| |
|
|
 |
| |
|
| |
The IPP Partnership Seed Fund has been established as a new initiative to enhance NASA's ability to meet mission technology goals by providing seed funding to address barriers and initiate cost-shared, joint-development partnerships. The IPP Seed Fund will be used to provide "bridge" funding to enable larger partnerships and development efforts to occur and will encourage, to the maximum extent possible, the leveraging of funding, resources and expertise from non-NASA partners, NASA Programs and Projects and NASA Centers.
Partnership goals include providing for an increased range of technology solutions, a broadened technology portfolio, improved cost avoidance, accelerated development and maturation of technologies, and a larger pool of qualified commercial providers.
- An annual process for selecting innovative partnerships for funding, to address the technology priorities of NASA's Mission Directorates.
- Enhances NASA's ability to meet Mission capability goals by providing leveraged funding to address technology barriers via cost-shared, joint-development partnerships.
- The IPP Office at NASA HQ provides an annual Seed Fund Announcement of Opportunity to all NASA Centers for selecting innovative partnerships for funding.
- The technology landscape covered by the successful proposals embraces the needs of all four Mission Directorates.
- Seed Fund operates through a collaboration of Center IPP Offices, NASA co-PI, and external co-PI
| |
|
|
For Industry
NASA provides industry the opportunity to stimulate business investment in the development of new markets and industries in low Earth orbit, and to support NASA's mission and objectives. Businesses can work with NASA in a variety of ways, depending on the nature of the business, the size of a firm or a particular contract type.
+ Read More
|
| |
|
|
For Academia
Coming Soon
|
| |
|
|
For National Laboratories
The Federal Laboratory Consortium grew out of an earlier DoD Consortium formed in 1971 to improve collaboration among DoD labs and to find civilian uses for technical knowledge originally developed for military purposes. In 1974 this organization became the Federal Laboratory Consortium for Technology Transfer, with DoD still the primary focus. Congress broadened the organization by establishing in the Federal Technology Transfer Act of 1986 the charter to foster, through federal labs, the transfer of technology to the private sector, other federal labs, and state/local governments. This is a national organization divided into six regions (Far West, Mid-Continent, Midwest, Mid-Atlantic, Northeast, and Southeast). The Federal Lab Consortium has fostered collaboration among federal agencies in the efforts to transfer technology, has provided training for federal technology transfer professionals, and is actively engaged through the region networks to develop and sustain collaboration with state/local governments, academia, industry, and economic development organizations within a given region in the area of technology transfer. IPP through its NASA field center offices is actively involved in the Federal Lab Consortium.
+ Federal Laboratory Consortium
+ Federal Laboratory Consortium by Region
|
| |
|
|
For Government
There will be a number of significant challenges in the coming years to meet the objectives outlined in NASA's Strategic Plan. The leveraging of resources internal and external to NASA will be an important factor in meeting these challenges. IPP actively seeks to leverage NASA resources through partnerships with academia, the private sector, and other government: federal, state, and local. The Innovative Partnerships Program, with its cross-agency, cross-discipline scope, and new initiatives such as the Seed Fund, is in a strong position to foster government interagency and inter-organization collaboration. IPP is a facilitator, bringing parties together and bridging communication gaps. IPP is also a catalyst and change agent, fostering new partnerships and demonstrating the effectiveness of new approaches and methods. Through these partnerships, NASA and other organizations can pool resources to advance mutual goals.
|
| |
November 2008: Combining Resources to Make Great Things Possible Through the
IPP Partnership Seed Fund
Seed Fund recipients chosen for 2008: The IPP Office again coordinated proposal efforts for the Center in FY07, yielding five winning proposals. Principal investigators for these projects are looking toward highly innovative goals for their funded research in 2008.
- Enabling autonomous and computationally intensive capabilities for NASA missions
- Lowering the cost and risk of avionics systems for NASA missions
- Helping NASA better understand unknown planetary bodies and their potential risks to Earth
- Improving mapping techniques for topography and NASA exploration of icy moons
- Helping NASA ensure crew health and safety during hazardous space weather events
+ Read More
November 13, 2008: NASA Tests Lunar Rovers and Oxygen Production Technology
RELEASE: 08-288
Two IPP seed fund projects were integral elements in a two week testing period of exploration technologies on Hawaii's volcanic soil. The two seed fund projects were:
- Low-Temperature, Long-Life, Compliant Wheels For The Lunar Surface And Beyond, with Michelin, Clemson University, University of Hawaii/PISCES and
- Lunar Analog Field Demonstration Of ISRU & HRS, with University of Hawaii/PISCES, and State of Hawaii
+ Read More
Aeronautics Research Mission Directorate
Exploration Systems Mission Directorate
Space Operations Mission Directorate
Science Mission Directorate
| Lead Center |
Proposal Title |
| GRC |
Low-Density Turbine Blade Superalloys For Improved Engine Performance and Reduced Emissions
(Value listed below)
| Program/Project(s) Supported: Fundamental Aeronautics, Subsonic: Fixed Wing (SFW) Program |
| Technology Focus Area: Development of technologies for improving performance and reducing emissions for subsonic aircraft |
| Measurable Benefits: 1) Advances TRL from 3 to 5; 2) Provides near-term commercialization of NASA technology that is consistent with SFW goals; 3) Accelerates path to additional benefits through a new concept for a low-density single crystal/powder metallurgy turbine disk, to be initiated in FY08 in SFW. This is enabling for NASA's growing interest in blended-wing-body aircraft and is critical to AirForce long range strike aircraft. |
|
|
| ARC |
Advanced Thermal Protection Systems For Hypersonic Flight In Air and Planetary Atmosphere
(Value listed below)
| Program/Project(s) Supported: ESMD Orion Block III Mars-return vehicle, future SMD missions Mars Astrobiology Laboratory, Mars Sample return, and Saturn Multiprobe |
| Technology Focus Area: Advanced TPS materials for hypersonics |
| Measurable Benefits: Robust ablative TPS with greatly improved thermomechanical properties and reduced mass when compared to current TPS solutions (for example, carbon phenolic) |
|
|
| GRC |
Development and Validation of Foam - Metal Acoustic Liner For Attenuation of Turbofan Engine Noise
(Value listed below)
| Program/Project(s) Supported: Fundamental Aeronautics/Subsonic Fixed Wing |
| Technology Focus Area: Developing technologies for reducing noise for subsonic aircraft. Developing physics based analysis and design tools. |
| Measurable Benefits: 3 db Engine Noise Reduction with less than 1/2% change in specific fuel comsumption |
|
|
| LaRC |
Multifunctional Nanocomposites for Aerospace Applications
(Value listed below)
| Program/Project(s) Supported: Subsonic Fixed Wing/ARMD-1Q, Structures, Materials, Mechanisms/ETDP |
| Technology Focus Area: Fundamental Aeronautics, Subsonic Fixed Wing and Structures, Materials and Mechanisms, ETDP |
| Measurable Benefits: 1) Intrinsic multifunctionality in nanocomposites defined as simultaneous improvements in modulus of 50%, conductivity of 10, and two fold increase in permeability barrier properties. 2) By the endo of this program Vorbeck would enter into product prototyping relationships with some of their existing corporate partners on these systems. |
|
|
| LaRC |
Carbon Nanotube Yarn Multifunctional Sensors In Composite Structures
(Value listed below)
| Non-parasitic multifunctional sensors in composite structures |
| Measurable Benefits: Light weight and non-parasitic multifunctional sensing capability in composite structures that are applicable to aeronautical and aerospace vehicles and space structures |
|
|
| GRC |
Demonstration of Polymer Cross-Linked Aerogel Blanket Insulation
(Value listed below)
| Program/Project(s) Supported: Fundamental Aeronautics |
| Technology Focus Area: Subsonic Fixed Wing |
| Measurable Benefits: Improved acoustic insulation and ballistic impact resistance supporting the Subsonic Fixed Wing (SFW) Program; Improved insulation for EVA suits, cryogenic transfer lines and storage on launch pads and in future spacecraft in support ESMD programs in Structures, Materials and Mechanisms, Crew support and accomodations. |
|
|
| DFRC |
Distributed Aerodynamic Sensing and Processing (DASP) Toolbox |
^ back to top
| Lead Center |
Proposal Title |
| MSFC |
High Temperature Materials For Lunar Lander Engine
(Value listed below)
| Program/Project(s) Supported: PCAD & LLPO, Lunar Lander propellant decision in early 2009 & Key Lander Technologies |
| Technology Focus Area: ESMD (Propulsion and Cryogenics) - A Lunar Lander Risk Reduction Activity |
| Measurable Benefits: Development and test completion will provide relevant data to NASA in support of the ESMD Constellation Program requirements. |
|
|
| JSC |
Safer Lithium-Ion Rechargeable Cells For Energy Storage
(Value listed below)
| Program/Project(s) Supported: Robotic Lunar, Short Lunar, Long Lunar |
| Technology Focus Area: Power, Crew Support and Accommodations |
| Measurable Benefits: Absence of fire and thermal runaway under abusive conditions; significant weight reduction due to less complex protective electronics in battery module |
|
|
| GRC |
Generalizing Moon Tire Technology
(Value listed below)
| Program/Project(s) Supported: Human-Robotic Systems |
| Technology Focus Area: 1) Robotics and Operations / Surface Mobility Systems, 2) Structures, Materials, and Mechanisms / Low Temperature, Mechanisms |
| Measurable Benefits: Absence of fire and thermal runaway under abusive conditions; significant weight reduction due to less complex protective electronics in battery module |
|
|
| JPL |
Low-Temperature, Long-Life, Compliant Wheels For The Lunar Surface and Beyond
(Value listed below)
| Program/Project(s) Supported: Exploration Technology Development Program |
| Technology Focus Area: Structures, Materials, and Mechanisms, Robotics and Operations |
| Measurable Benefits: 1000km+ endurance in Lunar Analog Terrain, 1000km+ endurance in Lunar Thermal Environment (-230°C-+120°C), Wheel compliance & impact resistance (10cm obstacle @ 10kph), Lower Rolling Resistance, Uniformity of Contact Pressure |
|
|
| JPL |
Advanced High-Pressure Electrolysis System Development For NASA's Explorations Systems Program
(Value listed below)
| Program/Project(s) Supported: ETDP/Energy Storage Project, TRL 5 Regenerative Fuel Cell Demonstration, TRL 6 energy storage system by 2014, in anticipation of lunar deployment |
| Technology Focus Area: Power, Regenerative Fuel Cells |
| Measurable Benefits: High Efficiency, high pressure electrolyzer suitable for regenerative fuel cell with > 500 Wh/kg energy storage and will be five times lighter than advanced batteries |
|
|
| JSC |
Cold Hardware Ignition Demonstration Of Liquid Oxygen-Liquid Methane For Reaction Control and Main Propulsion Engines
(Value listed below)
| Program/Project(s) Supported: Constellation, Lunar Lander |
| Technology Focus Area: Propulsion and Cryogenics |
| Measurable Benefits: Direct benefit to Lunar Lander Project by reducing the risk of technology acceptance through capability demonstration and hardware optimization. Direct, long-term, benefit to NASA by developing a competitive reaction control and main engine vendor as a viable contendor for future NASA and Air Force contracts. Direct benefit to the PCAD Project by providing hardware with variable inlet and combustion geometry to ensure the challenge of proving reliable ignition at all feasible operational conditions is exceeded. |
|
|
| GRC |
Lunar Regolith Excavation, Handling and Processing Technology Development and Demonstrations For Outpost Operations
(Value listed below)
| Program/Project(s) Supported: ISRU oxygen production PDR for precursos demo |
| Technology Focus Area: ISRU: regolith excavation and material handling |
| Measurable Benefits: ISRU excavation technologies demonstrated in lunar-like environments support incorporation of ISRU in mission critical roles thereby saving metric tons of consumable materials transported to the moon on an annual basis |
|
|
| JSC |
Flight Demonstration Of A Lander Using Lox/Methane
(Value listed below)
| Program/Project(s) Supported: Data is needed by SRR for lander propulsion |
| Technology Focus Area: Propulsion and Cryogenics |
| Measurable Benefits: Lox/Methane provides higher lander performance (500 to 1600 lbms) payload to surface, LOx provides capability for future In-situ propellant usage, LOx based system are ECLSS and power compatible. Lox/methane technology is applicable to commercial ETO spacecraft |
|
|
| MSFC |
Advanced Deep Throttling Turbine Bypass Valve
(Value listed below)
| Program/Project(s) Supported: SAMS-Exploration Advanced Capabilities Office, Lander Project Office, MSFC's IR&D Project LLDET |
| Technology Focus Area: Advancing Technology for the Lunar Lander Descent Engine (LLDE) |
| Measurable Benefits: Risk mitigation and technology development for one of the LLDE's critical components. Investing now to mitigate the risks associated with this valve result in schedule and budget savings during the full scale development (FSD) of the flight engine. |
|
|
| KSC |
Development Of A Deployable Sun Shield To Support Long Duration In-Space Cryogenic Propellant Storage
(Value listed below)
| Program/Project(s) Supported: Any Program/Project requiring space-based croyogenic storage. Any Program/Project requiring space-based deployable structures. |
| Technology Focus Area: Structures, Materials, Mechanisms |
| Measurable Benefits: Development of sun shield expands upper stage transportation capabilities, enables space and lunar based cryogenic storage, enables space, lunar, and Martian deployable structures. |
|
|
| GSFC |
Extremely High-Performance, Ultra-Low Power, Radiation-Tolerant Processor: An Enabling Technology For Autonomous and Computationally Intensive Capabilities
(Value listed below)
| Program/Project(s) Supported: Radiation Hardened Electronics for Space Environments (RHESE) Project; ALHAT |
| Technology Focus Area: Avionics & Software |
| Measurable Benefits: Performance and power efficiency significantly superior to state-of-the-art spaceflight processors to enable or enhance deployment of critical autonomous and computationally intensive onboard capabilities |
|
|
| JSC |
Multi-Terrain Loader Remotely Supervised Leveling For Lunar Construction Development
(Value listed below)
| Program/Project(s) Supported: Supports the Exploration Techology Development Program (ETDP), Human Robot Systems. |
| Technology Focus Area: Lunar Construction - Civil engineering, regolith excavation, and material handling. Robotics - Advanced robotic systems for lunar outpost assembly and maintenance, surface mobility systems, and human-system interaction. |
| Measurable Benefits: This project will help NASA develop ISRU and surface handling equipment control and hardware requirements and human-system interaction processes for time-delayed operations |
|
|
| KSC |
Addition Of Electrodynamic and Mechanical Forces To Dem Software
(Value listed below)
| Program/Project(s) Supported: ETDP/Protection - Dust Mitigation, ETDP/ISRU - Excavation, Traction, & Material Flow |
| Technology Focus Area: Computer modeling of soils and planetary regoliths using advanced electrodynamics and mechanics input to the DEM software |
| Measurable Benefits: Earth-based simulation is cost effective over in-situ testing |
|
|
| SSC |
Integrated Systems Health Management (ISHM) Implementation and Validation For A-1 Test Stand and J-2x Power Pack
(Value listed below)
| Program/Project(s) Supported: Supports J-2X testing on the Constellation ARES Program |
| Technology Focus Area: Avionics & Software—ISHM |
| Measurable Benefits: Safer, less costly, timely, more effective test program for the J-2X engine. |
|
|
| GRC |
Human-Rated Space Power Systems Pallet Demonstrating Fuel Cells, Lithium-Ion Batteries and Advanced Thermal Management Technologies
(Value listed below)
| Program/Project(s) Supported: Multiple lunar surface missions |
| Technology Focus Area: Energy Storage and Thermal Management |
| Measurable Benefits: Provides valuable system integration experience, provides design and basis for in-space demonstration of critical technology elements, raises TRL of component technologies that are required for lunar surface operations |
|
|
| KSC |
Lunar Analog Field Demonstration of ISRU and HRS
(Value listed below)
| Program/Project(s) Supported: ETDP/ ISRU & HRS |
| Technology Focus Area: Oxygen Production for Regolith, Robotic Mobility Systems, Resource Prospecting |
| Measurable Benefits: Provides a lunar analog test site for all NASA technology projects without burdening NASA with the infrastructure costs; Improved interface between two interdependent technology programs, and a significant step forward in the Technology Readiness |
|
|
^ back to top
| Lead Center |
Proposal Title |
| SSC |
Glass Bubble Insulation For Cryogenic Tanks: A Field Demonstration
(Value listed below)
| Program/Project(s) Supported: Constellation Pad Activation, Rocket Propulsion Test Program |
| Technology Focus Area: Space Transportation: Propellant Storage and Transfer - Reduced ground ops cost, operational effective propellant storage |
| Measurable Benefits: The thermal performance of glass bubbles has been shown to be 30% better than perlite. The ROI is 2-10 years and is highly dependent on the baseline performance of the original perlite. |
|
|
| JSC |
Lunar Habitat Wireless Testbed
(Value listed below)
| Program/Project(s) Supported: 1) IPP partnerships with universities to advance TRL of strategic technologies; 2) IPP partnerships to facilitate transition of STTR Phase I/II contracts to Phase III for maturation & insertion into NASA missions (via current GRC Phase II STTR) |
| Technology Focus Area: SOMD / ESMD / SMD (1) SOMD: Technologies that enable innovative use of operational assets (CGBA-4, CGBA-5 onboard ISS) for flight testing of development hardware and software; (2) SOMD: Reprogrammable communications systems, alignment with Space Communications and Navigation Architecture (SCAWG); 3) ESMD: Habitability systems, crew healthcare systems, environmental monitoring & control, smart telemetry systems, integrated systems health management, IVHM; 4) SMD: Intelligent distributed systems that enable advanced communications, efficient data processing & transfer, autonomous operations of space-based assets. |
| Measurable Benefits: 1) Provides for the integration of independent vendor RFID and ZigBee products in a standards-based system, promoting interoperability and reducing risk for the Lunar Habitat; 2) Deploys a flexible, extensible common application framework for information mgmt (e.g., integrate Wi-Fi and WiMax for follow-on); 3) ISS payload BioNet/CGBA-5 to interface with RFID sensors (JSC-EV DTO) provides:(a) Device interface and ISS-to-ground communications (substantial cost reduction); 2) Mature in-place platform to advance the TRL level of Habitat wireless data systems; c) Operation in a relevant operational environment - both space and ground systems 4) Provision of C3I compliant implementation for Constellation interoperability testing for future while providing communciations support for legacy devices to protect current installation base and investments. |
|
|
| GSFC |
Integrating Space Weather Model and Event Data Into Decision Support Systems To Ensure Exploration Safety and Mission Success
(Value listed below)
| Program/Project(s) Supported: Constellation Program Mission Operations Project |
| Technology Focus Area: Space Operation |
| Measurable Benefits: First step in fulfilling needs to insure Crew Safety for Constellation |
|
|
| KSC |
The Development and Rapid Assessment Of A Smart, Environmentally Friendly Coating
(Value listed below)
| Program/Project(s) Supported: CXP-GOP & ETDP FY08 |
| Technology Focus Area: Space Transportation; Corrosion Protection |
| Measurable Benefits: Paint system for corrosion control and mitigation increases lifetime, effectiveness, and performance of launch and ground support equipment, and reduces life cycle costs in ground systems by reducing corrosion failures; Rapid prediction of long-term field performance of coated substrates offers early identification of coatings for inclusion in the NASA Coatings Standard. |
|
|
| JSC |
Innovative Treatments Of Dental Emergencies For Lunar And Exploration Missions
(Value listed below)
| Program/Project(s) Supported: Human Research Program |
| Technology Focus Area: Space Operation; Technologies that optimize crew health and performance using innovative technologies for procedure management of in-flight medical issues. |
| Measurable Benefits: Provide emergency dental treatments (tooth reconstruction and treatment of pulpal disease; i.e., no drill root canals) to astronauts on long-duration missions. Provide these treatments for commercial use in the private and miltary sectors. Also applicable to populations living in isolated areas with limited dental care. |
|
|
| KSC |
Liquid To Gaseous Helium Pump Skid |
^ back to top
| Lead Center |
Proposal Title |
| ARC |
Demonstration Of Precise Wavefront Control For Space Optics With A Mems Deformable Mirror
(Value listed below)
| Program/Project(s) Supported: TPF-C, JDEM, LUVO, and Life Finder |
| Technology Focus Area: New Remote Sensing Technologies / Large, Lower Cost Lightweight Mirrors |
| Measurable Benefits: 1) Diffraction-limited performance benefits nearly all space optical systems 2) Provides extrely low wavefront error needed to detect Earth-like planets near bright stars 3) Minimizes cost and mass for space observator |
|
|
| ARC |
Ice-Ax: ISRU Characterization Experiment - Astrobiology Explorer
(Value listed below)
| Program/Project(s) Supported: Astrobiology Field Laboratory, Mars Scout mission proposal |
| Technology Focus Area: New Remote Sensing Tech |
| Measurable Benefits: Accelerated development of low mass,robotic drill with down-hole inspection. Enables search for subsurface water and potential evidence for life. Enables discovery of accessible in situ resources for future missions. Leverages prior NASA investments. ROI potential large due to lower cost payload/lander/accomodations approach than existing technology |
|
|
| GSFC |
Mission Enabling, Lightweight, Ultra Bandwidth Inverse Synthetic Aperture Radar (ISAR) For Characterization Of The Interior Of Planetary Bodies
(Value listed below)
| Program/Project(s) Supported: Discovery and New Frontiers missions, ERIN-WSS, NEO Program |
| Technology Focus Area: New Remote Sensing Technologies |
| Measurable Benefits: Will make possible new paradigm-shifting measurements for understanding the assembly and evolution of small planetary bodies such as asteroids and cometary nuclei. Also has potential applications for subsurface planetary measurements on Presentation: 9/1/08Mars, the Moon, and even for Earth. Subsurface "imaging" radar technology will meet the needs of future planetary missions by being lightweight (<5 kg), compact (size <0.1 m^3) and having a step-frequency capability operating over a frequency band between 25-100 MHz (well-suited for multiple depths of sensitivity within the shallow interiors of primitive objects) |
|
|
| JPL |
Helium Superpressure Balloon Technology Validation Experiments
(Value listed below)
| Program/Project(s) Supported: Titan Flagship Mission Study in FY08; Venus New Frontiers and Discovery proposal opportunities in FY08/FY09; Mars Missions of Opportunity or Scout |
| Technology Focus Area: Novel Platforms |
| Measurable Benefits: We are seeking to provide a first use capability for NASA planetary balloons. The particular prototype to be tested in this IPP proposal is designed to fly a 5 kg payload in the Martian North Polar region for a 5 day mission. A key measurement in the IPP flight experiment is to verify that a 5 day flight is possible after aerial deployment and inflation. |
|
|
| JPL |
Risk Reduction Testing Of The Astromesh Reflector In Support Of Earth Science Missions
(Value listed below)
| Program/Project(s) Supported: SMAP, DESDynl and XOVWM will all benefit from having this task completed |
| Technology Focus Area: New Remote Sensing Technologies & Large, Lower Cost, Lightweight Mirrors and Space-Deployable Structures |
| Measurable Benefits: Risk reduction for top three Decadel Survey Missions: Project will validate whether a deployable mesh reflector can meet the very demanding passive pointing stability that is required by the SMAP, DESDynI and XOVWM instruments |
|
|
| ARC |
Small-Sat Technologies For Cost Effective Hyperspectral Remote Sensing Of The Environment
(Value listed below)
| Program/Project(s) Supported: HyspIRI mission: GEO-CAPE |
| Technology Focus Area: Cost effective hyperspectral remote sensing technologies for small satellite applications |
| Measurable Benefits: New sensor design and proven prototype, with cost/performance comparisons; new small-sat mission cost/performance data; new PhD's from 6 leading universities with critical small-sat competencies. |
|
|
| GSFC |
Replacing Multiple Fiber Amplifiers With One For Mapping Lidars Featuring Multiple Frequency-Doubled Beams
(Value listed below)
| Program/Project(s) Supported: Swath mapping Altimeter IIP/ESTO; National Lidar Mapping Initiative; Lidar Surface Topography mission |
| Technology Focus Area: New Remote Sensing Technologies |
| Measurable Benefits: Cost reduction up to 50%, Mass reduction up to 50%, Size reduction up to 50%, Decrease power consumption 10-15% |
|
|
| GSFC |
Spacewire Plug-and-Play Capable GPS Receiver
(Value listed below)
| Program/Project(s) Supported: Global Precipitation Measurement (GPM) & Magnetospheric MultiScale (MMS) |
| Technology Focus Area: Intelligent Distributed Systems - that enable advanced communications, efficient data processing and transfer, and autonomous operations of land- and space-based assets |
| Measurable Benefits: *GPS Navigator SpaceWire PnP Receiver development that can be used by GPM & MMS; as well as other future missions; *Reduce costs of avionics through reuse of PnP system; *Provide continued collaboration for other sensors & actuators; *Valuable insight into how NASA can standardize components up to the application layer |
|
|
| LaRC |
2 Micron Risk Reduction Laser Transmitter For Airborne and Space-Based Doppler Wind Lidar
(Value listed below)
| Program/Project(s) Supported: Airborne coherent wind lidar demonstrator |
| Technology Focus Area: Lidar based active remote sensing |
| Measurable Benefits: LIfetime demostration of critical laser technology |
|
|
^ back to top
For more information related to the Seed Fund, please contact the Chief Technologist.
|
Living on the Moon: Inflatable Habitat Research
When NASA astronauts explore the moon starting in 2020, they'll stay for about a week to start out and then gradually lengthen their visits as an outpost takes shape. + Read More
Apr 27, 2008 - Cat Shoots For The Moon: Company Teams with NASA to Build Habitats, Roads on Lunar Surface
Caterpillar Inc. doesn't plan to stop at being the No. 1 construction equipment maker in the world. It's aiming for the universe, with NASA as its partner. + Read More
Feb 26, 2008 - NASA Announces Agency Quality Award Winners
RELEASE: 08-070
NASA has presented its highest honor for quality and technical performance, the George M. Low Award, to four companies committed to innovative management, process quality and customer service. + Read More
Feb 6, 2008 - Goodyear and NASA to Develop Moon Tyre
Goodyear, the innovator of innovative tyre technology on Earth, is working with NASA Glenn Research Center (GRC) to significantly evolve its technology and take its capabilities to the rest of the universe. + View Site
Jan 2008 - Lunar/Antarctic Habitat Technology Demonstration Project
In January of 2008 ILC Dover, in partnership with NASA and the NSF Office of Polar Programs, successfully erected our Lunar Habitat structure at McMurdo Station, Antarctica. + View Site
Dec 6, 2007 - NASA Selects Dryden Project for IPP Seed Fund Award
NASA's Innovative Partnerships Program recently awarded a "Seed Fund" grant to Tao Systems, of Hampton, Va., for development of a compact aerodynamic sensing system that will help validate aircraft flight performance. + View Site
Nov 8, 2007 - NASA to Showcase Inflatable Habitat Headed For Antarctica
NASA, the National Science Foundation and ILC Dover invite the news media to view an Antarctic-bound inflatable habitat at 10 a.m. EST, Wednesday, Nov. 14, at ILC's facility at One Moonwalker Rd., Frederica, DE
+ Read More
+ Read Related NSF Article
Oct 31, 2007 - IPP FY07 Seed Fund Selections
The Innovative Partnerships Program FY07 Seed Fund proposals have been selected and publicly announced on October 31, 2007. The press release and list of selected proposals can be viewed from the following links. Please click any link below.
FY07 Seed Fund Press Release
FY07 Seed Fund Selectees List by Partner
FY07 Seed Fund Selectees List by Topic
FY07 Seed Fund Selectees List by State
Center Press Releases
NASA Selects 4 Ames Projects to Advance Key Technologies
2 of NASA's 38 Selected Partnerships to Advance Technologies at Stennis Space Center
FY06 Seed Fund Information
FY06 Seed Fund Selectees List by Partner
FY06 Seed Fund Selectees List by Topic
FY06 Seed Fund Selectees List by State
Jul 28, 2007 - Haughten Crater Site Survey Field Test
From July 10 through August 3, 2007, the Intelligent Robotics Group conducted a robotic field test in Haughton Crater (Devon Island, Canada). + Read More
|
|
