ELECTRONICS TECHNOLOGY

Abstract

This program element is budgeted in the Applied Research budget activity because its objective is to develop electronics that make a wide range of military applications possible. Advances in microelectronic device technologies, including digital, analog, photonic and MicroElectroMechanical Systems (MEMS) devices, continue to have significant impact in support of defense technologies for improved weapons effectiveness, improved intelligence capabilities and enhanced information superiority. The Electronics Technology program element supports the continued advancement of these technologies through the development of performance driven advanced capabilities, exceeding that available through commercial sources, in electronic, optoelectronic and MEMS devices, semiconductor device design and fabrication techniques, and new materials and material structures for device applications. A particular focus for this work is the exploitation of chip-scale heterogeneous integration technologies that permit the optimization of device and integrated module performance. The phenomenal progress in current electronics and computer chips will face the fundamental limits of silicon technology in the early 21st century, a barrier that must be overcome in order for progress to continue. Another thrust of the program element will explore alternatives to silicon-based electronics in the areas of new electronic devices, new architectures to use them, new software to program the systems, and new methods to fabricate the chips. Approaches include nanotechnology, nanoelectronics, molecular electronics, spin-based electronics, quantum-computing, new circuit architectures optimizing these new devices, and new computer and electronic systems architectures. Projects will investigate the feasibility, design, and development of powerful information technology devices and systems using approaches for electronic device designs that extend beyond traditional Complementary Metal Oxide Semiconductor (CMOS) scaling, including non silicon-based materials technologies to achieve low cost, reliable, fast and secure computing, communication, and storage systems. This investigation is aimed at developing new capabilities from promising directions in the design of information processing components using both inorganic and organic substrates, designs of components and systems leveraging quantum effects and chaos, and innovative approaches to computing designs incorporating these components for such applications as low cost seamless pervasive computing, ultra-fast computing, and sensing and actuation devices. This project has five major thrusts: Electronics, Photonics, MicroElectroMechanical Systems, Architectures, Algorithms, and other Electronic Technology research.

Document Details

Document Type

R2 Budgetary Justification

Publication Date

Oct 01, 2015

Source ID

0602716E_2_0400_PB_2015

Change Summary Explanation

FY 2013: Decrease reflects Congressional reductions for Sections 3001 & 3004 and directed reductions, sequestration adjustments, and the SBIR/STTR transfer offset by reprogrammings. FY 2014: Decrease reflects a reduction for program growth. FY 2015: Decrease reflects drawdown of several efforts prior to transition: Adaptive RF Technology, NEXT, Micro PNT, Microscale Power Conversion and POEM.

Service Agency Name

Defense Advanced Research Projects Agency

Entities

Tags

Related Documents

• Child Project: ELECTRONICS TECHNOLOGY
• Child Accomplishment: Terahertz Electronics
• Child Accomplishment: Adaptive Radio Frequency Technology (ART)
• Child Accomplishment: Nitride Electronic NeXt-Generation Technology (NEXT)
• Child Accomplishment: Diverse & Accessible Heterogeneous Integration (DAHI)
• Child Accomplishment: Micro-Technology for Positioning, Navigation, and Timing (Micro PN&T)
• Child Accomplishment: Microscale Plasma Devices (MPD)
• Child Accomplishment: IntraChip Enhanced Cooling (ICECool)
• Child Accomplishment: In vivo Nanoplatforms (IVN)
• Child Accomplishment: Pixel Network (PIXNET) for Dynamic Visualization
• Child Accomplishment: Arrays at Commercial Timescales (ACT)
• Child Accomplishment: Micro-coolers for Focal Plane Arrays (MC-FPA)
• Child Accomplishment: Vanishing Programmable Resources (VAPR)
• Child Accomplishment: Gargoyle
• Child Accomplishment: Cold-Atom Microsystems (CAMS)
• Child Accomplishment: Direct SAMpling Digital ReceivER (DISARMER)
• Child Accomplishment: Fast and Big Mixed-Signal Designs (FAB)
• Child Accomplishment: Microscale Power Conversion (MPC)
• Child Accomplishment: Photonically Optimized Embedded Microprocessor (POEM)
• Child Accomplishment: Advanced X-Ray Integrated Sources (AXIS)
• Child Accomplishment: Quantum Information Science (QIS)
• Child Accomplishment: Systems of Neuromorphic Adaptive Plastic Scalable Electronics (SyNAPSE)
• Child Accomplishment: Self-HEALing mixed-signal Integrated Circuits (HEALICs)
• Child Accomplishment: Efficient Linearized All-Silicon Transmitter ICs (ELASTx)
• Child Accomplishment: Analog-to-Information (A-to-I) Look-Through
• Child Accomplishment: Advanced Wide FOV Architectures for Image Reconstruction & Exploitation (AWARE)