基于最粗优势木胸径生长的湖南栎类天然林立地质量评价模型

doi:10.11707/j.1001-7488.20220809

Abstract

Abstract:

Objective: This study was carried out to analyze the effects of site factors on the DBH growth of the thickest dominant tree in the stand, construct a growth model of the dominant tree in Hunan Quercus natural forests with the mixed effects of site types and derive a site quality evaluation model based on the DBH of the thickest dominant tree as an indicator. The site quality evaluation equation was expected to propose a new method for the site quality evaluation of Quercus natural forests. Method: This paper took Hunan Quercus natural forests as the research objects. Based on the measured data of 51 plots, the site factors those having significant impacts on the growth of the dominant woods at breast height were selected by the quantitative method Ⅰ, and the site factors were classified and combined according to the standard. The initial site type, through the R language, the DBH-age of the dominant tree in the natural Quercus forests in Hunan was fitted, the optimal basic model was screened, and the initial site type was added as a random effect to the basic model to construct a mixed effect model. The k-means was used to gather the class clusters the initial site types with similar effects to form a site type group, and it was added as a random effect to the optimal basic model to construct a mixed-effect model containing the site type group. By derivative, the site quality evaluation model was obtained, and the analysis of variance was used to verify the significant relationships between forest stand area and site index. Result: The site factors those having significant effects on the growth of the thickest dominant tree diameter at breast height were altitude, slope gradient, slope position, and slope aspect. The order of significance was altitude>slope gradient>slope aspect>slope position. Four theoretical growth equations were selected for fitting, and the coefficient of determination of the model was about 0.7. The optimal basic model was the Richards model, and the coefficient of determination R² was 0.731 8, the mean absolute error (MAE) was 5.442 6, the root mean square error (RMSE) was 6.879 1, and the expression equation was D=a×[1-exp(-c×AGE)]^b.By combining the selected four significant site factors to form the initial site type and adding it to the basic model to construct a mixed effect model with site types, the determination coefficient (R²) was increased to 0.9016. The k-means clustering was used to cluster the initial site types into 6 site type groups, which were added to the basic model as a random effect, the optimal model expression equation was D_j=a_j×[1-exp(-c×AGE)]^b+ε, the model's determination coefficient (R²) was increased to 0.924 4, which was 26.7% higher than that of the basic model, whereas both AIC and BIC were reduced. By plotting a polymorphic site index curve based on a mixed effect model containing site type groups, the site quality evaluation equation of Hunan Quercus natural forests, based on site classification with the dominant wood diameter at breast height as the evaluation index, was derived as SQEI_M-DBH=a_j×[1-exp(-0.03×AGE₀)]^$\left\{\frac{\ln D_j}{\ln a_j \times[1-\exp (-0.03 \times \mathrm{AGE})]}\right\}$+ε, and through the stand-off area verification, the site index SQEI_M-DBH obtained in this study was significantly related to the stand-off area. Conclusion: Site factors might have a significant impact on the growth of the diameter at breast height of the Quercus in Hunan Province. It could be theoretically feasible to evaluate the site quality of natural Quercus forests and to predict the productivity of the natural forests based on the diameter of the thickest dominant wood as an indicator, which was expected to provide a way for the evaluation of site quality of natural forests.

Key words: Quercus natural forest, the thickest dominant tree, DBH growth, mixed effect, site quality evaluation model

CLC Number:

S757

Jing He,Xinjian Li,Jinmei Zhu,Guangyu Zhu. Site Quality Evaluation Model of Natural Quercus Forests in Hunan Based on the Growth of the Thickest Dominant Tree Diameter at Breast Height[J]. Scientia Silvae Sinicae, 2022, 58(8): 89-98.

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References 0

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变量	最小值	最大值	平均值	标准差
Variable	Minimum value	Maximum value	Average value	Standard deviation
优势木胸径DBH/cm	11.5	70.0	33.2	13.4
优势木树高Tree height/m	10.6	28.4	17.4	3.6
年龄Age/a	23	155	61.8	26.6
海拔Altitude/m	80	1 638	806	545.9
坡度Slope gradient/(°)	11	45	30	9.3
栎类树种组成系数Composition coefficient of oak species	5	10	6.6	1.5
株树密度Density/(tree·hm^-2)	722	4 118	1 528.6	824.3
断面积Basal area/(m²·hm^-2)	14.3	59.4	30.1	10.6

模型	模型名称	模型表达式	参数
Model	Model name	Model expression	Parameter
M1	Logistic	D=a/[(1+b×exp(-c×AGE)]	a, b, c>0
M2	Mitscherlich	D=a×[1-exp(-b×AGE)]	a, b>0
M3	Compertz	D=a×exp[-b×exp(-c×AGE)]	a, b, c>0
M4	Richards	D=a×[1－exp(-c×AGE)]^b	a, b, c>0

调查因子 Investigation factor	符号 Symbol	等级划分 Grade division
海拔Altitude	ALT	200 m为一级，共7级With 200 m as one level, a total of seven levels
坡度Slope gradient	SLO	5°~14°	15°~24°	25°~34°	35°~44°	≥45°
坡位Slope position	SP	脊部Ridge part	上坡Upslope	中坡Mesoslope	下坡Downslope
坡向 Slope aspect	SA	阳坡 Sunny slope	半阳坡 Half-sunny slope	阴坡 Shady slope	半阴坡 Half-shady slope
土壤类型Soil types	TL	黄壤Yellow soil	黄棕壤Yellow brown soil

因子组	平方和	自由度	均方	F	Pr＞F
Factor group	Sum of squares	Degree of freedom	Mean square	F	Pr＞F
海拔Altitude	7 599.981 6	6	1 266.663 6	22.966 6	0.0001
坡度Slope gradient	1 193.981 2	4	298.495 3	5.412 2	0.000 4
坡位Slope position	979.346 1	3	326.448 7	3.042 4	0.046 5
坡向Slope aspect	1 125.054 7	3	375.018 2	3.057 6	0.038 8
土壤类型Soil types	153.558 9	1	153.558 9	1.252 0	0.269 7

模型	模型名称	参数	参数值	确定系数	平均绝对误差	均方根误差
Model	Model name	Parameters	Values	R²	MAE	RMSE
M1	Logistic	a	76.566	0.723 7	5.702 4	7.051 4
		b	5.346
		c	0.022 8
M2	Mitscherlich	a	94.817 9	0.727 6	5.582 5	6.942 1
M2	Mitscherlich	b	0.007 3	0.727 6	5.582 5	6.942 1
M3	Compertz	a	87.757 9	0.726 1	5.637 0	7.021 1
		b	2.176 2
		c	0.013 2
M4	Richards	a	134.7	0.731 8	5.442 6	6.879 1
		b	0.720 1
		c	0.002 5

Site Quality Evaluation Model of Natural Quercus Forests in Hunan Based on the Growth of the Thickest Dominant Tree Diameter at Breast Height

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样地号 Sample No.	因子等级Factor levels				初始立地类型 Initial site type	立地类型组合 Site type group
样地号 Sample No.	海拔Altitude	坡向Slope aspect	坡度Slope gradient	坡位Slope position	初始立地类型 Initial site type	立地类型组合 Site type group
1	5	4	2	2	5 422	6
2	5	2	2	2	5 222	6
3	5	2	2	2	5 222	6
4	5	4	3	2	5 432	6
5	5	3	3	2	5 332	4
6	5	4	2	2	5 422	6
7	5	2	3	2	5 232	6
8	5	2	4	2	5 242	3
9	5	4	4	2	5 442	2
10	5	3	4	2	5 342	5
…	…	…	…	…	…
50	1	4	4	4	1 444	4
51	2	4	3	4	2 434	3

模型	随机效应构造	最优参数组合	参数	参数值	AIC	BIC	Loglik	R²
Model	Random effect structure	Optimal combination	Parameters	Values	AIC	BIC	Loglik	R²
M4	无None	无None	a	134.7	349.43	357.16	-170.72	0.731 8
			b	0.720 1
			c	0.002 5
M4.1	初始立地类型 Initial site type	a	a	48.369 2	319.62	328.28	-159.81	0.901 6
			b	1.786 6
			c	0.030 0

聚类数 Cluster numbers	精度 Precision	立地类型 Site type	样本量 Sample size
1	0	Ⅰ	2
2	63.9	Ⅱ	6
3	81.1	Ⅲ	15
4	88.6	Ⅳ	11
5	93.9	Ⅴ	9
6	96.4	Ⅵ	8

模型Model	立地类型组 Site type group	a	b	c	AIC	BIC	Loglik	R²	MAE	RMSE
M4.2	1	68.228 2	1.786 6	0.030 0	313.280 8	322.939 9	-151.640 4	0.926 9	2.881 2	3.598 5
	2	60.293 6
	3	53.715 3
	4	46.628 8
	5	42.393 8
	6	33.280 9

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