数字高程模型在群落内物种共存研究中的应用——以神农架米心水青冈-曼青冈群落的地形模型建立为例

doi:10.17521/cjpe.2005.0025

摘要/Abstract

摘要：

地形是环境异质性产生的原因之一。受技术条件的限制, 以往研究中地形因子只能作为背景因子介入, 无法分析地形的细微变化对植物分布格局的影响。该文将数字高程模型引入群落内物种多样性研究, 以神农架米心水青冈 (Fagusengleriana) _曼青冈 (Cyclobalanopsisoxyodon) 群落固定样地的地形分析为例, 介绍DEM的建立及地形因素的提取。摸拟 0.96hm2 样地的地形变化, 发现样地总坡向为西偏北 30°, 总坡度为 4 0.0 1°, 最大坡度为74.6°, 最小坡度为 18.2°, DEM的精度为 0.4m。选择群落中 2 4种植物与坡度、坡向及坡位等地形因素进行相关分析, 发现不同的种对地形变化的反应不同。该次研究中, DEM量化了地形数据, 使之可以参与到生物多样性研究中, 为在连续面上分析地形因素对群落内植物分布的影响提供了极大的便利。DEM在小尺度中应用的主要问题是原数据的采集, 该次研究中的地形数据为人工野外测量, 研究规模受到一定限制。

关键词: 坡度, 坡向, DEM, 神农架

Abstract:

Topography is a primary factor that creates microenvironmental heterogeneity in a landscape. In previous studies, topographic factors, such as slope and aspect, were measured as discrete data and had limited use in analyses. In this paper, a digital elevation model (DEM) was used to analyze the influence of topographic heterogeneity on the distribution patterns of woody plants at the community level by calculating digital topographic values and creating a digital description of the landform. The establishment of a DEM can be generalized in three steps: 1) gathering the topographic data; 2) data adjustment & interpolation; and 3) displaying the data. To illustrate this process, a DEM was built based on a 0.96 hm 2 permanent forest plot in the Shennongjia area (31°19′4″ N, 110°29′44″ E). The forest was dominated by Fagus engleriana and Cyclobalanopsis oxyodon. Topographic data were gathered when the plot was established. A total of 425 sample points were mapped by elevation. An inverse distance weighted method was used to interpolate data between points. Using Arcview GIS software, the slope and aspect of all 425 points within the plot were calculated. The slope varied from 18.2 to 74.6 degrees in the 0.96 hm 2 plot. The precision of the DEM was 0.4 m. Using the DEM, the slope and aspect of every point within the permanent plot were calculated and these topographic factors were then used to analyze species distribution patterns. Twenty-four species were chosen to calculate their correlations with slope, aspect and position. The positive and negative correlations with the slope, aspect and position were 7, 7, 6, 3, and 8, 5 respectively. One problem of using a DEM at small scales is related to the difficulties associated with the collection of the original data. Under the forest canopy, it was difficult to gather topographic data using GPS, remote pictures or other automated tools. To achieve the required precision, all topographic data were acquired using a compass, which limited the scale at which the analysis could be conducted. Although improvements are needed in this method, the DEM provided a lot of information and was a convenient method for analyzing species distributions in relation to topographic factors. Because remote sensing cannot provide a detailed description of species distributions within forest communities, such research should be combined with the establishment of permanent plots.

Key words: Slope, Aspect, DEM, Species distribution, Shennongjia

张谧, 熊高明, 陈志刚, 樊大勇, 谢宗强. 数字高程模型在群落内物种共存研究中的应用——以神农架米心水青冈-曼青冈群落的地形模型建立为例. 植物生态学报, 2005, 29(2): 197-201. DOI: 10.17521/cjpe.2005.0025

ZHANG Mi, XIONG Gao-Ming, CHEN Zhi-Gang, FAN Da-Yong, XIE Zong-Qiang. THE APPLICATION OF DIGITAL ELEVATION MODELS IN COMMUNITY BIODIVERSITY RESEARCH WITH AN EXAMPLE FROM A FAGUS ENGLERIANA-CYCLOBALANOPSIS OXYODON COMMUNITY IN SHENNONGJIA AREA. Chinese Journal of Plant Ecology, 2005, 29(2): 197-201. DOI: 10.17521/cjpe.2005.0025

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2005.0025

https://www.plant-ecology.com/CN/Y2005/V29/I2/197

图/表 4

参考文献 13

[1]	Chen LZ (陈灵芝), Wang ZW (王祖望) (1999). TheImpactofHumanAlternationonEcosystemDiversity (人类活动对生态系统多样性的影响). ZhejiangScienceandTechnologyPress, Hangzhou,139-197. (inChinese).
[2]	DeMers MN TranslatedbyWu FD (武法东), Fu ZT (付宗堂), Wang XN (王小牛) (2001). FundamentalsofGeo graphicInformationSystems (inEnglish). ElectronicIndus tryPress, Beijing,22-196.
[3]	DozierJ, StrahlerAH (1983). Groundinvestigationsinsup portofremotesensing.In:ColwellRHed.ManualofRe moteSensing. CambridgeUniversityPress, Cambridge, 1232.
[4]	Editorial Group for Country Studies on Biodiversity in China (中国生物多样性国情研究报告编写组) (1998). The Nation Report of China Biodiversity Status (中国生物多样性国情研究报告). China Environment Science Press, Beijing, 1-10. (inChinese).
[5]	Fang JY (方精云), Guo QH (郭庆华), Liu GH (刘国华) (1999). DistributionpatternsofChineseBeech (FagusL.)speciesinrelationtotopography. ActaBotanicaSinica (植物学报), 41,766-774. (inChinesewithEnglishab stract).
[6]	Guo ZH (郭志华), Peng SL (彭少麟), Wang BS (王伯荪), Zhang Z (张征) (1999). EstimationofradiationabsorptionbyGuangdongvegetationusingGISandRS. ActaEcologicaSinica (生态学报), 19,441-446. (inChinesewithEng lishabstract).
[7]	Horn BP (1981). Hillshadingandthereflectancemap. Pro ceedingsoftheInstituteofElectrical&ElectronicEngi neers, 69,14.
[8]	Li X (李新), Cheng GD (程国栋), Lu L (卢玲) (2000). Comparisonofspatialinterpolationmethods. AdvanceinEarthSciences (地球科学进展), 15,260-265. (inChi nesewithEnglishabstract).
[9]	Li ZL (李志林) (2000). DigitalElevationModel (数字高程模型). ScienceandTechnologyTopographyUniversityPress, Wuhan, 125-158. (inChinese).
[10]	Shen ZH (沈泽昊), Fang JY (方精云) (2001). Nichecom parisonoftwoFagusspeciesbasedonthetopographicpat ternsoftheirpopulations. ActaPhyhtoecologicaSinica (植物生态学报), 25,392-398. (inChinesewithEnglishab stract).
[11]	Shen ZH (沈泽昊), Zhang XS (张新时) (2000). ThespatialpatternandtopographicinterpretationoftheforestvegetationatDalaolingregioninthethreeGorges. ActaBotanicaSini ca (植物学报), 42,1089-1095. (inChinesewithEnglishabstract).
[12]	Song YC (宋永昌) (2001). Vegetation Ecology (植被生态学). EastChinaNormalUniversityPress, Shanghai,173-176. (inChinese).
[13]	Zhang M (张谧), Xiong GM (熊高明), Chen ZG (陈志刚), Fan DY (樊大勇), Xie ZQ (谢宗强) (2004). Thetopogra phyheterogeneityofFagusengleriana_Cyclobalanopsisoxyo doncommunityinShennongjiaregion. ActaEcologicaSinica (生态学报), 24,2686-2692. (in Chinese with English abstract)

植物名 Species	相关系数 Correlation coefficients
植物名 Species	坡度 Slope	坡向 Aspect	坡位 Position
曼青冈 (1)	-0.535	0.913	-0.771
米心水青冈 (2)	0.994	0.004	-0.327
粉白杜鹃 (3)	-0.887	-0.977	-0.870
石栎 (4)	-0.800	0.895	0.655
四照花 (5)	-0.001	0.270	-0.993
香椿 (6)	0.797	0.975	0.721
小叶青皮槭 (7)	0.871	-0.031	0.415
鄂椴 (8)	0.846	-0.416	0.993
血皮槭 (9)	-0.152	-0.523	-0.240
三桠乌药 (10)	-0.954	-0.609	-0.866
水榆花楸 (11)	-0.970	0.731	-0.866
山白树 (12)	-0.909	-0.123	-0.327
木来木 (13)	-0.078	0.961	0.655
稠李 (14)	-0.401	0.429	0.397
华榛 (15)	-0.014	0.247	0.866
巴东栎 (16)	0.841	0.814	0.866
领春木 (17)	0.592	0.263	0.952
锥栗 (18)	-0.943	-0.813	-0.866
化香 (19)	0.179	0.993	0.866
灯台 (20)	-0.815	0.786	0.866
紫茎 (21)	0.027	-0.969	-1.000
石灰花楸 (22)	-0.901	0.000	-0.933
鸡爪槭 (23)	0.757	0.731	-0.277
扇叶槭 (24)	0.981	-0.555	0.866

植物名 Species	相关系数 Correlation coefficients
植物名 Species	坡度 Slope	坡向 Aspect	坡位 Position
曼青冈 (1)	-0.535	0.913	-0.771
米心水青冈 (2)	0.994	0.004	-0.327
粉白杜鹃 (3)	-0.887	-0.977	-0.870
石栎 (4)	-0.800	0.895	0.655
四照花 (5)	-0.001	0.270	-0.993
香椿 (6)	0.797	0.975	0.721
小叶青皮槭 (7)	0.871	-0.031	0.415
鄂椴 (8)	0.846	-0.416	0.993
血皮槭 (9)	-0.152	-0.523	-0.240
三桠乌药 (10)	-0.954	-0.609	-0.866
水榆花楸 (11)	-0.970	0.731	-0.866
山白树 (12)	-0.909	-0.123	-0.327
木来木 (13)	-0.078	0.961	0.655
稠李 (14)	-0.401	0.429	0.397
华榛 (15)	-0.014	0.247	0.866
巴东栎 (16)	0.841	0.814	0.866
领春木 (17)	0.592	0.263	0.952
锥栗 (18)	-0.943	-0.813	-0.866
化香 (19)	0.179	0.993	0.866
灯台 (20)	-0.815	0.786	0.866
紫茎 (21)	0.027	-0.969	-1.000
石灰花楸 (22)	-0.901	0.000	-0.933
鸡爪槭 (23)	0.757	0.731	-0.277
扇叶槭 (24)	0.981	-0.555	0.866

[1]	何青, 袁旭东, 任博申, 冯治洋, 鲁梦珍, 林巧玲, 姜庆虎, 杨林森, 余辉亮, 姚辉, 杨敬元, 刘峰, 江明喜. 一年蓬（Erigeron annuus）入侵对亚高山泥炭湿地植物群落结构与多样性的影响[J]. 植物生态学报, 2026, 50(预发表): 0-.
[2]	赵常明, 熊高明, 申国珍, 葛结林, 徐文婷, 徐凯, 武元帅, 谢宗强. 2010年神农架常绿落叶阔叶混交林和亚高山针叶林长期监测样地植物物种组成和群落特征数据集[J]. 植物生态学报, 2025, 49(8): 1215-1228.
[3]	和璐璐, 张萱, 章毓文, 王晓霞, 刘亚栋, 刘岩, 范子莹, 何远洋, 席本野, 段劼. 辽东山区不同坡向长白落叶松人工林树冠特征与林木生长关系[J]. 植物生态学报, 2023, 47(11): 1523-1539.
[4]	臧永新, 马剑英, 周晓兵, 陶冶, 尹本丰, 沙亚古丽•及格尔, 张元明. 极端干旱和降水对沙垄不同坡向坡位短命植物地上生产力的影响[J]. 植物生态学报, 2022, 46(12): 1537-1550.
[5]	李全弟, 刘旻霞, 夏素娟, 南笑宁, 蒋晓轩. 甘南高寒草甸群落的物种-多度关系沿坡向的变化[J]. 植物生态学报, 2019, 43(5): 418-426.
[6]	车应弟, 刘旻霞, 李俐蓉, 焦骄, 肖卫. 基于功能性状及系统发育的亚高寒草甸群落构建[J]. 植物生态学报, 2017, 41(11): 1157-1167.
[7]	段贝贝, 赵成章, 徐婷, 郑慧玲, 冯威, 韩玲. 兰州北山不同坡向刺槐叶脉密度与气孔性状的关联性分析[J]. 植物生态学报, 2016, 40(12): 1289-1297.
[8]	菊花, 申国珍, 马明哲, 葛结林, 徐文婷, 赵常明, 张秋良. 北亚热带地带性森林土壤温室气体通量对土地利用方式改变和降水减少的响应[J]. 植物生态学报, 2016, 40(10): 1049-1063.
[9]	宋清华, 赵成章, 史元春, 杜晶, 王继伟, 陈静. 高寒草地甘肃臭草根系分形结构的坡向差异性[J]. 植物生态学报, 2015, 39(8): 816-824.
[10]	宋清华, 赵成章, 史元春, 杜晶, 王继伟, 陈静. 不同坡向甘肃臭草根系分叉数和连接长度的权衡关系[J]. 植物生态学报, 2015, 39(6): 577-585.
[11]	史元春, 赵成章, 宋清华, 杜晶, 陈静, 王继伟. 兰州北山刺槐枝叶性状的坡向差异性[J]. 植物生态学报, 2015, 39(4): 362-370.
[12]	郑慧玲, 赵成章, 徐婷, 段贝贝, 韩玲, 冯威. 红砂根系分叉数和分支角度权衡关系的坡向差异[J]. 植物生态学报, 2015, 39(11): 1062-1070.
[13]	党晶晶, 赵成章, 李钰, 侯兆疆, 董小刚. 祁连山高寒草地甘肃臭草叶性状与坡向间的关系[J]. 植物生态学报, 2015, 39(1): 23-31.
[14]	侯兆疆, 赵成章, 李钰, 张茜, 马小丽. 不同坡向高寒退化草地狼毒株高和枝条数的权衡关系[J]. 植物生态学报, 2014, 38(3): 281-288.
[15]	党晶晶, 赵成章, 李钰, 侯兆疆, 董小刚. 高寒草地甘肃臭草茎-叶性状的坡度差异性[J]. 植物生态学报, 2014, 38(12): 1307-1314.