Three-Terminal Ovonic Threshold Switch (3T-OTS) with Tunable Threshold Voltage for Versatile Artificial Sensory Neurons.
Hyejin LeeSeong Won ChoSeon Jeong KimJaesang LeeKeun Su KimInho KimJong-Keuk ParkJoon Young KwakJaewook KimJongkil ParkYeonJoo JeongGyu Weon HwangKyeong-Seok LeeDaniele IelminiSuyoun LeePublished in: Nano letters (2022)
Inspired by information processing in biological systems, sensor-combined edge-computing systems attract attention requesting artificial sensory neurons as essential ingredients. Here, we introduce a simple and versatile structure of artificial sensory neurons based on a novel three-terminal Ovonic threshold switch (3T-OTS), which features an electrically controllable threshold voltage ( V th ). Combined with a sensor driving an output voltage, this 3T-OTS generates spikes with a frequency depending on an external stimulus. As a proof of concept, we have built an artificial retinal ganglion cell (RGC) by combining a 3T-OTS and a photodiode. Furthermore, this artificial RGC is combined with the reservoir-computing technique to perform a classification of chest X-ray images for normal, viral pneumonia, and COVID-19 infections, releasing the recognition accuracy of about 86.5%. These results indicate that the 3T-OTS is highly promising for applications in neuromorphic sensory systems, providing a building block for energy-efficient in-sensor computing devices.
Keyphrases
- spinal cord
- sars cov
- deep learning
- coronavirus disease
- machine learning
- single cell
- magnetic resonance imaging
- high resolution
- mesenchymal stem cells
- stem cells
- mass spectrometry
- magnetic resonance
- cell therapy
- health information
- respiratory failure
- contrast enhanced
- energy transfer
- community acquired pneumonia
- water quality