Quantized Coconut Detection Models with Edge Devices

J. Interconnect. Networks Pub Date : 2022-02-09 DOI:10.1142/s0219265921440102

V. Joshi, Jeena Thomas, Ebin Deni Raj

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引用次数: 1

Abstract

Coconut is a multipurpose fruit with high economic value and since it is unique to the landscape of Kerala, it plays an important role in the economy of the state. Skilled labour is one of the key components in coconut farming and lack of its availability can hurt its business. Even if this requirement is met, currently practiced traditional methods for plucking the fruit requires the labour to climb the tree which involves a huge risk factor given the height of the tree they have to scale. There are tools that assist in the climb but they can only reduce the risk factor by a small margin. Robotic harvesting is one of the key solutions to the aforementioned problem as it has the ability to perform accurate coconut plucking since it relies on cutting edge object detection modules, it can provide deep insights into the quality of coconuts to be yielded and also excel at working in remote conditions. The primary aim of this paper is to cover the development of a fast as well as accurate perception module for detection of coconuts, which will serve as a strong foundation for any robotic implementation. In this study we try to explore and compare multiple deep learning based object detection frameworks such as Single Shot Detector and YOLO for efficient and accurate deployment on various edge devices like Raspberry Pi and Nvidia jetson nano by using state of the art methods such as quantization aware training, inference accelerators, multiple augmentation strategies (cutmix, mosaic) for best results. We have also curated a novel, manually annotated dataset of drone based coconut videos (effective/usable content of 30 minutes) in order to capture the naturally setting of coconuts i.e. the true distribution of image data containing background noises, occlusion, shadow as well as natural lighting conditions. The peak performance achieved in our study was a frame rate of 12.7 with a mean average precision of 0.4 by using a tiny YOLOv4 on an Nvidia Jetson Nano.

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带有边缘器件的量化椰子检测模型

椰子是一种具有高经济价值的多用途水果，由于它是喀拉拉邦独特的景观，它在该州的经济中起着重要作用。熟练劳动力是椰子种植的关键组成部分之一，缺乏熟练劳动力可能会损害其业务。即使满足了这一要求，目前采用的传统采摘方法也需要劳动力爬上树，考虑到他们必须爬上的树的高度，这涉及到巨大的风险因素。有一些工具可以帮助攀爬，但它们只能在很小的范围内减少风险因素。机器人收割是上述问题的关键解决方案之一，因为它有能力进行准确的椰子采摘，因为它依赖于尖端的物体检测模块，它可以深入了解要生产的椰子的质量，也擅长在偏远条件下工作。本文的主要目的是开发一种快速而准确的椰子检测感知模块，这将为任何机器人实现奠定坚实的基础。在本研究中，我们尝试探索和比较多个基于深度学习的目标检测框架，如Single Shot Detector和YOLO，通过使用最先进的方法，如量化感知训练、推理加速器、多种增强策略(cutmix、mosaic)，在各种边缘设备(如Raspberry Pi和Nvidia jetson nano)上高效准确地部署，以获得最佳结果。我们还策划了一个新颖的，手动注释的无人机椰子视频数据集(30分钟的有效/可用内容)，以捕捉椰子的自然环境，即包含背景噪声，遮挡，阴影以及自然光照条件的图像数据的真实分布。在我们的研究中，通过在Nvidia Jetson Nano上使用微型YOLOv4，实现的峰值性能是帧率为12.7，平均精度为0.4。

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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J. Interconnect. Networks

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