Developing Aerial Stand Volume Tables Based on Laser Scanning Data for Forest Region of Northeast China

doi:10.13466/j.cnki.lyzygl.2021.01.019

Abstract

Abstract:

Based on the airborne laser scanning(ALS) data and field measurement data of 1 947 sample plots distributed across the spruce & fir(Picea spp.& Abies spp.),larch(Larix spp.),Mongolian scotch pine(Pinus sylvestris var mongolica),Korean pine(Pinus koraiensis),oak(Quercus spp.),birch(Betula spp.),poplar(Populus spp.),elm(Ulmus spp.),linden(Tilia spp.),and other three precious broadleaved species(Fraxinus mandshurica,Juglans mandshurica & Phellodendron amurense) forest stands in Northeast China,the stand volume regression models were developed through multiple linear regression and nonlinear regression methods,and the base regression model was determined with comparison and analysis.Then,the integrated stand volume models with stand type-specific parameters and the same ALS variables were developed,using the dummy variable modeling approach.The results showed that multiple linear volume regression models developed in this study for the 10 stand types have 2~7 explainable variables and the coefficients of determination(R ²) are between 0.460~0.858;and the nonlinear models have 2~4 explainable variables and the R ² are between 0.461~0.846.The two-variable nonlinear volume models based on mean height and mean intensity of point clouds are defined as standard volume models,of which the R ² are between 0.440~0.815,the mean prediction errors(MPEs) are between 2.88%~4.42%,and the mean percent standard errors(MPSEs) are between 16.76%~25.52%,which almost meet the need for precision requirements of the regulation on forest management inventory.According to the stand volume models developed in this study for 10 forest types,aerial stand volume tables based on ALS data can be established,which may be applied in forest management inventory.

Key words: airborne laser scanning, linear model, nonlinear model, dummy variable model, stand volume table

CLC Number:

TP79

ZENG Weisheng, SUN Xiangnan, WANG Liuru, WANG Wei, PU Ying. Developing Aerial Stand Volume Tables Based on Laser Scanning Data for Forest Region of Northeast China[J]. FOREST RESOURCES WANAGEMENT, 2021, (1): 147-155.

Figures/Tables 7

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References 24

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类型	样地数/个	平均值	最小值	最大值	标准差	变动系数
云冷杉林(Picea spp.& Abies spp.)	190	182.40	5.29	445.83	96.49	52.90
落叶松林(Larix spp.)	191	114.10	5.94	274.48	56.87	49.85
樟子松林(Pinus sylvestris var.mongolica)	190	204.02	1.00	456.11	87.39	42.83
红松林(Pinus koraiensis)	191	273.86	9.94	667.27	128.59	46.95
栎树林(Quercus spp.)	191	82.31	6.47	292.44	45.86	55.71
桦树林(Betula spp.)	202	88.04	4.78	190.18	39.49	44.85
杨树林(Populus spp.)	206	158.02	2.45	347.18	77.25	48.88
榆树林(Ulmus spp.)	198	130.36	25.10	306.16	50.82	38.98
椴树林(Tilia spp.)	193	199.67	65.03	446.75	69.60	34.86
水胡黄林(Fraxinus mandshurica,Juglans mandshurica & Phellodendron amurense)	195	175.23	35.88	291.27	47.53	27.12

类型	模型	k	R²	SEE/m³	TRE/%	ASE/%	MPE/%	MPSE/%
云冷杉林(Picea spp.& Abies spp.)	(1)	5	0.789	44.91	0.00	8.20	3.52	28.39
云冷杉林(Picea spp.& Abies spp.)	(2)	3	0.771	46.57	-0.27	-1.88	3.65	21.35
落叶松林(Larix spp.)	(1)	6	0.770	27.67	-0.03	-2.27	3.46	23.46
落叶松林(Larix spp.)	(2)	3	0.731	29.63	-0.38	-2.32	3.71	21.34
樟子松林(Pinus sylvestris var.mongolica)	(1)	6	0.541	60.17	-0.01	-1.10	4.22	24.67
樟子松林(Pinus sylvestris var.mongolica)	(2)	2	0.461	64.51	0.29	1.32	4.53	29.09
红松林(Pinus koraiensis)	(1)	7	0.858	49.42	-0.01	-5.82	2.57	26.35
红松林(Pinus koraiensis)	(2)	4	0.846	51.04	0.07	0.64	2.66	16.52
栎树林(Quercus spp.)	(1)	5	0.706	25.22	-0.02	0.17	4.37	24.48
栎树林(Quercus spp.)	(2)	2	0.669	26.52	-0.08	-0.82	4.60	27.08
桦树林(Betula spp.)	(1)	2	0.670	22.78	0.00	-2.69	3.59	25.63
桦树林(Betula spp.)	(2)	2	0.663	23.04	-0.37	-2.10	3.63	22.62
杨树林(Populus spp.)	(1)	2	0.604	48.83	0.01	1.83	4.24	30.09
杨树林(Populus spp.)	(2)	2	0.613	48.31	0.32	1.25	4.20	28.82
榆树林(Ulmus spp.)	(1)	6	0.664	29.91	0.01	1.93	3.21	19.75
榆树林(Ulmus spp.)	(2)	2	0.608	32.00	-0.11	-0.55	3.44	19.67
椴树林(Tilia spp.)	(1)	4	0.577	45.74	-0.01	0.23	3.25	18.34
椴树林(Tilia spp.)	(2)	2	0.525	48.22	-0.08	-0.28	3.43	18.75
水胡黄林(Fraxinus mandshurica,Juglans mandshurica & Phellodendron amurense)	(1)	3	0.460	35.19	0.00	-25.54	2.83	42.11
	(2)	3	0.466	35.00	-0.04	-0.31	2.82	16.15

森林类型	参数估计值			评价指标
森林类型	b₀	b₁	b₂	R²	SEE/m³	TRE/%	ASE/%	MPE/%	MPSE/%
云冷杉林	2410.3	1.4756	-0.60615	0.735	52.85	-0.23	-1.62	4.03	22.18
落叶松林	41243	1.4766	-0.91117	0.681	35.66	-0.52	-2.39	4.25	24.43
樟子松林	393.57	1.1275	-0.33010	0.535	58.87	0.13	0.64	4.20	25.52
红松林	15787	1.6264	-0.82476	0.815	57.97	-0.12	-0.91	2.89	18.13
栎树林	67.159	1.2607	-0.21084	0.713	26.48	-0.45	-2.25	4.42	24.64
桦树林	1140.9	1.5617	-0.60041	0.700	23.74	-0.29	-1.97	3.67	21.42
杨树林	10896	1.2497	-0.71193	0.705	41.71	-0.37	-1.63	3.81	23.02
榆树林	28.106	1.3999	-0.18102	0.609	31.90	-0.16	-0.77	3.44	19.33
椴树林	23292	1.1947	-0.77172	0.497	54.54	-0.04	-0.13	3.76	19.41
水胡黄林	13110	1.0675	-0.74513	0.440	35.87	-0.09	-0.50	2.88	16.76

X35/m	X90(×10000)
X35/m	1.8	2.0	2.2	2.4	2.6	2.8	3.0	3.2	3.4	3.6
3					25.70	24.57	23.57	22.66	21.85	21.10
4				41.25	39.29	37.57	36.03	34.65	33.40	32.26
5			60.44	57.33	54.62	52.22	50.08	48.16	46.42	44.84
6		83.80	79.10	75.03	71.48	68.34	65.54	63.03	60.75	58.68
7		105.20	99.30	94.20	89.73	85.79	82.28	79.12	76.27	73.67
8	136.56	128.12	120.92	114.71	109.28	104.48	100.20	96.35	92.88	89.72
9	162.49	152.43	143.88	136.49	130.02	124.31	119.22	114.64	110.51
10	189.82	178.07	168.08	159.44	151.89	145.22	139.27	133.93	129.10
11	218.48	204.97	193.46	183.52	174.83	167.15	160.30	154.15
12	248.41	233.05	219.96	208.66	198.78	190.05	182.27	175.27
13	279.56	262.26	247.54	234.82	223.70	213.88	205.12	197.25
14	311.86	292.57	276.15	261.96	249.55	238.59	228.82
15	345.29	323.92	305.74	290.03	276.30	264.16	253.34
16	379.78	356.29	336.29	319.01	303.90	290.55	278.65
17	415.33	389.63	367.76	348.86	332.34	317.74
18	451.87	423.92	400.12	379.57	361.59	345.71
19	489.40	459.12	433.35	411.09	391.62	374.42
20	527.88	495.22	467.42	443.41	422.41