Mars In-Situ Resource UtilizationSample Return MISR

Combination Lander Concept on Mars Surface

NASA Design Reference Mission 3.0 was a

NASA The National Aeronautics and Space Administration (NASA ) is an independent agency of the US federal government responsible for the civil space program, aeronautics research, and space research. NASA was established in 1958, succeeding t ...

study for a human space mission to the planet

Mars Mars is the fourth planet from the Sun and the second-smallest planet in the Solar System, only being larger than Mercury (planet), Mercury. In the English language, Mars is named for the Mars (mythology), Roman god of war. Mars is a terr ...

in the 1990s. It was a plan for a human exploration architecture for Mars, and was released in 1998 as an addendum to the early design plans released in 1994. The plan is for a series of multiple launches to send various space transpiration, surface exploration hardware, and human crew to Mars, and to return the crew to Earth in the early 21st century. Various technologies are explored to launch the payloads into space, to send them to Mars, and to reduce overall weight of the mission by various technologies or techniques including nuclear, solar, aerobraking, and in-situ resource use.

Overview

The study was performed by the NASA Mars Exploration Team at the NASA's

Johnson Space Center The Lyndon B. Johnson Space Center (JSC) is NASA's center for human spaceflight (originally named the Manned Spacecraft Center), where human spaceflight training, research, and flight control are conducted. It was renamed in honor of the late U ...

(JSC) in the 1990s. Personnel representing several NASA field centers formulated a "Reference Mission" addressing human exploration of Mars. The plan describes the first human missions to Mars with concept of operations and technologies to be used as a first cut at an architecture. The architecture for the Mars Reference Mission builds on previous work, principally on the work of the Synthesis Group (1991) and Robert Zubrin's (1991) concepts for the use of propellants derived from the Martian atmosphere. The primary purpose of the Reference Mission was to stimulate further thought and development of alternative approaches which can improve effectiveness, reduce risks, and reduce cost. Improvements can be made at several levels; for example, in the architectural, mission, and system levels. The report of the Reference Mission Version 3.0 states:

From the work of the original Reference Mission (Version 1.0), the strategy for the human exploration of Mars has evolved from its original form to one of reduced system mass, use of a smaller, more reasonable launch vehicle, and use of more current technology. The steps which have been taken by the Exploration Team are motivated by the need to reduce the mass of the payload delivery flights, as well as the overall mission cost, without introducing additional mission risk. By eliminating the need for a large heavy-lift launch vehicle and deleting the redundant habitat delivery flight in Version 3.0, two launches from the Earth were eliminated. The net result is a current Version 3.0 Reference Mission which requires an injected mass of approximately one-half that of the 1993/94 Reference Mission.

The purpose of the Reference plan, including the 3.0 update is to provide a template for a variety of Mars mission planning and technology purposes, and also to stimulate thought and further ideas for Mars missions in the "exploration community and beyond".

Aspects

List: *Cargo Vehicles *Piloted Vehicles *Mars Surface Lander *Inflatable Surface Habitat *Magnum Launch Vehicle *Propulsion studies including **Nuclear Thermal Rocket **Solar Electric *Earth Return Vehicle *Aerobrake at Mars *In-situ resource *Misc. Other items

Mission items

The DRM 3.0 covered or touched upon a wide variety of institutions, vehicle, and mission concepts which are further explored or analyzed. Examples: *

Evolved Expendable Launch Vehicle National Security Space Launch (NSSL) — formerly Evolved Expendable Launch Vehicle (EELV) from 1994 to 2019 — is a program of the United States Space Force (USSF) intended to assure access to space for United States Department of Defense and o ...

(EELV) *Earth

Entry Entry may refer to: *Entry, West Virginia, an unincorporated community in the United States *Entry (cards), a term used in trick-taking card-games *Entry (economics), a term in connection with markets * ''Entry'' (film), a 2013 Indian Malayalam fil ...

Vehicle *EVA Mobility Unit *Electric Propulsion Module *Earth Return Vehicle * Extra Vehicular Activity *

Mars Habitat A Mars habitat is a hypothetical place where humans could live on Mars. Mars habitats would have to contend with surface conditions that include almost no oxygen in the air, extreme cold, low pressure, and high radiation. Alternatively, the habi ...

Heavy Lift Launch Vehicle A heavy-lift launch vehicle, HLV or HLLV, is an orbital launch vehicle capable of lifting between (by NASA classification) or between (by Russian classification) into low Earth orbit (LEO).50t payloads" , operational heavy-lift launch vehicl ...

*Initial Mass in Low Earth Orbit *

In-Situ Resource Utilization In space exploration, in situ resource utilization (ISRU) is the practice of collection, processing, storing and use of materials found or manufactured on other astronomical objects (the Moon, Mars, asteroids, etc.) that replace materials that ...

*Liquid Fly Back Booster *

Life Support System A life-support system is the combination of equipment that allows survival in an environment or situation that would not support that life in its absence. It is generally applied to systems supporting human life in situations where the outsid ...

*Mars Ascent Vehicle *Mars Transfer Vehicle *Nuclear Thermal Propulsion *

Nuclear Thermal Rocket A nuclear thermal rocket (NTR) is a type of thermal rocket where the heat from a nuclear reaction, often nuclear fission, replaces the chemical energy of the propellants in a chemical rocket. In an NTR, a working fluid, usually liquid hydro ...

*Pressurized Control Research Vehicle *Power Management and Distribution *

Photovoltaic Array A photovoltaic system, also PV system or solar power system, is an electric power system designed to supply usable solar power by means of photovoltaics. It consists of an arrangement of several components, including solar panels to absorb and co ...

Reaction Control System A reaction control system (RCS) is a spacecraft system that uses thrusters to provide attitude control and translation. Alternatively, reaction wheels are used for attitude control. Use of diverted engine thrust to provide stable attitude contr ...

* Shuttle Derived Vehicle *

Solar Electric Propulsion Solar electric propulsion (SEP) refers to the combination of solar cells and electric thrusters to propel a spacecraft through outer space. This technology has been exploited in a variety of spacecraft by the European Space Agency (ESA), th ...

Space Transportation System The Space Transportation System (STS), also known internally to NASA as the Integrated Program Plan (IPP), was a proposed system of reusable crewed space vehicles envisioned in 1969 to support extended operations beyond the Apollo program. ...

*Transit Habitat *Thermal Protection System ;Institutions *

Ames Research Center The Ames Research Center (ARC), also known as NASA Ames, is a major NASA research center at Moffett Federal Airfield in California's Silicon Valley. It was founded in 1939 as the second National Advisory Committee for Aeronautics (NACA) laborat ...

Marshall Space Flight Center The George C. Marshall Space Flight Center (MSFC), located in Redstone Arsenal, Alabama (Huntsville postal address), is the U.S. government's civilian rocketry and spacecraft propulsion research center. As the largest NASA center, MSFC's first ...

Jet Propulsion Laboratory The Jet Propulsion Laboratory (JPL) is a federally funded research and development center and NASA field center in the City of La Cañada Flintridge, California, United States. Founded in the 1930s by Caltech researchers, JPL is owned by NASA an ...

Kennedy Space Center The John F. Kennedy Space Center (KSC, originally known as the NASA Launch Operations Center), located on Merritt Island, Florida, is one of the National Aeronautics and Space Administration's (NASA) ten field centers. Since December 1968 ...

Langley Research Center The Langley Research Center (LaRC or NASA Langley), located in Hampton, Virginia, United States of America, is the oldest of NASA's field centers. It directly borders Langley Air Force Base and the Back River on the Chesapeake Bay. LaRC has fo ...

Lewis Research Center NASA John H. Glenn Research Center at Lewis Field is a NASA center within the cities of Brook Park and Cleveland between Cleveland Hopkins International Airport and the Rocky River Reservation of Cleveland Metroparks, with a subsidiary facilit ...

(later renamed Glenn Research Center)

Mission plan

Info graphic highlight a possible sequence of launches to Mars and overall design. On the left is a sequence of launches that would send mission items to Mars and the right, it shows how they are utilized. A major component that was sent is the Earth return vehicle, which would use aerobraking to get into Mars orbit. Next, a cargo Mars lander would get important hardware to the surface of Mars which would also use aerobraking. Finally, the crew would land on the surface and use the pre-positioned hardware to conduct the mission and then return to Earth. This plan would use the in-situ production of fuel for Mars ascent stage of returning crew. Both aerocapture and in-situ resource production were methods to reduce overall launch weight of mission plan. ReferenceMissionSequenceVersion3

References

External links

NASA Design Reference Mission

JSC Exploration Site
*[https://web.archive.org/web/20070617120619/http://ares.jsc.nasa.gov/HumanExplore/Exploration/EXLibrary/docs/MarsRef/addendum/index.htm Addendum (Update) to Human Exploration of Mars: The Reference Mission of the NASA Mars Exploration Study Team, 1998, NASA JSC Exploration Office (Mars Reference Mission - DRM 3.0)]
A Mission Design for International Manned Mars Mission, From the 1991 International Space University (ISU) Design Project (Mendell, Wendell)Mars Exploration Strategies: A Reference Program and Comparison of Alternative ArchitecturesNASA Report, Mars Design Reference Mission 3"Reference Mission Version 3.0 Addendum to the Human Exploration of Mars: The Reference Mission of the NASA Mars Exploration Study Team," Bret G. Drake, editor, NASA Lyndon B. Johnson Space Center
*[https://web.archive.org/web/20061005143754/http://ston.jsc.nasa.gov/collections/TRS/_techrep/TP-2001-209371.pdf NASA TP 2001-209371: The Mars Surface Reference Mission: A Description of Human and Robotic Surface Activities]
Stoffel, Wilhelm, and Wendell Mendell, "An Organizational Model for an International Mars Mission", From the 1991 International Space University (ISU) Design ProjectWeaver, David B., and Michael B. Duke, "Mars Exploration Strategies: A Reference Program and Comparison of Alternative Architectures, Conference Paper AIAA 93-4212, (1993)Weaver, David B., Michael B. Duke, and Barney B. Roberts, "Mars Exploration Strategies: A Reference Design Mission," Conference Paper IAF 93-Q.1.383, (1993)NASA illustrations of DRM (Source: Mars Society)

General Mars exploration

The Mars Society Paper ArchivePDF summary of Mars Society Papers
{{DEFAULTSORT:Nasa Design Reference Mission 3.0 NASA oversight Human missions to Mars