OARS funding Engineering

he NRA covers all aspects of basic and applied supporting research and technology in space and Earth sciences, including, but not limited to: theory, modeling, and analysis of SMD science data; aircraft, scientific balloon, sounding rocket, International Space Station, CubeSat and suborbital reusable launch vehicle investigations; development of experiment techniques suitable for future SMD space missions; development of concepts for future SMD space missions; development of advanced technologies relevant to SMD missions; development of techniques for and the laboratory analysis of both extraterrestrial samples returned by spacecraft, as well as terrestrial samples that support or otherwise help verify observations from SMD Earth system science missions; determination of atomic and composition parameters needed to analyze space data, as well as returned samples from the Earth or space; Earth surface observations and field campaigns that support SMD science missions; development of integrated Earth system models; development of systems for applying Earth science research data to societal needs; and development of applied information systems applicable to SMD objectives and data.

In today's increasingly networked, distributed, and asynchronous world, cybersecurity involves hardware, software, networks, data, people, and integration with the physical world. However, society's overwhelming reliance on this complex cyberspace has exposed its fragility and vulnerabilities: corporations, agencies, national infrastructure and individuals have been victims of cyber-attacks. Achieving a truly secure cyberspace requires addressing both challenging scientific and engineering problems involving many components of a system, and vulnerabilities that arise from human behaviors and choices. Examining the fundamentals of security and privacy as a multidisciplinary subject can lead to fundamentally new ways to design, build and operate cyber systems, protect existing infrastructure, and motivate and educate individuals about cybersecurity.

The Emerging Frontiers in Research and Innovation (EFRI) program of the NSF Directorate for Engineering (ENG) serves a critical role in helping ENG focus on important emerging areas in a timely manner. This solicitation is a funding opportunity for interdisciplinary teams of researchers to embark on rapidly advancing frontiers of fundamental engineering research. For this solicitation, we will consider proposals that aim to investigate emerging frontiers in the following two research areas: Chromatin and Epigenetic Engineering (CEE) Continuum, Compliant, and Configurable Soft Robotics Engineering(C3 SoRo) This solicitationwill becoordinated with the Directorate for Biological Sciences (BIO) andthe Directorate for Computer and Information Science and Engineering (CISE). EFRI seeks proposals with transformative ideas that represent an opportunity for a significant shift in fundamental engineering knowledge with a strong potential for long term impact on national needs or a grand challenge. The proposals must also meet the detailed requirements delineated in this solicitation.

This National Aeronautics and Space Administration NRA "Solicitation of Proposals for Possible Inclusion in a Russian Bion-M2 Mission" is an Appendix to the NASA Omnibus Research Announcement ROSBio-2016 (NNH16ZTT001N NRA). NASA's Space Life and Physical Sciences Research and Applications Division (SLPSRAD) has been invited to propose candidate experiments from U.S. investigators for possible inclusion in the Bion-M2 mission, which will occur in 2020 or 2021. The NASA Space Biology Program, therefore, requests proposals for flight investigations that fit within the Russian IBMP flight experiment designs as described in Appendix C (NNH16ZTT001N-BION) to the ROSBio-2016 Omnibus NRA. For this Appendix, NASA Space Biology will use a two-phase submission and review process. The first phase will require the submission of a preliminary proposal, hereafter referred to as a pre-proposal. Pre-proposals will be evaluated by NASA and possibly by the IBMP/RAS for their suitability for inclusion in mission planning. Investigators whose pre-proposals are found to satisfy the evaluation criteria described in Appendix C will be invited to submit complete full proposals during phase 2, which will occur at a later date, after more details about the Bion-M2 mission become available.

The U.S. Consulate General in Ho Chi Minh City invites proposals for projects that focus on at least one of the priority women's empowerment programs and target audiences specified including Professional Skills, Science Technology Engineering Mathematics (STEM) and Business, Media & Arts, Civil Society, Women in Politics and Governance, and Underprivileged and Vulnerable Groups.

"Maximize the Warfighter's Survivability, Sustainability, Mobility, Combat Effectiveness and Field Quality of Life by Treating the Warfighter as a System." Our focus is to deliver world class research, development, systems engineering, and services with a uniquehuman-centric focus by: * cultivating a highly motivated, expert, and agile workforce; * exceeding customer and stakeholder expectations; * delivering what we promise at an unprecedented pace and honoring our commitments; * fostering long term strategic partnerships and collaborations with key customers, other Government agencies, industry and academia. General information on NSRDEC can be obtained from the NSRDEC website at

Understanding the critical role of establishing that independence early in one's career, it is expected that funds will be used to support untenured faculty or research scientists (or equivalent) in their first three years in a primary academic position after the PhD, but not more than a total of five years after completion of their PhD. One may not yet have received any other grants or contracts in the Principal Investigator (PI) role from any department, agency, or institution of the federal government, including from the CAREER program or any other program, post-PhD, regardless of the size of the grant or contract, with certain exceptions noted below. Serving as co-PI, Senior Personnel, Postdoctoral Fellow, or other Fellow does not count against this eligibility rule. Grants, contracts, or gifts from private companies or foundations; state, local, or tribal governments; or universities do not count against this eligibility rule.

The technology demonstrations that result from this BAA will substantially improve the Air Force's capability to conduct missions in a variety of environments while minimizing the risks to Airmen. The overall impact of integration of autonomous systems into the mission space will enable the Air Force to operate inside of the enemy's decision loop. STAT will develop and apply autonomy technologies to enhance the full mission cycle, including mission planning, mission execution, and post-mission analysis. Particular areas of interest include multi-domain command and control, manned-unmanned teaming, and information analytics. The technology demonstrations that result from this BAA will substantially improve the Air Force's capability to conduct missions in a variety of environments while minimizing the risks to Airmen. The overall impact of integration of autonomous systems into the mission space will enable the Air Force to operate inside of the enemy's decision loop. This effort plans to demonstrate modular, transferable, open system architectures, and deliver autonomy technologies applicable to a spectrum of multi-domain applications.

The major investments made to upgrade the MAST-U and NSTX-U facilities were strongly motivated by an important observation identified in both machines, which showed that energy confinement in spherical tokamaks may scale more favorable than for conventional aspect ratio tokamaks as collisionality is reduced. If the present empirical scalings hold, then STs may provide a much more compact design path to future fusion reactors than conventional tokamaks. At present, the interplay between collisionality, turbulent transport, wall conditioning (e.g., lithium coatings, boronization) and/or density control at low aspect ratio represents the forefront of ST research. The complementary capabilities of the MAST-U and LTX-β facilities allow for this interplay to be explored. Late in the three year period of these proposals FY 2018 - FY2020 the MAST-U facility is slated to utilize strong cryopumping capabilities in its world class advanced divertor to control plasma density and hence collisionality. Alternatively, the neutral beam heated and fueled LTX-β will control density using lithium wall coatings, which dramatically reduces the flux of cold neutral atoms that are recycled back into the plasma after their initial expulsion. In addition to plasma performance, the compact geometry of MAST-U and its future enhanced auxiliary heating power will result in exhaust power reaching plasma facing components that is in excess of that expected in ITER. This coupled with MAST-U's unprecedentedly flexible divertor geometry, makes it a world leading facility for the study of power exhaust and plasma material interactions.

CISE’s Division of Information and Intelligent Systems (IIS) supports research and education projects that develop new knowledge in three core programs: The Cyber-Human Systems(CHS) program; The Information Integration and Informatics (III)program; and The Robust Intelligence (RI) program. Proposals in the area of computer graphics and visualization may be submitted to anyof the three core programs described above. Proposers are invited to submit proposals in three project classes, which are defined as follows: Small Projects - up to $500,000 total budget with durations up to three years; Medium Projects - $500,001 to $1,200,000 total budget with durations up to four years; and Large Projects - $1,200,001 to $3,000,000 total budget with durations up to five years. A more complete description of the three project classes can be found in Section II. Program Description of this document.

In a world in which computers and networks are increasingly ubiquitous, computing, information, and computation play a central role in how humans work, learn, live, discover, and communicate. Technology is increasingly embedded throughout society, and is becoming commonplace in almost everything we do. The boundaries between humans and technology are shrinking to the point where socio-technical systems are becoming natural extensions to our human experience - second nature, helping us, caring for us, and enhancing us. As a result, computing technologies and human lives, organizations, and societies are co-evolving, transforming each other in the process. Cyber-Human Systems (CHS) research explores potentially transformative and disruptive ideas, novel theories, and technological innovations in computer and information science that accelerate both the creation and understanding of the complex and increasingly coupled relationships between humans and technology with the broad goal of advancing human capabilities: perceptual and cognitive, physical and virtual, social and societal.

The Algorithmic Foundations (AF) program supports potentially transformative research and education projects advancing design and analysis of algorithms and characterized by algorithmic thinking accompanied by rigorous analysis. Research on algorithms for problems that are central to computer science and engineering, as well as new techniques for the rigorous analysis of algorithms, are of interest. AF supports theoretical research that bounds the intrinsic difficulty of problems to determine the measures of complexity in formal models of computation, classical or new. The goal is to understand the fundamental limits of resource-bounded computation and to obtain efficient algorithms operating within those limits. The time and space complexity of finding exact and approximate solutions in deterministic and randomized models of computation is a central concern of the program; research on resources other than time and space, such as communication and energy, is also encouraged. In addition to the traditional, sequential computing paradigm, AF supports research on the design and analysis of novel algorithms in parallel and distributed models, in particular, in heterogeneous multi-core and many-core machines; the computational models and algorithms that capture essential aspects of computing over massive data sets; and alternative forms of computation and information processing, including quantum computing and biological models of computation.

Computer systems support a broad range of applications and technologies that seamlessly integrate with human users. While many key building blocks of computer systems are today commercial technologies, the challenge ahead is to envision new technologies, as well as to combine existing technologies, software, and sensing systems into the computer systems of the future that will span wearable computing, the Internet of Things (IoT), "Smart Cities," intelligent transportation systems, personalized healthcare, and beyond. Such computer systems will require new, innovative, and visionary approaches to hardware, wired and wireless communications, consideration of human-computer interactions, and new programming languages and compilers that are limited only by the imagination. They will need to be reliable in the presence of unreliable components, adaptive to changing environments, capable of supporting high-throughput applications and large-scale data storage and processing, and able to meet performance and energy objectives for applications ranging from very low-power embedded systems to large high-performance computing systems. Furthermore, computer systems of the future will need to provide mechanisms for ensuring security and privacy.

The MTEC mission is to assist the U.S. Army Medical Research and Materiel Command (USAMRMC) by providing cutting-edge technologies and effective materiel life cycle management to transition medical solutions to industry that protect, treat, and optimize Warfighters' health and performance across the full spectrum of military operations. MTEC is a biomedical technology consortium collaborating with multiple government agencies under a 10-year renewable Other Transaction Agreement (OTA), Agreement No. W81XWH-15-9-0001, with the U.S. Army Medical Research Acquisition Activity (USAMRAA). MTEC currently is recruiting a broad and diverse membership that includes representatives from large businesses, small businesses, "non-traditional" government contractors, academic research institutions and not-for-profit organizations.

The major investments made to upgrade the MAST-U and NSTX-U facilities were strongly motivated by an important observation identified in both machines, which showed that energy confinement in spherical tokamaks may scale more favorable than for conventional aspect ratio tokamaks as collisionality is reduced. If the present empirical scalings hold, then STs may provide a much more compact design path to future fusion reactors than conventional tokamaks. At present, the interplay between collisionality, turbulent transport, wall conditioning (e.g., lithium coatings, boronization) and/or density control at low aspect ratio represents the forefront of ST research. The complementary capabilities of the MAST-U and LTX-β facilities allow for this interplay to be explored. Late in the three year period of these proposals FY 2018 - FY2020 the MAST-U facility is slated to utilize strong cryopumping capabilities in its world class advanced divertor to control plasma density and hence collisionality. Alternatively, the neutral beam heated and fueled LTX-β will control density using lithium wall coatings, which dramatically reduces the flux of cold neutral atoms that are recycled back into the plasma after their initial expulsion. In addition to plasma performance, the compact geometry of MAST-U and its future enhanced auxiliary heating power will result in exhaust power reaching plasma facing components that is in excess of that expected in ITER. This coupled with MAST-U's unprecedentedly flexible divertor geometry, makes it a world leading facility for the study of power exhaust and plasma material interactions.

NineSigma, representing a global industrial manufacturer, invites proposals for engineering services for design and prototype of rugged power supplies for industrial applications.

Organizations interested in becoming an Allied Organization should submit a proposal describing the specific area of interest and the technology(s) they seek to advance. Wherein this NOTICE is a request for Allied Organizations for future Challenges, submitting a Challenge Concept and Team Capability are optional. If interested organizations would like to propose a Challenge, they will need to include the Challenge Concept that they wish to pursue with NASA.

Amendment 000002 to DE-FOA-0001730 - This Amendment is to embed a revised, fillable Budget Justification Form (as per Section IV. Applications and Submission Information, part C. Content and Application) in order to supersede an unnavigable/corrupt Form previously utilized. Amendment 000001: The purpose of the previous Amendment was to increase the total Estimated Funding of this Funding Opportunity and increase the Anticipated Award Size Range for Topic Area 6 from $350,000 to $600,000. The Period of Performance for Topic Area 6 is also revised from 24-36 months to 36 months. Appropriate changes have been made within this FOA under Section II - Award Information. The objective of this FOA is to solicit and competitively award university-based R&D projects that address and resolve scientific challenges and applied engineering technology issues associated with advancing the performance and efficiency of combustion turbines in combined cycle applications (e.g., IGCC/NGCC) in fossil fuel power generation. The FOA will seek to solicit and competitively award laboratory/bench-scale R&D in the following six technical topic areas: 1) Low-NOx Combustion Technology Development for 'Air-Breathing' Advanced Turbines 2) Advanced Cooling Technology Development for 'Air-Breathing' Advanced Turbines 3) Advanced Materials Technology Development for 'Air-Breathing' Advanced Turbines 4) Big Data Analytics 5) Advanced Instrumentation 6) Pressure Gain Combustion

The DOE Traineeship in Accelerator Science and Engineering provides support to address critical, targeted workforce development in fields of study that are currently supported by U.S. Department of Energy (DOE) research awards. Up to two Cooperative Agreements may provide funding to universities or consortia of universities for up to two years of tuition, stipend, and travel support to students enrolled in specific accelerator science and engineering degree programs, and to provide a modest topic-specific curriculum development and program administration support. Award term is expected to be up to five years, with the possibility of renewal for a second term. This program does not support lines of Research and Development (R&D). Support for accelerator R&D is provided through the High Energy Physics (HEP) General Accelerator R&D and Accelerator Stewardship programs, through accelerator R&D programs elsewhere in DOE, and by other federal agencies.