THE NETWORKING AND INFORMATION TECHNOLOGY RESEARCH AND DEVELOPMENT (NITRD) PROGRAM 2012 STRATEGIC PLANThis five-year strategic plan for the Federal Networking and Information TechnologyResearch and Development (NITRD) Program considers IT R&D in its broader societal context.It calls upon the Federal Government and private sector to work together to develop new, morepowerful kinds of partnerships between humans and digital devices; learn how to engineersystems and devices that earn society’s trust and confidence; and innovate in education for“cyber-capable” citizens and workers.About this Document -- This report was developed by the Subcommittee on Networking and Information Technology Research and Development (NITRD) of the NSTC’s Committee on Technology. The report is published by the National Coordination Office (NCO) for the NITRD Program.Copyright Information -- This document is a work of the United States Government and is in the public domain (see 17 U.S.C. §105). Subject to the stipulations below, it may be distributed and copied with acknowledgment toNCO. Copyrights to graphics included in this document are reserved by the original copyright holdersor their assignees and are used here under the government’s license and by permission. Requests touse any images must be made to the provider identified in the image credits or to NCO if no provideris identified.U.S. Networking and Information Technology Research and Development ProgramNITRD_b3dd12be-e784-11df-a5d3-6a0c7a64ea2aExecutive Office of the PresidentNational Science and Technology CouncilAbout the National Science and Technology Council -- The National Science and Technology Council (NSTC) is the principal means by which the Executive Branch coordinates science and technology policy across the diverse entities that make up the Federal research and development enterprise. A primary objective of the NSTC is establishing clear national goals for Federal science and technology investments. The NSTC prepares research and development strategies that are coordinated across Federal agencies to form investment packages aimed at accomplishing multiple national goals. The work of the NSTC is organized under five committees: Environment, Natural Resources and Sustainability; Homeland and National Security; Science, Technology, Engineering, and Math (STEM) Education; Science; and Technology. Each of these committees oversees subcommittees and working groups focused on different aspects of science and technology. More information is available at http://www.whitehouse.gov/ostp/nstc.John P. HoldrenNational Science and Technology Council Chair; Assistant to the President for Science and Technology; Director, Office of Science and Technology PolicyPedro I. EspinaStaff: Executive Director of the National Science and Technology Council & Executive Secretary of the Committee on TechnologyCommittee on TechnologyThomas C. PowerCommittee on Technology Chair; Deputy Chief Technology Officer of the United States for Telecommunications, Office of Science & Technology PolicyOffice of Science and Technology PolicyAbout the Office of Science and Technology Policy -- The Office of Science and Technology Policy (OSTP) was established by the National Science and Technology Policy, Organization, and Priorities Act of 1976. OSTP’s responsibilities include advising the President in policy formulation and budget development on questions in which science and technology are important elements; articulating the President’s science and technology policy and programs; and fostering strong partnerships among Federal, state, and local governments, and the scientific communities in industry and academia. The Director of OSTP also serves as Assistant to the President for Science and Technology and manages the NSTC. More information is available at http://www.whitehouse.gov/ostp.Subcommittee on Networking and Information Technology Research and DevelopmentAbout the Subcommittee on Networking and Information Technology Research and Development -- The Subcommittee coordinates the multi-agency Networking and Information Technology Research and Development (NITRD) Program to help: * Assure continued U.S. leadership in networking and information technology * Satisfy the needs of the Federal government for advanced networking and information technology * Accelerate development and deployment of advanced networking and information technology This focus enables the United States to maintain world leadership in science and engineering, enhance national defense and national U.S. productivity and competitiveness and promote longterm economic growth, improve the health of the U.S. citizenry, protect the environment, improve education, training, and lifelong learning, and improve the quality of life. It also implements relevant provisions of the High Performance Computing Act of 1991 (P.L. 102-194), as amended by the Next Generation Internet Research Act of 1998 (P. L. 105-305), and the America Creating Opportunities to Meaningfully Promote Excellence in Technology, Education and Science (COMPETES) Act of 2007 (P.L. 110-69). For more information, visit http://www.nitrd.gov/.George O. StrawnSubcommittee on Networking and Information Technology Research and Development Co-chair -- Director, National Coordination Office for Networking and Information Technology Research and DevelopmentFarnam JahanianSubcommittee on Networking and Information Technology Research and Development Co-chair -- Assistant Director, Computer and Information Science and Engineering Directorate, National Science FoundationBryan A. BiegelSubcommittee on Networking and Information Technology Research and Development Member -- Acting Deputy Division Chief, AdvancedSupercomputing Division. National Aeronautics and Space AdministrationAlan BlateckySubcommittee on Networking and Information Technology Research and Development Member -- Director, Office of Cyberinfrastructure.National Science FoundationRobert ChadduckSubcommittee on Networking and Information Technology Research and Development Member -- Principal Technologist for Applied Research,National Archives and Records AdministrationPedro I. EspinaSubcommittee on Networking and Information Technology Research and Development Member -- Program Analyst. Office of Science & Technology PolicyJ. Michael FitzmauriceSubcommittee on Networking and Information Technology Research and Development Member -- Senior Science Advisor for Information Technology,Agency for Healthcare Research and QualityMarilyn FreemanSubcommittee on Networking and Information Technology Research and Development Member -- Deputy Assistant Secretary for Research &Technology, ArmyDouglas B. FridsmaSubcommittee on Networking and Information Technology Research and Development Member -- Director, Office of Standards and Interoperability,Department of Health and Human Services, Office of the National Coordinator for Health Information TechnologyDeborah A. FrinckeSubcommittee on Networking and Information Technology Research and Development Member -- Deputy Director of Research, National Security AgencyArti GargSubcommittee on Networking and Information Technology Research and Development Member -- Program Examiner, Office of Management and BudgetRobert GoldSubcommittee on Networking and Information Technology Research and Development Member -- Director, Information Systems and Cyber Security,Office of the Secretary of DefenseDaniel A. HitchcockSubcommittee on Networking and Information Technology Research and Development Member -- Associate Director, Office of Advanced ScientificComputing Research, Department of Energy, Office of ScienceCharles J. HollandSubcommittee on Networking and Information Technology Research and Development Member -- Special Programs, Microsystems TechnologyOffice, Defense Advanced Research Projects AgencyDouglas MaughanSubcommittee on Networking and Information Technology Research and Development Member -- Division Director, Cyber Security R&D,Science and Technology Directorate,Department of Homeland SecurityRobert MeisnerSubcommittee on Networking and Information Technology Research and Development Member -- Director, Office of Advanced Simulation andComputing, Department of Energy, National Nuclear SecurityAdministrationDavid MichaudSubcommittee on Networking and Information Technology Research and Development Member -- Director, High Performance Computing &Communications Office, National Oceanic and AtmosphericAdministrationKam NgSubcommittee on Networking and Information Technology Research and Development Member -- Deputy Director of Research, Office of NavalResearch, NavyCharles H. RomineSubcommittee on Networking and Information Technology Research and Development Member -- Director, Information Technology Laboratory,National Institute of Standards and TechnologyVacantSubcommittee on Networking and Information Technology Research and Development Member -- Director, Center for Bioinformatics andComputational Biology, National Institutes of HealthGary L. WalterSubcommittee on Networking and Information Technology Research and Development Member -- Computer Scientist, Atmospheric Modeling andAnalysis Division, Environmental Protection AgencyLt. Col. Dan WardSubcommittee on Networking and Information Technology Research and Development Member -- Chief of Acquisition Innovation, Air ForceVirginia MooreSubcommittee on Networking and Information Technology Research and Development Staff -- Executive SecretaryU.S. Federal GovernmentThe Federal Role -- In 1991, the legislative mandate for coordination of Federal IT R&D focused on networking and highendcomputing (then the two technologies deemed vital for Federal missions).29 Today, advancedinformation technologies of many different kinds play essential and critical roles in every high-prioritygovernment mission addressing the Nation’s goals and needs, and all Federal agencies rely on ITcapabilities and benefit from IT research advances.NITRD AgenciesCollaboration in Support of Mission Requirements -- The framework for multiagency coordination of Federal IT research, continuously evolving toencompass the widening range of technologies and application domains, has proven to be highlyeffective. Collaboration among the Federal research agencies in the NITRD Program has becomean intellectual and scientific imperative imposed by the diversity, complexity, interdependencies,and dynamism of contemporary IT environments. No single agency or disciplinary skill set can spanmore than a fraction of the IT knowledge base and investigative frontiers. Through coordination,agencies identify common mission requirements, assure focused research efforts in time-criticalR&D components, and share information on addressing IT’s higher-risk, higher-payoff challenges. Byleveraging each other’s common interests, work products, and technical expertise, NITRD agenciesderive increased value and cost-effectiveness from Federal research investments and assure R&Dcoverage across the entire spectrum of technologies and domains.Such combined efforts produce broadly applicable results that no one agency could attain on its ownand that propel innovation. For example, the field of telemedicine -- including two-way telepresence,remote diagnostic and haptic devices, and robotic surgical systems -- emerged out of pioneeringcollaborative investigations and proofs-of-concept primarily funded by NIH/National Library of Medicine (NLM), NSF, DoD, NASA, and the Department of Veterans Affairs (VA).NIHNational Library of Medicine (NLM)NSF DoD NASA Department of Veterans Affairs (VA)Federal LaboratoriesInfrastructure for Leadership -- The multidisciplinary reach of Federal NITRD funding is extended through R&D activities inFederal laboratories, universities, research institutions, and partnerships with industry. Thesediversified efforts engage thousands of researchers and their students in the intellectual challengesof networking and IT and provide the principal source of education and training for the newgenerations of IT researchers, inventors, entrepreneurs, and technical professionals the Nation needs.In addition, the Program’s emphasis on coordination and collaboration across agencies and private sector institutions helps promote the transfer of research results and prototypes to Federal nonresearchagencies and out to the marketplace.For example, the NITRD advanced-networking agencies have collaborated with private-sectorpartner Internet 2 in developing an infrastructure called perfSONAR that makes it possible, for thefirst time, to automatically measure the performance of optical networks across multiple domains.Optical networking technology is at the leading edge of next-generation networking speeds andcapacity. Accurate performance information is needed by network operators, managers, and securityenforcers to support isolating and correcting network bottlenecks and anomalies; to supportthe configuration of network links in dynamic environments; and to detect, isolate, and correctsecurity breaches and problems. Information on network segments in each domain is needed,requiring cooperation among the agencies and science networks maintaining these domains andnetwork links. As a result of NITRD efforts, the perfSONAR infrastructure is being adopted by sciencenetworks, commercial network managers, and international science networks through cooperativedevelopment and deployment.NITRD coordination of advanced technological capabilities to support Federal missions alsohelps define national research needs in critical technologies, such as high-end systems, advancednetworking, cyber-physical systems, and cyber security and information assurance. In addition,the NITRD research portfolio promotes the types of multidisciplinary thinking and approachesthat are necessary to develop highly complex systems of systems with a myriad of heterogeneouscomponents.UniversitiesResearch Institutions IndustryResearchers StudentsIT ResearchersInventorsEntrepreneurs Technical ProfessionalsPrivate Sector InstitutionsInternet 2Research PartnersPartnership Synergies Are Essential -- Since the dawn of the digital age, U.S. technological and economic innovation has been fueled bycontinuing cycles of basic exploration, experimentation, prototype implementation, feedback, anddeployment of novel products. This “ecosystem” for innovation encompasses Federal researchers,private-sector researchers and developers, students and educational institutions, entrepreneurs,industries, and end users.Today, such interactions are more necessary than ever, and many forms of engagement are neededat global scales. Strengthening security in cyberspace, for example, will require internationalcollaboration among governments, service providers, researchers, standards organizations, lawenforcement, and other stakeholders on security architectures and protocols, crime investigation,and identity management, among other issues. In a related area—the robustness and end-to-endperformance of the U.S. cyber infrastructure -- partnerships between government and industry inrealistic-scale testbeds, technology standards, and prototype deployments of new infrastructuremodels such as clouds are essential to speed research advances in networking and network securityto the marketplace. Innovative partnerships with the open-source software development communityalso should be pursued, including policy frameworks that recognize intellectual property. Theexploration initiated by NITRD agencies in recent years of open-source approaches to address thechallenges of complex and ultra-scale software should be continued and expanded.Foundational long-term R&D is required to maintain a full pipeline of scientific findings and conceptsfor the future. This role is played by Federal research investments in advanced sciences, technology,and engineering, which complement industry’s focus on bringing new products rapidly to market. TheNITRD Program’s vision for the future aligns with the strategic plans of its member agencies to pursuesuch fundamental technological advances as essential means of addressing the some of Nation’s mostcritical needs. The NITRD Strategic Plan recognizes, however, that the scale and complexity of 21stcentury national challenges demand ongoing outreach and partnership development by the NITRDenterprise to generate synergies in the Nation’s broader IT ecosystem that can accelerate beneficialadvances for society and the world.The NITRD agencies look forward to working with the research community, the private sector, and ITstakeholders everywhere to realize the future of promise described in this strategic plan.High-speed networks, systems, software, devices, data, and applications are fully secure, safe, reliable,multimodal, and easy to use. This ultra-high-bandwidth infrastructure -- including both flexible,mobile wireless and hard-wired connectivity -- is always available, ubiquitous, and can be activatedwhen needed; it is affordably accessible to anyone, anywhere, anytime. Information shared over theinfrastructure is completely secure; user privacy and confidentiality can be assured on demand; andpervasive repositories provide for archiving and retrieving data in perpetuity. In the all-encompassingdimension called cyberspace, people -- unfettered from constraints of time, circumstance, and location -- partner with computing devices and their capabilities to learn, imagine, discover, play, create, invent,interact, and collaborate in real time in ways that enhance life and generate solutions for the world’s mostcomplex problems._b3dd19e4-e784-11df-a5d3-6a0c7a64ea2aTo make possible the visionary advances in science and technology that will keep the U.S. at the forefront of economic prosperity, innovation, and scientific leadership_b3dd1b92-e784-11df-a5d3-6a0c7a64ea2aNational PrioritiesAdvancing Our National Priorities --Rapid change is often cited as the only constant in networking and IT. After all, in only a few decades,IT systems have evolved from relatively rudimentary “dinotech” to futuristic electronic marvels thatenable people the world over to communicate, access information, and compete using a device thatfits in the palm.In fact, there has been another constant throughout the IT revolution: U.S. leadership in the inventionof digital technologies. As a result of that leadership, IT has significantly enhanced the Nation’seconomy, quality of life, and national security. Ongoing Federal R&D to provide the world’s mostadvanced IT capabilities for U.S. government missions has fueled the creation of new ideas, andinnovations that have enabled the United States to address key national priorities. For example:ProsperityEconomic prosperity -- new multibillion-dollar IT industries have arisen from R&Dbreakthroughs; communications technologies and standards make possible vibrante-commerce, more efficient business-to-business interactions, and improved industrialprocess control systemsQuality of LifeQuality of life -- advances in communications standards, electronics, and the Internet havespurred an explosion of novel social networking and web applications with millions ofparticipants, enabling people to collaborate effectively over great distancesNational SecurityNational security and defense -- digital capabilities have transformed strategiccommunications and reduced battlefield risk for military personnelNational DefenseHealth Health and health care -- IT makes possible skilled on-site medical care, in the home and atremote locationsHealth CareEnergyEnergy and environment -- sensors and high-fidelity modeling and simulation enable betterenergy efficiency and weather and climate-change prediction, and speed development ofrenewable energy sourcesEnvironmentEducation Education and training -- learners of all ages now have on-demand access to vast educationand knowledge resourcesTrainingOpennessOpen and transparent government -- rapidly growing electronic access systems areopening government information and participation to the public and increasing efficiency ingovernment servicesTransparencyWeComputeExpanded human-computer partnerships, more powerful digital tools for people, and new forms of collaboration between the two._b3dd1d0e-e784-11df-a5d3-6a0c7a64ea2a1WeCompute -- new understandings and technologies that expand and exploit the intellectualand creative potential of synergy between humans -- from individuals to large-scale groups -- andcomputing systems and data. Deepening this dynamic partnership will enable new levels ofintelligence, intuition, and awareness emerging as greater than the sum of the parts in the union ofcyber, human, and social capabilities. The artifacts we engineer and manufacture will increasinglymeld digital, physical, and cognitive attributes in unprecedented ways that enhance the quality of lifeand extend the frontiers of discovery, innovation, and achievement.AccessibilityMaking the Digital World Accessible to Everyone_b3dd1e76-e784-11df-a5d3-6a0c7a64ea2a1.1Making the Digital World Accessible to Everyone (A7) -- In the NITRD vision, the IT infrastructure of the future will be everywhere and always available,making possible Anywhere, Anytime, Affordable Access to Anything by Anyone Authorized (A7). ITcapabilities that enable universal participation will radically democratize the IT domain, so that allcan contribute to and share in the resources and benefits of cyberspace. At the same time, groups ofindividuals with similar interests (e.g., a research collaboration) can form and dissolve dynamically topursue their mutual interests privately and securely as needed.Where we are now -- the global Internet points toward the future with its rapid expansion toencompass the burgeoning technologies of wireless networking. But today’s Internet is not nearlyrobust or advanced enough to satisfy the demands of a future in which devices, data, and people atevery scale are interconnected and in constant communication, not just worldwide but across outerspace. For example, most people on Earth still lack access to the Internet; even in the United Statesone-third of the population currently lacks broadband Internet connectivity at home (lagging 14other advanced nations), and a majority cites cost and lack of computer skills as key factors.9 Indeed,access to the information riches and services of cyberspace today remains limited mainly to peoplewho know how to work keyboard-activated devices and have the high-speed network connectivityrequired to experience bandwidth-intensive Internet applications, such as streaming video andreal-time interactivity. (The Administration has announced a National Broadband Plan; its dual aimis to provide jobs by incentivizing companies to both extend broadband connectivity to rural andunderserved communities and increase U.S. broadband network speeds, which also lag those ofmany other countries.)Research needs -- in addition to fundamental networking research (see “Evolving and Scaling Socio-Technical Network Infrastructure” below), enabling a more powerful, more scalable IT infrastructurefor the future will require advances across the spectrum of information technologies. For example,power consumption must be reduced to enable ubiquitous computation.* Language barriers willneed to be eliminated through instantaneous language translation. Interoperability issues in data,systems, and software will have to be resolved through agreement on common standards, protocols, and policy regimes; systems must be designed that can adjust to changing environments and theneeds of individual users; and substantial improvements in end-to-end performance will be requiredto provide users with seamless access to resources from their own desktop, laptop, or mobile device.R&D in new materials must be pursued to produce gains in energy efficiency and miniaturizationthat can continue driving down per-unit costs of IT devices and services, so the IT infrastructure canreadily expand to include new participants and uses. R&D to enable specification and enforcement ofdynamic security and privacy policies tailored to individuals as well as to organizations will also be akey underpinning of the A7 environment.Wireless broadband access will play a central role. Radio spectrum resources are finite and are alreadyunder tremendous demands from a large number of applications, including military, commercial,broadcast, and mobile services. Technological and regulatory solutions to enhancing spectrumefficiency and access can have a tremendous impact on the wireless economy and are ripe for R&Dactivities. In response to the Presidential Memorandum on Unleashing the Wireless BroadbandRevolution, a wireless spectrum R&D group has been established under NITRD to coordinatespectrum efficiency research across the Government.11Power ConsumptionReduce power consumption to enable ubiquitous computation._b3dd206a-e784-11df-a5d3-6a0c7a64ea2a1.1.1Language BarriersEliminate language barriers through instantaneous language translation._b3dd25e2-e784-11df-a5d3-6a0c7a64ea2a1.1.2InteroperabilityResolve interoperability issues in data, systems, and software through agreement on common standards, protocols, and policy regimes_b3dd283a-e784-11df-a5d3-6a0c7a64ea2a1.1.3Adjustable SystemsDesign systems that can adjust to changing environments and the needs of individual users_b3dd29fc-e784-11df-a5d3-6a0c7a64ea2a1.1.4PerformanceSubstantially improve end-to-end performance to provide users with seamless access to resources from their own desktop, laptop, or mobile device_b3dd2d3a-e784-11df-a5d3-6a0c7a64ea2a1.1.5New MaterialsConduct R&D in new materials to produce gains in energy efficiency and miniaturization that can continue driving down per-unit costs of IT devices and services, so the IT infrastructure can readily expand to include new participants and uses._b3dd2f7e-e784-11df-a5d3-6a0c7a64ea2a1.1.6Security and PrivacyConduct R&D to enable specification and enforcement of dynamic security and privacy policies tailored to individuals as well as to organizations._b3dd3154-e784-11df-a5d3-6a0c7a64ea2a1.1.7AccelerationAccelerating the Future of Computing_b3dd34a6-e784-11df-a5d3-6a0c7a64ea2a1.2Accelerating the Future of Computing -- Historically, the United States has pioneered advances in high-performance computing (calledhigh-end computing [HEC] in the NITRD Program). The HEC technical area encompasses all of thechallenges of leading this advancement, including not just better (e.g., massively scaled-up, moreefficient and resilient) system hardware and software, but also more efficient provisioning models(e.g., surge and cloud computing), improved mathematical and computer science underpinningsfor analysis, modeling, and visualization of multi-scale and ultra-scale data, and new programmingenvironments and tools for easier development and usability of advanced scientific applications.Where we are now -- the most powerful Federal leadership systems have achieved petascale speeds(1,000 trillion floating-point calculations [flops] per second) and are expected to reach the exascale (aquintillion flops, or 1018). At the same time, however, our current means of reaching these everhighercomputational speeds -- packing multiple processors into every computer chip -- is creatinga crisis in our ability to program system and application software to efficiently exploit the emergingmulti-core and heterogeneous computing architectures. Moreover, as the number of cores andcomponents rises, the likelihood diminishes of correctly completing data-intensive computationsof increasing scale and complexity. In addition, the cost to power large HPC facilities is growingunsustainably rapidly.Research needs -- the massive parallelism necessary to enable software to fully exploit the speedsand computational capabilities of supercomputing systems with heterogeneous components andup to millions of microprocessors presents enormous challenges for both system and applicationdesigners. Developing robust code that can be partitioned into many parallel subroutines for efficientmulti-core processing and then reintegrating the results as final output, require breakthroughadvances in the underlying mathematics, design, and engineering of HEC software. The goal ofmaking HEC environments easier to use and more productive, reducing time to solution, remainselusive; even at today’s levels of system complexity, down time due to software issues is rising as a proportion of total operational costs. One promising R&D avenue is resilience -- concepts andtechnologies enabling a HEC system to continue to function amid software faults, anomalies, anderrors, and to alert operators about problems without necessitating a shutdown.Also critical to the long-term future of supercomputing is research in technological approachesto reduce the steadily rising energy demands of large-scale HEC systems and facilities, whichtypically consume many megawatts per year for operations and cooling. Because advances tochange this unsustainable energy-use trajectory may arise from multiple research fields, the searchfor scientific breakthroughs must be pursued across the board: in power management and heatdissipation technologies; new materials such as nanoscale composites; novel power-saving platformand system architectures; computational technologies and methods such as spin-based logicand cloud computing; and next-generation computing concepts such as quantum informationscience. Advances in nano, biological, and quantum sciences also may lead the way to radicallydifferent system architectures and computational methods, providing the basis for next-generationcomputing at all scales.Parallel ProcessingDevelop robust code that can be partitioned into many parallel subroutines for efficient multicore/many-core processing and reintegration of the results._b3dd36ea-e784-11df-a5d3-6a0c7a64ea2a1.2.1ProductivityMake HEC environments easier to use and more productive, reducing time to solution as well as down time due to software issues as a proportion of total operational costs._b3dd3906-e784-11df-a5d3-6a0c7a64ea2a1.2.2One promising R&D avenue is resilience – concepts and technologies enabling a HEC system to continue to function amid software faults, anomalies, and errors, and to alert operators about problems without necessitating a shutdown.HEC Energy DemandsReduce the steadily rising energy demands of large-scale HEC systems and facilities, which typically consume many megawatts per year for operations and cooling._b3dd3c94-e784-11df-a5d3-6a0c7a64ea2a1.2.3Because advances to change this unsustainable energy-use trajectory may arise from multiple research fields, the search for scientific breakthroughs must be pursued across the board, in power management and heat dissipation technologies, new materials such as nanoscale composites, novel power-saving platform and system architectures, computing technologies (e.g., nonvolatile computing), and computational methods (e.g., spintronics, analog computing), as well as in next-generation computing concepts such as quantum information science. Advances in nano, biological, and quantum sciences also may lead the way to radically different system architectures and computational methods, providing the basis for next-generation leadership in computing at all scales.Network InfrastructureEvolving and Scaling Socio-Technical Network Infrastructure_b3dd3f0a-e784-11df-a5d3-6a0c7a64ea2a1.3Evolving and Scaling Socio-Technical Network Infrastructure -- Network connectivity, beginning at the computing platform or device and radiating outward throughlocal-area networks connecting to wide-area networks connecting to the Internet’s network ofnetworks, creates the wired and wireless communications fabric that makes a digital world possible.Over the last four decades, Federal investments in basic network research have led the way to theInternet, the World Wide Web, wireless mobile and optical networking, and an array of network-basedapplications that are reshaping societies and economies around the globe.Where we are now -- advanced computer networks provide the infrastructure for transporting,developing, archiving, accessing, and using the huge volumes of data that support critical functionsin every sector, such as storage and nearly instantaneous interchange of data in the financial markets.Scientific experiments such as the Large Hadron Collider (LHC) at CERN distribute petabytes of datato thousands of scientists around the world who are seeking to uncover the fundamental nature ofmatter and the “dark energy” that dominates the universe. Dynamic, heterogeneous, secure, andreliable networks are also critical to the Department of Defense’s (DoD’s) ability to defeat adversaries,to Department of Homeland Securities’ (DHS’s) ability to respond to natural disasters and terrorism,and to Federal efforts to improve health care for all.Like the LHC, a growing number of scientific applications require very large bandwidths to supportmassive data transfers and the need for near-real-time coordination and data transmission protocolstailored to the data requirements. Other such applications include Earth system modeling supportedby the Earth Systems Grid (ESG); computational genomics; and Very Long Baseline Interferometry(VLBI), a radio astronomy application enabling simultaneous observations of an object by manytelescopes combined, emulating a telescope with a size equal to the maximum separation betweenthe telescopes.Current high-performance networking (including science networks) does not generally supportthese demanding requirements; the current approach is to provide dedicated point-to-point network links and services among the key researchers (or to have researchers move to sites where adequatenetworking is available). Today, such services lie mostly outside the science networking providedto the larger research community and are implemented outside the university science networkinginfrastructure.Research needs -- the network infrastructure of the 21st century must be robust enough to meet verydiverse demands, including network services supporting A7; exponential increases in data volumesand changes in how people access data (e.g., data in the network); ultra-reliable, secure networking(e.g., for national security and the commercial and banking sectors); new networking technologies thatscale (e.g., all-optical networking) to provide the end-to-end bandwidth, performance, and servicesrequired for data-intensive science; and heterogeneous networking (e.g., wireless, optical networking,satellite communications, and others). The following are core areas of networking R&D in whichadvances are needed:* Foundations -- architectural principles, frameworks, and network models to deal withcomplexity; heterogeneity; multi-domain federation, management, and transparency; endto-end performance; and differentiated services* Design -- secure, near-real-time, flexible, adaptive services with built-in intelligence tofacilitate discovery, federation, and management of resources across domains and to increasethe application robustness and resistance to attack even in extraordinarily complex systemsand new ways of interconnecting networks to provide those services* Management -- management methods and tools that incorporate intelligence in thenetwork to enable effective deployment, control, and utilization of complex networks andresources in dynamic environments, across domains, and with ever-increasing network andapplication complexity* Privacy and Security -- achievement of a high degree of security even in complex,heterogeneous federation and policy environments, especially in the face of componentfailures, untrusted components, malicious activities, and attacks, while also respectingprivacy and maintaining usability, (e.g., provide scalable federated policies for authentication,authorization and accountancy)* Usability -- adaptable, user-centered services and interfaces that promote efficiency,effectiveness, and fulfillment of user needs without overwhelming users with unnecessary orunauthorized dataThis agenda must be pursued across the spectrum from fundamental to applied research and withengagement of all sectors to attain widely deployable innovations. Necessary elements include:* Basic and applied research in the full range of network architectures, theoretical models,analysis techniques, hardware, software, security and privacy, and middleware neededto support the next generation of uses for networks and explore new paths to developcapabilities that cannot be supported on the current evolutionary path* Partnerships with application developers, users, and stakeholders to test basic research ideason real problems in areas including national security, support of scientific leadership, andhuman health* A suite of prototype networks and testbeds that enable understanding and creation ofnew technologies, data systems, and improvements in end-to-end performance at varyingscales. The massive size of existing deployed networks such as the Internet limits R&D, whilelaboratory and simulation studies cannot address some aspects of the solutions, particularlycomplexity, their ability to scale, and their potential realism.Research, partnerships, and prototype networks and testbeds are closely interrelated. The latter areneeded to test and develop new networking capabilities in realistic environments, to assure theycan be implemented technically and economically, and to explore policy frameworks. Partnershipsbetween the researchers and the application developers will help assure that R&D capabilities can beimplemented in real networks and that other application resources such as computing and storageare provided.Network InfrastructureMake the network infrastructure of the 21st century robust enough to meet very diverse demands._b3dd413a-e784-11df-a5d3-6a0c7a64ea2a1.3.1[Such demands include] network services supporting A7; exponential increases in data volumes and changes in how people access data (e.g., data in the network); ultra-reliable, secure networking (e.g., for national security and the commercial and banking sectors); new networking technologies that scale (e.g., all-optical networking) to provide the end-to-end bandwidth, performance, and services required for data-intensive science; and heterogeneous networking (e.g., wireless, optical networking, satellite communications, and others).Core AreasMake advances in core areas of networking R&D._b3dd4522-e784-11df-a5d3-6a0c7a64ea2a1.3.1.1FoundationsArchitectural principles, frameworks, and network models to deal with complexity; heterogeneity; multi-domain federation, management, and transparency; end-to-end performance; and differentiated services._b3dd486a-e784-11df-a5d3-6a0c7a64ea2a1.3.1.1.1DesignSecure, near-real-time, flexible, adaptive services with built-in intelligence to facilitate discovery, federation, and management of resources across domains and to increase the application robustness and resistance to attack even in extraordinarily complex systems and new ways of interconnecting networks to provide those services._b3dd4b12-e784-11df-a5d3-6a0c7a64ea2a1.3.1.1.2ManagementManagement methods and tools that incorporate intelligence in the network to enable effective deployment, control, and utilization of complex networks and resources in dynamic environments, across domains, and with ever-increasing network and application complexity._b3dd4f22-e784-11df-a5d3-6a0c7a64ea2a1.3.1.1.3Privacy and SecurityAchievement of a high degree of security even in complex, heterogeneous federation and policy environments, especially in the face of component failures, untrusted components, malicious activities, and attacks, while also respecting privacy and maintaining usability, e.g., provide scalable federated policies for authentication, authorization and accountancy._b3dd5224-e784-11df-a5d3-6a0c7a64ea2a1.3.1.1.4Research SpectrumPursue this agenda across the spectrum from fundamental to applied research and with engagement of all sectors to attain widely deployable innovations._b3dd54ea-e784-11df-a5d3-6a0c7a64ea2a1.3.1.2Basic and Applied Research[Conduct] basic and applied research in the full range of network architectures, theoretical models, analysis techniques, hardware, software, security and privacy, and middleware needed to support the next generation of uses for networks and explore new paths to develop capabilities that cannot be supported on the current evolutionary path._b3dd5922-e784-11df-a5d3-6a0c7a64ea2a1.3.1.2.1Partnerships[Enter into] pPartnerships with application developers, users, and stakeholders to test basic research ideas on real problems in areas including national security, support of scientific leadership, and human health._b3dd5c42-e784-11df-a5d3-6a0c7a64ea2a1.3.1.2.2Testbeds and Prototype Networks[Develop] a suite of testbeds and prototype networks that enable understanding and creation of new technologies, data systems, and improvements in end-to-end performance at varying scales._b3dd5f08-e784-11df-a5d3-6a0c7a64ea2a1.3.1.2.3The massive size of existing deployed networks such as the Internet limits research and development, while laboratory and simulation studies cannot address some aspects of the solutions, particularly complexity, their ability to scale, and their potential realism. The testbeds and prototypes will range from high-flexibility/low-cost platforms to high performance embedded systems. Research, partnerships, and testbeds and prototype networks are closely interrelated. Testbeds and prototypes are needed to test and develop new networking capabilities in realistic environments, to assure they can be implemented technically and economically, and to explore policy frameworks. Partnerships between the researchers and the application developers will help assure that R&D capabilities can be implemented in real networks and that other application resources such as computing and storage are provided.Smart PlanetCreating the Smart Planet_b3dd634a-e784-11df-a5d3-6a0c7a64ea2a1.4Creating the Smart Planet -- A smarter world will be one in which all kinds of objects, devices, and large-scale physical systemsare interconnected, compute-empowered, and instrumented to perform tasks with, on behalfof, and in the best interest of people. This infrastructure will also enable people to collaborate inreal time, dynamically creating short-term ad hoc networks linking them to devices, data, andinformation, computing platforms, and applications as needed. Some components of the smartplanet infrastructure will be stand-alone robotic systems designed to perform tasks autonomously;others will be what are now called cyber-physical systems. These are networked computingsystems -- interconnected software, microprocessors, sensors, and actuators -- deeply integratedwithin engineered physical systems to monitor and control capabilities and behaviors of the physicalsystem as a whole. Such systems are already essential to the effective operation of U.S. defense andintelligence systems and critical infrastructures, industrial-process control systems, and other largescalecivilian systems, as well as to smaller-scale applications in cars and medical devices. Demand forand uses of cyber-physical systems are growing worldwide.Where we are now -- computing was once a minimal component of engineered systems, andsystems were designed to be operated separately and in benign or controlled environments. Nowthe “cyber” aspects of engineered systems and products are becoming the very key to making thesesystems more capable. And the need for deployment is increasingly in situations where systems mustbe designed to interact and cooperate, often with high degrees of autonomy. This is illustrated inthe rapidly growing demand for increased capability in transportation, manufacturing, agricultureand mining, and medical diagnosis and therapies. Society benefits when surgery can become lessinvasive, reducing recovery times. Advances in computer-controlled robotic and laser surgery (suchas those enabled by the da Vinci® medical robotic system) are in this direction. The U.S. industrialeconomy has depended upon the productivity of its workforce -- enabled by its technologicalcapability -- for relative U.S. strength in industrial sectors worldwide. That lead has declined as othernations have rapidly joined the technology race and have sought to produce ever-more sophisticatedproducts and systems.Research needs -- a new systems science is needed to provide unified foundations, models and tools,system capabilities, and architectures that enable innovation in highly dependable cyber-enabledengineered and natural systems. Better understanding of system complexity is also necessary in thisresearch area to aid in improved management and decision support. Specific technical areas foremphasis include:* Unifying foundations for modeling, predicting, and controlling systems that exhibitcombined cyber (logical/discrete/digital) and physical (continuous/analog) system behaviors* New approaches for supervisory control of systems that must interact on an ad hoc basis* Scientific and engineering principles, metrics, and standards that integrate the disciplines ofreal-time embedded systems, control, communications/networking, security, and humanmachineinteraction* Technology to close the design and productivity gap between modeling, programming, andruntime execution of cyber-physical systems* Principles for reasoning about and actively managing properties of complex, multiscale,real-time cyber-physical system interactions, including safety, security, reliability, andperformance* Design methods and systems technology for autonomy, human interaction, andmanagement of control authority* Open systems approaches for composition, integration, and coordination of cyber-physicalsystemsSystems Science[Develop] a new systems science is needed to provide unified foundations, models and tools, system capabilities, and architectures that enable innovation in highly dependable cyber-enabled engineered and natural systems._b3dd6692-e784-11df-a5d3-6a0c7a64ea2a1.4.1Management and Decision Support[Achieve] better understanding of system complexity to aid in improved management and decision support._b3dd69bc-e784-11df-a5d3-6a0c7a64ea2a1.4.2Areas of EmphasisEmphasize specific technical areas._b3dd6ebc-e784-11df-a5d3-6a0c7a64ea2a1.4.3FoundationsUnifying foundations for modeling, predicting, and controlling systems that exhibit combined cyber (logical/discrete/digital) and physical (continuous/analog) system behaviors_b3dd7254-e784-11df-a5d3-6a0c7a64ea2a1.4.3.1Supervisory ControlNew approaches for supervisory control of systems that must interact on an ad hoc basis_b3dd7592-e784-11df-a5d3-6a0c7a64ea2a1.4.3.2Principles, Metrics, and StandardsScientific and engineering principles, metrics, and standards that integrate the disciplines of real-time embedded systems, control, communications/networking, security, human-machine interaction_b3dd7a60-e784-11df-a5d3-6a0c7a64ea2a1.4.3.3Design and Productivity GapTechnology to close the design and productivity gap between modeling, programming, and runtime execution of cyber-physical systems_b3dd7e2a-e784-11df-a5d3-6a0c7a64ea2a1.4.3.4Reasoning and ManagementPrinciples for reasoning about and actively managing properties of complex, multiscale, realtime cyber-physical system interactions, including: safety, security, reliability, performance_b3dd8172-e784-11df-a5d3-6a0c7a64ea2a1.4.3.5Autonomy, Human Interaction, and AuthorityDesign methods and systems technology for autonomy, human interaction, and management of control authority_b3dd862c-e784-11df-a5d3-6a0c7a64ea2a1.4.3.6Open SystemsOpen systems approaches for composition, integration, and coordination of cyber-physical systems_b3dd8a00-e784-11df-a5d3-6a0c7a64ea2a1.4.3.7SoftwareEngineering Complex and Sophisticated Software_b3dd8d66-e784-11df-a5d3-6a0c7a64ea2a1.5Engineering Complex and Sophisticated Software -- Like networking technologies, software makes the digital world possible, directing the functioning ofcomputers and devices and providing the electronic instructions for the applications of computingthat shape our lives. For example, NASA spaceflight software controls a preponderance of overallsystem functionality. A complex software system can be defined as a system comprising interacting“simple” software modules that, working together, exhibit a high degree of complexity resulting ina higher-order behavior. The more complex the software system is, however, the greater the chancefor unpredictable emergent behavior, which increases the risk of system failure with potentiallysignificant impacts to the businesses, services, equipment, or users depending on the systems.Where we are now -- critical U.S. defense, security, health care, and economic capabilities dependon complex software-based systems that must remain operational, useful, and relevant for decades.Today’s software design and development tools and practices can make any of these goals difficult toachieve. For example, consider keeping software relevant for decades -- the requirements originallyused to design the software often change multiple times during the development phase, thenmany more times during the continued use of the software system. How can the need to keep thesoftware relevant and useful be balanced with the need for software that is well defined, tested, andmeets evolving operational requirements? The persistent and widening gap between the quality of hardware and that of software continues to burden systems development and broader efforts toinnovate in networking and information technologies.Research needs the tradition of incremental changes in software development provides aninadequate basis to address the complexity of contemporary critical systems. Improving the quality,cost-effectiveness, and sustainability of this software constitutes a core technical challenge thatrequires breakthrough innovations, ranging from the fundamental science and engineering ofsoftware to the application level. Research is needed to rethink software design -- from the basicconcepts of design, evolution, and adaptation, to advanced systems that seamlessly integrate humanand computational capabilities. New practices, technologies, tools, and measurement methodsare required that can reduce the errors, defects, and vulnerabilities that occur during softwaredevelopment. Specific research topics include:* Foundational principles for software design* Formalized science-based software architectures and design methods* Tools and principles to build, maintain, and expand ultra-large-scale software systems* Programming languages, tools, and practices for modeling, designing, developing, testing,and validating software* Tools and practices for improving the interoperability and usability of software applications* Repositories of software design and development knowledge and reference software* Improved software assurance that reduces or eliminates software defects, weaknesses, andvulnerabilities through improvements in automated test methods, measurement methods,technology and tools, and guidance and standards for development of trustworthy systems* Parallel programming languages, compilers, operating systems, environments, and models* Software for computation- and data-intensive applications* Software effectiveness metrics* Highly user-friendly and interactive software systemsCritical SystemsImprove the quality and cost-effectiveness of critical systems software._b3dd9248-e784-11df-a5d3-6a0c7a64ea2a1.5.1The tradition of incremental changes in software development provides an inadequate basis to address the complexity of contemporary critical systems. [This] constitutes a core technical challenge that requires breakthrough innovations, ranging from the fundamental science and engineering of software to the application level.Software DesignRethink software design – from the basic concepts of design, evolution, and adaptation to advanced systems that seamlessly integrate human and computational capabilities._b3dd96c6-e784-11df-a5d3-6a0c7a64ea2a1.5.2Practices, Technologies, Tools, and Measurements[Develop] new practices, technologies, tools, and measurement methods are required that can reduce the errors, defects, and vulnerabilities that occur during software development._b3dd9a68-e784-11df-a5d3-6a0c7a64ea2a1.5.3Foundational PrinciplesFoundational principles for software design_b3dd9f7c-e784-11df-a5d3-6a0c7a64ea2a1.5.3.1Architectures and MethodsFormalized science-based software architectures and design methods_b3dda3b4-e784-11df-a5d3-6a0c7a64ea2a1.5.3.2Ultra-Large SystemsTools and principles to build, maintain, and expand ultra-large-scale software systems_b3dda79c-e784-11df-a5d3-6a0c7a64ea2a1.5.3.3ProgrammingProgramming languages, tools, and practices for modeling, designing, developing, testing, and validating software_b3ddace2-e784-11df-a5d3-6a0c7a64ea2a1.5.3.4Interoperability and UsabilityTools and practices for improving the interoperability and usability of software applications_b3ddb106-e784-11df-a5d3-6a0c7a64ea2a1.5.3.5RepositoriesRepositories of software design and development knowledge and reference software_b3ddb4da-e784-11df-a5d3-6a0c7a64ea2a1.5.3.6Software AssuranceImproved software assurance that reduces or eliminates software defects, weaknesses, and vulnerabilities through improvements in automated test methods, measurement methods, technology and tools, and guidance and standards for development of trustworthy systems_b3ddba02-e784-11df-a5d3-6a0c7a64ea2a1.5.3.7Parallel ProgrammingParallel programming languages, compilers, operating systems, environments, and models_b3ddbe8a-e784-11df-a5d3-6a0c7a64ea2a1.5.3.8Intensive ApplicationsSoftware for computation- and data-intensive applications_b3ddc24a-e784-11df-a5d3-6a0c7a64ea2a1.5.3.9MetricsSoftware effectiveness metrics_b3ddc77c-e784-11df-a5d3-6a0c7a64ea2a1.5.3.10User-Friendliness and InteractivityHighly user-friendly and interactive software systems_b3ddcbbe-e784-11df-a5d3-6a0c7a64ea2a1.5.3.11KnowledgeFrom Data to New Knowledge_b3ddcfb0-e784-11df-a5d3-6a0c7a64ea2a1.6From Data to New Knowledge -- Most of the world’s information is now “born digital,” and legacy texts, images, sounds, videos, andfilms as well are being digitized around the clock. Although statistical estimates vary, they agree thatthe amount of digital data generated annually is many orders of magnitude greater than the totalamount of information in all the books ever written, and the total is expected to continue growingexponentially. In the advanced sciences alone, the proliferation of ultra-powerful and distributeddata-collection instruments and experimental facilities has turned the conduct of leading-edgeresearch into a global-scale, data-intensive enterprise. The Federal agencies in the NITRD Programtogether generate exabytes of research data annually. Financial, commercial, communications, andWeb-based enterprises likewise continually generate vast amounts of new digital information.Where we are now -- today, our capacity to create electronic data is outpacing advances in thetechnologies needed to manage and make effective use of society’s data resources. Ultra-large-scaledata sets -- what scientists refer to as “big data” -- are troves of potential new knowledge, but as notedabove, the current networking infrastructure does not provide levels of end-to-end performancethat would enable individuals and groups to access and work with big data on their desktops.While the plummeting cost of mass storage eases the stress of archiving massive data resources,we also do not yet know how to design scalable technologies—such as semantic frameworks andopen ontologies—that would substantially advance capabilities for rapidly identifying, integrating,refining, analyzing, and visualizing heterogeneous and ultra-scale information in ways thatwould help people learn, think, and decide. Nor do we yet have a rationalized, robust informationinfrastructure for the long-term preservation, curation, federation, sustainability, accessibility,and survivability of vital Federal electronic records and data collections, such as those overseenby the National Archives and Records Administration (NARA). “Harnessing the Power of DigitalData for Science and Society,” the 2009 report of the Interagency Working Group on Digital Data(which includes many NITRD agencies), has proposed an initial framework for developing such aninfrastructure.Research needs -- we need far more powerful and nuanced tools than exist today to mine data trovesdeeply, and to combine and visualize diverse forms of data, in order to “see” the significant items,patterns, and relationships that could lead to new insights. To support complex human, societal,and organizational ideas, analysis, and timely action and decision-making, multisource forms oflarge-scale, raw digital information (e.g., sensor data) must be managed, assimilated, and accessiblein formats responsive to the user’s needs and expertise. At the extreme scale represented by 21stcentury scientific and other data, significant R&D challenges in applying information to enhancediscovery and decision-making remain to be addressed, including:* Information standards—data interoperability and integration of distributed data;generalizable ontologies; data format description language (DFDL) for electronic recordsand data; data structure research for complex digital objects; interoperability standards forsemantically understood ubiquitous health information records; and information services forcloud-based systems* Decision support -- next-generation machine learning, semantic logic, and data miningalgorithms; portals and frameworks for data and processes; tools for large-scale collaboration;user-oriented and collaborative techniques and tools for thematic discovery, synthesis, dataprovenance, analysis, and visualization for decision making; mobile, distributed informationfor emergency personnel; management of human responses to data; collaborativeinformation triage; portfolio analysis; development of data corpora for impact assessmentand other metrics of scientific R&D; and multidisciplinary R&D in ways to convert data intoknowledge and discovery* Information management -- intelligent rule-based data management; increasing access toand cost-effective integration and maintenance of complex collections of heterogeneousdata; innovative architectures for data-intensive and power-aware computing; scalabletechnologies; integration of policies (differential sensitivity, security, user authentication) with data; integrated data repositories and computing grids; testbeds; sustainability andvalidation of complex models; and grid-enabled visualization for petascale collectionsSocial IntelligencePioneering Socially Intelligent Systems_b3ddd4ec-e784-11df-a5d3-6a0c7a64ea2a1.7Pioneering Socially Intelligent Systems -- Emerging types of collaboration, communication, and cooperation -- from open source softwaredevelopment, crowdsourcing, and clickworking -- illustrate the potential for a new form of “socialintelligence” that melds human and computer abilities. Socially intelligent systems can range in scalefrom one person and one machine to many people and many machines distributed over the globe.WeCompute envisions enhanced environments and tools for large-scale collaborative problemsolvingin which the intelligence of large numbers of people, operating in real-time computationalenvironments, can accelerate solutions to the most complex problems by simultaneouslyletting humans do what they do best (e.g., deriving meanings from sensory inputs, synthesizingdisparate experiences, drawing inferences) and machines do what they do best (e.g., fast, complexcomputation). Such environments would include the far more powerful analytical tools describedabove to enable people to make effective decisions.The “intelligence” exhibited in these systems will mimic human capability to reason, perceive theenvironment, and collaborate with humans and other machines. An intelligent system will learnfrom all past experience and adapt over time as well as understand people’s cognitive and socialabilities. The “social” aspects of the system will result from optimizing human actions, interactions,knowledge, and skills in relation to overall goals. Socially intelligent systems may be designed to actautonomously so that humans can remain “out of the loop,” as in dynamic allocation of bandwidth orrecovery of transportation systems during emergencies. But human-computer partnerships, allowingfor new forms of complementary engagement, may be the most effective of all.Where we are now -- online commerce and communication have been revolutionized throughinnovations such as micro-blogging, security, video, recommender and reputation systems, andscience has been advanced through cyber-enabled discovery and virtual organizations. Even so,today’s systems are merely suggestive of the powerful versions of social intelligence that may bedeveloped in the future. The goal is to advance knowledge at the frontiers of computationallymediated human-machine interactions that would reframe the meaning of intelligence.Research needs -- new findings about how the mind perceives, evaluates, categorizes, synthesizes,analyzes, retains, and makes decisions about inputs -- both internal and from the outside world -- willprovide researchers with models for engineering intelligence into the capabilities of networking andcomputing technologies. Research needs to focus on computers as intelligent participants whoseperception, computational capabilities, and learning may be unique and able to scale at rates difficultfor humans to grasp. At the same time, we also need a better understanding of how people bestcoordinate, collaborate, and participate in collective action at such large scales and in real time. Onegoal is to better understand the types of problems that are best suited for these types of humancomputerpartnerships. Key areas of research include: machine learning and artificial intelligence;immersive environments and 4-D touch displays; understanding, modeling, and managing complexsystems; computational photography; graphics and visualization; social and humanoid robotics;speech recognition, natural language understanding and dialogue systems; and mechanization ofeconomic theories (e.g., n-way kidney exchanges).Some research questions to be answered: What is the nature of this collective intelligence? Can webuild computational models of political discourse to better understand each other’s point of view andresolve disputes? Can a distributed collection of machines and people learn to collect data, analyzethem, and ask good research questions, ultimately changing the way science is conducted? Howdo we best understand the human capabilities that outperform computers and then harness thoseassets in new human-computer partnerships? How are value systems (i.e., cultural, ethical, legal, etc.)embedded in algorithms and collective enterprises and how should they be evaluated? What newdesign techniques and methods would result in a broad array of behaviors and achievements thatcould effectively address current social issues (e.g., emergency response)? How can human needs andvalues be strengthened through socially intelligent systems? What new theories could explain thebehaviors of these complex, dynamic systems?Computers as ParticipantsFocus on computers as intelligent participants whose perception, computational capabilities, and learning may be unique and able to scale at rates difficult for humans to grasp._b3ddd974-e784-11df-a5d3-6a0c7a64ea2a1.7.1Coordination, Collaboration, and Participation[Develop] a better understanding of how people best coordinate, collaborate, and participate in collective action at such large scales and in real time._b3ddddc0-e784-11df-a5d3-6a0c7a64ea2a1.7.1.1Human-Computer Partnerships[Develop a] better understand[ing of] the types of problems that are best suited for these types of human-computer partnerships._b3dde3ce-e784-11df-a5d3-6a0c7a64ea2a1.7.1.2Key Research[Focus on] key areas of research._b3dde888-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3Some research questions include: What is the nature of this collective intelligence? Can we build computational models of political discourse to better understand each other’s point of view and resolve disputes? Can a distributed collection of machines and people learn to collect data, analyze them, and ask good research questions, ultimately changing the way science is conducted? How do we best understand the human capabilities that outperform computers and then harness those assets in new humancomputer partnerships? How are value systems (i.e., cultural, ethical, legal, etc.) embedded in algorithms and collective enterprises and how should they be evaluated? What new design techniques and methods would result in a broad array of behaviors and achievements that could effectively address current social issues (e.g., emergency response)? How can human needs and values be strengthened through socially intelligent systems? What new theories could explain the behaviors of these complex, dynamic systems?Machine Learning and AI[Conduct research on] machine learning and artificial intelligence_b3ddecde-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3.1Immersion and 4-D Displays[Conduct research on] immersive environments and 4-D touch displays_b3ddf2d8-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3.2Complex Systems[Conduct research on] understanding, modeling, and managing complex systems_b3ddf7b0-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3.3Computational Photography[Conduct research on] computational photography_b3ddfc24-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3.4Graphics and Visualization[Conduct research on] graphics and visualization_b3de021e-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3.5Robotics[Conduct research on] social and humanoid robotics_b3de0714-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3.6Speech Recognition, Natural Language, and Dialogue[Conduct research on] speech recognition, natural language understanding and dialogue systems_b3de0c00-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3.7Mechanization of Economic Theories[Conduct research on] mechanization of economic theories (e.g., n-way kidney exchanges)_b3de1240-e784-11df-a5d3-6a0c7a64ea2a1.7.1.3.8Trust & ConfidenceThe ability to design and build systems with levels of security, safety, privacy, reliability, predictability, and dependability that “you can bet your life on.”_b3de175e-e784-11df-a5d3-6a0c7a64ea2a2Trust and Confidence -- A screen freeze may be a trivial inconvenience, but the consequences of more serious IT flaws -- suchas a digitally controlled diagnostic system whose malfunctioning delivers lethal doses of radiation,trains that have a fatal head-on collision due to a software error, or the theft of sensitive informationover the Internet -- undermine society’s trust in the efficacy of IT as the basic infrastructure ofthe digital age. The perspective of the NITRD agencies is that one of the most significant tests oftechnological leadership in the years ahead will be the ability to engineer and build IT systems thatinspire high levels of confidence because they function as intended—safely, securely, reliably, andcost-effectively. Fundamental research to ensure that digital networks, systems, devices, applications,and communications processes earn and deserve the trust and confidence of society thus constitutesan essential foundation for the Nation’s future. Since technology is only half of the equation, thiswork should include a robust interdisciplinary R&D agenda in the behavioral, ethical, legal, andsocietal aspects of achieving trust and confidence -- for example, how to make systems much moreuser-friendly, so it is easy for users to “do the right thing” in engaging security and privacy-protectionfeatures. Following are the key elements of this vision and the major research challenges to be met ineach.TrustworthinessMaking the Digital World More Trustworthy_b3de1c04-e784-11df-a5d3-6a0c7a64ea2a2.1Making the Digital World More Trustworthy -- The necessity for trust and confidence spans far more than the interconnected networks, systems,and software of the Internet and the information residing in those systems. It encompasses thenetworked computing systems that are deeply integrated within complex life- and safety-criticalphysical structures such as power grids, buildings, airplanes and spacecraft, ground transportation,and medical devices; and it includes stand-alone computing systems that also perform critical taskson which human life, safety, and security depend.Where we are now -- over the past decade, we have become increasingly aware as a society of thevulnerabilities associated with our IT systems and infrastructure. The reality is that many of thesetechnologies were invented and engineered before the security implications of pervasive societalreliance on IT systems and networks came to the fore. In the national security, aviation, and spaceexploration arenas, Federal research has long pursued technical means of assuring that networks and systems can continue to function in adverse environments and amid internal faults and failures;but to date, system redundancy remains the principal failsafe. Since 9/11, Federal agencies, inpartnership with private-sector stakeholders, have also focused on research to harden against cyberinvasions that attack the process-control systems of critical U.S. infrastructures that rely on Internetconnectivity. In broad terms, however, efforts to increase IT reliability, safety, and security continueto target add-on fixes for existing technologies rather than new concepts, designs, architectures, andsecurity standards that would incorporate those attributes from the ground up.Research needs -- evolutionary system hardening and software patching will continue to benecessary in dealing with the legacy systems of prior decades still in service. Only foundational basicresearch, however, can produce the advances needed to make possible inherently more stable,reliable, safe, secure, self-diagnosing, self-healing -- and thus far more cost-effective -- systems,software, and devices for the dynamic environments of a fully digital world. A fundamental scienceof security must be developed as an essential component of high-quality IT design and engineeringacross all technologies and application domains. The science of security must also infuse curriculaand training activities at every educational level. Multiple dimensions of the security challenge aredescribed below.System Hardening and Software Patching[Pursue] evolutionary system hardening and software patching in dealing with the legacy systems of prior decades still in service._b3de20c8-e784-11df-a5d3-6a0c7a64ea2a2.1.1Basic Research[Conduct] foundational basic research [to] produce the advances needed to make possible inherently more stable, reliable, safe, secure, self-diagnosing, self-healing – and thus far more cost-effective – systems, software, and devices for the dynamic environments of a fully digital world._b3de2596-e784-11df-a5d3-6a0c7a64ea2a2.1.2Science of Security[Develop] a fundamental science of security as an essential component of high-quality IT design and engineering across all technologies and application domains._b3de2bfe-e784-11df-a5d3-6a0c7a64ea2a2.1.3Curricula and TrainingInfuse curricula and training activities at every educational level._b3de3194-e784-11df-a5d3-6a0c7a64ea2a2.1.3.1Cyber SecuritySecuring Life in Cyberspace_b3de3694-e784-11df-a5d3-6a0c7a64ea2a2.2Securing Life in Cyberspace -- As the President’s May 2009 “Cyberspace Policy Review” notes, the Internet’s global fabric of nearinstantaneousinterconnectivity is at once transformative and fragile—beset by the unintendedconsequences of its multi-decade growth and survival in increasingly dangerous times.Where we are now -- the vast sea of information that flows over the Internet and is stored in Internetconnectedsystems mostly is not secure, nor are the networks and systems themselves. The basicopenness and anonymity built into the Internet’s trust-based legacy architecture -- combined with aseemingly endless assortment of hardware and software vulnerabilities in computing systems -- areexploited around the clock by hackers, criminals, and U.S. adversaries. According to some experts, thenetworks of zombie attack computers called “botnets” today constitute the largest supercomputerin the world. The lack of end-to-end security in cyberspace costs organizations in all sectors manybillions of dollars annually; it also threatens major U.S. Government objectives, such as improvingthe health care system with the aid of health IT and stimulating economic innovation. Further, theinterconnections of the Internet with critical infrastructures and systems (e.g., financial) providevectors for potentially devastating cyber attacks. Currently, attackers have the upper hand; defendersrely for the most part on a never-ending cycle of patching networks and systems, but this defendsonly against previously identified threats, not the constantly emerging new ones.The Federal government has initiated high-priority efforts to improve coordination of cybersecurityR&D across Federal agencies, with the goals of better securing government information and networksand expanding collaboration with the private sector to address cybersecurity objectives. Becausemuch of the digital infrastructure lies in the private sector, however, developing R&D partnershipsand technology deployment strategies acceptable across sectors outside the Government presentscomplex challenges.Research needs -- the goal of cybersecurity R&D must be to provide end-to-end security in networkedenvironments. The immense dynamism and complexity of global networking make this goal a grandchallenge for which there will be no single solution. Advances of many kinds are needed, in the policyand educational arenas as well as in diverse technologies. In addition to more inherently securecomponents, new methods for proactive approaches to improving cybersecurity must be pursued,such as dynamic security; stronger global-scale identity management; better situational awareness;new means of attack attribution and combating malware, botnets, and insider threats; enterpriselevelsecurity metrics for assessing the relative effectiveness of policies and techniques; cybersecurityeducation; and easy-to-use security techniques. One conceptual approach being advanced by theFederal cybersecurity community specifically focuses on ways to eliminate the cyber attacker’sadvantage over the defender -- for example, by employing dynamic virtualization to make attacktargets much harder to pinpoint or by creating “tailored trustworthy spaces” on the Internet thatprovide elevated levels of security and privacy.End-to-End SecurityProvide end-to-end security in networked environments._b3de3d24-e784-11df-a5d3-6a0c7a64ea2a2.2.1The immense dynamism and complexity of global networking make this goal a grand challenge for which there will be no single solution.Myriad Advances[Achieve] advances of many kinds, in the policy and educational arenas as well as in diverse technologies._b3de42b0-e784-11df-a5d3-6a0c7a64ea2a2.2.1.1Proactive Approaches[Pursue] new methods for proactive approaches to improving cybersecurity_b3de47d8-e784-11df-a5d3-6a0c7a64ea2a2.2.1.2Dynamic SecurityDynamic security_b3de4e90-e784-11df-a5d3-6a0c7a64ea2a2.2.1.2.1Identity ManagementStronger global-scale identity management_b3de5426-e784-11df-a5d3-6a0c7a64ea2a2.2.1.2.2Situational AwarenessBetter situational awareness_b3de59bc-e784-11df-a5d3-6a0c7a64ea2a2.2.1.2.3Attack Attribution and CombatNew means of attack attribution and combating malware, botnets, and insider threats_b3de6092-e784-11df-a5d3-6a0c7a64ea2a2.2.1.2.4Security MetricsEnterprise-level security metrics for assessing the relative effectiveness of policies and techniques_b3de6650-e784-11df-a5d3-6a0c7a64ea2a2.2.1.2.5EducationCybersecurity education_b3de6ba0-e784-11df-a5d3-6a0c7a64ea2a2.2.1.2.6TechniquesEasy-to-use security techniques_b3de7276-e784-11df-a5d3-6a0c7a64ea2a2.2.1.2.7SystemsSystems You Can Bet Your Life On_b3de7848-e784-11df-a5d3-6a0c7a64ea2a2.3Systems You Can Bet Your Life On -- Cyber-enabled engineered systems in which cyber capability is deeply embedded at all scales -- andon which life and safety often depend -- must remain ultra safe, secure, and reliable. The challengeof building such systems, often from fundamentally untrusted components, spans essentially everyengineering domain. It requires the integration of knowledge and engineering principles acrossmany computational and engineering research disciplines (computing, networking, control, humaninteraction, and learning theory, as well as electrical, mechanical, chemical, biomedical, nanobioengineering,and other engineering disciplines) to develop a “new cyber-physical system science.”Where we are now -- the complexity of cyber-physical systems, including robotic and autonomoussystems, is at a point where current methods are inadequate to anticipate possible failure modes andguarantee safe, predictable, efficient operation. The world’s leading automotive manufacturers, forexample, have suffered catastrophic product failures that resulted in enormous recall costs and loss ofconsumer confidence with potentially huge economic consequences. Deaths due to infusion pumpfailures have reached such a high level that the FDA has found it necessary to mount an initiativeto investigate. At the same time, our appetite for systems of this kind -- in which the engineeredsystems are monitored and controlled by computer and communication networks -- drives thesteep upward growth curve in system complexity. The dynamic, often decentralized nature of thesecomplex systems places unprecedented demands on the contributing areas of real-time computing,communication, networked control; on engineering for the physical domains; and on verification,validation, and certification support for all of these. Over-design currently is the only path to safetyand successful system certification, leading to a mindset of optimizing for a narrow task instead ofencouraging adaptability and evolvability.Research needs -- we need to establish new, unified scientific and engineering foundations tosecurely, safely, and systematically understand, build, manage, and adapt these complex systems -- cyber-physical systems that remain reliable as they interact across internal subsystems, with eachother, with human users, and with highly complex and uncertain physical environments -- and weneed successful exemplars of such systems. A core element of this agenda is the development of new, more cost-effective approaches to certifying the quality of these systems, a challenge that todayconsumes, for example, an estimated 50% of the resources required to develop new, safety-criticalsystems in the aviation industry. Essential R&D areas include:* Comprehensive integrated design approaches for cyber and physical system events andactions -- for example, exploration and simplification of both nominal and failure modedesign for complex system environments that may incur undesirable or hazardous emergentbehavior* Improved models of system and human behavior that can provide a framework for humansystemand system-system interoperation that can enforce safe operation in mixed-initiativesystems. For example, models should support interaction without introducing problems suchas mode confusion or technology surprise.* New approaches to fault tolerance -- system prediction, recovery, and adaptation technologyfor rapidly identifying and avoiding potentially reachable failure states, and for maximizingeffective fall-back and fail-safe recovery when these cannot be avoided* Hardware, software, and control platforms and frameworks that support rigorous -- checked or verified -- composition of system components and guaranteed regulation of componentinteractions* New scientific underpinnings and design approaches for securing cyber-physical systems,addressing both cyber and natural or malicious physical disruptions (and interactions ofthese)* Technology-supported certification approaches that are based on claims and analyticevidence, rather than merely process-based checklists, and that can support modularcertification of components and assemblies, with incremental re-certification after systemmodification (e.g., knowing and certifying what exactly it is that you can trust, and why youcan trust it)* A new generation of design and analysis toolchains that can produce rigorous evidencefor high-confidence system design, implementation and evaluation. For example, thesewould integrate discrete and continuous mathematical models and support rigorousreasoning about the interacting behaviors of cyber and physical components. They mightinclude frameworks that equally support evaluation, verification and validation (V&V), andcertification activities, in addition to design and implementation.Integrated DesignComprehensive integrated design approaches for cyber and physical system events and actions – for example, exploration and simplification of both nominal and failure mode design for complex system environments that may incur undesirable or hazardous emergent behavior._b3de7dac-e784-11df-a5d3-6a0c7a64ea2a2.3.1ModelsImproved models of system and human behavior that can provide a framework for humansystem and system-system interoperation that can enforce safe operation in mixed-initiative systems._b3de855e-e784-11df-a5d3-6a0c7a64ea2a2.3.2For example, models should support interaction without introducing problems such as mode confusion or technology surprise.Fault ToleranceNew approaches to fault tolerance ... for rapidly identifying and avoiding potentially reachable failure states, and for maximizing effective fall-back and fail-safe recovery when these cannot be avoided._b3de8bbc-e784-11df-a5d3-6a0c7a64ea2a2.3.3PredictionSystem prediction technology_b3de9184-e784-11df-a5d3-6a0c7a64ea2a2.3.3.1RecoverySystem recovery technology_b3de98e6-e784-11df-a5d3-6a0c7a64ea2a2.3.3.2AdaptationSystem adaptation technology_b3de9f26-e784-11df-a5d3-6a0c7a64ea2a2.3.3.3Composition and GuaranteesHardware, software, and control platforms and frameworks that support rigorous – checked or verified – composition of system components and guaranteed regulation of component interactions._b3dea520-e784-11df-a5d3-6a0c7a64ea2a2.3.4Cyber-Physical SystemsNew scientific underpinnings and design approaches for securing cyber-physical systems, addressing both cyber and natural or malicious physical disruptions (and interactions of these)._b3dead40-e784-11df-a5d3-6a0c7a64ea2a2.3.5CertificationTechnology-supported certification approaches that are based on claims and analytic evidence, rather than merely process-based checklists, and that can support modular certification of components and assemblies, with incremental re-certification after system modification – e.g., knowing and certifying what exactly it is that you can trust, and why you can trust it._b3deb42a-e784-11df-a5d3-6a0c7a64ea2a2.3.6Tool ChainsA new generation of design and analysis toolchains that can produce rigorous evidence for high-confidence system design, implementation and evaluation._b3debab0-e784-11df-a5d3-6a0c7a64ea2a2.3.7For example, these would integrate discrete and continuous mathematical models and support rigorous reasoning about the interacting behaviors of cyber and physical components. They might include frameworks that equally support evaluation, V&V, and certification activities, in addition to design and implementation.Information Assurance and SharingInformation Assurance and Sharing_b3dec2bc-e784-11df-a5d3-6a0c7a64ea2a2.4Information Assurance and Sharing -- A primary function of cyber infrastructure is to provide for the safe, secure creation, transmission,storage, and retrieval of all kinds of digital information -- including sensitive data belonging toindividuals, private-sector organizations, and government. Ideally, both the creator and any recipients or viewers of nonpublic digital information should be authorized and should be able to access itsecurely; identify its origin and history, or provenance; authenticate its integrity (no one has tamperedwith the content); and maintain its confidentiality as required. The information assurance field looksat cybersecurity specifically from the perspective of what is required to maintain the confidentiality,integrity, and availability of data.Where we are now -- current concerns in information assurance range from protecting the bitsthemselves through guarding the larger digital environments in which they reside. Technical areasinclude security governance and privacy policies; network and system access controls, identityauthentication, management, and non-repudiation technologies and policies; cryptographictechniques for data encryption and decryption; and forensic capabilities for identifying securitybreaches. In highly sensitive information environments such as DoD, “mission assurance” alsoemploys risk analysis and management tools to analyze and mitigate the security risks ofenvironments in which information is shared across multiple security levels. Today, encryptiontechniques provide the only data-based direct means of preventing unauthorized persons fromobtaining access to digital data. Public Key Infrastructure (PKI) exemplifies the approach of creating atrusted multi-domain network environment, but PKI has been slow to achieve widespread adoptionbecause it is costly and cumbersome to administer.Research needs -- the same characteristics of complex enterprises that enable network andinformation managers to institute access controls and security monitoring (i.e., large-scale systemhomogeneity, static configuration, and software monoculture) also make it easier for cyber attackersto access, tamper with, or destroy information. To realize the NITRD vision, research must seekfundamental advances in hardware, software, and network architectures that can provide immunityfrom tampering and attacks, possibly by identifying and actively defeating them or increasing systemdiversity. Likewise, next-generation approaches are needed for securing digital information itself.Exploration of such techniques as homomorphic encryption, for example, may lead the way to dataformats that are intrinsically encoded but still usable in controlled environments.Advanced ArchitecturesSeek fundamental advances in hardware, software, and network architectures that can provide immunity from tampering and attacks, possibly by identifying and actively defeating them or increasing system diversity._b3dec9ba-e784-11df-a5d3-6a0c7a64ea2a2.4.1Digital Information[Develop] next-generation approaches for securing digital information itself._b3ded0d6-e784-11df-a5d3-6a0c7a64ea2a2.4.2Homomorphic EncryptionExplore such techniques as homomorphic encryption [that] may lead the way to data formats that are intrinsically encoded but still usable in controlled environments._b3ded932-e784-11df-a5d3-6a0c7a64ea2a2.4.2.1Security and PrivacyUnderstanding the Trade-offs: Balancing Security and Privacy With Other Values_b3dee076-e784-11df-a5d3-6a0c7a64ea2a2.5Understanding the Trade-offs: Balancing Security and Privacy With Other Values -- Designing a system or a network that satisfies a single design goal -- security -- is still a grandchallenge in computer science research. Yet, in reality, many systems and networks like the Internetthat are used by real people have to satisfy not just one goal but an array of them. For example, theyneed to be usable; they should give users the information and personal privacy they expect; theyshould be open enough so that users can connect with others at a distance and obtain informationthat is available on other systems and networks. At the same time, the systems need to provide thelevel of security required by the end users. In many cases, however, it is not possible to satisfy allcompeting goals.Where we are now -- we are just beginning to understand the implications of such conflicts. If it is notpossible to design a system that is simultaneously secure, privacy-preserving, usable, and open, whatare the potential trade-offs among those attributes? We need to better understand these trade-offsand expand the space of possible solutions.Research needs -- research is necessary to investigate how we can more effectively comprehend,model, and optimize an array of conflicting design goals. In addition, new tools are needed to enableIT managers and end users both to monitor and act to mitigate security risks.Design ConflictsInvestigate how we can more effectively comprehend, model, and optimize an array of conflicting design goals._b3dee76a-e784-11df-a5d3-6a0c7a64ea2a2.5.1Monitoring and Mitigation Tools[Develop] new tools to enable IT managers and end users both to monitor and act to mitigate security risks._b3deefe4-e784-11df-a5d3-6a0c7a64ea2a2.5.2Cyber CapableTransformed education and training ensure that current generations benefit fully from cyber capabilities and inspire a diverse, prepared, and highly productive next-generation workforce of cyber innovators._b3def7c8-e784-11df-a5d3-6a0c7a64ea2a3Cyber InnovatorsCyber Capable -- The third essential foundation for the bright future envisioned by the NITRD agencies involves thehuman side of the human-computer partnership. To remain at the forefront, the Nation will needa cyber-capable citizenry -- Americans well prepared to be savvy consumers and users of IT and,with advanced education and training, to generate the discoveries, inventions, and creative ideasthat will propel U.S. innovation in an increasingly competitive global economy. In the NITRD vision,cyber capabilities and tools will be applied to provide learners at every level with rich and excitingknowledge environments informed by the science of learning, tailored to individual needs, andguided by educators with theoretical and practical IT knowledge. The cyber-capable society willthus require an education and training system that can deliver world-class preparation in computerscience and other science disciplines, technology, engineering, and mathematics.Following are the key elements of this vision and the major research challenges to be met in each.WorkforceA Workforce of Cyber Innovators_b3defeda-e784-11df-a5d3-6a0c7a64ea2a3.1A Workforce of Cyber Innovators -- Tomorrow’s workforce will have to be agile, adaptable, well educated and trained, and able to keeplearning continuously to take maximum advantage of technological advances and contribute toAmerican innovation. This applies not only to cyber professionals, who even today struggle to staycurrent with their rapidly changing and advancing field, but to professional and technical workers inevery sector.Where we are now -- a 2009 study conducted for the NITRD Program notes that two IT-relatedoccupations -- network systems and data communications analyst, and computer applicationssoftware engineer -- are among the five fastest-growing in the U.S. economy, and the only two of thefive to require a college degree. According to the Bureau of Labor Statistics (BLS) projections reportedin the study, the professional and technical workforce in networking and computing should expandby more than 1.2 million, or 24 percent, to 3.5 million between 2006 and 2016. The professional/technical workforce over all is expected to grow by 17 percent over the same period. Projections thatinclude IT-related jobs that do not necessarily require a college degree (such help desk specialists,electronic records processors, tellers, etc.) double the size of the IT workforce in 2016. By contrast, thenumber of computer science and electrical engineering degrees at all levels has been declining since2004, as has the percentage of degree holders who are U.S. citizens or residents. Government andprivate-sector employers alike report difficulty finding people with the requisite IT skills.Labor market projections for the IT workforce, however, do not capture the reality that a very broadrange of occupations increasingly involves applications that require IT knowledge and skills. Norcan statistical projections serve as a guide for assessing the adequacy of the educational system toprepare a workforce that leads the world in advanced innovation.Research and education needs -- information technologies are interdependent and are developedfrom an inherently multidisciplinary basis in the sciences and in engineering. Building systemsand large-scale applications takes teamwork across diverse technologies and academic fields.Moreover, IT capabilities are used in a wide variety of social contexts that IT professionals also needto understand in order to create and use applications effectively. For example, in the 1990’s the lackof professionals trained in both computer science and biology prompted National Institute of Health(NIH) to establish the Nation’s first graduate fellowship programs in bio-informatics; as a result, suchtraining is now part of the curriculum at many graduate and medical schools.The PCAST argued in its 2007 NITRD review that the traditional disciplinary stovepipes of theformal educational system present a substantial barrier to development of diversified, broadlyinterdisciplinary new generations of cyber innovators.22 We need advances in thinking about how toorganize education and training curricula and experiences, particularly at the postsecondary level,to help students develop the intellectual capacity to synthesize knowledge from multiple disciplinesand work collaboratively on complex interdisciplinary problems, whether the setting is IT foradvanced manufacturing or for a regional social services delivery system.Education and Training[Develop] advances in thinking about how to organize education and training curricula and experiences, particularly at the postsecondary level, to help students develop the intellectual capacity to synthesize knowledge from multiple disciplines and work collaboratively on complex interdisciplinary problems, whether the setting is IT for advanced manufacturing or for a regional social services delivery system._b3df05ec-e784-11df-a5d3-6a0c7a64ea2a3.1.1Information technologies are interdependent and are developed from an inherently multidisciplinary basis in the sciences and in engineering. Building systems and large-scale applications takes teamwork across diverse technologies and academic fields. Moreover, IT capabilities are used in a wide variety of social contexts that IT professionals also need to understand in order to create and use applications effectively. For example, in the 1990’s the lack of professionals trained in both computer science and biology prompted NIH to establish the Nation’s first graduate fellowship programs in bio-informatics; as a result, such training is now part of the curriculum at many graduate and medical schools. The PCAST argued in its 2007 NITRD review that the traditional disciplinary stovepipes of the formal educational system present a substantial barrier to development of diversified, broadly interdisciplinary new generations of cyber innovators.EducationThe Education of Cyber-Capable Citizens_b3df0cfe-e784-11df-a5d3-6a0c7a64ea2a3.2The Education of Cyber-Capable Citizens -- Many scientists believe that our society will benefit when K-12 students gain a better understandingof how digital technologies work and how to use their applications safely and wisely. Innovation inseveral dimensions of education could accelerate this process: employing learning technologies in allgrades and subjects; incorporating “computational thinking” -- the concepts, mathematics, and logicof digital processes -- throughout the formal curriculum at all levels; and expanding outreach effortsto raise public awareness and better inform people of all ages about best practices for IT users.Where we are now -- early IT educational applications offered mainly reading lessons or “skill anddrill” testing; emerging science-based knowledge about learning (e.g., its neural basis, psychologicaltheories of knowing, and biologically inspired learning algorithms) is informing the developmentof more sophisticated learning technologies. In addition, precollegiate educators could exploit thetypes of computational resources that have transformed the conduct of science and engineering(e.g., authentic and realistic data, digital telescopes, immersive environments, mobile and portabledevices, modeling and simulation capabilities, sensor networks, and remote instruments) totransform classroom learning. Deploying such approaches widely will require educators able to applyIT expertise to subject-matter pedagogy.Today, however, according to computer science (CS) experts who spoke at a NITRD strategic planningpublic forum in 2008, the K-12 curriculum in computer science is extremely limited, mainly focusedon beginning programming at the senior-high level. The Computer Science Teachers Association hasreported that the proportion of high schools offering an introductory CS course dropped from 78percent in 2005 to 69 percent in 2011; only 36 percent offered an Advanced Placement (AP) coursein 2011, and about 11 percent of AP test takers were CS students.23 As The Washington Post noted,“It would be hard to find a student… who has never used the Internet for a research assignment,socialized with Facebook, or played a video game. But few know much about how computers and theWeb actually work.”Accordingly, NSF has initiated programs to: 1) recruit 10,000 skilled CS teachers for schools andtransform the CS curriculum; 2) introduce computational thinking into STEM education at alllevels; and 3) create a new conceptual framework bringing together the fields of pedagogy andlearning science. But this work is just beginning. An Administration initiative coordinated by theNational Institute of Standards and Technology (NIST) is launching a multi-pronged educationaleffort specifically targeting cybersecurity, with the goals of increasing public awareness; expandingcybersecurity education and training at all levels; recruiting skilled cybersecurity workers for Federalmissions; and boosting cybersecurity training for Federal employees.28 Many NITRD agencies, suchas the Department of Energy/Office of Science (DOE/SC), NASA, NOAA, and the National ScienceFoundation (NSF), sponsor a variety of educational activities and Web materials for schools related totheir scientific missions.Research and education needs -- developing the cyber-capable society will require ongoingadvances in all the areas discussed. Public awareness and education reform take time, persistence,sustained coordination of efforts, and high-visibility support in every sector. A great nationalchallenge, similar to winning the space race in the 1960s, may also be needed to focus the attentionof students, parents, educators, and the public at large on the strategic importance of IT knowledgeand skills for economic and scientific innovation, and on IT capabilities to advance education at alllevels.Multi-Faceted Advances[Pursue] advances in all the areas discussed. Public awareness and education reform take time, persistence, sustained coordination of efforts, and high-visibility support in every sector._b3df15e6-e784-11df-a5d3-6a0c7a64ea2a3.2.1IT Knowledge and SkillsFocus the attention of students and their parents, educators, and the public at large on the strategic importance of acquiring IT knowledge and skills._b3df1e4c-e784-11df-a5d3-6a0c7a64ea2a3.2.2StudentsParentsEducatorsThe PublicTechnologiesTechnologies To Empower 21st Century Learning_b3df25c2-e784-11df-a5d3-6a0c7a64ea2a3.3Technologies to Empower 21st Century Learning -- In the NITRD vision, IT capabilities yet to be invented will play as critical a role in education as existingIT capabilities already play in advanced scientific discovery. Today’s notions of “learning technologies”will give way to concepts informed by new knowledge about the bio-chemistry of the human brainand about how the human mind develops and acquires, stores, and uses information in perceiving,thinking, and acting. Such advances in neuroscience, and parallel gains in educational and socialscienceresearch as well as in machine intelligence, will provide a basis for learning systems tailored toindividuals at every stage of cognitive development.The personalized learning system might, for example, constantly capture and update all knowledgeabout how individuals best learn and retain information and operationalize that knowledge in cybertools customized for each learner. A set of cyber tools covering all domains of knowledge would bemade widely available. The key aspect of these advanced cyber technologies would be their ability,through interactions with a specific individual, to adaptively recognize that person’s particularcharacteristics as a learner and adjust the learning experience accordingly. Teachers could spendmore time coaching and counseling individuals and leading hands-on activities.Where we are now -- while most U.S. schools have computers and Internet connectivity, theavailability of this infrastructure for teaching varies widely by school district and type of classroom.The increasing number of professional organizations of teacher educators and practicing teachersinterested in using technology indicates growing awareness of the IT potential, and schools ofeducation have incorporated IT in teacher training. Nonetheless, the K-12 system generally lags inmaking effective use of digital capabilities.Research and education needs -- to realize the NITRD vision, fundamental explorations of thebasis and processes of human learning should be pursued aggressively. As noted elsewhere in thisplan, expanded understanding of how the mind works is a prerequisite for building smarter, morecapable digital machines. In the context of education, new multidisciplinary knowledge abouthuman cognition and development likewise will be the basis for designing revolutionary learningenvironments that meet the needs of individuals, whatever their location, age, socio-economic status,or educational level. These systems will become possible through technical advances in such areas asartificial intelligence, human-machine interfaces, visualization and virtual reality technologies, dataanalytics, compute power, networking, and distributed systems. Educators appropriately equipped towork with technologies for learning will also be necessary.Human LearningAgresssively pursue fundamental explorations of the basis and processes of human learning should be pursued aggressively._b3df2ee6-e784-11df-a5d3-6a0c7a64ea2a3.3.1As noted elsewhere in this plan, expanded understanding of how the mind works is a prerequisite for building smarter, more capable digital machines.Learning EnvironmentsDesign revolutionary learning environments that meet the needs of individuals, whatever their location, age, socioeconomic status, or educational level._b3df3634-e784-11df-a5d3-6a0c7a64ea2a3.3.2These systems will become possible through technical advances in such areas as artificial intelligence, human-machine interfaces, visualization and virtual reality technologies, data analytics, compute power, networking, and distributed systems.Educators[Develop] new generations of educators appropriately equipped to work with technologies for learning._b3df3d1e-e784-11df-a5d3-6a0c7a64ea2a3.3.3Educators2012-08-312012-11-09http://www.nitrd.gov/pubs/strategic_plans/2012_NITRD_Strategic_Plan.pdfOwenAmburOwen.Ambur@verizon.net