SpikiLi: A Spiking Simulation of LiDAR based Real-time Object Detection for Autonomous Driving

2022 8th International Conference on Event-Based Control, Communication, and Signal Processing (EBCCSP) Pub Date : 2022-06-06 DOI:10.1109/EBCCSP56922.2022.9845647

S. Mohapatra, Thomas Mesquida, Mona Hodaei, S. Yogamani, H. Gotzig, Patrick Mäder

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Abstract

Spiking Neural Networks are a recent and new neural network design approach that promises tremendous improvements in power efficiency, computation efficiency, and processing latency. They do so by using asynchronous spike-based data flow, event-based signal generation, processing, and modifying the neuron model to resemble biological neurons closely. While some initial works have shown significant initial evidence of applicability to common deep learning tasks, their applications in complex real-world tasks have been relatively low. In this work, we first illustrate the applicability of spiking neural networks to a complex deep learning task, namely LiDAR based 3D object detection for automated driving. Secondly, we make a step-by-step demonstration of simulating spiking behavior using a pre-trained Convolutional Neural Network. We closely model essential aspects of spiking neural networks in simulation and achieve equivalent run-time and accuracy on a GPU. We expect significant improvements in power efficiency when the model is implemented on neuromorphic hardware.

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SpikiLi:基于激光雷达的自动驾驶实时目标检测的峰值仿真

脉冲神经网络是一种最新的神经网络设计方法，它承诺在功率效率、计算效率和处理延迟方面有巨大的改进。他们通过使用基于异步尖峰的数据流、基于事件的信号生成、处理和修改神经元模型来接近生物神经元来实现这一目标。虽然一些初步的工作已经显示出对普通深度学习任务的适用性，但它们在复杂的现实世界任务中的应用相对较低。在这项工作中，我们首先说明了尖峰神经网络在复杂深度学习任务中的适用性，即基于激光雷达的自动驾驶3D物体检测。其次，我们使用预训练的卷积神经网络逐步演示模拟尖峰行为。我们在仿真中密切模拟了峰值神经网络的基本方面，并在GPU上实现了等效的运行时间和精度。当该模型在神经形态硬件上实现时，我们期望能显著提高功率效率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 8th International Conference on Event-Based Control, Communication, and Signal Processing (EBCCSP)

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