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the nasa proposal area for manned space flight environment monitoring and control systems (mens) is a key part of a national smart mobility initiative supported by the obama administration. if successful, mens will improve safety of flight, lower operational costs, and enhance efficiency of the transportation system. mens will require the development and demonstration of some of the most advanced sensor technologies ever developed for space applications including damage detection from lightning strike, electrostatic charge, impact and penetration testing, integrated testing of composite materials, and ultrasonic transducers for inspection. mens will enhance the environment monitoring and control systems capabilities of the manned space flight vehicles and enable and enhance the safety of space transportation.
the payload processing subtopic goal is to identify and develop novel approaches to separation, processing, and combination of different types of data collected by the flight software. the subtopic objective is to develop systems and systems architectures that can be extended to include new types of sensor data. this includes the development of approaches that will be effective in the next generation of low-earth orbit spacecraft that will carry a wide variety of very different types of sensors and an unprecedented range of payloads.
the r&d topics goal is to identify and develop sensors for space applications. the subtopic objective is to create innovative components that can be integrated into spacecraft systems to facilitate the collection of information and to process the data. the sensors will need to be capable of making observations at intervals that are dictated by the demands of the mission design.
a partnership between nasa, the european space agency (esa), and the canadian space agency (csa), will develop the u.s. segment of the international space station (iss), designated the u. laboratory module (ulm). the ulm will be an “open” structure, providing access to each of the three basic science disciplines (biological, physical, and earth sciences) of the iss. the ulm will be based on the proven space shuttle technology and will be capable of supporting long-duration crew stays on station. it will be the primary means for transporting and handling iss experiments and crewmen between the iss and the ground.
specialties: radiation detection, localization, and monitoring. radiological monitoring, detection, and imaging of radiation from background sources in space (e.g., solar particle events, solar flares), sources in space (e., high energy particles, radiation belts, radiation fields), or sources on the moon or mars (e., radiation exposure of astronauts and mars missions). specialties include the development of innovative sensor systems that will be capable of detecting, localizing, and measuring radiation with the capability to be implemented on low cost, low power platforms with low volume and mass. medical effects of radiation in humans, biological effects of radiation on plants, and other biological effects of radiation in space and in planetary environments. the effects of radiation in the various biological domains are a significant concern in space, and the understanding of the biological effects of radiation in space is essential to the understanding of the long-term health risks for crews in future human spaceflight missions. optical and other spectroscopic instruments for mineralogical, biological, and other materials. specialties include, but are not limited to, the development of innovative spectroscopic sensors that will be capable of detecting, identifying, and characterizing materials in remote and harsh space environments. aerospace and military payloads. specialties include, but are not limited to, the development of innovative payloads that will be capable of detecting, identifying, characterizing, and discriminating between materials in remote and harsh space environments.