Neural State Machines for Robust Learning and Control of Neuromorphic Agents
Mixed-signal analog/digital neuromorphic circuits are characterized by ultra-low power consumption, real-time processing abilities, and low-latency response times. These features make them promising for robotic applications that require fast and power-efficient computing. However, due to the device...
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| Veröffentlicht in: | IEEE journal on emerging and selected topics in circuits and systems 2019-12, Vol.9 (4), p.679-689 |
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| container_title | IEEE journal on emerging and selected topics in circuits and systems |
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| creator | Liang, Dongchen Kreiser, Raphaela Nielsen, Carsten Qiao, Ning Sandamirskaya, Yulia Indiveri, Giacomo |
| description | Mixed-signal analog/digital neuromorphic circuits are characterized by ultra-low power consumption, real-time processing abilities, and low-latency response times. These features make them promising for robotic applications that require fast and power-efficient computing. However, due to the device mismatch and variability present in these circuits, developing architectures that can perform complex computations in a robust and reproducible manner is quite challenging. In this paper, we present a spiking neural network architecture implemented using these neuromorphic circuits, that enables reliable control of an autonomous agent as well as robust learning and recognition of visual patterns in a noisy real-world environment. While learning is implemented with a software algorithm running with a chip-in-the-loop setup, the inference and motor control processes are implemented exclusively by the neuromorphic processor, situated on the neuromorphic agent. In addition to this processor device, the agent comprises a dynamic vision sensor which produces spikes as it interacts with the environment in real-time. We show how the robust learning and reliable control properties of the system arise out of a recently proposed neural computational primitive denoted as Neural State Machine (NSM). We describe the features of the NSMs used in this context and demonstrate the agent's real-time robust perception and action behavior with experimental results. |
| doi_str_mv | 10.1109/JETCAS.2019.2951442 |
| format | Article |
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These features make them promising for robotic applications that require fast and power-efficient computing. However, due to the device mismatch and variability present in these circuits, developing architectures that can perform complex computations in a robust and reproducible manner is quite challenging. In this paper, we present a spiking neural network architecture implemented using these neuromorphic circuits, that enables reliable control of an autonomous agent as well as robust learning and recognition of visual patterns in a noisy real-world environment. While learning is implemented with a software algorithm running with a chip-in-the-loop setup, the inference and motor control processes are implemented exclusively by the neuromorphic processor, situated on the neuromorphic agent. In addition to this processor device, the agent comprises a dynamic vision sensor which produces spikes as it interacts with the environment in real-time. We show how the robust learning and reliable control properties of the system arise out of a recently proposed neural computational primitive denoted as Neural State Machine (NSM). 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| subjects | Algorithms Analog circuits Circuit reliability Low-power electronics Machine learning Microprocessors Network architecture Neural networks Neuromorphic computing Neuromorphics noisy spiking neural networks Object recognition Power consumption Reagents Real time Real-time systems Robotics Robust control robust object recognition self-supervised learning State machines ultra-low-power |
| title | Neural State Machines for Robust Learning and Control of Neuromorphic Agents |
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