Your search keyword '"Boudreaux, Mark"' showing total 11 results

1. Design in the Age of Change

Author

Srinivasan, Srini R., Bilson, Carole, Rashid, Karim, Nixon, Natalie, Mau, Bruce, Heller, Steven, Vaid-Menon, Alok, Wilson, Randall, Norman, Don, Telalbasic, Ida, Boudreaux, Mark, Friedman, Ken, Muratovski, Gjoko, Srinivasan, Srini R., Bilson, Carole, Rashid, Karim, Nixon, Natalie, Mau, Bruce, Heller, Steven, Vaid-Menon, Alok, Wilson, Randall, Norman, Don, Telalbasic, Ida, Boudreaux, Mark, Friedman, Ken, and Muratovski, Gjoko

Published

2022

2. Solar and Drag Sail Propulsion: From Theory to Mission Implementation

Author

Johnson, Les, Alhorn, Dean, Boudreaux, Mark, Casas, Joe, Stetson, Doug, and Young, Roy

Subjects

Spacecraft Propulsion And Power

Abstract

Solar and drag sail technology is entering the mainstream for space propulsion applications within NASA and around the world. Solar sails derive propulsion by reflecting sunlight from a large, mirror- like sail made of a lightweight, reflective material. The continuous sunlight pressure provides efficient primary propulsion, without the expenditure of propellant or any other consumable, allowing for very high V maneuvers and long-duration deep space exploration. Drag sails increase the aerodynamic drag on Low Earth Orbit (LEO) spacecraft, providing a lightweight and relatively inexpensive approach for end-of-life deorbit and reentry. Since NASA began investing in the technology in the late 1990's, significant progress has been made toward their demonstration and implementation in space. NASA's Marshall Space Flight Center (MSFC) managed the development and testing of two different 20-m solar sail systems and rigorously tested them under simulated space conditions in the Glenn Research Center's Space Power Facility at Plum Brook Station, Ohio. One of these systems, developed by L'Garde, Inc., is planned for flight in 2015. Called Sunjammer, the 38m sailcraft will unfurl in deep space and demonstrate solar sail propulsion and navigation as it flies to Earth-Sun L1. In the Flight Center (MSFC) managed the development and testing of two different 20-m solar sail systems and rigorously tested them under simulated space conditions in the Glenn Research Center's Space Power Facility at Plum Brook Station, Ohio. One of these systems, developed by L'Garde, Inc., is planned for flight in 2015. Called Sunjammer, the 38m sailcraft will unfurl in deep space and demonstrate solar sail propulsion and navigation as it flies to Earth-Sun L1. In the interim, NASA MSFC funded the NanoSail-D, a subscale drag sail system designed for small spacecraft applications. The NanoSail-D flew aboard the Fast Affordable Science and Technology SATellite (FASTSAT) in 2010, also developed by MSFC, and began its mission after it was ejected from the FASTSAT into Earth orbit, where it remained for several weeks before deorbiting as planned. NASA recently selected two small satellite missions for study as part of the Advanced Exploration Systems (AES) Program, both of which will use solar sails to enable their scientific objectives. Lunar Flashlight, managed by JPL, will search for and map volatiles in permanently shadowed Lunar craters using a solar sail as a gigantic mirror to steer sunlight into the shaded craters. The Near Earth Asteroid (NEA) Scout mission will use the sail as primary propulsion allowing it to survey and image one or more NEA's of interests for possible future human exploration. Both are being studied for possible launch in 2017. The Planetary Society's privately funded LightSail-A and -B cubesat-class spacecraft are nearly complete and scheduled for launch in 2015 and 2016, respectively. MMA Design launched their DragNet deorbit system in November 2013, which will deploy from the STPSat-3 spacecraft as an end of life deorbit system. The University of Surrey is building a suite of cubesat class drag and solar sail systems that will be launched beginning in 2015. As the technology matures, solar sails will increasingly be used to enable science and exploration missions that are currently impossible or prohibitively expensive using traditional chemical and electric rockets. For example, the NASA Heliophysics Decadal Survey identifies no less than three such missions for possible flight before the mid-2020's. Solar and drag sail propulsion technology is no longer merely an interesting theoretical possibility; it has been demonstrated in space and is now a critical technology for science and solar system exploration.

Published

2014

3. FASTSAT a Mini-Satellite Mission...A Way Ahead

Author

Boudreaux, Mark, Pearson, Steve, and Casas, Joseph

Subjects

Spacecraft Design, Testing And Performance

Abstract

The Fast Affordable Science and Technology Spacecraft (FASTSAT) is a mini-satellite weighing less than 150 kg. FASTSAT was developed as government-industry collaborative research and development flight project targeting rapid access to space to provide an alternative, low cost platform for a variety of scientific, research, and technology payloads. The initial spacecraft was designed to carry six instruments and launch as a secondary rideshare payload. This design approach greatly reduced overall mission costs while maximizing the on-board payload accommodations. FASTSAT was designed from the ground up to meet a challenging short schedule using modular components with a flexible, configurable layout to enable a broad range of payloads at a lower cost and shorter timeline than scaling down a more complex spacecraft. The integrated spacecraft along with its payloads were readied for launch 15 months from authority to proceed. As an ESPA-class spacecraft, FASTSAT is compatible with many different launch vehicles, including Minotaur I, Minotaur IV, Delta IV, Atlas V, Pegasus, Falcon 1/1e, and Falcon 9. These vehicles offer an array of options for launch sites and provide for a variety of rideshare possibilities.

Published

2012

4. Science of Opportunity: Heliophysics on the FASTSAT Mission and STP-S26

Author

Rowland, Douglas E, Collier, Michael R, Sigwarth, John B, Jones, Sarah L, Hill, Joanne K, Benson, Robert, Choi, Michael, Chornay, Dennis, Cooper, John, Feng, Steven, Gill, Nathaniel, Goodloe, Colby, Han, Lawrence, Hancock, Holly, Hunsaker, Floyd, Jones, Noble, Keller, John W, Klenzing, Jeffrey, Kleyner, Igor, Moore, Tom, Ogilvie, Keith, Boudreaux, Mark, Casas, Joseph, Myre, David, and Smith, Billy

Subjects

Spacecraft Instrumentation And Astrionics

Abstract

The FASTSAT spacecraft, which was launched on November 19, 2010 on the DoD STP-S26 mission, carries three instruments developed in joint collaboration by NASA GSFC and the US Naval Academy: PISA, TTl, and MINI_ME.I,1 As part of a rapid-development, low-cost instrument design and fabrication program, these instruments were a perfect match for FASTSAT, which was designed and built in less than one year. These instruments, while independently developed, provide a collaborative view of important processes in the upper atmosphere relating to solar and energetic particle input, atmospheric response, and ion outflow. PISA measures in-situ irregularities in electron number density, TIl provides limb measurements of the atomic oxygen temperature profile with altitude, and MINI-ME provides a unique look at ion populations by a remote sen sing technique involving neutral atom imaging. Together with other instruments and payloads on STP-S26 such as the NSF RAX mission, FalconSat-5, and NanoSail-D (launched as a tertiary payload from FASTSAT), these instruments provide a valuable "constellation of opportunity" for following the now of energy and charged and neutral particles through the upper atmosphere. Together, and for a small fraction of the price of a major mission, these spacecraft will measure the energetic electrons impacting the upper atmosphere, the ions leaving it, and the large-scale plasma and neutral response to these energy inputs. The result will be a new model for maximizing scientific return from multiple small, distributed payloads as secondary payloads on a larger launch vehicle.

Published

2011

5. FASTSAT-HSV01 Synergistic Observations of the Magnetospheric Response During Active Periods: MINI-ME, PISA and TTI

Author

Casas, Joseph C, Collier, Michael R, Rowland, Douglas E, Sigwarth, John B, and Boudreaux, Mark E

Subjects

Space Sciences (General)

Abstract

Understanding the complex processes within the inner magnetosphere of Earth particularly during storm periods requires coordinated observations of the particle and field environment using both in-situ and remote sensing techniques. In fact in order to gain a better understanding of our Heliophysics and potentially improve our space weather forecasting capabilities, new observation mission approaches and new instrument technologies which can provide both cost effective and robust regular observations of magnetospheric activity and other space weather related phenomenon are necessary. As part of the effort to demonstrate new instrument techniques and achieve necessary coordinated observation missions, NASA's Fast Affordable Science and Technology Satellite Huntsville 01 mission (FASTSAT-HSVOI) scheduled for launch in 2010 will afford a highly synergistic solution which satisfies payload mission opportunities and launch requirements as well as contributing iri the near term to our improved understanding of Heliophysics. NASA's FASTSAT-HSV01 spacecraft on the DoD Space Test Program-S26 (STP-S26) Mission is a multi-payload mission executed by the DoD Space Test Program (STP) at the Space Development and Test Wing (SDTW), Kirtland AFB, NM. and is an example of a responsive and economical breakthrough in providing new possibilities for small space technology-driven and research missions. FASTSAT-HSV is a unique spacecraft platform that can carry multiple small instruments or experiments to low-Earth orbit on a wide range of expendable launch vehicles for a fraction of the cost traditionally required for such missions. The FASTSAT-HSV01 mission allows NASA to mature and transition a technical capability to industry while increasing low-cost access to space for small science and technology (ST) payloads. The FASTSAT-HSV01 payload includes three NASA Goddard Space Flight Center (GSFC) new technology built instruments that will study the terrestrial space environment and potentially contribute to space weather research in a synergistic manner. MINI-ME, a neutral atom imager, will observe the neutral atom inputs to ionospheric heating which can be important during high levels of magnetospheric activity. PISA, a plasma impedance spectrometer, will measure simultaneously the local electron densities and temperatures as well as measure small scale density structure (500 m spatial scale) during these active periods. TTI, a thermospheric imager, will remotely determine the thermospheric temperature response to this magnetospheric activity. Together, these observations will contribute significantly to a comprehensive understanding of the flow of energy through and the response of the storm-time terrestrial magnetosphere.

Published

2010

6. A Fast, Affordable, Science and Technology SATellite (FASTSAT) and the Small Satellite Market Development Environment

Author

Boudreaux, Mark, Montgomery, Edward, and Cacas, Joseph

Subjects

Spacecraft Design, Testing And Performance

Abstract

The National Aeronautics and Space Administr ation at Marshall Space Flight Center and the National Space Science and Technology Center in Huntsville Alabama USA, are jointly developing a new class of science and technology mission small satellites. The Fast, Affordable, Science and Technology SATell ite (FASTSAT) was designed and developed using a new collaborative and best practices approach. The FASTSAT development, along with the new class of low cost vehicles currently being developed, would allow performance of ~ 30 kg payload mass missions for a cost of less than 10 million US dollars.

Published

2008

7. Lab-on-a-Chip: From Astrobiology to the International Space Station

Author

Maule, Jake, Wainwright, Nor, Steele, Andrew, Gunter, Dan, Monaco, Lisa A, Wells, Mark E, Morris, Heather C, and Boudreaux, Mark E

Subjects

Exobiology

Abstract

The continual and long-term habitation of enclosed environments, such as Antarctic stations, nuclear submarines and space stations, raises unique engineering, medical and operational challenges. There is no easy way out and no easy way to get supplies in. This situation elevates the importance of monitoring technology that can rapidly detect events within the habitat that affect crew safety such as fire, release of toxic chemicals and hazardous microorganisms. Traditional methods to monitor microorganisms on the International Space Station (ISS) have consisted of culturing samples for 3-5 days and eventual sample return to Earth. To augment these culture methods with new, rapid molecular techniques, we developed the Lab-on-a-Chip Application Development - Portable Test System (LOCAD-PTS). The system consists of a hand-held spectrophotometer, a series of interchangeable cartridges and a surface sampling/dilution kit that enables crew to collect samples and detect a range of biological molecules, all within 15 minutes. LOCAD-PTS was launched to the ISS aboard Space Shuttle Discovery in December 2006, where it was operated for the first time during March-May 2007. The surfaces of five separate sites in the US Lab and Node 1 of ISS were analyzed for endotoxin, using cartridges that employ the Limulus Amebocyte Lysate (LAL) assay; results of these tests will be presented. LOCAD-PTS will remain permanently onboard ISS with new cartridges scheduled for launch in February and October of 2008 for the detection of fungi (Beta-glucan) and Gram-positive bacteria (lipoteichoic acid), respectively.

Published

2008

8. Flight Manifesting Process for NASA Microgravity Payloads

Author

Matisak, Brian, Boudreaux, Mark, Anderson, Sherwood, Ramage, William, and Henderson, Robin N

Subjects

Space Processing

Abstract

The objective of NASA's Microgravity Research Program is to utilize the low gravity environment of space to explore the nature of physical phenomena that contributes to progress in science and technology on Earth. Under the oversight of NASA Headquarters, the Microgravity Research Program Office (MRPO) at the Marshall Space Flight Center (MSFC) assumes all program management responsibilities associated with Microgravity Research and Space Product Development. One program management responsibility that plays a vital role to the success of the MRPO is the flight manifesting process for MRPO-sponsored payloads. In this paper, the authors will examine the various processes utilized by MRPO personnel in acquiring flight opportunities for MRPO-sponsored payloads.

Published

2001

9. The Fast, Affordable, Science and Technology Satellite (FASTSAT) Mission

Author

Boudreaux, Mark, Pearson, Steve, and Casas, Joseph

Abstract

The Fast Affordable Science and Technology Spacecraft (FASTSAT - HSV01) is a mini-satellite weighing less than 150 kg. FASTSAT was developed as a government-industry collaborative research and development flight project targeting rapid access to space to provide an alternative, low cost platform for a variety of scientific, research, and technology payloads. This initial spacecraft mission carried six instruments and was launched as a secondary “rideshare” payload. The design approach greatly reduced overall mission costs while maximizing the on-board payload accommodations. FASTSAT was designed from the ground up to meet a challenging short schedule using modular components with a flexible, configurable layout to enable a broad range of payloads at a lower cost and shorter timeline than scaling down a more complex spacecraft. The integrated spacecraft along with its payloads were readied for launch in 15 months from authority to proceed. As an Enhanced Expendable Launch Vehicle Secondary Payload Adaptor ESPA-class spacecraft, FASTSAT is compatible with a variety of launch vehicles. These vehicles offer an array of options for launch sites and provide for a variety of rideshare possibilities.

Published

2013

10. Science of opportunity: Heliophysics on the FASTSAT mission and STP-S26

Author

Rowland, Douglas E., primary, Collier, Michael R., additional, Sigwarth, John B., additional, Jones, Sarah L., additional, Hill, Joanne K., additional, Benson, Robert, additional, Choi, Michael, additional, Chornay, Dennis, additional, Cooper, John, additional, Feng, Steven, additional, Gill, Nathaniel, additional, Goodloe, Colby, additional, Han, Lawrence, additional, Hancock, Holly, additional, Hunsaker, Floyd, additional, Jones, Noble, additional, Keller, John W., additional, Klenzing, Jeffrey, additional, Kleyner, Igor, additional, Moore, Tom, additional, Ogilvie, Keith, additional, Pfaff, Robert, additional, Price, Tracy, additional, Roman, Joe, additional, Rodruiguez, Marcello, additional, Rozmarynowski, Paul, additional, Saulino, Mark, additional, Sheikh, Salman, additional, Simms, Ken, additional, Yew, Alvin, additional, Young, Eric, additional, Kujawski, Joseph, additional, Boudreaux, Mark, additional, Casas, Joseph, additional, Myre, David, additional, and Smith, Billy, additional

Published

2011

11. Here's the man who designed Star Wars toys for 40 years

Author

Bloomberg LP, production company. and Boudreaux, Mark, speaker.

Published

2015