全球多尺度海岸线数据在珠江口岸线的精度评价及适用性分析

以珠江口为研究区,对全球自洽分层高分辨率地理数据库（GSHHG）中的全分辨率、高分辨率、中分辨率、低分辨率和粗分辨率等5种海岸线数据开展评价与适用性分析,评估5个尺度海岸线数据的长度及其分形维数差异,并选择珠江口两岸部分区域为例,以不同时期陆地资源卫星Landsat影像为基础,对比不同尺度GSHHG海岸线数据与实际数据之间的差异。结果表明：1）5个尺度海岸线数据的长度及分形维数具有显著差异,分辨率越高,岸线长度越长,其分形维数也越大;2）通过与1978和2018年2个时期基于Landsat影像提取的岸线数据对比表明：GSHHG海岸线数据与实际数据在岸线长度及形态特征上总体一致,但GSHHG海岸线的形态特征与1978年海岸线更接近,反映的是较为早期的海岸线特征。最后建议在进行海岸线变迁与现状调查时,需要根据海岸线长度、岸线形态复杂程度等谨慎选择海岸线数据。     

中国大陆海岸线随机前分形分维及其长度不确定性探讨

一个国家或地区海岸线长度的确定,应首先计算其标度区和分维,然后选用标度区下限附近的量测尺度进行量算。以1∶50万电子地图为基础,在Arc GIS技术支持下选用33种尺度研究中国大陆海岸线的标度区及其盒计维,用手工作业法量测海岸线的量规维,并对中国现行大陆海岸线长度的可靠性进行讨论。结果表明:中国大陆海岸线的标度区在400~0.1 km之间。海岸线量规维和盒计维分别是1.2004和1.0929,量规维比盒计维更能精确表征海岸线不规则程度。杭州湾以南和以北海岸线的量规维分别是1.2565和1.1204。当量测尺度为0.1 km时,中国大陆海岸线的长度约21900 km;当尺度为0.25 km时,长度为18214 km,接近现行海岸线长度。     

1980～2017年环渤海海岸线和围填海时空演变及其影响机制

运用3S技术,采用水体指数法（MNDWI）、分形维数法、土地利用转移矩阵和回归分析等方法,以环渤海海岸带1980、1985、1990、1995、2000、2005、2010、2015和2017年9个时期TM遥感影像为主数据源,研究近40 a围填海活动影响下的环渤海海岸线动态演变特征。结果表明：1980~2017年环渤海海岸线增加了1 159.9 km,分形维数持续增加,岸线呈曲折化。其中,人工岸线增长了1 977.9 km,自然岸线减少了80%。重点变化区域包括黄河三角洲及莱州湾、渤海湾、辽东湾顶部、普兰店湾等地区。1980~2017年环渤海围填海的面积增加了1 988.5 km ²。主要类型由养殖池、盐田及农用地向养殖池、盐田、建筑用地转化。围填海活动与岸线长度、属性变化呈显著线性关系。综上,水产养殖、围海晒盐、农田开垦、工业化和城镇化建设等围填海活动影响了岸线长度及属性等特征的变化。     

2000-2012年中国北方海岸线时空变化分析

利用遥感和GIS 技术获取了中国北方“三省一市”2000 年、2005 年、2008 年、2010年、2011 年与2012 年共6 期大陆海岸线的时空分布情况;采用网格法计算了各个时期海岸线的分形维数;分析了海岸线时空变化特征、海岸线长度变化与分形维数变化之间的关系,以及海岸线动态变化的原因。2000-2012 年,研究区海岸线长度持续增加,总共增加了637.95km,年均增加53.16 km。从区域上看,以天津市与河北省所在的渤海湾区域海岸线变化最强烈;从时间过程上看,2008 年后海岸线长度进入快速增长时期,其中2010-2011 年是海岸线长度变化最剧烈的时期,变化强度为2.49%。2000-2012 年研究区海岸线的分形维数不断增大,其中渤海湾区域海岸线分形维数变化最剧烈;历史海岸线的长度与分形维数之间存在较好的线性关系,相关系数为0.9962;通过对大量海岸线动态引起的整体海岸线长度变化与分形维数变化的统计分析研究表明,在大多数情况下,局部海岸线长度增大(或缩减) 会导致整体海岸线分形维数增大(或减小),并且呈正比例变化。从2000-2012 年各时段海岸线动态对应的各类沿海工程的面积汇总情况来看,港口建设、渔业设施建设以及盐场建设分别占前三位,人类工程建设是中国北方海岸线变化最主要原因;与人类活动影响相比,自然变化如河口淤积与侵蚀对海岸线影响比较小。     

基于遥感和GIS的江苏省海岸线时空变化

以江苏省海岸1973-2012年的Landsat MSS/TM/ETM+遥感影像为数据源,利用遥感和GIS技术,对江苏省海岸线的时空变化进行分析。结果表明：显著侵蚀岸段以废黄河口为中心,北至新淮河口,南至双洋港,长度约79.05 km,占研究区岸线总长度的8%;淤涨岸段以弶港为中心,北至运粮河口,南至新中港,长约715.50 km,占72%;其它部分稳定岸段与淤涨岸段相间存在。最大侵蚀速率为-23.37±11.92 m/a,位于废黄河口南侧;最大淤涨速率为445.37±66.80 m/a,位于射阳河口南侧。围垦是江苏省岸线变化的主要因素。总的来看,1973年以来40年间共围垦1912.4 km²,1980年前后出现了一个围垦高峰,之后围垦强度明显减弱且进入休养期,90年代以后围垦又普遍加强。     

1990年以来中国大陆海岸线稳定性研究

海岸线变迁是一个动态的演变过程,它是自然与人类共同作用的结果。基于1990年、2000年、2007年和2012年4个时期的资源卫星、Landsat系列卫星的遥感影像,采用色差Canny算子计算方法提取岸线数据,计算近22 a来中国大陆海岸线向海推进或向陆后退的空间位置变化量及年均变化速度,研究中国大陆海岸线空间位置与稳定性的演变规律,得出以下结论：① 中国海岸线空间位置变化以向海推进为主;② 中国海岸线多为相对稳定海岸线,其次为强烈岸进岸线,稳定性岸线全国均有分布,而强烈岸进岸线多分布于江苏和辽宁两省;③ 自1990年以来,中国大陆岸线的稳定性指数逐渐降低,22 a下降了1.1,以长江入海口为分界,南方沿海城市岸线稳定性指数高于北方。     

基于遥感的江苏省大陆岸线岸滩时空演变

基于江苏省1984-2016年61景多源遥感影像数据和部分实测潮位、坡度数据,利用遥感技术结合改进的水边线方法提取了多时相的海岸线和平均大潮低潮线,研究了江苏省绣针河口至连兴河口大陆岸线岸滩的时空演变特征。结果表明：1984-2016年,由于海岸带开发,江苏省的海岸线整体以向海推进为主,自然岸线由458.24 km逐渐减少至166.74 km,人工岸线由163.66 km快速增加至598.74 km,大陆岸线长度由621.90 km增加至765.48 km。发生位置和长度变化的岸段中,淤长岸段长127.62 km,年均向海推进83.03 m;围垦岸段长401.21 km,年均向海推进87.63 m;冲刷岸段长71.17 km,年均离海后退10.81 m;围垦被侵蚀岸段长25.95 km,年均离海后退8.64 m。海岸线的空间变化导致江苏省沿海陆地面积净增加104332 hm²,其中由于围垦增加的陆地面积98520 hm²,围垦是陆地面积增加的主要原因。海岸线的离海后退主要发生在废黄河三角洲岸段,但是到2008-2016年,岸线的侵蚀范围已向南扩大至新洋河口至斗龙港岸段。受围垦活动及岸线侵蚀影响,江苏省潮间带坡度不断变陡,统计断面的平均坡度由1.4‰增加至1.9‰,其中废黄河三角洲岸段的中山河口至扁担河口岸段坡度最陡,基本在3~14‰之间;辐射沙洲陆岸岸段坡度最为平缓,但坡度也在逐渐陡化,由0.9‰增加至1.5‰。潮间带面积由271747 hm²减少至168645 hm²,减幅38%;潮间带平均宽度由5064 m减少至3096 m,减幅39%。     

太湖贡湖湾滨岸带微生境特征与主要水质指标的关系分析

2014年8月26日和2015年1月18日,测量了太湖贡湖湾北侧的退圩还湖生态修复区滨岸带不同微生境下水体的主要水质指标,并进行了比较。采用单因素方差分析法,分析不同微生境下水质指标的差异,结合冗余分析法,计算各微生境因子对水质指标变化的解释率。结果表明,8月26日各主要水质指标含量都高于1月18日,不同岸线段之间和不同水深采样点之间的水质指标的差异更大。1月18日凹形岸线段的总氮、总磷、铵态氮和硝态氮的含量相对较高,而化学需氧量在凸形和平直岸线段含量相对较高;8月26日化学需氧量在凹形岸线段含量较高,而总磷和铵态氮在凸形岸线段含量相对较高。冗余分析发现,在1月18日岸线形态是影响各采样点主要水质指标最重要的因子,在8月26日水深对水体水质指标有较大影响。总体上,不同岸线形态段下水质指标随着水深的增加,变化不同,各岸线类型采样点之间的差异也不相同,构建相对复杂的岸线形态有利于提高水体水质指标的差异,增加滨岸带生境的多样性。     

不同海岸地貌背景下的南海周边岸带35年建设用地扩张分析

通过提取1975年与2010年左右南海海岸带建设用地信息,并对南海海岸带区域进行地貌分区,分析了不同类型海岸带35年建设用地扩张空间格局.结果表明:① 华南大陆和马来半岛建设用地扩张普遍快,中南半岛扩张程度中等,苏门答腊岛,加里曼丹岛和菲律宾群岛除马尼拉湾外普遍扩张程度慢.② 不同海岸地貌因自然资源条件,开发难易程度,腹地大小不同,其建设用地扩张程度差异显著.三角洲平原岸和河口平原岸因水运条件好,腹地广,建设用地扩张普遍显著,台地岸和沙坝--潟湖平原岸因适宜建中小型港口,扩张较为显著,海湾平原岸与山地岸则因平原面积小,开发潜力有限,建设用地扩张普遍不大,平直沙堤平原岸因腹地小,水运不发达而扩张甚微.③ 不同类型海岸带开发模式各异.三角洲平原岸和河口平原岸建设用地空间形态多样化,山地岸,台地岸,海湾平原岸以团块状或条带状为主,沙坝--潟湖平原岸以团块状与星状为主,平直沙堤平原岸多呈条带状,线状或点状分布.     

长江经济带岸线资源调查与评估研究

岸线资源是重要而特殊的国土资源与国土空间,在江河沿岸地区经济社会发展和生态环境建设中发挥重要的支撑作用。基于遥感解译、部门座谈、实地勘察和采样测试等技术方法,对长江经济带干支流岸线资源开展了系统的调查评估分析。结果表明,岸线资源条件存在较大的空间差异,岸线资源生态敏感程度较高,开发与保护协调困难,岸线利用对滨岸带水环境和水生态产生影响,局部岸段健康风险突出,滨江湿地呈萎缩、破碎化趋势。从岸线资源空间管控等方面提出政策建议,以期为促进长江经济带绿色高质量发展、生态环境保护规划及国土空间规划等战略和工作提供参考借鉴。     

中国陆地海岸线尺度效应研究(英文)

Spatial scale is a fundamental problem in Geography. Scale effect caused by fractal characteristic of coastline becomes a common focus of coastal zone managers and researchers. In this study, based on DEM and remote sensing images, multi-scale continental coastlines of China were extracted and the fractal characteristic was analyzed. The results are shown as follows. (1) The continental coastline of China fits the fractal model, and the fractal dimension is 1.195. (2) The scale effects with fractal dimensions of coastline have significant differences according to uplift and subsidence segments along the continental coastlines of China. (3) The fractal dimension of coastline has significant spatial heterogeneity according to the coastline types. The fractal dimension of sandy coastline located in Luanhe River plain is 1.109. The dimension of muddy coastline located in northern Jiangsu Plain is 1.059, while that of rocky coastline along southeastern Fujian is 1.293. (4) The length of rocky coastline is affected by scale more than that of muddy and sandy coastline. Since coastline is the conjunction of sea, land and air surface, the study of coastline scale effect is one of the scientific bases for the researches on air-sea-land interaction in multi-scales.     

快速城市化地区海岸线分维动态演变研究——以深圳市为例

以快速城市化地区深圳市为研究区域,以1978、1986、1995和2005年4期Landsat MSS/TM影像为数据源,利用阈值结合NDVI指数法提取海岸线,计算海岸线分维数,系统分析了深圳市多期海岸线分维变化特征,并初步揭示快速城市化地区海岸线分维变化机制,为进～步掌握快速城市化地区人类活动对海岸带变化影响进行了探索与总结.研究结果表明:(1)不同类型海岸的海岸线分维不同,由基岩海岸、人工海岸到淤泥质海岸递减:(2)研究时段内,深圳市东海岸海岸线分维总体降低,西海岸总体上升:(3)人类活动对海岸线分维变化影响显著.人类活动强度与海岸线分维变化程度呈正相关,人类活动方式包括滩涂围垦和填海造地对海岸线的分维变化幅度影响不同,其中滩涂围垦使海岸线分维变化幅度较小,填海造地使海岸线分维变化幅度显著.     

海岸线空间分形性质探讨——以江苏省为例

根据分形理论 ,借助于GIS技术的支持 ,以江苏省海岸线为例 ,对以往研究少有涉及的海岸线空间分形性质进行了初步探讨 ,包括不同比例尺下海岸线长度的分形标定、不同潮滩分界线是否具有分形性质等 ,在江苏省海岸线长度的分形标定中取得了实际应用 ,由此获得了对海岸线分形性质及其分维意义的一些深入认识。     

2000–2012年中国北方海岸线时空变化（英文）

This study examined the spatial distribution of the continent coastline in northern China using remote sensing and GIS techniques,and calculated the fractal dimension of the coastline by box-counting method,with a time span from 2000 to 2012.Moreover,we analyzed the characteristics of spatial-temporal changes in the coastline's length and fractal dimension,the relationship between the length change and fractal dimension change,and the driving forces of coastline changes in northern China.During the research period,the coastline of the study area increased by 637.95 km,at a rate of 53.16 km per year.On the regional level,the most significant change in coastline length was observed in Tianjin and Hebei.Temporally,the northern China coastline grew faster after 2008.The most dramatic growth was found between 2010 and 2011,with an increasing rate of 2.49% per year.The fractal dimension of the coastline in northern China was increasing during the research period,and the most dramatic increase occurred in Bohai Rim.There is a strong-positive linear relationship between the historical coastline length and fractal dimension(the correlation coefficient was 0.9962).Through statistical analysis of a large number of local coastline changes,it can be found that the increase(or decrease) of local coastline length will,in most cases,lead to the increase(or decrease) of the whole coastline fractal dimension.Civil-coastal engineering construction was the most important factor driving the coastline change in northern China.Port construction,fisheries facilities and salt factories were the top three construction activities.Compared to human activities,the influence of natural processes such as estuarine deposit and erosion were relatively small.     

Spatial and temporal variations of coastlines in northern China （2000-2012）

This study examined the spatial distribution of the continent coastline in northern China using remote sensing and GIS techniques, and calculated the fractal dimension of the coastline by box-counting method, with a time span from 2000 to 2012. Moreover, we ana- lyzed the characteristics of spatial-temporal changes in the coastline＇s length and fractal di- mension, the relationship between the length change and fractal dimension change, and the driving forces of coastline changes in northern China. During the research period, the coast- line of the study area increased by 637.95 km, at a rate of 53.16 km per year. On the regional level, the most significant change in coastline length was observed in Tianjin and Hebei. Temporally, the northern China coastline grew faster after 2008. The most dramatic growth was found between 2010 and 2011, with an increasing rate of 2.49% per year. The fractal dimension of the coastline in northern China was increasing during the research period, and the most dramatic increase occurred in Bohai Rim. There is a strong-positive linear relation- ship between the historical coastline length and fractal dimension （the correlation coefficient was 0.9962）. Through statistical analysis of a large number of local coastline changes, it can be found that the increase （or decrease） of local coastline length will, in most cases, lead to the increase （or decrease） of the whole coastline fractal dimension. Civil-coastal engineering construction was the most important factor driving the coastline change in northern China. Port construction, fisheries facilities and salt factories were the top three construction activi- ties. Compared to human activities, the influence of natural processes such as estuarine deposit and erosion were relatively small.     

Spatial and temporal variations of coastlines in northern China (2000-2012)

This study examined the spatial distribution of the continent coastline in northern China using remote sensing and GIS techniques, and calculated the fractal dimension of the coastline by box-counting method, with a time span from 2000 to 2012. Moreover, we analyzed the characteristics of spatial-temporal changes in the coastline's length and fractal dimension, the relationship between the length change and fractal dimension change, and the driving forces of coastline changes in northern China. During the research period, the coastline of the study area increased by 637.95 km, at a rate of 53.16 km per year. On the regional level, the most significant change in coastline length was observed in Tianjin and Hebei. Temporally, the northern China coastline grew faster after 2008. The most dramatic growth was found between 2010 and 2011, with an increasing rate of 2.49% per year. The fractal dimension of the coastline in northern China was increasing during the research period, and the most dramatic increase occurred in Bohai Rim. There is a strong-positive linear relationship between the historical coastline length and fractal dimension (the correlation coefficient was 0.9962). Through statistical analysis of a large number of local coastline changes, it can be found that the increase (or decrease) of local coastline length will, in most cases, lead to the increase (or decrease) of the whole coastline fractal dimension. Civil-coastal engineering construction was the most important factor driving the coastline change in northern China. Port construction, fisheries facilities and salt factories were the top three construction activities. Compared to human activities, the influence of natural processes such as estuarine deposit and erosion were relatively small.     

海岸线分类体系探讨

对海岸线分类体系进行探讨,依据海岸线自然属性改变与否,将海岸线划分为自然海岸线和人工海岸线;依据海岸底质特征和空间形态,将海岸线划分为基岩海岸线、砂质海岸线、淤泥质海岸线、生物海岸线和河口海岸线;依据海岸线功能用途,将海岸线划分为渔业岸线、港口码头岸线、临海工业岸线、旅游娱乐岸线、城镇岸线、矿产能源岸线、保护岸线、特殊用途岸线和未利用岸线;依据海岸线时间尺度,将海岸线划分为历史海岸线、现状海岸线和未来海岸线;依据海岸线管理实践,将海岸线划分为管理岸线和实际岸线,并就海岸线分类的几点问题进行探讨。     

GIS支持的中美澳海岸线分维及其比较研究

利用GIS对中国、美国、澳大利亚海岸线进行了研究。主要内容包括：第一,同方法与同比例尺图源情况下各自海岸线分维的计算与比较;第二,中美澳海岸线分维随纬向的可能变化特征探讨;第三,海岸线分维在海岸线整体与部分之间的可能变化关系。所得结论在一定程度上丰富与加深了对海岸线分形性质的认识。     

Geomorphometric analysis of a rocky coastline: an example from Hornsund,Svalbard

We describe a method to extract a number of quantitative morphometric characteristics of a rocky coastline. The algorithm, which is implemented in the free open-source software GNU Octave, takes as its input an ordered set of coordinate pairs defining the coastline. It finds vertices of specific angularity at two different levels, first approximating convex features (headlands) and then looking for local maxima (embayment edges) in their vicinity. It extracts numerical parameters for each embayment delimited by the former points, including basic geometric parameters (e.g. area, depth and width) and coefficients expressing shapes of embayments (e.g. form factor, coefficient of asymmetry and compactness). These we adapted from morphometric studies of other geomorphic features. Complex headlands and random sectors of the coastline which are delimited by embayment edges are automatically removed. The method was developed and tested on Hornsund in Svalbard, where 20 headlands, 28 embayment edges and 20 embayments were identified, but could be adapted to a wide range of coastal situations. We consider a range of possible applications of the methods, including to the classification of coastlines, change detection and identifying controls on their morphologies, and we discuss the choice of optimum parameters for the algorithm.