Defense Advanced Research Projects AgencyTagged Content List

Information Microsystems

Relating to computer and other digital electronic systems

Showing 5 results for Microsystems + Quantum RSS
Since its inception in 1991, DARPA’s Microsystems Technology Office (MTO) has been working to create and prevent strategic surprise through investments in compact microelectronic components such as microprocessors, microelectromechanical systems (MEMS), and photonic devices. MTO-derived innovations and advanced capabilities in areas such as wide-band gap materials, phased-array radars, high-energy lasers, and infrared imaging have helped the United States establish and maintain technological superiority for more than two decades.
Constantly losing energy is something we deal with in everything we do. If you stop pedaling a bike, it gradually slows; if you let off the gas, your car also slows. As these vehicles move, they also generate heat from friction. Electronics encounter a similar effect as groups of electrons carry information from one point to another. As electrons move, they dissipate heat, reducing the distance a signal can travel. DARPA-sponsored researchers under the Mesodynamic Architectures (Meso) program, however, may have found a potential way around this fundamental problem.
DARPA published its Young Faculty Award (YFA) 2018 Research Announcement today, seeking proposals in 26 different topic areas—the largest number of YFA research areas ever solicited.
Precise timing is essential across DoD systems, including communications, navigation, electronic warfare, intelligence systems reconnaissance, and system-of-systems platform coordination, as well as in national infrastructure applications in commerce and banking, telecommunications, and power distribution. Improved clock performance throughout the timing network, particularly at point-of-use, would enable advanced collaborative capabilities and provide greater resilience to disruptions of timing synchronization networks, notably by reducing reliance on satellite-based global navigation satellite system (GNSS) timing signals.
The Mesodynamic Architectures (Meso) program seeks to address future Defense needs by exploiting unique characteristics of matter and energy emerging at small spatial and short temporal scales including new states of matter, untapped forces, novel relationships between fields and excitations and the importance of noise and nonlinearity. The parallel goals of the Meso program are to provide DoD with unrivaled communication, sensing, and computation by exploiting mesoscale characteristics, while establishing well-defined problems to accelerate the transition to quantum engineering.