Litcius/Paper detail

One-dimensional organic artificial multi-synapses enabling electronic textile neural network for wearable neuromorphic applications

Seonggil Ham, Minji Kang, Seonghoon Jang, Jingon Jang, Sanghyeon Choi, Tae‐Wook Kim, Gunuk Wang

2020Science Advances175 citationsDOIOpen Access PDF

Abstract

One-dimensional (1D) devices are becoming the most desirable format for wearable electronic technology because they can be easily woven into electronic (e-) textile(s) with versatile functional units while maintaining their inherent features under mechanical stress. In this study, we designed 1D fiber-shaped multi-synapses comprising ferroelectric organic transistors fabricated on a 100-μm Ag wire and used them as multisynaptic channels in an e-textile neural network for wearable neuromorphic applications. The device mimics diverse synaptic functions with excellent reliability even under 6000 repeated input stimuli and mechanical bending stress. Various NOR-type textile arrays are formed simply by cross-pointing 1D synapses with Ag wires, where each output from individual synapse can be integrated and propagated without undesired leakage. Notably, the 1D multi-synapses achieved up to ~90 and ~70% recognition accuracy for MNIST and electrocardiogram patterns, respectively, even in a single-layer neural network, and almost maintained regardless of the bending conditions.

Topics & Concepts

Neuromorphic engineeringMNIST databaseArtificial neural networkWearable computerComputer scienceMaterials scienceWearable technologyBendingTransistorTextileSynapseArtificial intelligenceNanotechnologyElectrical engineeringEmbedded systemNeuroscienceEngineeringComposite materialVoltageBiologyAdvanced Sensor and Energy Harvesting MaterialsAdvanced Memory and Neural ComputingConducting polymers and applications