Accurate and Efficient Event-based Semantic Segmentation Using Adaptive Spiking Encoder-Decoder Network

Low-power event-driven computation and inherent temporal dynamics render spiking neural networks (SNNs) ideal candidates for processing highly dynamic and asynchronous signals from event-based sensors. However, due to the challenges in training and architectural design constraints, there is a scarcity of competitive demonstrations of SNNs in event-based dense prediction compared to artificial neural networks (ANNs). In this work, we construct an efficient spiking encoder-decoder network for large-scale event-based semantic segmentation tasks, optimizing the encoder with hierarchical search. To improve learning from highly dynamic event streams, we exploit the intrinsic adaptive threshold of spiking neurons to modulate network activation. Additionally, we develop a dual-path spiking spatially-adaptive modulation (SSAM) block to enhance the representation of sparse events, significantly improving network performance. Our network achieves 72.57% mean intersection over union (MIoU) on the DDD17 dataset and 57.22% MIoU on the newly proposed larger DSEC-Semantic dataset, surpassing current record ANNs by 4% while utilizing much lower computation costs. To the best of our knowledge, this is the first instance of SNNs outperforming ANNs in challenging event-based semantic segmentation tasks, demonstrating their immense potential in event-based vision. Our code will be publicly available.