Defense Advanced Research Projects AgencyTagged Content List


Compatible interconnection of disparate components and systems

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With the official roll out of the Electronics Resurgence Initiative’s latest investments today, DARPA hopes to open new innovation pathways to address impending engineering and economics challenges that, if left unanswered, could challenge what has been a relentless half-century run of progress in microelectronics technology. To maintain healthy forward momentum, the ERI over the next four years will commit hundreds of millions of dollars to nurture research in advanced new materials, circuit design tools, and system architectures. In addition to a half-dozen or so existing DARPA programs, and the largest program in the U.S. that funds basic electronics research at universities, 
The growing complexity of space operations coupled with an increased need for timely decisions demands innovative approaches to battle management command and control (BMC2) technologies. To help ensure future U.S. technological and strategic superiority, DARPA’s Hallmark program seeks to develop revolutionary tools and technologies to plan, assess, and execute U.S. military operations in space. The program has completed initial research and awarded Phase 1 contracts to 11 organizations, which both augment existing commercial technologies and pursue entirely new capabilities. Hallmark has released a Broad Agency Announcement seeking additional technologies for potential inclusion.
The microelectronics community is facing an array of long foreseen obstacles to Moore’s Law, the transistor scaling that has allowed for 50 years of rapid progress in electronics. Current economic, geopolitical, and physics-based complications make the future of the electronics industry uniquely interesting at this moment. To jump-start innovation in the field, DARPA announced in June 2017 that it would coalesce a broad series of programs into the Electronics Resurgence Initiative (ERI).
Only a few decades ago, finding a particular channel on the radio or television meant dialing a knob by hand, making small tweaks and adjustments to hone in on the right signal. Of course, we now take such fine tuning for granted, simply pressing a button to achieve the same effect. This convenience is enabled by radio frequency synthesis, the generation of accurate signal frequencies from a single reference oscillator.
Chemical innovation plays a key role in developing cutting-edge technologies for the military. Research chemists design and synthesize new molecules that could enable a slew of next-generation military products, such as novel propellants for spacecraft engines; new pharmaceuticals and medicines for troops in the field; lighter and longer-lasting batteries and fuel cells; advanced adhesives, coatings and paints; and less expensive explosives that are safer to handle. The problem, however, is that existing molecule design and production methods rely primarily on experts’ intuition in a laborious, trial-and-error research process.