Abstract
The processing of large amounts of data requires a high energy efficiency and fast processing time for high-performance computing systems. However, conventional von Neumann computing systems have performance limitations because of bottlenecks in data movement between separated processing and memory hierarchy, which causes latency and high power consumption. To overcome this hindrance, logic-in-memory (LIM) has been proposed that performs both data processing and memory operations. Here, we present a NAND and NOR LIM composed of silicon nanowire feedback field-effect transistors, whose configuration resembles that of CMOS logic gate circuits. The LIM can perform memory operations to retain its output logic under zero-bias conditions as well as logic operations with a high processing speed of nanoseconds. The newly proposed dynamic voltage-transfer characteristics verify the operating principle of the LIM. This study demonstrates that the NAND and NOR LIM has promising potential to resolve power and processing speed issues.
Highlights
The processing of large amounts of data requires a high energy efficiency and fast processing time for high-performance computing systems
New emerging resistance-based memory (RRAM, phase-change memory (PCM), and STT-MRAM) has a non-volatile memory (NVM) capability, and LIM based on resistance-based memory has been presented[19–24]
We propose a NAND and NOR LIM composed of silicon nanowire (SiNW) feedback field-effect transistors (FBFETs) to verify universal gate functions, where the configuration of the SiNW FBFETs maintains conventional CMOS logic gates
Summary
The processing of large amounts of data requires a high energy efficiency and fast processing time for high-performance computing systems. Conventional von Neumann computing systems have performance limitations because of bottlenecks in data movement between separated processing and memory hierarchy, which causes latency and high power consumption. To overcome this hindrance, logic-in-memory (LIM) has been proposed that performs both data processing and memory operations. The PCM-based LIM has a low write speed (~ 50 ns) compared to other memory devices due to the switching between crystalline and amorphous phases, and a comparatively high operating voltage (< 3 V)[26]. Resistance-based memory requires new fabrication processes and new materials (not based on CMOS fabrication technology), and it is not yet mature enough to be available for commercial technology/products[18,28]
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