Sistemas de información geográfica y cartografía geomorfológica aplicados al inventario de deslizamientos y cartografía de susceptibilidad en la cuenca del río El Estado, Pico de Orizaba, México
José Fernando Aceves Quesada , Gabriel Legorreta Paulín , José Lugo Hubp , Juan Umaña Romero , Héctor Alfredo Legorreta Cuevas
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However, these studies set a general framework and guidance (that includes basic concepts and explanations of landslide classification, triggering mechanisms, criteria, considerations, and analysis for landslide hazard reconnaissance, etc.) for preparing a landslide atlas at state and city levels. So far, these have not developed a practical and standardized approach incorporating geomorphological maps into the landslide inventory using <span>gis</span>. This paper describes the analysis conducted to develop an analytical technique and morphometric analysis for a multi-temporal landslide inventory. Three data management levels are used to create <span>gis</span> thematic layers. For the first level, analogue topographic, geological, land-use, and climate paper are converted to raster format, georeferenced, and incorporated as <span>gis</span> thematic layers. For the second level, five layers are derived from topographic elevation data: slope angles, slope curvature, contributing area, flow direction, and saturation. For the third level, thematic maps are derived from the previous two levels of data: a hypsometric map (heuristically classified to highlight altimetric levels), a reclassified slope map (allowing to highlight differences in relief), and a morphographic map (derived from a heuristic reclassification of the slope map to highlight volcanic landforms). The theoretical aspects of geomorphological mapping contribute to set the conceptual basis to support landslide mapping. The <span>gis</span> thematic layers provide context and establish an overall characterization of landslide processes within the watershed. Through the retrieval and on-off switching of layers in the <span>gis</span> system, a base map is created to assist in the digitizing of landslides and the modeling of susceptibility. A landslide inventory is created from aerial photographs, field investigations, and all the above <span>gis</span> thematic layers. El Estado river watershed on the southwestern flank of Pico de Orizaba volcano has been selected as study area. The watershed is located in the southwestern slope of Citlaltepetl or Pico de Orizaba volcano. Geological (the stream channel of El Estado river erodes Tertiary and Quaternary lavas, disjointed volcanoclastic materials such as pyroclastic flows, fall deposits, lahars deposits, and alluvium) and geomorphological factors (steep slopes, energy relief, and vertical erosion) in combination with high seasonal rainfall (annual rainfall averages 1000-1100 mm/yr at > 4000 m a.s.l. and 927 mm/yr at <1500 m a.s.l.), and the high degree of weathering, make the study area susceptible to landslides. To assess landslide susceptibility, a landslide inventory map and geomorphometric cartography (altimetry, slope and geomorphography) were reviewed, and field work was conducted. In the study area, more than one hundred landslides were mapped. Shallow landslides (including debris slides and debris flows) are the predominant type. Shallow landslides predominate on hills capped with ash and pyroclastic deposits. The second major landslide process includes rock falls (which occur where the stream erodes lava flows and lahars) and deep-seated landslides (which occur in ash and pyroclastic deposits where lava flows act as a slip plane). In parallel, the spatial geodatabase of landslides was constructed from standardized <span>gis</span> datasets. Pertinent attributes are recorded on a geo-dataset. These include 1) mass wasting process, 2) level of certainty of the observation, 3) photo identification date, 4) landslide size, 5) landslide activity, 6) landslide parts (head, evacuation zone, deposit), 7) slope shape, 8) field slope gradient, 9) map gradient measured from the 10 m digital elevation model (<span>dem</span>), 10) landslide delivery, 11) land use, 12) elevation at which the landslide started, 13) aerial photograph identification number, 14) landslide area, and 15) researcher comments. Each attribute is standardized by the geo-dataset domains in the <span>gis</span> system. With this information the landslide susceptibility is modeled using <span>mlr</span> within a <span>gis</span> platform. <span>mlr</span> is used to examine the relation between land sliding and several independent variables (elevation, slope, contributing area, land use, geology, and terrain curvature) to create the susceptibility map. With six independent variables, the multiple logistic model susceptibility map tends to overpredict landslides at a 10 m pixel resolution. However, the model is statistically valid and able to predict 79.81% of the existing landslides. The implementation of a landslide inventory and susceptibility mapping techniques demonstrate the feasibility of the method for use in other volcanic areas of Mexico.</p></div>","PeriodicalId":39866,"journal":{"name":"Investigaciones Geograficas","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2016-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.14350/rig.46503","citationCount":"4","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Investigaciones Geograficas","FirstCategoryId":"1085","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0188461117300043","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"Social Sciences","Score":null,"Total":0}
引用次数: 4
Abstract
With the aim of raising awareness on the prevention of landslide disasters, this work develops a methodology that incorporates geomorphological mapping into the mapping of landslide susceptibility using Geographic Information Systems (gis) and Multiple Logistic Regression (mlr). In Mexico, some studies have evaluated the stability of hillsides using gis. However, these studies set a general framework and guidance (that includes basic concepts and explanations of landslide classification, triggering mechanisms, criteria, considerations, and analysis for landslide hazard reconnaissance, etc.) for preparing a landslide atlas at state and city levels. So far, these have not developed a practical and standardized approach incorporating geomorphological maps into the landslide inventory using gis. This paper describes the analysis conducted to develop an analytical technique and morphometric analysis for a multi-temporal landslide inventory. Three data management levels are used to create gis thematic layers. For the first level, analogue topographic, geological, land-use, and climate paper are converted to raster format, georeferenced, and incorporated as gis thematic layers. For the second level, five layers are derived from topographic elevation data: slope angles, slope curvature, contributing area, flow direction, and saturation. For the third level, thematic maps are derived from the previous two levels of data: a hypsometric map (heuristically classified to highlight altimetric levels), a reclassified slope map (allowing to highlight differences in relief), and a morphographic map (derived from a heuristic reclassification of the slope map to highlight volcanic landforms). The theoretical aspects of geomorphological mapping contribute to set the conceptual basis to support landslide mapping. The gis thematic layers provide context and establish an overall characterization of landslide processes within the watershed. Through the retrieval and on-off switching of layers in the gis system, a base map is created to assist in the digitizing of landslides and the modeling of susceptibility. A landslide inventory is created from aerial photographs, field investigations, and all the above gis thematic layers. El Estado river watershed on the southwestern flank of Pico de Orizaba volcano has been selected as study area. The watershed is located in the southwestern slope of Citlaltepetl or Pico de Orizaba volcano. Geological (the stream channel of El Estado river erodes Tertiary and Quaternary lavas, disjointed volcanoclastic materials such as pyroclastic flows, fall deposits, lahars deposits, and alluvium) and geomorphological factors (steep slopes, energy relief, and vertical erosion) in combination with high seasonal rainfall (annual rainfall averages 1000-1100 mm/yr at > 4000 m a.s.l. and 927 mm/yr at <1500 m a.s.l.), and the high degree of weathering, make the study area susceptible to landslides. To assess landslide susceptibility, a landslide inventory map and geomorphometric cartography (altimetry, slope and geomorphography) were reviewed, and field work was conducted. In the study area, more than one hundred landslides were mapped. Shallow landslides (including debris slides and debris flows) are the predominant type. Shallow landslides predominate on hills capped with ash and pyroclastic deposits. The second major landslide process includes rock falls (which occur where the stream erodes lava flows and lahars) and deep-seated landslides (which occur in ash and pyroclastic deposits where lava flows act as a slip plane). In parallel, the spatial geodatabase of landslides was constructed from standardized gis datasets. Pertinent attributes are recorded on a geo-dataset. These include 1) mass wasting process, 2) level of certainty of the observation, 3) photo identification date, 4) landslide size, 5) landslide activity, 6) landslide parts (head, evacuation zone, deposit), 7) slope shape, 8) field slope gradient, 9) map gradient measured from the 10 m digital elevation model (dem), 10) landslide delivery, 11) land use, 12) elevation at which the landslide started, 13) aerial photograph identification number, 14) landslide area, and 15) researcher comments. Each attribute is standardized by the geo-dataset domains in the gis system. With this information the landslide susceptibility is modeled using mlr within a gis platform. mlr is used to examine the relation between land sliding and several independent variables (elevation, slope, contributing area, land use, geology, and terrain curvature) to create the susceptibility map. With six independent variables, the multiple logistic model susceptibility map tends to overpredict landslides at a 10 m pixel resolution. However, the model is statistically valid and able to predict 79.81% of the existing landslides. The implementation of a landslide inventory and susceptibility mapping techniques demonstrate the feasibility of the method for use in other volcanic areas of Mexico.
地理信息系统和地貌制图在墨西哥奥里萨巴Pico de Orizaba El Estado河流域滑坡清查和敏感性制图中的应用
为了提高人们对预防滑坡灾害的认识,这项工作开发了一种方法,该方法使用地理信息系统(gis)和多元逻辑回归(mlr)将地貌测绘纳入滑坡易感性测绘。在墨西哥,一些研究利用地理信息系统评估了山坡的稳定性。然而,这些研究为编制国家级和市级滑坡地图集提供了总体框架和指导(包括滑坡分类的基本概念和解释、触发机制、标准、注意事项、滑坡灾害侦察分析等)。到目前为止,他们还没有开发出一种实用和标准化的方法,利用地理信息系统将地貌图纳入滑坡清单。本文描述了为开发一种分析技术而进行的分析和多时间滑坡清单的形态计量分析。三个数据管理级别用于创建gis主题层。在第一级,模拟地形、地质、土地利用和气候文件被转换为栅格格式、地理参考,并合并为gis主题层。对于第二层,从地形高程数据导出五个层:坡度角、坡度曲率、贡献面积、流向和饱和度。第三个层次的专题地图是由前两个层次的数据派生而来的:一个半高程地图(启发式分类以突出高程水平),一个重新分类的坡度图(允许突出地形差异),和一个地貌图(从斜坡图的启发式重新分类派生以突出火山地貌)。地貌填图的理论研究为滑坡填图提供了理论基础。地理信息系统专题层提供了流域内滑坡过程的背景和总体特征。通过gis系统中各层的检索和开关,创建了一个基础地图,以协助滑坡的数字化和易感性的建模。滑坡清单是根据航空照片、实地调查和所有上述gis专题层创建的。选取Pico de Orizaba火山西南侧的El Estado河流域作为研究区域。该分水岭位于Citlaltepetl或Pico de Orizaba火山的西南坡。地质因素(El Estado河的河道侵蚀了第三纪和第四纪熔岩、火山碎屑流、瀑布沉积物、火山泥流沉积物和冲积物等断裂的火山碎屑物质)和地貌因素(陡坡、能量起伏和垂直侵蚀),以及高季节性降雨(年平均降雨量为1000-1100毫米/年);4000 m A.S.L.和1500 m A.S.L.的927 mm/年),以及高度的风化,使研究区容易发生滑坡。为了评估滑坡的易感性,对滑坡库存图和地貌学制图(高程、坡度和地貌)进行了审查,并进行了实地工作。在研究区域,绘制了100多个滑坡的地图。浅层滑坡(包括泥石流和泥石流)是主要类型。浅层滑坡主要发生在覆盖着火山灰和火山碎屑沉积物的山丘上。第二大滑坡过程包括岩石坠落(发生在河流侵蚀熔岩流和火山泥流的地方)和深层滑坡(发生在火山灰和火山碎屑沉积物中,熔岩流起到滑动面的作用)。同时,利用标准化gis数据集构建滑坡空间地理数据库。相关属性记录在地理数据集中。这些包括1)质量消耗过程,2)观测的确定性水平,3)照片识别日期,4)滑坡大小,5)滑坡活动,6)滑坡部分(头部,疏散区,沉积物),7)斜坡形状,8)现场坡度,9)从10米数字高程模型(dem)测量的地图坡度,10)滑坡传递,11)土地利用,12)滑坡开始的高程,13)航空照片识别号码,14)滑坡区域,15)研究人员评论。每个属性都通过gis系统中的地理数据集域进行标准化。利用这些信息,在gis平台上使用mlr对滑坡易感性进行建模。MLR用于研究陆地滑动与几个自变量(高程、坡度、贡献面积、土地利用、地质和地形曲率)之间的关系,以创建敏感性图。在具有6个自变量的情况下,多logistic模型敏感性图倾向于在10 m像素分辨率下过度预测滑坡。然而,该模型在统计上是有效的,能够预测79.81%的现有滑坡。 滑坡清单和易感性测绘技术的实施证明了该方法在墨西哥其他火山地区使用的可行性。
期刊介绍:
Investigaciones Geográficas, es una revista arbitrada y de circulación internacional, en donde se publican contribuciones de especialistas en geografía y disciplinas afines, con trabajos originales de investigación, ya sean avances teóricos, nuevas tecnologías o estudios de caso sobre la realidad geográfica mexicana y mundial.