多时相影像福州市不透水面对城市地表温度的空间分布研究

随着城市化进程的加快,城市热力场也随之发生变化,从而影响着城市区域环境、社会经济以及社会环境。由于NDVI具有季相变化的不稳定性,本研究采用两个时相TM/ETM+影像分析福州市及其周边地区不透水面对热力场的时空分布变化状况。为了获取精确的城市不透水面信息,本实验采用NDVI二元法结合2000年同区域的IKONOS影像提取不透水面信息。通过定量分析不透水面百分比、NDVI与地表温度的关系,得出不透水面百分比与城市地表温度呈线性相关,其相关系数在0.7左右;尤其30%以上的不透水面对地表热环境的空间分布影响最为突出,因此,相对于不稳定的NDVI而言,不透水面信息能更好地反映城市热环境的空间分布状况。     

中小城市地表温度变化与下垫面关系

针对中小城市地表温度变化与下垫面的关系问题,以合肥市城区和六安市金安区为例,基于Landsat-8热红外卫星影像数据,采用大气校正法反演研究区地表温度。对其进行归一化处理后,利用密度分割技术分析研究区城市热场空间格局,以城市热岛比例指数评价了研究区热岛效应,得到热岛效应强度分布情况,并结合地理国情数据,采用数理统计和空间统计相结合的方法,在水体、植被、不透水面3种不同下垫地表覆盖面积比例与地表温度之间建立关联,进而得出城市下垫面布局对热环境的贡献。结果发现,对于中小城市而言,在城市发展的进程中,若能保持区域内植被覆盖面积高占比,即使不透水面的面积占比有所增加,人类活动区域加大,也不一定会导致城市热岛现象的加剧。     

基于混合光谱分解的兰州城市热岛与下垫面空间关系分析

利用Landsat ETM+数据,采用混合像元线性光谱分解方法提取的城市植被覆盖度与不透水面表征城市下垫面,通过单窗算法反演地表真实温度,对兰州市中心城区的夏季城市热岛强度与城市下垫面的空间分布关系进行相关分析。结果显示,利用中等分辨率ETM+影像对兰州中心城区不透水面和植被盖度分布提取,其成本较低,精度令人满意;兰州城区植被覆盖、不透水面与热岛强度的分布呈空间正自相关,地表温度的空间依赖性极强,与植被盖度和不透水面在空间方向上的相关性差异较大。     

超大城市土地覆盖与热环境的随机森林回归模型研究

目前对于超大城市土地覆盖和热环境定量模型研究报道不足,这主要是因为大城市地表温度和地表生物物理组分之间存在复杂的潜在非线性关系,这使得准确评估城市热环境情况遇到了严峻的技术挑战。研究选取中外6个典型超大城市（北京、上海、广州、伦敦、纽约和东京）为研究对象,以Landsat遥感影像为主要数据源,利用单通道算法反演各城市地表温度,采用随机森林回归模型（RFR）建立土地覆盖类型与城市热环境定量关系模型（LCT）,综合分析城市土地覆盖因子与热环境间的多维定量关系。土地覆盖与地表温度的定量关系显示,城市地表热场的空间结构在很大程度上被下垫面用地类型所左右,不透水面会导致高温热场的聚集,而植被和水体则有降温作用。6个超大城市地表覆盖结构变化产生的升温/降温效应有所差异,北京、上海、纽约和东京等城市区域的植被和水体降温效应较广州和伦敦显著。基于随机森林回归方法建立了NDVI、MNDWI和NDISI等3种土地覆盖类型与城市热环境的综合定量关系模型（LCT）,模型得到的精度高于基于多元线性回归方法建立的模型。LCT_RF模型的R²值在0.623~0.826之间,比LCT_MLR模型高0.021~0.074;RMSE比LCT_MLR模型低0.07℃~0.35℃。研究超大城市土地覆盖与城市热环境的互动作用机理,能为未来生态城市建设提供宝贵建议。     

加尔各答市地表温度与不透水面比例季相相关性研究

城市化的显著特征是自然地表不断被热容量大的不透水面取代,进而造成城市热岛效应和严重的城市生态问题。孟中印缅经济走廊是古代南方丝绸之路的重要路段和“一带一路”建设的重要战略通道,加尔各答市是孟中印缅经济走廊印度境内的重要节点城市,战略地位重要,对其城市化进程及与地表温度相关性研究对孟中印缅经济走廊印度段建设具有重要的借鉴意义。传统地表温度与不透水面的相关性研究主要以年为时间尺度,较少关注城市不同季相地表温度与不透水面的相关性及其差异。以热带季风气候的季相区分为依据,基于旱季、雨季和凉季3个季相的Landsat 8影像反演了加尔各答市地表温度和不透水面比例,定量研究两者的关系,探讨了地表温度与不透水面比例的季相相关性。结果表明：①研究区内,低温和高温空间分布相对比较集中,高温区域集中在建成区,而低温主要分布在茂密植被覆盖区和水体区域;②加尔各答市从旱季到雨季再到凉季热岛效应程度总体呈下降趋势,旱季时城市热岛效应最强,凉季时城市热岛效应最弱;③每个季相,地表温度与不透水面比例都呈正相关,地表温度随着不透水面比例增加均呈现先快速上升,后缓慢增加,最后急剧增加的趋势,其中旱季时地表温度增长最快,雨季时地表温度增长次之,凉季时地表温度增长最慢。加尔各答市热环境研究将对孟中印缅经济走廊印度段城市热环境背景及生态效应认知等方面产生积极意义。     

基于ASTER遥感的杭州城市热/冷岛的景观特征分析

以杭州市中心城区为研究对象,基于ASTER热红外遥感数据反演杭州市中心城区地表温度、提取热环境边界,结合Landsat8OLI数据进行土地利用分类来提取不透水面和植被信息。在此基础上主要进行以下两方面研究:通过均值—标准差法提取杭州市热岛和冷岛边界,对比分析热岛和冷岛区内的景观模式差异,识别对杭州市中心城区地表温度影响最大的地物;使用空间梯度分析法来定量揭示杭州市地表温度与植被、不透水面的关系,并分析杭州市地表温度的空间分布特征。结果表明:(1)热岛和冷岛区域内存在较大的景观模式差异,热岛区域内不透水面对温度变化影响最大,而冷岛区域内植被对杭州市中心城区地表温度影响最为明显,且降温效果大于水体;(2)随着与市中心距离的增加,地表温度平均值与不透水面密度趋势线走向基本一致(正相关),与植被密度趋势线走向大致相反(负相关),且不透水面对地表温度的增温效应大于植被的冷却效应。     

武汉市主城区公园景观的热环境效应

针对城市热岛效应给城市居民生活带来的负面影响日益显著的问题,以武汉市为研究区,使用高分2号遥感影像,采用人机交互解译方法得到研究区公园景观类型,同时基于2016年7月23日Landsat-8 OLI影像,采用IB算法(image-based method)反演得到主城区地表温度,对研究区公园景观的热环境效应进行分析。研究表明:公园内部不透水层地表平均温度最高,为36.19℃,而林地、草地和水体平均温度相对较低,均低于30℃,其中水体平均温度最低,仅有27.57℃;公园内部林地、草地和水体上空形成明显低温集聚区,而不透水层地表上空易形成高温集聚区;公园降温影响范围和降温幅度与公园中林草地面积、林草地景观聚集度呈现明显的正相关性,而与不透水层面积和景观聚集度之间呈现明显的负相关性。本研究对于城市公园规划选址、公园内部景观结构设计和提升城市人居环境适宜性都有着重要意义。     

成都市地表温度对不透水面的响应研究

根据成都三环路内的Landsat 7/ETM+影像,利用单窗算法和不透水面与植被覆盖度在城市建成区呈负相关关系两种反演方法,通过空间建模建立反演模型,获取地表温度与不透水面信息。通过随机样点分析、相关性分析以及等温线与等透水面线叠加分析等方法,研究了城市地表温度对不透水面的响应效果。结果表明:地表温度随距市中心区距离增大而降低,同时不透水能力也降低;成都市地表温度与不透水面之间存在着正相关关系,相关度为0.7253;等透水面线的空间分布对等温线具有显著的响应规律。研究成果对于改善城市生态环境、提升土地利用水平和加强科学规划等都具有参考价值。     

广州市地表温度反演与土地利用覆盖变化关系研究

利用环境星1A/1B遥感影像,运用Jiménez-Munoz & Sobrino's普适性单通道算法定量反演广州市的地表温度(Land Surface Temperature,LST) ,结合MNF主成分分析和支持向量机获取的不透水面分布格局,利用面向对象分类方法获得了土地利用覆盖情况,重点研究广州市不透水面、土地覆盖和植被指数与城市热环境的定量关系。研究结果显示:基于大气水汽含量实测数据的JM&S普适性单通道算法反演结果更精确;广州市2009~2011年的不透水面面积和土地覆盖与平均地表温度相关性分析表明:广州市连续3 a呈现城市扩张的现象,城市热效应显著加剧;城市平均地表温度与不透水面面积呈现正相关,与城市的植被指数和裸土指数呈现负相关。     

城市不透水面及其与城市热岛的关系研究-以泉州市区为例

利用Landsat TM卫星影像提取了泉州市1989到1996年的城市建成区不透水面,并研究了其与城市热岛之间的关系。根据Ridd(1995)提出的城市建成区不透水面与植被覆盖度有很强的负相关关系的思想,先利用归一化植被指数求出泉州市建成区的植被覆盖度,进而提取了泉州市建成区的不透水面。通过比较所提取的两个时相不透水面信息,可以看出泉州市区不透水面的面积在7年里有了明显的增加,并主要沿研究区东南部扩展。通过将所提取的不透水面信息与利用TM6波段反演的地表温度进行相关分析,可发现二者之间存在着明显的正相关关系。     

Comparison of impervious surface area and normalized difference vegetation index as indicators of surface urban heat island effects in Landsat imagery

This paper compares the normalized difference vegetation index (NDVI) and percent impervious surface as indicators of surface urban heat island effects in Landsat imagery by investigating the relationships between the land surface temperature (LST), percent impervious surface area (%ISA), and the NDVI. Landsat Thematic Mapper (TM) and Enhanced Thematic Mapper Plus (ETM+) data were used to estimate the LST from four different seasons for the Twin Cities, Minnesota, metropolitan area. A map of percent impervious surface with a standard error of 7.95% was generated using a normalized spectral mixture analysis of July 2002 Landsat TM imagery. Our analysis indicates there is a strong linear relationship between LST and percent impervious surface for all seasons, whereas the relationship between LST and NDVI is much less strong and varies by season. This result suggests percent impervious surface provides a complementary metric to the traditionally applied NDVI for analyzing LST quantitatively over the seasons for surface urban heat island studies using thermal infrared remote sensing in an urbanized environment.     

非渗透表面丰度提取方法运用——以广州市海珠区为例

非渗透表面丰度即非渗透表面含量百分比,是水文学中不透水层与遥感领域混合像元分解概念相结合的产物。在城市区域,非渗透表面多指房屋、道路、停车场等建设用地区。本文基于广州市海珠区2000年ETM＋数据,首次采用单窗算法反演的地表温度数据与植被-非渗透表面-土壤（V-I-S）模型、归一化线性混合光谱模型（NSMA）相结合的方法提取研究区非渗透表面丰度值,并对提取结果进行49个300m×300m有效样区的抽样检验。结果表明抽样值与真实值之间存在10.03%的均方根误差以及2.65%的系统误差,从而进一步验证了三模型结合使用提取非渗透表面丰度的可行性。     

Impacts of landscape structure on surface urban heat islands: A case study of Shanghai, China

Urbanization is taking place at an unprecedented rate around the world, particularly in China in the past few decades. One of the key impacts of rapid urbanization on the environment is the effect of urban heat island (UHI). Understanding the effects of landscape pattern on UHI is crucial for improving the ecology and sustainability of cities. This study investigated how landscape composition and configuration would affect UHI in the Shanghai metropolitan region of China, based on the analysis of land surface temperature (LST) in relation to normalized difference vegetation index (NDVI), vegetation fraction (Fv), and percent impervious surface area (ISA). Two Landsat ETM+ images acquired on March 13 and July 2, 2001 were used to estimate LST, Fv, and percent ISA. Landscape metrics were calculated from a high spatial resolution (2.5 × 2.5 m) land-cover/land-use map. Our results have showed that, although there are significant variations in LST at a given fraction of vegetation or impervious surface on a per-pixel basis, NDVI, Fv, and percent ISA are all good predictors of LST on the regional scale. There is a strong negative linear relationship between LST and positive NDVI over the region. Similar but stronger negative linear relationship exists between LST and Fv. Urban vegetation could mitigate the surface UHI better in summer than in early spring. A strong positive relationship exists between mean LST and percent ISA. The residential land is the biggest contributor to UHI, followed by industrial land. Although industrial land has the highest LST, it has limited contribution to the overall surface UHI due to its small spatial extend in Shanghai. Among the residential land-uses, areas with low- to-middle-rise buildings and low vegetation cover have much high temperatures than areas with high-rise buildings or areas with high vegetation cover. A strong correlation between the mean LST and landscape metrics indicates that urban landscape configuration also influences the surface UHI. These findings are helpful for understanding urban ecology as well as land use planning to minimize the potential environmental impacts of urbanization.     

Characterizing fractional vegetation cover and land surface temperature based on sub-pixel fractional impervious surfaces from Landsat TM/ETM+

Estimating the distribution of impervious surfaces and vegetation is important for analysing urban landscapes and their thermal environment. The application of a crisp classification of land-cover types to analyse urban landscape patterns and land surface temperature (LST) in detail presents a challenge, mainly due to the complex characteristics of urban landscapes. In this article, sub-pixel percentage impervious surface areas (ISAs) and fractional vegetation cover (FVC) were extracted from bitemporal Thematic Mapper/Enhanced Thematic Mapper Plus (TM/ETM+) data by linear spectral mixture analysis (LSMA). Their accuracy was assessed with proportional area estimates of the impervious surface and vegetation extracted from high-resolution data. A range approach was used to classify percentage ISA into different categories by setting thresholds of fractional values and these were compared for their LST patterns. For each ISA category, FVC, LST, and percentage ISA were used to quantify the urban thermal characteristics of different developed areas in the city of Fuzhou, China. Urban LST scenarios in different seasons and ISA categories were simulated to analyse the seasonal variations and the impact of urban landscape pattern changes on the thermal environment. The results show that FVC and LST based on percentage ISA can be used to quantitatively analyse the process of urban expansion and its impacts on the spatial–temporal distribution patterns of the urban thermal environment. This analysis can support urban planning by providing knowledge on the climate adaptation potential of specific urban spatial patterns.     

使用单窗算法研究北京城区热岛效应

随着全球变暖和城市化进程的加快,大城市城区的热岛效应日益严重。城市下垫面对地表能量交换的影响巨大,引起地表温度分布的不均一性。遥感技术的发展为地表温度的反演提供了可能。近年来人们使用劈窗算法对均一的海面温度的反演很成功,但是受空间分辨率的限制以及陆面的不均一性,陆面温度的反演一直是一个没有解决好的问题。覃志豪提出了一种TM热红外波段单窗算法,可以利用辅助气象资料快速计算出地表温度。本文以北京市城区为研究区,采用LandsetETM第6波段的单窗算法,反演了亮度温度和地表实际温度,分析了城市下垫面情况下NDVI与地表温度的相关关系,并解释了北京城区热岛在空间上的分布及其可能的原因。结果表明:北京市城区热岛效应显著;地表温度与NDVI相关性显著;城区绿地和水体在区域的温度分布中起到重要作用。     

Analysis of Landscape Characteristics of Urban Heat /Sink Islandin Hangzhou based on ASTER Remote Sensing Imagery

Rapid urbanization has significant contributions to the Surface Urban Heat Island (SUHI).Analyzing the SUHI distribution and its impact factors using remote sensing data has received increasing attentions in the past decades,whereas few study has investigated that of the surface Urban Heat Sink Island (SUHI).The paper selects Hangzhou metropolis as a case study to explore SUHI/SUHS spatial patterns and its causes.We first retrieve the Land Surface Temperature (LST) using ASTER thermal infrared remote sensing imagery and extract the region of SUHI/SUHS using the Mean\|Standard deviation method.Landsat8 OLI data is used to classify land use and extract both impervious surface and vegetation information.After that,different landscape patterns within SUHI/SUHS area are analyzed and quantified by using several selected landscape index.The largest impact factors in SUHI/SUHS areas are identified.Finally,we analyze the spatial characteristics of LST using the spatial gradient analysis method,and reveal its relationship with vegetation and impervious surface.The results show that：(1) a large landscape pattern difference exists within SUHI/SUHS area;the impervious surface has the greatest impact on LST of the SUHI area,whereas the vegetation has more obviously cooling effect on LST of the SUHS area than the water body;(2) with the increasing distance from the city center,the same trend was found between the mean LST values and the impervious surface density (positive correlations),whereas the opposite trend between the mean LST values and the vegetation density (negative correlations).And the warming effect of impervious surface is greater than the cooling effect of vegetation in Hangzhou.     

Scaling of impervious surface area and vegetation as indicators to urban land surface temperature using satellite data

Vegetation and impervious surface as indicators of urban land surface temperature (LST) across a spatial resolution from 30 to 960 m were investigated in this study. Enhanced thematic mapper plus (ETM+) data were used to retrieve LST in Nanjing, China. A land cover map was generated using a decision tree method from IKONOS imagery. Taking the normalized difference vegetation index (NDVI) and percent vegetation area (V) to present vegetated cover, and the normalized difference building index (NDBI) and percent impervious surface area (I) to present impervious surface, the correlation coefficients and linear regression models between the LST and the indicators were simulated. Comparison results indicated that vegetation had stronger correlation with the LST than the impervious surface at 30 and 60 m, a similar magnitude of correlation at 120 and 240 m, and a much lower correlation at 480 and 960 m. In total, the impervious surface area was a slightly better indicator to the LST than the vegetation because all of the correlation coefficients were relatively high (>0.5000) across the spatial resolution from 30 to 960 m. The indicators of LST, V and I are slightly better than the NDVI and NDBI, respectively, based on the correlation coefficients between the LST and the four indices. The strongest correlation of the LST and vegetation at the resolution of 120 m, and the strongest correlation between the LST and impervious surface at 120, 480 and 960 m, denoted the operational scales of LST variations.     

An integrated soft and hard classification approach for evaluating urban expansion from multisource remote sensing data: a case study of the Beijing–Tianjin–Tangshan metropolitan region,China

Integrating soft and hard classification to monitor urban expansion can effectively provide comprehensive urban growth information to urban planners. In this study, both the impervious surface coverage (as a soft classification result) and land cover (as a hard classification result) in the Beijing–Tianjin–Tangshan metropolitan region (BTTMR), China, were extracted from multisource remote sensing data from 1990 to 2015. Then, we evaluated urban expansion based on centre migration, standard deviation ellipse, and spatial autocorrelation metrics. Furthermore, the differences between the soft and hard classification results were analysed at the landscape scale. The results showed that (1) the impervious surface area increased considerably over the past 25 years. Notably, the areas of urban built-up land and industrial production land increased rapidly, while those of ecological land and agricultural production land seriously decreased. (2) The distribution of impervious surfaces was closely related to the regional economic development plan of ‘One Axis, Two Wing, and Multi-Node’ in the BTTMR. (3) The contributions of different land use types to impervious surface growth ranked from high to low as follows: urban built-up land, rural residential land, industrial production land, agricultural production land, and ecological land. (4) The landscape metrics varied considerably based on the hard and soft classification results and were sensitive to different factors.