基于MWFCNet的树木根区相对介电常数反演

doi:10.11707/j.1001-7488.LYKX20240801

摘要/Abstract

摘要：

目的: 针对树木根区探地雷达（GPR）检测图像复杂、解译困难以及反演精度低等问题，提出一种基于偏移权值指导的改进全卷积神经网络（MWFCNet）的树木根区相对介电常数反演方法，实现树木根区地下相对介电常数环境的高精度反演重建，为树木根系无损检测和根域土壤环境探测提供一种高效、可靠的技术手段，为树木?土壤介电环境相互作用机制的深入研究提供新的工具和方法。方法: 以成熟三倍体毛白杨根区环境为研究对象，利用开源软件gprMax生成GPR B-scan仿真模拟样本，结合CycleGAN实现样本风格迁移，构建3 000对GPR B-scan与对应测线剖面二维相对介电常数模型的训练样本；为解决反演网络对背景介质反演效果不佳的问题，在输入模块中引入GPR偏移图像序列及其对应的偏移权值序列，构建一个以编码器?解码器为主干的网络架构，采用2种不同卷积尺寸并行处理，并通过跳跃连接实现特征图像的多尺度特征提取；应用全连接层进一步整合图像特征，增强特征表达能力，进而输出所测根区地下二维相对介电常数模型。选取结构相似度指数（SSIM）、峰值信噪比（PSNR）和均方误差（MSE）作为GPR反演效果的评价指标，背景方差作为对背景介质还原程度的评价指标。结果: 相较于现有的Enc-Dec、U-net、PInet等方法，在对相同测试集的反演上，MWFCNet方法的SSIM提高0.11%~3.23%，MSE提升0.11~0.73，PSNR提升0.31~5.83 dB；在对背景介质还原程度上，MWFCNet方法的背景方差下降0.035~0.15。结论: 基于MWFCNet的树木根区相对介电常数反演方法能够精准识别出树木粗根位置，实现对GPR测线剖面地下相对介电常数图谱的二维重建还原，结合GPR采样方式还可实现对根区地下三维相对介电环境的重建还原。

关键词: 基于偏移权值指导的改进全卷积神经网络（MWFCNet）, 相对介电常数, 树木根区, 探地雷达, B-scan图像反演

Abstract:

Objective: To address the problems of complex detection images with ground penetrating radar (GPR), difficult interpretation, and low inversion accuracy in tree root zone, an improved fully convolutional networks (MWFCNet) based on migration weight guidance is proposed to invert the relative dielectric constant of tree root zone, achieving high-precision inversion and reconstruction of the underground relative dielectric constant environment in tree root zone, providing an efficient and reliable technical means for non-destructive testing of tree roots and detection of root zone soil environment, aiming to provide new tools and methods for in-depth research on the interaction mechanism between trees and soil dielectric environment. Method: The mature triploid Populus tomentosa root zone environment was taken as the research object. The open source software gprMax was used to generate GPR B-scan simulation samples, and combining CycleGAN to achieve sample style transfer, and construct 3 000 pairs of training samples for GPR B-scan and corresponding two-dimensional relative dielectric constant models of measurement line profiles. To solve the problem of poor inversion performance of background media by inversion networks, GPR migration image sequences and their corresponding migration weight sequences were introduced into the input module, and a network architecture with encoder decoder as the backbone was constructed. Two different convolution sizes were used for parallel processing, and multi-scale feature extraction of feature images was achieved through skip connections. The image features were further integrated with fully connected layers to enhance feature expression ability, and output a two-dimensional relative dielectric constant model of the measured root zone underground. Structural similarity index (SSIM) was selected, peak signal to noise ratio (PSNR), and mean squared error (MSE) were used as evaluation indicators for GPR inversion performance, and background variance was used as an evaluation indicator for the degree of background medium restoration. Result: Compared with existing methods such as Enc-Dec, U-net, PInet, etc., the MWFCNet method improved SSIM by 0.11%?3.23%, MSE by 0.11?0.73, and PSNR by 0.31?5.83 dB in the inversion of the same test set. In the restoration of the background medium, the background variance of the MWFCNet method decreased by 0.035?0.15. Conclusion: The MWFCNet based method for inverting the relative dielectric constant of tree roots can accurately identify the position of thick roots of trees, and also achieve two-dimensional reconstruction and restoration of the underground relative dielectric constant map of GPR survey lines. Combined with GPR sampling method, it can reconstruct and restore the three-dimensional relative dielectric environment of the root zone underground.

Key words: improved fully convolutional neural network based on migration weight (MWFCNet), relative dielectric constant, tree root zone, ground penetrating radar, B-scan image inversion

中图分类号:

S757
TP79

覃荣翰,樊国秋,韩巧玲,郑一力,徐吉臣,梁浩. 基于MWFCNet的树木根区相对介电常数反演[J]. 林业科学, 2026, 62(1): 109-121.

Ronghan Qin,Guoqiu Fan,Qiaoling Han,Yili Zheng,Jichen Xu,Hao Liang. Inversion of Relative Dielectric Constant of Tree Root Zone Based on MWFCNet[J]. Scientia Silvae Sinicae, 2026, 62(1): 109-121.

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模块名称 Module name	层名称 Layer name	块名称 Block name	卷积核 Kernel	步长 Stride	输入尺度 Input size	输出尺度 Output size
输入模块 Input	INPUT	—	—	—	—	(1, 512, 200)
	F-K	—	—	—	(1, 512, 200)	(15, 512, 200)
	GV	—	—	—	(15, 512, 200)	(1, 15)
	GVReshape	—	—	—	(1, 15)	(15, 1, 1)
	CBAM	—	—	—	(15, 512, 200) (15, 1, 1)	(15, 512, 200)
	B0	Conv Block 0	(3, 3)	(2, 2)	(15, 512, 200)	(16, 512, 200)
编码模块 Encoder	B1	Conv Block 1 Conv Block 3	(3, 1) (3, 3) (7, 1) (3, 3)	(2, 1) (1, 1) (2, 1) (1, 1)	(16, 512, 200)	(16, 256, 200)
	B2	Conv Block 2 Conv Block 4	(3, 1) (3, 3) (7, 1) (3, 3)	(2, 2) (1, 1) (2, 2) (1, 1)	(16, 256, 200)	(32, 128, 100)
	B3	Conv Block 2 Conv Block 4	(3, 1） (3, 3) (7, 1) (3, 3)	(2, 2） (1, 1) (2, 2) (1, 1)	(32, 128, 100)	(64, 64, 50)
	B4	Conv Block 2 Conv Block 4	(3, 1) (3, 3) (7, 1) (3, 3)	(2, 2) (1, 1) (2, 2) (1, 1)	(64, 64, 50)	(128, 32, 25)
	B5	Conv Block 2 Conv Block 4	(3, 1) (3, 3） (7, 1) (3, 3)	(2, 2) (1, 1） (2, 2) (1, 1)	(128, 32, 25)	(256, 16, 13)
特征提取模块 Feature extraction	Flatten	—	—	—	(256, 16, 13)	(256, 16×13)
	LSTM	—	—	—	(256, 16×13)	(256, 16×13)
	FC1	—	—	—	(256, 16×13)	(256, 1024)
	FC2	—	—	—	(256, 1024)	(256, 512)
	FC3	—	—	—	(256, 512)	(256, 256)
	FC4	—	—	—	(256, 256)	(256, 128)
	FC5	—	—	—	(256, 128)	(256, 64)
	FC6	—	—	—	(256, 64)	(256, 8×7)
	Unflatten	—	—	—	(256, 8×7)	(256, 8, 7)
解码模块 Decoder	B6	DeConv Block 1	(3, 3) (3, 3)	(2, 2) (1, 1)	(256, 8, 7) (256, 16, 13)	(256, 16, 13)
	B7	DeConv Block 2	(3, 3) (3, 3)	(2, 2) (1, 1)	(256, 16, 13) (128, 32, 25)	(128, 32, 25)
	B8	DeConv Block 2	(3, 3) (3, 3)	(2, 2) (1, 1)	(128, 32, 25) (64, 64, 50)	(64, 64, 50)
	B9	DeConv Block 2	(3, 3) (3, 3)	(2, 2) (1, 1)	(64, 64, 50) (32, 128, 100)	(32, 128, 100)
	B10	DeConv Block 2	(3, 3) (3, 3)	(2, 2) (1, 1)	(32, 128, 100) (16, 256, 200)	(16, 256, 200)
输出模块 Output	B11	Conv Block 5	(3, 3)	(2, 2)	(16, 256, 200)	(1, 512, 400)
	B12	Interpolation	—	—	(1, 512, 400)	(1, 350, 500)
	OUTPUT	—	—	—	(1, 350, 500)	—

方案序号 Scheme No.	模型 Model	训练时间 Training time	SSIM	PSNR/dB	MSE	VAR_background
1	Enc-Dec	66 min 4 s	0.989 1	24.324 4	0.132 3	0.101 1
2	Enc-Dec-SC	81 min 15 s	0.991 3	25.451 2	0.108 5	0.066 7
3	DPEnc-Dec-SC	123 min 8 s	0.991 4	25.639 3	0.107 4	0.058 5
4	DPEnc-FC-Dec-SC	124 min 22 s	0.993 3	25.175 2	0.118 3	0.089 7
5	FK-DPEnc-FC-Dec-SC	135 min 31 s	0.995 3	26.168 3	0.088 0	0.027 3
6	MWFCNet	137 min 25 s	0.996 5	26.535 0	0.075 8	0.009 0

方案序号 Scheme No.	模型 Model	训练时间 Training time	SSIM	PSNR/dB	MSE	VAR_background
1	Enc-Dec (Alvarez et al.，2018)	77 min 15 s	0.964 8	15.508 0	1.006 7	0.158 5
2	FCNVMB (Yang et al.，2019)	81 min 7 s	0.997 8	21.022 0	0.265 1	0.077 6
3	PINet (Ji et al.，2021)	86 min 44 s	0.996 0	19.941 0	0.287 1	0.042 7
4	MWFCNet	137 min 25 s	0.997 1	21.335 0	0.276 4	0.007 3

损失函数Loss function	训练时间Training time	SSIM	PSNR/dB	MSE
loss_MSE	37 min 21 s	0.992 5	21.934 0	0.269 8
loss_DSSIM	32 min 50 s	0.298 5	0.290 0	33.200 3
loss_DSSIM+MSE	29 min 54 s	0.996 8	22.617 0	0.248 6

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