This is the presentation given at the end of the Space studies program at NASA Ames, August 2009. The ACCESS Mars project stands for Assessing Cave Capabilities and Evaluating Specific Solutions (ACCESS) Mars explores the future of robotic and human exploration missions to Mars via subsurface habitation.
Mission statement: "...to develop a mission architecture for an initial settlement on Mars by assessing the feasibility of cave habitation as an alternative to proposed surface-based solutions".
all points choose is perfect . read for knowledge and what will be future if we have space elevator in real because this is science friction concept which really possible by discover carbon nano tube and now what is carbon nano tube read it in report thank you
Galaxy Forum USA 2016 - Prof Imke de Pater, UC BerkeleyILOAHawaii
Background:
Galaxy Forum is the primary education and outreach initiative of ILOA, it is an architecture designed to advance 21st Century science, education, enterprise and development around the world.
Galaxy Forums are public events specifically geared towards high school teachers, educators, astronomers of all kinds, students and the general public. Presentations are provided by experts in the fields of astrophysics / galaxy research, space exploration and STEM education, as well as related aspects of culture and traditional knowledge. Interactive panel discussions allow for community participation and integration of local perspectives.
Stats:
Almost 70 Galaxy Forums, with a total of about 300 presentations to date.
Held in 26 locations worldwide including Hawaii, Silicon Valley, Canada, China, India, Southeast Asia, Japan, Europe, Africa, Chile, Brazil, Kansas and New York.
Started with Galaxy Forum USA, July 4, 2008 in Silicon Valley, California.
International Lunar Observatory Association (ILOA) is an interglobal enterprise incorporated in Hawaii as a 501(c)(3) non-profit to expand human knowledge of the Cosmos through observation from our Moon and to participate in internationally cooperative lunar base build-out, with Aloha – the spirit of Hawai`i.
Space elevator- a stage for cheap space exploration and tourismMOHAMMED FAZIL
It is the latest technology in the field of Aerospace industry. It consist of a platform from where rockets or space shuttles can be launched from the stratosphere , bringing surplus economy reduction in space exploration programmes. It thus satisfies the concept of cheap space tourism.
Design and Assembly of an Economically-viable Near-Earth Asteroid Mining Robotadamwick
Presented in 2005
Outer space is a dangerous environment for humans to explore. However, unmanned spacecraft, the workhorses of NASA’s current space program, can travel through space with relative ease. By constructing an advanced robotic mining craft using a combination of current and easily obtained future technologies, a mining expedition could be made to one of Earth’s nearest neighbors, a near-Earth asteroid. Near-Earth Asteroids (NEAs) come in all shapes and in all varieties, which makes choosing the proper asteroid to mine a nontrivial affair: considerations must be made of asteroidal orbit, size, and composition. In addition, once the asteroid is reached by the mining craft, the physical and chemical act of mining an asteroid in deep space, far from places where “normal” conditions like gravity and an oxygenated atmosphere prevail, is substantially difficult; each mining implement, procedure, and storage technique must be chosen precisely. After the completion of the first mining mission, the mining craft will return to Earth orbit where it will transfer its precious cargo of ferrous metals, rarer-metals, and volatile gasses to an awaiting orbital station, thus avoiding any further need to launch minerals from Earth, which is extremely expensive. As a result of the asteroid mining and resource gathering operation, the National Aeronautics and Space Association will be able to expand the number of its deep-space operations exponentially.
Markets in Motion: Developing Markets in Low Earth OrbitISSRDC
Increased commercial activity in space has gradually transformed low Earth orbit into an emerging market. This session will focus on four development areas—biological and pharmaceutical, Earth imaging, materials science, and space transportation—where companies are finding and targeting customer groups that have the potential to develop into market sectors in low Earth orbit.
This presentation gives a brief concept (engineering related) about solar space propulsion. It is all about the travelling technology of satellite in the space world. Hope it helps !
all points choose is perfect . read for knowledge and what will be future if we have space elevator in real because this is science friction concept which really possible by discover carbon nano tube and now what is carbon nano tube read it in report thank you
Galaxy Forum USA 2016 - Prof Imke de Pater, UC BerkeleyILOAHawaii
Background:
Galaxy Forum is the primary education and outreach initiative of ILOA, it is an architecture designed to advance 21st Century science, education, enterprise and development around the world.
Galaxy Forums are public events specifically geared towards high school teachers, educators, astronomers of all kinds, students and the general public. Presentations are provided by experts in the fields of astrophysics / galaxy research, space exploration and STEM education, as well as related aspects of culture and traditional knowledge. Interactive panel discussions allow for community participation and integration of local perspectives.
Stats:
Almost 70 Galaxy Forums, with a total of about 300 presentations to date.
Held in 26 locations worldwide including Hawaii, Silicon Valley, Canada, China, India, Southeast Asia, Japan, Europe, Africa, Chile, Brazil, Kansas and New York.
Started with Galaxy Forum USA, July 4, 2008 in Silicon Valley, California.
International Lunar Observatory Association (ILOA) is an interglobal enterprise incorporated in Hawaii as a 501(c)(3) non-profit to expand human knowledge of the Cosmos through observation from our Moon and to participate in internationally cooperative lunar base build-out, with Aloha – the spirit of Hawai`i.
Space elevator- a stage for cheap space exploration and tourismMOHAMMED FAZIL
It is the latest technology in the field of Aerospace industry. It consist of a platform from where rockets or space shuttles can be launched from the stratosphere , bringing surplus economy reduction in space exploration programmes. It thus satisfies the concept of cheap space tourism.
Design and Assembly of an Economically-viable Near-Earth Asteroid Mining Robotadamwick
Presented in 2005
Outer space is a dangerous environment for humans to explore. However, unmanned spacecraft, the workhorses of NASA’s current space program, can travel through space with relative ease. By constructing an advanced robotic mining craft using a combination of current and easily obtained future technologies, a mining expedition could be made to one of Earth’s nearest neighbors, a near-Earth asteroid. Near-Earth Asteroids (NEAs) come in all shapes and in all varieties, which makes choosing the proper asteroid to mine a nontrivial affair: considerations must be made of asteroidal orbit, size, and composition. In addition, once the asteroid is reached by the mining craft, the physical and chemical act of mining an asteroid in deep space, far from places where “normal” conditions like gravity and an oxygenated atmosphere prevail, is substantially difficult; each mining implement, procedure, and storage technique must be chosen precisely. After the completion of the first mining mission, the mining craft will return to Earth orbit where it will transfer its precious cargo of ferrous metals, rarer-metals, and volatile gasses to an awaiting orbital station, thus avoiding any further need to launch minerals from Earth, which is extremely expensive. As a result of the asteroid mining and resource gathering operation, the National Aeronautics and Space Association will be able to expand the number of its deep-space operations exponentially.
Markets in Motion: Developing Markets in Low Earth OrbitISSRDC
Increased commercial activity in space has gradually transformed low Earth orbit into an emerging market. This session will focus on four development areas—biological and pharmaceutical, Earth imaging, materials science, and space transportation—where companies are finding and targeting customer groups that have the potential to develop into market sectors in low Earth orbit.
This presentation gives a brief concept (engineering related) about solar space propulsion. It is all about the travelling technology of satellite in the space world. Hope it helps !
The Future of Mars Exploration: A Tale of Perseverance and CuriosityData Con LA
Data Con LA 2020
Description
The Mars 2020 Rover sets the stage for Mars Sample return and continues NASA's explorarion of the red planet. Dr. Sengupta will discuss the scientific goals and unique technology challenges that will bring humanity closer to setting foot on the surface of Mars than ever before.
Speaker
Anita Sengupta, University of Southern California, Research Professor
A GEO satellite’s distance from earth gives it a large coverage area, almost a fourth of the earth’s surface and also have 24 hour view of a particular area.This will be very helpful to army,navy etc.,These factors make it ideal for satellite broadcast and other multipoint applications.Continuous monitoring is done and also cost effective in long term, risk-less.
For the full video of this presentation, please visit:
http://www.embedded-vision.com/platinum-members/embedded-vision-alliance/embedded-vision-training/videos/pages/may-2016-embedded-vision-summit-nasa-keynote
For more information about embedded vision, please visit:
http://www.embedded-vision.com
Larry Matthies, senior research scientist at the NASA Jet Propulsion Laboratory, presents the "Using Vision to Enable Autonomous Land, Sea and Air Vehicles" keynote at the May 2016 Embedded Vision Summit.
Say you’re an autonomous rover and you’ve just landed on Mars. Vexing questions now confront you: “Where am I and how am I moving?” “What obstacles are around me?” “Are the obstacles moving?” “What other objects are around me that matter to my mission?” As it turns out, Earth isn’t that different from Mars in this regard. If you’re an autonomous car or drone, you face similar challenges. You’ve got to find combinations of sensors that work across different illumination, weather, temperature, and vehicle dynamics; processors that fit the size, weight, and power constraints of the system; and algorithms that can answer the questions given the sensors and processors available. In this talk, Matthies gives an overview of autonomous vehicle computer vision applications, explores successful approaches, and illustrates concepts with application examples from applications on Earth and in planetary exploration.
In this paper with the reference of NASA’s MARS Curiosity Rover, this project is meant for a low cost, lightweight and small size unmanned ground vehicle (UGV) which is controlled by NI-myRIO a hardware component of National Instruments can be used for surveying and determining the natural conditions for living beings like identification of gases, collection of picture samples etc., It consists of six individual motors with lightweight chassis for achieving various movements of rover, gas sensors, camera with servos, long-lasting power supply with its required communication tools. The Six wheeled Rover with three or more suspension alignments will move and collect various samples for identification of gases and taking pictures around the astronomical areas automatically by the automated movements.
Similar to ACCESS Mars project final presentation (20)
2. ACCESS MARS Space Studies Program 2009 Team Project Final Presentation August 27 th , 2009 NASA Ames Research Center NASA Exploration Systems Mission Directorate (ESDM) International Space University
23. Artist’s Conception of the Habitat Design (Tomás Saraceno) Cave Habitat Structure Advantages Disadvantages Lava Tube: Pressurized pneumatic habitat within a natural lava tube. - Readily available radiation shielding - No excavation required - Lightweight construction - Structural stability - Scientific merit - Expandable within cave network - Potential access to underground resources - Deeper drilling capability - Natural stable temperature environment - Location specific - Limitation for landing site - Limitation for mobility and access to surface resources - Fixed entry way - Precursor mission needed
24. Power Systems A: Surface rovers D: Human transport vehicles -: Not suggested B: Microbots E: Habitat R: Suggested redundancy C: Cargo delivery rovers F: Future concept for settlement S: Suggested solution Power Source Advantages Disadvantages A B C D E Primary Batteries -Cheap, reliable, full-time operation -No energy capture required -Very short lifetime -Low power output - - - - - Solar power and Secondary Batteries -High reliability -Mature technology -Renewable energy -Low efficiency and large area -Degradation and damage -Intermittent power generation -Need to transport solar arrays R S - - - Solar power and RFCs -Renewable fuel -Lower array area required -Degradation and damage -Intermittent power generation -Need to transport solar arrays S - R R R Wind Energy -Renewable energy -Low atmospheric density - -Large structures required - - - - - Geothermal -High efficiency -High reliability -No proof of concept (Arizona State University, 2009a; Arizona State University, 2009b) - - - - - Nuclear Fission and Nuclear RTG -Optimal for large-scale, high-power missions -Full-time operation and long lifetime -Compliments nuclear propulsion -High reliability -Ethical and safety concerns -Radiation shielding -Low specific power - - S S S, R ISRU -Sustainable energy source -Long lifetime -Abundance of fuel -Insufficient knowledge and access to resources -New technology - - F F F
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26. Music by Megatrax with Danielle Cormier and Jeffrey Apeldoorn August 27 th , 2039
27. Calculated Frequency and Duration of EVA In Each Scenario Space Medicine Scenario Duration Frequency Critical Path (Time) Min. Path (Time) Rover inside other caves 10-15 days, with maximum 8 hours inside other cave 1-2/month 720h/month 240h/month Rover inside main habitat cave 1-5 days 4-5/month 600h/month 96h/month Foot inside cave 2-8 hours 3/week 24h/week 6h/week Rover outside cave 10-15 days 1-2/month 720/month 240h/month On foot outside cave 2- 6 hours 3/week 18h/week 6h/week
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29. Space Medicine Health risks Bone loss Muscle loss Cardiovascular deconditioning Orthostatic intolerance. Health Risk Probabilities, calculated after (HUMEX study, ESA, 2003) More research needed Long-term analogs Countermeasures Estimated Probabilities of Health Issue Outcomes (%) Scenario Scenario Condition DRM EDRM Condition DRM EDRM Acute respiratory infections 54.95 85.99 Urinary calculus 0.03 0.04 Pneumonia and influenza 0.14 0.22 Disease of male genital organs 0.03 0.04 Neoplasms (pre & post flight control) 0.01 0.02 Disease of breast or female organs 0.71 1.11 Endocrine, nutritional, metabolic, immunity 0.04 0.07 Heat and light effects 0.10 0.15 Blood diseases and blood forming organisms 0.03 0.04 Open wounds / bleeding 0.14 0.22 Cardiovascular disease 0.14 0.22 Ischemic heart disease 0.06 0.09 Hypertensive disease 0.01 0.22 Disease of liver or gall bladder 0.07 0.11
40. Space and Society Stakeholder Matrix Stakeholders Interest Governments Social Impact, Political, Economical, Policy NGO’s Social Impact, Political Space Agencies Science, Technology, Political Large Aerospace Companies Technology, Financial, Economical Small Aerospace Companies Technology, Financial, Economical Private Enterpreneurs Financial, Technology Eng. TaxPayers Social Impact Space Lobbyist organizations Political, Regulatory/Policy Academia Science, Technology, Education Cultural Institution Social impact, Cultural Mass and Social Media Social Impact
41. Music by Megatrax with Danielle Cormier and Jeffrey Apeldoorn August 27 th , 2039
45. Conclusions CHALLENGES MITIGATION In-Situ Resource Utilization Methods T echnological development (Earth, Moon) Detecting and assessing caves P recursor Mars robotic and orbital missions Unknowns related to caves Study of analogue sites in lava tubes Cave stability P roper roof thickness and lack of surface impacts Psychological effects of cave environment Crew training through analogue missions Mobility in caves Rover and aerial vehicle development Communication and navigation in caves Relay network system Planetary protection and legal considerations International cooperation and discussions
49. We would like to extend special thanks to NASA Ames Research Center and NASA Exploration Systems Mission Directorate (ESMD) for all their support and resources throughout this project Video clips courtesy of NASA Video soundtracks: Theme from Armageddon by Trevor Rabin (Sony) Hoppípolla by Sigur Rós (EMI)
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52. Acknowledgements Abdul Mohsen Al Husseini Q&A, Editor, Life Science Luis Alvarez Sanchez Konstantinos Antonakopoulos Distant supporter Engineering Jeffrey Apeldoorn Anchor Man, Q&A, Engineering Kenneth Ashford Editor, Interdisciplinary Kutay Deniz Atabay Video Team, Life Sciences Ignacio Barrios Video Team, Physical Science Yasemin Baydaroglu Life Sciences Katherine Bennell Expert Physical Science, Physical Science Jie Chen Engineering Xin Chen Life Sciences Danielle Cormier Anchor Woman, Producer, System Architect Patrick Crowley Casting, Life Sciences Guy de Carufel Physical Science Benoit Deper Engineering Line Drube Q&A, Physical Science Paul Duffy Editor, Life Science Phillip Edwards Video Team, Physical Science Esteban Gutierrez Engineering Olivia Haider Design, Astronaut, Interdisciplinary Ganesh Kumar Hair Shankar Lal Das Video Team, Engineering Carsten Henselowsky Physical Science Daichi Hirano Astronaut, Engineering Tomas Hirmer Director, Editor, Life Science Barry Hogan Editor, Astronaut, Life Sciences Andrea Jaime Albalat Video Team, Life Sciences Elizabeth (Beth) Jens Editor, Astronaut, Life Sciences Iulia Jivanescu Physical Science Aliac Jojaghaian Set Decoration, Engineering Mary Kerrigan Video Team, Poem Writer, Physical Science Yukiko Kodachi Interdisciplinary Sara Langston Editor, Video Team , Interdisciplinary Reggie MacIntosh Design, Steward, Life Sciences Xavier Miguelez Video Team, Design, Engineering Natalie Panek Editor, Stewardess, Life Science Campbell Pegg Interdisciplinary Expert, Engineering Regina Peldszus Design, Video Team, Life Sciences Xiaobo Peng Engineering Antoni Perez Poch Expert Life Sciences, Life Sciences Alexandre Perron Content, Engineering Jiawen Qiu Engineering Pascal Renten Video Team, Life Sciences Joao Ricardo Casting, Engineering Tomas Saraceno Design, Video Team, Life Sciences Felipe Sauceda Producer, Astronaut, System Architect Azam Shaghaghi Varzaghani Weather Reporter, Physical Science Rogan Shimmin Life Sciences Ruben Solaz Engineering Alexandre Sole Video Team, Voice, Life Sciences Rahul Suresh Life Sciences Tatiana Mar Vaquero Escribano Engineering expert, Engineering Marta Vargas Munoz Set Decoration, Engineering Pierre-Damien Vaujour Interdisciplinary Dominic Veillette Engineering Yonatan Winetraub Engineering Oliver Zeile Astronaut, Engineering
53. “ To develop a mission architecture for an initial settlement on Mars by assessing the feasibility of cave habitation as an alternative to proposed surface-based solutions” Questions and Answers
Editor's Notes
Phil & Ganesh
Danielle & Jeffrey
For you guys that are not familar with the work performed 30 years ago, here you can see an overview of what was covered during the study and which will be discussed during todays ACCESS Mars News special!
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Danielle & Jeffrey
Question asked by anchorman & women Background Astronaut from video doing nothing waiting for question