systems. Throughout all programmatic phases in the life of the program, engineering ingenuity and technological inno- vation will characterize the Initiative. Significant technology development needs to begin as soon as possible. A bal- anced, focused investment in technology will make possible the levels of per- formance and the scope of operations envisioned. Technology development will precede and foretell the major accomplishments of exploration, leading by sev- eral years the actual missions to the Moon and Mars. National and Institutional Impact The Human Exploration Initiative presents our Nation with exhilarating chal- lenges, significant opportunities, and enormous benefits into the first part of the next century and beyond. The Human Exploration Initiative will draw heavily on NASA's personnel, facilities, and equipment. This resource base, the NASA institutional core capability, is built on 75 years of research, development, and operational experi- ence and hundreds of unique national facilities. From the National Advisory Committee on Aeronautics to the creation of NASA in 1958 to the present, the Agency has developed an unparalleled capability in civil space research and development and aeronautics. NASA will request a significant augmentation of civil service positions to sup- port the Human Exploration Initiative. These positions will provide the 1-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 necessary technical expertise, program management, and administrative sup- port to meet the objectives of the Initiative. The augmentation will also enhance the in-house work force, providing a solid balance between in-house and con- tracted efforts. The Human Exploration Initiative will challenge current management systems. It presents a unique opportunity to explore and test streamlined administrative and management processes for directing long-term, complex, highly visible U.S. programs having significant international implications. The lessons learned may yield invaluable guidance transferable to other important U.S. programs. Three areas will offer the greatest opportunity to realize significant efficiencies and enhanced effectiveness: the acquisition system, the budget process, and human resource management systems. NASA has already begun to address these areas internally, but some elements are outside NASA's control and will require active support from other Government quarters. Potential international participation in the Human Exploration Initiative is the subject of a separate policy analysis being conducted under the direction of the National Space Council. That analysis will assess international capabilities, opportunities, issues, and options related specifically to the Human Exploration Initiative. This document complements that activity by pulling together infor- mation based on NASA's extensive experience in conducting space missions with foreign partners. With the growing capabilities and increasing number of other spacefaring na- tions, the environment for international participation is considerably different than it has been in the past. The Human Exploration Initiative offers the poten- tial for a variety of cooperative approaches with a number of potential partners. Different models may be appropriate for cooperation with different nations or for different phases of the Initiative. The National Space Council will consider these and other factors in assessing the feasibility of further international participation. International cooperation and the use of the Initiative to serve important foreign policy goals are only two of its many benefits. The Initiative will also stimulate interest in science and engineering education, strengthen our national techno- logical capabilities, offer a wealth of new scientific knowledge, and serve as a source of national pride. NASA contributes to the Nation's base of technology through the transfer of research knowledge into the public and private sectors. The application and reapplication of this knowledge has a multiplicative effect, in which the general increase of efficiency and wealth from the advanced knowledge spreads through- out society. The Human Exploration Initiative will expand this contribution as 1-8 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 advanced technologies are developed. Another increasingly important benefit is the stimulus that the Human Explora- tion Initiative can provide to education. To help ensure that the Nation has an adequate, continuing supply of scientists, engineers, and other technical person- nel to successfully implement the President's Human Exploration Initiative, an aggressive and targeted educational action plan is needed. To contribute to solving the predicted shortage of scientists and engineers, NASA will redirect and enhance its existing aerospace education program into a new, comprehen- sive, educational initiative entitled "Space Literacy for the 21st Century." The educational frontiers opened by space exploration will captivate new gen- erations of students, the scientific and technical work force of the future. This phenomenon, combined with the other scientific and political benefits of the Initiative, will open new horizons of achievement and will serve as a source of national pride. Taken together, the benefits of the Initiative ? scientific under- standing, technological advancement, motivation of our Nation's youth, and more ? will significantly strengthen our position in the global community. Some day it may be said that the residents of Earth had to leave their planet in order to find it. Indeed, from space, humans first got to see their own planet, floating in blackness above the barren moonscape like a blue and white marble. Perhaps more than anything else, this view of Earth dramatized our planet's uniqueness, and its fragility. The last half of the 20th Century and the first half of the 21st Century will almost certainly be remembered as the era when men and women broke the bonds that bound them to Earth and set forth on a journey into space. That journey will, in time, extend human presence throughout the solar system. Historians will note that the Moon became a familiar place to Earthlings very early in that period. They returned there to follow in the bootprints of Arm- strong, Aldrin, and their Apollo colleagues, to establish an outpost for further exploration and expansion of human activities, to Mars and beyond. Historians will further note that the journey to expand human presence into the solar system began in earnest on July 20, 1989, the 20th anniversary of the Apollo 11 lunar landing when President George Bush announced his proposal for a long-range continuing commitment to a bold program of human exploration of the solar system. 1-9 Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 SECTION 2 Introduction Human exploration of the Moon and Mars has been a sustaining vision of the U.S. civil space program almost since its inception. With the Apollo Program, we took our first small steps on the surface of another world; never again would our vision be restricted to the narrow confines of Earth's bounda- ries. Throughout the 20 years that have passed since the Apollo 11 astronauts first landed on the Moon, the aspiration to further explore has remained a beacon to the future. In fact, during the Apollo era, Wernher von Braun led a task force to develop long-range goals for the space program after Apollo: more lunar missions, a space transportation system, a space station, and human journeys to Mars. The Space Shuttle became the space transportation system, Skylab was the first and Freedom will be the second space station, and several studies throughout the years have examined concepts and identified supporting requirements for hu- man missions to the Moon and Mars. Events over the past several years have increased awareness of the significant opportunities for human exploration and have provided a wealth of technical data to support a response to the President's bold new initiative. In 1986, the National Commission on Space published its report, 'Pioneering the Space Frontier." The Commission was appointed by then-President Ronald Reagan and mandated by Congress to formulate a visionary agenda to lead America's civilian space enterprise into the 21st century. The Commission recommended to the Nation a bold plan for the next half century in space: "To lead the explo- ration and development of the space frontier, advancing science, technology, and enterprise, and building institutions and systems that make accessible vast new resources and support human settlements beyond Earth orbit, from the high- lands of the Moon to the plains of Mars." Later that year, then-NASA Administrator James C. Fletcher asked scientist astronaut Sally Ride to lead a NASA-wide task force to define and evaluate potential long-range goals for the U.S. civilian space program, building on earlier technical studies conducted throughout NASA and outside NASA in direct response to the Commission. The task force report, "Leadership and America's Future in Space," was released in August 1987. The report identified and analyzed four potential initiatives that could ensure continued civilian space program leadership: Mission to Planet Earth, Robotic Exploration of the Solar System, Outpost on the Moon, and Humans to Mars. 2-1 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 NASA's Office of Exploration was established in June 1987 in response to the task force's recommendation that NASA establish a focal point to fund, lead, and coordinate studies examining potential approaches to human exploration of the solar system, based on the Outpost on the Moon and Humans to Mars Initia- tives. For the past 2 years, NASA has examined in detail a number of potential strategies: Apollo-type expeditions to Mars and its moons, evolutionary plans for permanent human presence on the Moon and Mars, and scientific observato- ries on the Moon. The goal of this effort has been to develop a substantial base of knowledge on technical and programmatic requirements in order to enable the President to define a pathway for the human exploration of the Moon and Mars. With the President's historic announcement, that pathway has been defined. We are going to build Space Station Freedom, and then we are going back to the Moon and on to Mars, to continue the remarkable journey of exploration that began more than 25 years ago when human beings first rocketed into space. Exploration is a human imperative, one deeply rooted in American history and its destiny. Our flag still flies on the Moon, and exploration is an endeavor in which our Nation excels. Returning to the Moon and journeying to Mars are goals worthy of our heritage, signalling an America with the vision, courage, and skills essential for leadership among spacefaring nations in the 21st Century. Now that the President has defined where we are going, the next step is to decide how and when. To support the Vice President and the National Space Council in this task, NASA initiated a study to develop the reference base from which strategic options could be derived. The pages that follow describe the results of a 90-day internal study for which NASA assembled a team of repre- sentatives from the NASA program offices and field centers. The purpose of the study was to examine the elements of a human exploration program, assess current capabilities, determine ways in which the capabilities might need to be augmented, identify areas in which new developments would be required, and provide this information in a cohesive package to support the decision-making process. The process by which this information was derived began with the examination of the basic objectives of the Human Exploration Initiative: to return to the Moon to stay, and then to journey on to Mars, conducting significant scientific research every step of the way. An end-to-end strategy was then developed, be- ginning with robotic missions to characterize the environment in which humnns and machines must function. The next steps are launching personnel and equip- ment from Earth, exploiting the unique capabilities of human presence in low Earth orbit aboard Space Station Freedom, transporting crew and cargo from 2-2 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Earth orbit to lunar and Mars orbits and surfaces, and developing the planetary surface systems that support human life, extraterrestrial work, and science, and allow a significant degree of self-sufficiency. In parallel, NASA's existing and planned infrastructure of Earth-to-orbit transportation, Space Station Freedom, and telecommunications, navigation, and information management was as- sessed to determine its ability to accommodate the increased demands of the Initiative. The synergistic areas of human needs, science, and technology were also intensively assessed for the opportunities they bring to and derive from this program. Finally, programmatic matters, such as resources, management systems, international participation, and national benefits were examined to develop a perspective embracing the broader implications of the Initiative. Key Technical Variables Studied ? Launch vehicle size ? In-space assembly or direct to surface ? Space Station Freedom, new spaceport, or direct assembly ? Chemical, electric, nuclear, or unconventional propulsion ? Aerobraking or all-propulsive vehicles ? Expendable or reusable spacecraft ? Propellant or tank transfer ? Open or closed life support ? Zero-gravity or artificial-gravity Mars vehicle ? In situ or Earth-supplied resources In developing a preliminary program plan for human exploration of the Moon and Mars, results of past studies examining a wide variety of fundamental approaches formed the basis for the selection of certain key technical parame- ters. For the most part, these assumptions were derived from the past 2 years of intensive trade analyses conducted as part of the human exploration case studies. However, the case studies themselves built upon a rich heritage of earlier studies that established a foundation of technical information from which to draw. Combined with the strategy established by President Bush, this foun- dation provided a starting point for the development of the Human Exploration Initiative. 2-3 Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Certain technological approaches, described in detail in Section 8 of this docu- ment, have been proven to be the most feasible ways of building capability in the development of an outpost either on the Moon or Mars. It is known, for ex- ample, that some degree of in-space assembly and maintenance is necessary for the vehicles that transport cargo and crew to their ultimate planetary destina- tions. Trade studies of the location and function of the transportation node at which these functions are performed have determined that Space Station Free- dom is both a necessary and feasible approach to meeting this requirement. Power for outpost operations, for another example, is provided in initial stages by photovoltaic systems with regenerative fuel cells, a known and well-devel- oped technology that is entirely adequate for early power requirements. As the outpost develops, the next level of power generation is provided by space-based nuclear systems. For life support, regenerative systems provide the most cost- effective approach. A significant trade study conducted over the past 2 years addressed the consid- eration of balancing the need to occasionally deliver relatively large masses, such as living quarters and utilities, to planet surfaces with the need to more regularly deliver the smaller masses associated with logistics resupply and crew transfer. This balance affects the sizing of launch and space transportation vehicles, the need for vehicle reusability, and the buildup sequence of the out- post. The balance must be arrived at considering reasonable flight rates, on- orbit assembly capabilities, and operations scenarios. For missions to the Moon, this balance has been found to be best achieved by launch vehicles in the 50 to 80 metric ton payload class, which carry payloads to Space Station Freedom for final assembly and checkout before departure for the Moon. Although designed for no human intervention, lunar vehicles and pay- loads will, realistically, require some hands-on activity in Earth orbit. Separate Earth-orbit-to-lunar-orbit and lunar ascent/descent vehicles are required to satisfy operational and abort considerations. The vehicles need to be reusable and capable of delivering in the range of 15 to 40 metric tons to the lunar sur- face. For Mars missions, launch vehicles having a payload capability well in excess of 120 metric tons are required to achieve a balance between larger, fewer launches and less assembly at Freedom and smaller, more numerous flights that greatly complicate the assembly tasks. An area in which a very wide range of system technology options were examined is propulsion systems for space transfer vehicles. Approaches ranged from conventional all-chemical propulsion to a variety of nuclear systems to solar sails and mass drivers. What emerged from these analyses was a succinct definition of the relative advantages and disadvantages of each approach. 2-4 Declassified in Part - Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Whereas several techniques, such as nuclear and solar electric propulsion and solar sails offered efficient transportation of large payload masses, this advan- tage is somewhat negated by slow travel time or significant operational complex- ity. Further study determined that the use of an aerobrake in conjunction with chemical propulsion could reduce required initial mass in the low Earth orbit by more than 50 percent, in addition to reducing operations costs. Therefore, all-chemical propulsion with aerobraking was selected as the baseline for space transfer vehicle propulsion, and this assumption was used in develop- ing mission profiles for the Initiative. However, for transportation from Earth orbit to Mars, nuclear propulsion shows a great deal of promise as an option for significantly enhancing mission performance. Solid-core nuclear thermal rockets, a mature technology that was designed, built, and tested from 1955 to 1973, offers a savings in mass in low Earth orbit of approximately 40 percent over chemical propulsion without aerobraking. Chemical propulsion with aerobraking and solid-core nuclear thermal rockets are, therefore, essentially equivalent in their advantage over chemical propul- sion without aerobraking. However, gas-core nuclear rockets, for which concepts were also formulated during the same time, offer the significant advantage of reducing round-trip travel time to Mars to less than 1 year. As the development of the Human Exploration Initiative unfolds, these and other issues will continue to be examined to identify the most efficient ap- proaches to the various elements of the program. 2-5 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 SECTION 3 The Human Exploration Initiative M he overarching goal of the Human Exploration Initiative is to expand human presence in the solar system, developing nearly self-sufficient communities on new worlds and promoting significant advances in science and technology. The Initiative will follow an evolutionary pathway over a 30-year horizon begin- ning with Space Station Freedom in the 1990s, followed by a permanent outpost on the Moon at the beginning of the next century, and culminating with Mars expeditions that lead to a permanent martian outpost. Figure 3-1 illustrates the relative timing of the full array of scientific and technical systems that will enable and support this goal. These systems are discussed in detail in this and subsequent sections. Space Station Freedom, the first step on the pathway, will provide the essential scientific and technological foundation for later human missions to the planets. For example, a particularly critical factor in planning human exploration is the determination of the physiological and psychological effects of low gravity and long-term habitation of the space environment, which will be studied on Free- dom. Initially, crew members will remain on Space Station Freedom for 3 months; research will focus on understanding the various mechanisms respon- sible for adaptation to weightlessness and the physiological problems encoun- tered upon return to Earth. Later, an extended-duration crew certification program will prolong visits to 180 days or more and will include enhanced physiological countermeasures for low gravity and radiation effects. Systems developed for use on Space Station Freedom will enhance and strengthen the technological base for human planetary exploration. Freedom will serve as a controlled test-bed for developing and validating systems and elements, such as habitation and laboratory modules and life support systems, to be used later on the Moon and Mars. In addition, Freedom will support tech- nology experiments and advanced development in mission-critical areas, such as spacecraft assembly, servicing, and system development. When the exploration missions begin, Freedom will become a transportation node where both lunar and Mars vehicles will be assembled, tested, launched, and refurbished to fly again. (Freedom's role as a transportation node is discussed in more detail in Section 5.) The next step in this evolutionary process will be to build a permanent outpost on the Moon to establish human presence for science and exploration. 3-1 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Rovers and crew will explore the geology and geophysics of the Moon itself, and rock and soil samples will be analyzed in a lunar laboratory. The unique char- acteristics of the lunar environment make it an excellent platform from which to conduct astronomy, physics, and life sciences research. The Moon also provides an ideal location, just a 3-day trip from Earth, at which human beings can learn to live and work productively in an extraterrestrial environment with increasing self-sufficiency, using local lunar resources to support the outpost. In this way, the lunar outpost will both advance science and serve as a test-bed for validating critical mission systems, hardware, technologies, human capability and self- sufficiency, and operational techniques that can be applied to further explora- tion. Once the lunar outpost has verified the techniques and demonstrated the sys- tems, the next evolutionary step will be to launch the first human expedition to Mars. Initial missions to Mars will prove the systems and techniques required for continuing human missions and will conduct further reconnaissance of selected landing sites. Later missions will establish a Mars outpost with the objective of conducting science and exploration on the solar system's most Earth- like planet, expanding mankind's sphere of influence in the solar system, and living and working in an extraterrestrial environment with a high degree of self-sufficiency. Valuable scientific knowledge will be gained through the search for evidence of past and present life, exploration of the geology and geophysics of Mars and its moons, utilization of martian resources, and studies of biological responses in humans, plants, and animals To examine potential approaches to building permanent lunar and Mars out- posts, an end-to-end strategy was developed that provides a logical mechanism for stepping through the various elements and milestones of the Initiative. The strategy begins with the preparatory phase of robotic exploration to obtain early scientific and technical data prior to the human exploration missions. Once the robotic missions have satisfied this requirement, the development of permanent, largely self-sufficient outposts on the Moon and Mars proceeds through three progressive phases: emplacement, consolidation, and operation. The emplacement phase emphasizes accommodating basic habitation needs, establishing surface equipment and science instruments, and laying the founda- tion for future, more complex instrument networks and surface operations by testing prototypes of later systems. In the process, human explorers begin to learn to live and work on another planetary body, conducting local geologic investigations, performing experiments in mining the lunar soil to demonstrate the feasibility of oxygen production on the Moon, and exnnyining the possibility of oxygen and water extraction on Mars. By the end of the emplacement phase, the support facilities include landing vehicle servicing equipment to prepare for 3-2 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Declassified in Part- Sanitized Copy Approved for Release 2013/11/04: CIA-RDP91B01306R000300070005-7 Space Station '"''' -,,,,,,..,,,..:.,.,,,, IMITRENIMMON. ; .A.A7.7,777.7777-7777:77.777.7.7..e ....0. .. -7.;:i.:4M....z., ....,..LAKIM,PMS' , ,,.,-'?-g'.' d?aggiikaJ77%., Freedom -g;M'iI;;? '!'" PiIMMMMT,:r.r,MgC4411:iT;;F:,.. :.:::;N.V.,.R4AWAVii845.W,T6EmWiAt.a%,,K ;:'.? ;EMISCOM Mission Lunar Outpost Mars Outpost .........? ....? ? MOW .A ......igs ,--..... I'. P." '...ai- A 4 4_ / \ Robotics . - -../.\ - ii . iv. ''. I amg, ' I ' Mars Site..' '':17 1111111 41.6 Sill Mars Lunar Mars Global Mars Sam2le Reconnaissance Rover Rover Rover Observer Observer Network Return Orbiter Space Transportation S.. ? -.':-.'f.'.- ? .::-777:,:::.: ''' o ...... 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