A crop’s spectral signature is worth a compressive text

IF 7.7 1区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Computers and Electronics in Agriculture Pub Date : 2024-11-04 DOI:10.1016/j.compag.2024.109576

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引用次数: 0

Abstract

The accuracy of crop mapping based on remotely sensed hyperspectral imagery has been significantly improved through the use of deep learning. However, traditional deep learning can be computationally intensive, requiring millions of parameters, which can make it ‘expensive’ to deploy and optimize. Inspired by studies in natural language processing, we consider the spectral signature corresponding to each pixel as text. Specifically, we first feed the hyperspectral image (HSI) data into the Channel2Vec module to generate channel embeddings. Based on the channel embeddings, we use a lossless compressor and Normalized Compression Distance (NCD) to create a spectral tokenizer. It can segment the spectral signature corresponding to each pixel into multiple windows along the channel dimension, and then extract local sequence information from each window. By combining the local sequence information with the original HSI data, we construct spectral embeddings. Finally, we again use the lossless compressor to compute the NCD between the spectral embeddings, and then classify using only the

k

-nearest-neighbor classifier (

k

NN). The proposed framework is ready-to-use and lightweight. Without any training, it achieves results competitive with deep learning models on three benchmark datasets. It outperforms the average of 11 advanced deep learning methods trained at scale. Moreover, it outperforms more than half of these models in the few-shot scenario, where there are not enough labels to effectively train a neural network.

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作物的光谱特征值得压缩文本

通过使用深度学习，基于遥感高光谱图像的作物测绘精度得到了显著提高。然而，传统的深度学习计算密集，需要数百万个参数，因此部署和优化成本 "昂贵"。受自然语言处理研究的启发，我们将每个像素对应的光谱特征视为文本。具体来说，我们首先将高光谱图像（HSI）数据输入 Channel2Vec 模块，生成通道嵌入。在通道嵌入的基础上，我们使用无损压缩器和归一化压缩距离（NCD）来创建光谱标记器。它可以将每个像素对应的光谱特征沿信道维度分割成多个窗口，然后从每个窗口中提取局部序列信息。通过将局部序列信息与原始 HSI 数据相结合，我们构建了光谱嵌入。最后，我们再次使用无损压缩器计算光谱嵌入之间的 NCD，然后仅使用 k-nearest-neighbor 分类器（kNN）进行分类。所提出的框架是即用型和轻量级的。无需任何训练，它就能在三个基准数据集上取得与深度学习模型相当的结果。它的表现优于经过大规模训练的 11 种高级深度学习方法的平均水平。此外，在没有足够标签来有效训练神经网络的 "少数几个镜头 "场景中，它的表现优于一半以上的模型。

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

Computers and Electronics in Agriculture 工程技术-计算机：跨学科应用

CiteScore

15.30

自引率

14.50%

发文量

800

审稿时长

62 days

期刊介绍： Computers and Electronics in Agriculture provides international coverage of advancements in computer hardware, software, electronic instrumentation, and control systems applied to agricultural challenges. Encompassing agronomy, horticulture, forestry, aquaculture, and animal farming, the journal publishes original papers, reviews, and applications notes. It explores the use of computers and electronics in plant or animal agricultural production, covering topics like agricultural soils, water, pests, controlled environments, and waste. The scope extends to on-farm post-harvest operations and relevant technologies, including artificial intelligence, sensors, machine vision, robotics, networking, and simulation modeling. Its companion journal, Smart Agricultural Technology, continues the focus on smart applications in production agriculture.