Making non-volatile nanomagnet logic non-volatile

Making non-volatile nanomagnet logic non-volatile

Field-coupled nanomagnets can offer significant energy savings at iso-performance versus CMOS equivalents. Magnetic logic could be integrated with CMOS, operate in environments that CMOS cannot, and retain state without power. Clocking requirements lead to inherently pipelined circuits, and high thr...

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Bibliographische Detailangaben
Hauptverfasser: Dingler, Aaron, Kurtz, Steve, Niemier, Michael, Hu, Xiaobo Sharon, Csaba, Gyorgy, Nahas, Joseph, Porod, Wolfgang, Bernstein, Gary, Li, Peng, Sankar, Vjiay Karthik
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Circuit stability
Clocks
Hardware > Hardware validation
Hardware > Integrated circuits > Logic circuits > Finite state machines
Logic gates
Magnetic devices
Magnetization
MQCA
Nanomagnet logic
nanotechnology
NML
Stability analysis
Thermal stability
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Beschreibung
Zusammenfassung:Field-coupled nanomagnets can offer significant energy savings at iso-performance versus CMOS equivalents. Magnetic logic could be integrated with CMOS, operate in environments that CMOS cannot, and retain state without power. Clocking requirements lead to inherently pipelined circuits, and high throughput further improves application-level performance. However, bit conflicts -- that will occur in defect free, pipelined ensembles -- can make non-volatile logic volatile. Assuming a field-based clock, we present hardware designs to improve steady state non-volatility, and explain how design enhancements could increase clock energy. We then suggest materials-related design levers that could simultaneously deliver non-volatility and low clock energy.
ISSN:0738-100X
DOI:10.1145/2228360.2228445