东北地区落叶松人工林生物量转换与扩展因子空间自回归模型

doi:10.11707/j.1001-7488.20211005

摘要/Abstract

摘要：

目的: 基于东北地区落叶松人工林森林资源连续清查固定样地数据，探讨生物量转换与扩展因子（BCEF）的最优模型形式，建立落叶松人工林BCEF空间自回归模型，为生物量精准估算提供模型支撑和依据。方法: 选择多种模型形式建立BCEF普通回归模型，从中选择拟合效果最好的模型，运用空间误差模型（SEM）和空间滞后模型（SLM）2种空间自回归方法重新拟合模型，采用决定系数（R²）、均方根误差（RMSE）和相对均方根误差（rRMSE）对模型进行评价，使用莫兰指数（MI）检验各变量和BCEF模型残差的空间自相关性。结果: 1）BCEF存在明显的空间自相关性，空间距离较小时，同一省内的落叶松人工林BCEF属性相似，随着空间距离增大，各省之间的BCEF属性差异逐渐体现出来，最终趋向随机分布；2）在普通回归模型中，异速生长模型、对数模型和双曲线模型拟合效果较好，不同自变量对应的最优模型形式不同；林分平方平均直径（D_g）是解释能力最高的变量，以D_g为自变量的有效模型的R²在0.945~0.958之间；其次是林分平均高和蓄积量，其有效模型的R²在0.60以上；林分平均年龄的解释能力略低，其有效模型的R²仅0.50左右；林分断面积（BA）和密度（N）对BCEF的解释能力较差，R²均不超过0.50；以D_g为自变量的普通回归模型的残差存在明显空间自相关性；3）以D_g为自变量的双曲线空间自回归模型最优，且SEM优于SLM，与对应普通回归模型相比，SEM的R²提高3%，RMSE和rRMSE分别降低33%和35%，模型残差的MI不超过0.02，可较好消除空间自相关性。结论: 双曲线是BCEF最稳定的模型形式，D_g是解释BCEF的最优变量，建议采用以D_g为预测变量的双曲线函数空间误差模型估算BCEF。

关键词: 生物量转换与扩展因子, 空间自回归模型, 林分平方平均胸径, 落叶松人工林

Abstract:

Objective: Based on the national forest inventory sample plot data of larch plantation in northeast China, the best model form of biomass conversion and expansion factor(BCEF) were discussed, and the spatial autoregressive BCEF model was established for larch plantation in northeast China. The model is useful for accurate stand biomass estimations. Method: Selecting a variety of model forms to establish BCEF general regression model, from which the best fitting model is selected. The two spatial autoregressive methods, spatial error model(SEM) and spatial lag model(SLM), were used to renew the BCEF model. The determination coefficient(R²), root mean square error (RMSE) and relative root mean square error(rRMSE) were used to evaluate the model. Moran index(MI) was applied to test the spatial autocorrelation of all variables and BCEF model residuals. Result: 1) There is obvious spatial autocorrelation in BCEF data. When the spatial distance is small, the BCEF attributes of stands within a province are similar. The differences of BCEF attributes among provinces are gradually appeared with the increase of spatial distance, and tend to random distribution finally. 2) The fitting results of allometric model, logarithmic model and hyperbolic model are better than those of other regression models, and the optimal models varied with independent variables. Stand quadratic mean diameter (D_g) is the best variable for interpreting BCEF. The R² of the effective model with D_g as an independent variable is between 0.945 and 0.958. Followed by stand mean height(H) and volume(V), the R² of the effective model is more than 0.60. The explanatory ability of stand average age is slightly lower than that of D_g, H and V, and the R² of its effective model is only about 0.50. Stand basal area(BA) and density(N) are poorly to explain the variance of BCEF with R² less than 0.50. The residuals of the general regression model showed spatial autocorrelation. 3) The spatial autoregressive model of hyperbolic function with D_g as an independent variable is the best one with SEM better than SLM. Compared with the corresponding ordinary regression model, the R² of SEM is increased by 3%, and the RMSE and rRMSE are reduced by 33% and 35%, respectively. The MI of the model residual is less than 0.02, which eliminates the spatial autocorrelation. Conclusion: The hyperbolic model is the most stable model for BCEF, and D_g is the best independent variable. It is recommended to adopt the hyperbolic function with the inclusion of spatial error model and with D_g as the predictor to estimate BCEF.

Key words: biomass conversion and expansion factors(BCEF), spatial autoregressive model, stand quadratic mean diameter, larch plantations

中图分类号:

S757

何潇,雷相东. 东北地区落叶松人工林生物量转换与扩展因子空间自回归模型[J]. 林业科学, 2021, 57(10): 49-58.

Xiao He,Xiangdong Lei. Spatial Autoregressive Biomass Conversion and Expansion Factor Models for Larch Plantations in Northeast China[J]. Scientia Silvae Sinicae, 2021, 57(10): 49-58.

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变量Variables	平均值Mean	最大值Max.	最小值Min.	变异系数CV(%)
生物量转换与扩展因子Biomass conversion and expansion factors(BCEF)/(mg·m^-³)	0.77	0.81	0.74	1.70
林分蓄积Volume(V)/(m³·hm^-2)	85.22	299.32	4.23	63.75
林分平方平均直径Quadratic mean diameter(D_g)/cm	12.40	26.40	5.70	33.66
林分断面积Basal area(BA)/(m²·hm^-2)	11.65	34.60	0.81	55.48
林分平均高Mean height(H)/m	11.90	24.00	3.50	35.16
林分密度Density(N)/(tree·hm^-2)	1 020.00	3 600.00	250.00	56.00
林分平均年龄Mean age(Age)/a	25.00	52.00	8.00	38.26

模型名称Model name	模型表达式Model expression
异速生长模型Allometric model	lnBCEF= a+b×ln X+ε
指数模型Exponential model	lnBCEF= a+b×X+ε
对数模型Logarithmic model	BCEF= a+b×ln X+ε
双曲线模型Hyperbolic model	BCEF= a+b/X+ε
S形曲线模型S-shaped model	1/BCEF= a+b×exp(- X) +ε

模型形式 Model function	序号 Number	自变量 Independent variable	参数Parameters		R²	RMSE/(mg·m^-³)	rRMSE(%)
模型形式 Model function	序号 Number	自变量 Independent variable	a	b	R²	RMSE/(mg·m^-³)	rRMSE(%)
异速生长模型 Allometric model： lnBCEF= a+b×ln X+ε	1	V	-0.188^***	-0.016^***	0.603	0.008	1.07
	2	D_g	-0.133^***	-0.050^***	0.958	0.003	0.35
	3	BA	-0.219^***	-0.017^***	0.473	0.010	1.23
	4	H	-0.165^***	-0.038^***	0.710	0.007	0.91
	5	N	-0.326^***	0.010^***	0.103	0.012	1.61
	6	Age	-0.158^***	-0.032^***	0.543	0.009	1.15
指数模型 Exponential model： lnBCEF= a+b×X+ε	7	V	-0.237^***	-2.324E-4^***	0.555	0.009	1.13
	8	D_g	-0.209^***	-3.872E-3^***	0.907	0.004	0.52
	9	BA	-0.237^***	-1.686E-3^***	0.415	0.010	1.30
	10	H	-0.216^***	-3.456E-3^***	0.719	0.007	0.90
	11	N	-0.267^***	9.749E-6^***	0.106	0.012	1.61
	12	Age	-0.224^***	-1.303E-3^***	0.524	0.009	1.17
对数模型 Logarithmic model： BCEF= a+b×ln X+ε	13	V	0.827^***	-0.013^***	0.604	0.008	1.07
	14	D_g	0.869^***	-0.039^***	0.957	0.003	0.35
	15	BA	0.803^***	-0.013^***	0.474	0.010	1.23
	16	H	0.844^***	-0.029^***	0.712	0.007	0.91
	17	N	0.721^***	0.008^***	0.100	0.012	1.61
	18	Age	0.850^***	-0.024^***	0.543	0.009	1.15
双曲线模型 Hyperbolic model： BCEF= a+b/X+ε	19	V	0.767^***	0.298^***	0.397	0.010	1.32
	20	D_g	0.735^***	0.431^***	0.945	0.003	0.40
	21	BA	0.766^***	0.056^***	0.364	0.010	1.36
	22	H	0.749^***	0.258^***	0.632	0.008	1.03
	23	N	0.781^***	-5.360^***	0.079	0.013	1.63
	24	Age	0.751^***	0.474^***	0.511	0.009	1.19
S形曲线模型 S-shaped model: 1/BCEF= a+b×exp(- X) +ε	25	V	1.293^***	-5.972^***	0.031	0.013	1.67
	26	D_g	1.298^***	-31.389^***	0.414	0.010	1.30
	27	BA	1.296^***	-0.200^***	0.204	0.012	1.52
	28	H	1.295^***	-3.274^***	0.152	0.012	1.56
	29	N	1.293^***	-1.517E+7	0.004	0.013	1.69
	30	Age	1.294^***	-204.884^*	0.069	0.013	1.64

模型形式 Model function	序号 Number	SAR模型 SAR model	参数Parameters		滞后参数 Lag parameter	R²	RMSE/(mg·m^-3)	rRMSE(%)
模型形式 Model function	序号 Number	SAR模型 SAR model	a	b	滞后参数 Lag parameter	R²	RMSE/(mg·m^-3)	rRMSE(%)
异速生长模型 Allometric model	31	ESM	-0.133^***	-0.050^***	λ= -142.780^***	0.980	0.002	0.24
异速生长模型 Allometric model	32	LSM	-0.204	-0.050^***	ρ= -0.277	0.958	0.003	0.35
对数模型 Logarithmic model	33	ESM	0.870^***	-0.039^***	λ= -142.070^***	0.980	0.002	0.24
对数模型 Logarithmic model	34	LSM	1.097^***	-0.039^***	ρ= -0.293	0.957	0.003	0.35
双曲线模型 Hyperbolic model	35	ESM	0.737^***	0.413^***	λ= -150.940^***	0.976	0.002	0.26
双曲线模型 Hyperbolic model	36	LSM	1.199^***	0.433^***	ρ= -0.599^***	0.945	0.003	0.40

模型 Model	序号 Number	SAR模型 SAR model	参数Parameters				滞后参数 Lag parameter	R²	RMSE/(mg·m^-3)	rRMSE(%)
模型 Model	序号 Number	SAR模型 SAR model	a	b	c	d	滞后参数 Lag parameter	R²	RMSE/(mg·m^-3)	rRMSE(%)
BCEF= a+b/D_g+ c/H	37	SEM	0.736^***	-0.436^***	-0.019^***	—	λ= -151.280^***	0.978	0.002	0.26
BCEF= a+b/D_g+ c/H	38	SLM	1.220^***	0.456^***	-0.020^***	—	ρ= -0.628^**	0.947	0.003	0.39
BCEF= a+b/D_g + c/Age	39	SEM	0.737^***	-0.419^***	-0.012	—	λ= -150.620^***	0.976	0.002	0.26
BCEF= a+b/D_g + c/Age	40	SLM	1.194^***	0.438^***	-0.001	—	ρ= -0.593	0.946	0.003	0.40
BCEF= a+b/H+c/Age	41	SEM	0.748^***	0.112^***	0.308^***	—	λ= -182.050^***	0.907	0.004	0.52
BCEF= a+b/H+c/Age	42	SLM	0.342	0.187^***	0.205^***	—	ρ= -0.523	0.682	0.007	0.96
BCEF= a+b/D_g +c/ H+d/Age	43	SEM	0.736^***	0.437^***	-0.019^***	-0.004	λ= -150.230^***	0.977	0.002	0.26
BCEF= a+b/D_g +c/ H+d/Age	44	SLM	1.219^***	0.457^***	-0.020^***	-0.002	ρ= -0.626^**	0.947	0.003	0.39