Superyolo: Super Resolution Assisted Object Detection in Multimodal Remote Sensing Imagery

IF 0.5 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Journal of Electrical Systems Pub Date : 2024-05-13 DOI:10.52783/jes.3664

Syam Sundar, Dr. B. Chaitanya Krishna, Dr. B. Chaitanya

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引用次数: 0

Abstract

Finding small things quickly and correctly in remote sensing pictures (RSI) is very hard because you need to use strong feature extraction and complex deep neural networks need a lot of computing power. The study introduces SuperYOLO, a novel approach to identifying objects that seeks to achieve a good combination of speed and accuracy in RSI analysis. SuperYOLO uses a multimodal data fusion method to combine information from different data sources in a way that makes it better at finding small items in RSI. This multimodal fusion (MF) process is both symmetric and compact, which makes it easy to combine data. SuperYOLO has an enhanced super-resolution (SR) learning branch in addition to MF. This SR branch lets the model make high-resolution (HR) feature representations, which lets it tell small items apart from the background when the input is low-resolution (LR). This makes recognition much more accurate without adding too much work to the computer. One great thing about SuperYOLO is that the SR branch is only used during training and is thrown away during inference. This method reduces the need for extra computing power, making sure that object recognition works quickly and efficiently. When tested on the well-known VEDAI RS dataset, SuperYOLO does better at accuracy than cutting-edge models like YOLOv5l, YOLOv5x, and YOLOrs. Additionally, SuperYOLO gets this level of accuracy while greatly lowering the model's parameter size and processing needs. Compared to YOLOv5x, SuperYOLO has 18 times fewer parameters and 3.8 times fewer GFLOPs. To sum up, SuperYOLO makes a strong case for choosing between accuracy and speed when it comes to finding small objects in RSI. The model does a better job than other options because it combines multimodal data fusion with assisted SR learning in a way that makes it more efficient and less complicated to use. This big step forward could have big effects in areas like remote sensing, where finding small things accurately is important for many jobs.

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Superyolo：多模态遥感图像中的超分辨率辅助物体检测

在遥感图片（RSI）中快速、正确地找到小东西非常困难，因为需要使用强大的特征提取，而复杂的深度神经网络需要大量的计算能力。本研究介绍了一种新颖的物体识别方法--SuperYOLO，它力求在 RSI 分析中实现速度和准确性的良好结合。SuperYOLO 采用多模态数据融合方法，将来自不同数据源的信息以一种能更好地在 RSI 中找到小物品的方式结合起来。这种多模态融合（MF）过程既对称又紧凑，因此很容易进行数据组合。除 MF 外，SuperYOLO 还有一个增强的超分辨率（SR）学习分支。该 SR 分支可让模型建立高分辨率（HR）特征表征，从而在输入为低分辨率（LR）时将小物件与背景区分开来。这使得识别更加准确，同时又不会给计算机增加太多工作。SuperYOLO 的一大优点是，SR 分支只在训练时使用，在推理时会被丢弃。这种方法减少了对额外计算能力的需求，确保物体识别快速高效地运行。在著名的 VEDAI RS 数据集上进行测试时，SuperYOLO 的准确性优于 YOLOv5l、YOLOv5x 和 YOLOrs 等尖端模型。此外，SuperYOLO 在获得这一精度水平的同时，还大大降低了模型的参数大小和处理需求。与 YOLOv5x 相比，SuperYOLO 的参数减少了 18 倍，GFLOPs 减少了 3.8 倍。总之，在寻找 RSI 中的小物体时，SuperYOLO 在精度和速度之间做出了有力的选择。该模型比其他方案做得更好，因为它将多模态数据融合与辅助 SR 学习相结合，使用起来更高效、更简单。这一重大进步可能会在遥感等领域产生重大影响，因为在这些领域，准确地找到小物体对许多工作都很重要。

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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来源期刊

Journal of Electrical Systems ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

1.10

自引率

25.00%

发文量

审稿时长

10 weeks