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Flexible Artificial Sensory Systems Based on Neuromorphic Devices.

Fuqin Sun1,2, Qifeng Lu1, Simin Feng1

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Flexible artificial sensory systems with neuromorphic electronics offer low-power, high-efficiency data processing. This review highlights advances in artificial synapses and their integration into intelligent perception systems.

Keywords:
artificial nerveartificial sensory systemsbioinspired devicesflexiblelow power consumptionmemristorneuromorphic devicessynaptic transistor

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Area of Science:

  • Neuromorphic electronics
  • Flexible artificial sensory systems
  • Artificial synapses

Background:

  • Neuromorphic electronics offer a promising solution for processing large datasets with minimal energy consumption.
  • Developing artificial sensory systems that mimic biological sensing and processing requires effective synaptic devices and sensing elements.

Purpose of the Study:

  • To review recent advancements in neuromorphic electronics for flexible artificial sensory systems.
  • To focus on artificial synapses, their structures, mechanisms, functions, and integration into intelligent perception systems.
  • To examine challenges and opportunities in flexible artificial perception systems and propose solutions.

Main Methods:

  • Review of recent progress in artificial synapse development, including device structures and mechanisms.
  • Analysis of intelligent, flexible perception system designs utilizing synaptic devices.
  • Examination of the coupling efficiency between sensing elements and synaptic devices.

Main Results:

  • Significant progress has been made in developing artificial flexible synapses with low power consumption and high-density integration capabilities.
  • Efficient coupling between sensing elements and synaptic devices is crucial for high-efficiency neuromorphic sensory systems.
  • Recent advances cover device structures, mechanisms, and functions of artificial synapses.

Conclusions:

  • Flexible artificial sensory systems based on neuromorphic electronics are essential for efficient, low-power data processing.
  • Continued development of artificial synapses and their integration is key to realizing advanced artificial perception systems.
  • Addressing challenges in device design and system integration will drive future opportunities in this field.