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    Area of Science:

    • Nanoelectronics
    • Neuromorphic Computing
    • Nonvolatile Memory

    Background:

    • Floating-gate devices offer potential for analog and mixed-signal neuromorphic computing.
    • Previous practical implementations were limited by large cell sizes.
    • Optimized embedded nonvolatile floating-gate cells are key to overcoming these limitations.

    Purpose of the Study:

    • To report a prototype neuromorphic network utilizing highly optimized floating-gate cells.
    • To demonstrate the feasibility of compact and efficient neuromorphic hardware.
    • To evaluate the performance of the network on a standard benchmark.

    Main Methods:

    • Redesigning cells from a commercial 180-nm NOR flash memory.
    • Fabricating a $28 imes 28$ binary-input, ten-output, three-layer neuromorphic network.
    • Testing the network's classification fidelity, speed, and energy efficiency.

    Main Results:

    • Achieved 94.7% classification fidelity on the Modified National Institute of Standards and Technology benchmark.
    • Demonstrated sub-1-$\mu$s classification time and sub-20-nJ energy consumption per pattern.
    • The entire circuit occupies less than 1 mm².

    Conclusions:

    • The prototype demonstrates a significant advancement in neuromorphic computing hardware.
    • The optimized floating-gate cells enable high performance in a compact area.
    • Future technology scaling promises substantial improvements in speed and energy efficiency.