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1.
全波形LiDAR数据分解的可变分量高斯混合模型及RJMCMC算法   总被引:1,自引:1,他引:0  
赵泉华  李红莹  李玉 《测绘学报》2015,44(12):1367-1377
传统激光雷达(light detection and ranging,LiDAR)数据处理均采用固定数的波形分解方法,容易遗漏部分重叠的返回波,降低波形拟合精度。为了实现可变数波形分解,本文提出了一种自动确定波形分解数的方法。假定波形数据服从混合高斯分布,并以此建立理想的波形模型;定义用于控制理想模型与实际波形拟合程度的能量函数,用吉布斯分布构建或然率;根据贝叶斯定理构建刻画波形分解的后验概率模型;设计可逆跳转马尔科夫链蒙特卡洛(reversible jump Markov chain Monte Carlo,RJMCMC)算法模拟该后验概率模型,以确定波形分解数并同时完成波形分解。为了验证提出算法的正确性,分别对不同区域的ICESat-GLAS波形数据进行了波形分解试验,定性和定量分析结果验证了本文方法的有效性、可靠性和准确性。  相似文献   

2.
波形分解是机载激光雷达全波形数据处理的重要基础工作,通过求解波形函数模型的参数,将波形数据利用具体的函数模型拟合出来,实现对全波形及其中各个子波形函数表达。LM(Levenberg-Marquardt)算法及其改进的算法是波形分解中对参数进行拟合求解的常用方法。针对LM算法在参数拟合计算的过程中存在大量迭代和矩阵运算,提出了基于线程块组和线程两级并行粒度的并行计算方案。将串行多次循环迭代求解参数改为单次并行计算取最佳值实现对参数的选择,将矩阵运算进行线程块的协同并行计算,实现了LM算法在通用计算图形处理器上的并行计算。实验证明,在规定阈值条件下,并行LM降低了算法的迭代次数,提高了波形分解LM算法的计算效率,为提高波形分解的处理效率提供了研究思路。  相似文献   

3.
Full-waveform topographic LiDAR data provide more detailed information about objects along the path of a laser pulse than discrete-return (echo) topographic LiDAR data. Full-waveform topographic LiDAR data consist of a succession of cross-section profiles of landscapes and each waveform can be decomposed into a sum of echoes. The echo number reveals critical information in classifying land cover types. Most land covers contain one echo, whereas topographic LiDAR data in trees and roof edges contained multi-echo waveform features. To identify land-cover types, waveform-based classifier was integrated single-echo and multi-echo classifiers for point cloud classification.The experimental area was the Namasha district of Southern Taiwan, and the land-cover objects were categorized as roads, trees (canopy), grass (grass and crop), bare (bare ground), and buildings (buildings and roof edges). Waveform features were analyzed with respect to the single- and multi-echo laser-path samples, and the critical waveform features were selected according to the Bhattacharyya distance. Next, waveform-based classifiers were performed using support vector machine (SVM) with the local, spatial features of waveform topographic LiDAR information, and optical image information. Results showed that by using fused waveform and optical information, the waveform-based classifiers achieved the highest overall accuracy in identifying land-cover point clouds among the models, especially when compared to an echo-based classifier.  相似文献   

4.
The Geoscience Laser Altimeter System (GLAS) aboard Ice, Cloud and land Elevation Satellite (ICESat) is a spaceborne LiDAR sensor. It is the first LiDAR instrument which can digitize the backscattered waveform and offer near global coverage. Among others, scientific objectives of the mission include precise measurement of vegetation canopy heights. Existing approaches of waveform processing for canopy height estimation suggest Gaussian decomposition of the waveform which has the limitation to properly characterize significant peaks and results in discrepant information. Moreover, in most cases, Digital Terrain Models (DTMs) are required for canopy height estimation. This paper presents a new automated method of GLAS waveform processing for extracting vegetation canopy height in the absence of a DTM. Canopy heights retrieved from GLAS waveforms were validated with field measured heights. The newly proposed method was able to explain 79% of variation in canopy heights with an RMSE of 3.18 m, in the study area. The unexplained variation in canopy heights retrieved from GLAS data can be due to errors introduced by footprint eccentricity, decay of energy between emitted and received signals, uncertainty in the field measurements and limited number of sampled footprints.Results achieved with the newly proposed method were encouraging and demonstrated its potential of processing full-waveform LiDAR data for estimating forest canopy height. The study also had implications on future full-waveform spaceborne missions and their utility in vegetation studies.  相似文献   

5.
激光雷达作为一种主动的三维遥感观测技术,在不同尺度的土地、矿产、森林、草原、湿地、水、海洋等自然资源的三维动态监测中发挥着越来越重要的作用。本文将在简要介绍激光雷达技术发展现状的基础上,重点阐述激光雷达技术在各类自然资源三维动态监测中的应用现状,同时对激光雷达在自然资源调查中的应用潜力和局限性进行综合分析,最后探讨以激光雷达技术为基础的自然资源三维动态监测的未来发展趋势和方向。随着激光雷达技术和平台的不断发展以及激光雷达信息的深入挖掘,将不断促进激光雷达技术在自然资源三维动态监测应用中的纵深发展。然而单一激光雷达数据由于其本身存在的局限性,难以满足自然资源全要素、全流程、全覆盖、高精度、高效率的现代化动态监测的要求,如何将多源、多尺度、多平台遥感数据与人工智能相结合,构建“天—空—地”一体化的自然资源调查监测技术体系,是未来自然资源三维动态监测的发展方向。  相似文献   

6.
黄克标  庞勇  舒清态  付甜 《遥感学报》2013,17(1):165-179
结合机载、星载激光雷达对GLAS(地球科学激光测高系统)光斑范围内的森林地上生物量进行估测,并利用MODIS植被产品以及MERIS土地覆盖产品进行了云南省森林地上生物量的连续制图。机载LiDAR扫描的260个训练样本用于构建星载GLAS的森林地上生物量估测模型,模型的决定系数(R2)为0.52,均方根误差(RMSE)为31Mg/ha。研究结果显示,云南省总森林地上生物量为12.72亿t,平均森林地上生物量为94Mg/ha。估测的森林地上生物量空间分布情况与实际情况相符,森林地上生物量总量与基于森林资源清查数据的估测结果相符,表明了利用机载LiDAR与星载ICESatGLAS结合进行大区域森林地上生物量估测的可靠性。  相似文献   

7.
大光斑激光雷达数据已广泛应用于森林冠层高度提取,但通常仅限于地形坡度小于20°的平缓地区。在地形坡度大于20°的陡峭山区,地形引起的波形展宽使得地面回波和植被回波信息混合在一起,给森林冠层高度提取带来巨大挑战。本文利用激光雷达回波模型和地形信息,提出了一种模型辅助的坡地森林冠层高度反演算法。该方法以激光雷达回波信号截止点为参考,定义了波形高度指数H50和H75,使用激光雷达回波模型与已知地形信息模拟裸地的激光雷达回波,将裸地回波信号截止点与森林激光雷达回波信号截止点对齐,利用裸地回波计算常用的波形相对高度指数RH50和RH75,对森林冠层高度进行反演。并与高斯波形分解法和波形参数法的反演结果进行了比较。研究结果表明:(1)利用所提取的波形指数RH50和RH75对胸高断面积加权平均高(Lorey’s height)进行了估算,在坡度小于20°时,高斯波形分解法、波形参数法和模型辅助法的估算结果与实测值线性拟合的相关系数(R2)分别为0.70,0.78和0.98,对应的均方根误差(RMSE)分别为2.90 m,2.48 m和0.60 m,模型辅助法略优于其他两种方法;(2)在坡度大于20°时,高斯波形分解法、波形参数法和模型辅助法的R2分别为0.14,0.28和0.97,相应的RMSE分别为4.93 m,4.53 m和0.81 m,模型辅助法明显优于其他两种方法;(3)在0°—40°时,模型辅助法对Lorey’s height估算结果与实测值的R2为0.97,RMSE为0.80 m。本研究提出的模型辅助法具有更好的地形适应性,在0°—40°的坡度范围内具备对坡地森林冠层高度反演的潜力。  相似文献   

8.
激光雷达森林参数反演研究进展   总被引:6,自引:0,他引:6  
李增元  刘清旺  庞勇 《遥感学报》2016,20(5):1138-1150
激光雷达通过发射激光能量和接收返回信号的方式,来获取高精度的森林空间结构和林下地形信息。全波形激光雷达通过记录返回信号的全部能量,得到亚米级植被垂直剖面;离散回波激光雷达记录的单个或多个回波,表示来自不同冠层的回波信号。星载激光雷达一般采用全波形或光子计数激光剖面系统,仅能获取卫星轨道下方的单波束或多波束数据,用于区域/全球范围的森林垂直结构及变化观测。机载激光雷达多采用离散回波或全波形激光扫描系统,能够获取飞行轨迹下方特定视场范围内的扫描数据,用于林分/区域范围的森林结构观测。地基激光雷达多采用离散回波激光扫描系统,获取以测站为中心的球形空间内扫描数据,用于单木/样地范围的森林结构观测。激光雷达单木因子估测方法可分为CHM单木法、NPC单木法和体元单木法3类。CHM单木法通过局部最大值识别树冠顶点,采用区域生长或图像分割算法识别树冠边界或树冠主方向,NPC单木法一般通过空间聚类或形态学算法识别单木,体元单木法在3维体元空间采用区域生长或空间聚类算法识别树冠。根据激光雷达冠层高度分布可以估测林分因子,冠层高度分布特征来自于离散点云或全波形。多时相激光雷达可用于森林生长量、生物量变化等监测,以及森林采伐、灾害等引起的结构变化监测。随着激光雷达技术的发展,它将在森林调查、生态环境建模等生产与科学研究领域中得到更为广泛的应用。  相似文献   

9.
全波形激光雷达的波形优化分解算法   总被引:1,自引:0,他引:1  
随着数据存储能力和处理速度的提高,三维激光扫描系统逐渐具备全波形采集和分析技术。为了从全波形数据中获得脉冲时间、幅度、脉宽以及多回波分布等综合信息,波形分解成为了全波形激光雷达数据处理的关键技术之一。针对LM算法在一定程度上依赖初值,而传统激光雷达数据处理容易遗漏部分重叠的返回波,本文提出了一种改进回波分量初值设定的算法来获取回波脉冲的位置、宽度和强度。针对一套自主研发的全波形记录激光雷达演示系统进行了波形分解试验,定性和定量分析结果验证了该方法的有效性、可靠性和准确性。  相似文献   

10.
卢昊  庞勇  李增元  王迪  陈博伟  马振宇 《遥感学报》2020,24(11):1353-1362
为揭示全波形激光雷达回波在森林等植被区域多回波信号的特征和对目标识别分类的影响,以激光雷达方程为模型基础,利用朗伯体目标为地面参考,提出了将激光雷达波形参数标定为后向散射截面、后向散射系数和漫反射率等物理量的方法,实现了机载小光斑全波形机载激光雷达数据绝对辐射定标。对两个不同实验区的LMS-Q680i数据标定结果表明,漫反射率与参考反射率相对误差总体分别小于10%和5.5%,误差标准差分别为0.044和0.077,有效消除了条带间差异。推导了多回波的激光雷达方程组,比较了相同系统在不同观测条件下的定标常数变化,重点分析了全波形激光雷达在穿透性目标上的多回波现象造成的能量衰减,及其对辐射定标结果的影响,证明了多回波现象是造成多回波信号减弱的主要原因。该现象是当前技术体制下激光雷达观测过程本身存在的缺陷,对基于激光雷达辐射信息的目标识别分类带来了一定的挑战,也是多光谱、高光谱激光雷达辐射信号定标必须解决的问题。  相似文献   

11.
目前常用的小光斑机载LiDAR波形数据与系统点云数据的来源相关性较大,波形数据的优势难以严格定量地评价和比较。LeicaALS60机载LiDAR系统记录的全波形数据与点云数据相对独立,点云数据来自硬件系统脉冲探测方法,而波形数据是未加处理的原始回波序列。本文对原始波形数据进行分解获取发射脉冲的全部回波,与系统探测点云进行了定量对比,并选取典型林区和城区数据,得到波形在两种地物类型中垂直信息获取能力的定量表征参数。结果表明,波形数据对不同地物类型均能丰富垂直结构信息和提高点云垂直分辨率,且这种提高在林区表现优于城区人工建筑和裸地;激光对树木冠层的穿透能力更明显地表现在回波波形信息中,相较于传统点云激光雷达,全波形LiDAR在森林垂直参数获取方面潜力更大。  相似文献   

12.
Interest in using Light Detection and Ranging (LiDAR) technology in Transportation Engineering has grown over the past decade. The high accuracy of LiDAR datasets and the efficiency by which they can be collected has led many transportation agencies to consider mobile LiDAR as an alternative to conventional tools when surveying roadway infrastructure. Nonetheless, extracting semantic information from LiDAR datasets can be extremely challenging. Although extracting roadway features from LiDAR has been considered in previous research, the extraction of some features has received more attention than others. In fact, for some roadway design elements, attempts to extract those elements from LiDAR have been extremely scarce. To document the research that has been done in this area, this paper conducts a thorough review of existing studies while also highlighting areas where more research is required. Unlike previous research, this paper includes a thorough review of the previous attempts at data extraction from LiDAR while summarizing the detailed steps of the extraction procedure proposed in each study. Moreover, the paper also identifies common tools and techniques used to extract information from LiDAR for transportation applications. The paper also highlights common limitations in existing algorithms that could be improved in future research. This paper represents a valuable resource for researchers and practitioners interested in knowing the current state of research on the applications of LiDAR in the field of Transportation Engineering while also understanding the opportunities and challenges that lie ahead.  相似文献   

13.
张良  姜晓琦  周薇薇  张帆 《测绘科学》2018,(3):148-153,160
针对传统的LM波形分解算法在GLAS大光斑波形数据处理中容易陷于局部最优解,限制了GLAS大光斑激光雷达数据在森林结构参数反演方面应用的问题,该文结合GLAS大光斑数据特征,引进优化后的EM算法对大光斑全波形数据进行分解,获取波形参数最优值。结合波形前缘长度和波形后缘长度,建立树高反演模型,并与LM分解算法建立的模型进行对比分析。研究结果表明,通过改进的EM算法对GLAS大光斑激光雷达数据进行处理,波形特征参数的获取更为精确,达到了较高的树高反演精度。  相似文献   

14.
吉林长白山森林冠顶高度激光雷达与MERSI联合反演   总被引:1,自引:0,他引:1  
将激光雷达与光学遥感相结合进行区域林分冠顶高度联合反演,提出了大脚印激光雷达GLAS脚点波形数据处理和不同地形条件下的森林冠顶高度反演算法,并建立了区域尺度不同森林类型林分冠顶高度GLAS+MERSI联合反演模型,制作了长白山地区森林冠顶高度图。  相似文献   

15.
Large footprint waveform LiDAR data have been widely used to extract tree heights. These heights are typically estimated by subtracting the top height from the ground. Compared to the top height detection, the identification of the ground peak in a waveform is more challenging. This is particularly evident in ground detection in shrub areas, where the reflection of the shrub canopy may significantly overlap with the ground reflection. To tackle this problem, a novel method based on Partial Curve-Fitting (PCF) of the shrub peak was developed to detect the ground peak. Results indicated that the PCF method improves ground identification by 32–42%, compared to existing methods. To offer further improvement, a Multi-Algorithm Integration Classifier (MAIC) was built to fuse multiple ground peak algorithms and selectively apply the best method for each waveform plot. The PCF ground peak identification method along with the MAIC-based fusion is expected to significantly improve ground detection and shrub height estimation, thus assisting biodiversity, forest succession, and carbon sequestration studies, while offering an early example of future multiple algorithm integration.  相似文献   

16.
Large footprint waveform LiDAR sensors have been widely used for numerous airborne studies. Ground peak identification in a large footprint waveform is a significant bottleneck in exploring full usage of the waveform datasets. In the current study, an accurate and computationally efficient algorithm was developed for ground peak identification, called Filtering and Clustering Algorithm (FICA). The method was evaluated on Land, Vegetation, and Ice Sensor (LVIS) waveform datasets acquired over Central NY. FICA incorporates a set of multi-scale second derivative filters and a k-means clustering algorithm in order to avoid detecting false ground peaks. FICA was tested in five different land cover types (deciduous trees, coniferous trees, shrub, grass and developed area) and showed more accurate results when compared to existing algorithms. More specifically, compared with Gaussian decomposition, the RMSE ground peak identification by FICA was 2.82 m (5.29 m for GD) in deciduous plots, 3.25 m (4.57 m for GD) in coniferous plots, 2.63 m (2.83 m for GD) in shrub plots, 0.82 m (0.93 m for GD) in grass plots, and 0.70 m (0.51 m for GD) in plots of developed areas. FICA performance was also relatively consistent under various slope and canopy coverage (CC) conditions. In addition, FICA showed better computational efficiency compared to existing methods. FICA’s major computational and accuracy advantage is a result of the adopted multi-scale signal processing procedures that concentrate on local portions of the signal as opposed to the Gaussian decomposition that uses a curve-fitting strategy applied in the entire signal. The FICA algorithm is a good candidate for large-scale implementation on future space-borne waveform LiDAR sensors.  相似文献   

17.
采用Levenberg Marquardt的逐步递进波形分解方法   总被引:1,自引:0,他引:1  
针对机载全波形Li DAR波形数据分解问题,提出一种采用Levenberg Marquardt的逐步递进波形分解方法。该方法基于Levenberg Marquardt的非线性最小二乘拟合算法,选取高斯函数模型并采用逐步递进的波形分解方式得到准确的模拟波形。对Riegl数据中的2条典型波形进行分解实验,并与普通非线性最小二乘方法的结果进行对比分析,证明该方法是可行有效的。  相似文献   

18.
星载大气探测激光雷达发展与展望   总被引:3,自引:0,他引:3  
从最早的星载激光雷达空间技术实验LITE出发,回顾了已成功发射的多颗星载激光雷达发展历程。详细阐述了LITE、CALIPSO等星载激光雷达在大气遥感领域,特别是气候环境变化和数值预报模式研究上所取得的成就。主要从全球气溶胶垂直结构及其辐射强迫、全球云垂直结构和特征、气溶胶-云-降水相互作用和气溶胶数据在雾-霾和沙尘天气预报中的应用等4个方面进行展开说明,并且深入分析了未来星载激光雷达在大气风场和大气成分探测方面所面临的需求和挑战。在大气风场探测需求方面,结合星载激光雷达探测优势从提高热带地区的天气预报准确率、提高非地转条件下中小尺度短时临近预报水平和填补卫星高/低空急流监测技术空白等3个方面进行详细论述。在大气成分探测需求方面,与传统被动探测仪器相比较,突出激光雷达在信噪比、CO2垂直结构和夜间探测上的明显优势。最后,指出全球风场和大气成分探测将成为未来星载激光雷达的重要发展方向。  相似文献   

19.
植被物候遥感监测研究进展   总被引:11,自引:0,他引:11  
植被物候是研究植被与气候、环境变化间关系的重要参量。本文针对目前常用的阈值法、拟合法和延迟滑动平均法等植被物候遥感监测方法进行比较分析;介绍了传感器网络法、物候模型法等物候遥感监测验证方法;从遥感监测方法和数据源两方面分析物候遥感监测的误差来源;针对目前研究中存在的问题,讨论了遥感物候的主要研究方向:从机理层面,应创新植被物候遥感监测方法;建立标准化地面验证数据源;利用多源遥感数据,组成高时间分辨率的原始遥感数据源,提高植被物候遥感监测的时间分辨率和测算精度。  相似文献   

20.
机载激光测深去卷积信号提取方法的比较   总被引:1,自引:1,他引:0  
为提高机载激光测深信号提取的精度,在测深波形数据处理中引入去卷积信号提取方法,即利用去卷积对波形进行预处理,再对去卷积后的波形实现峰值检测,以精确确定测深信号位置。通过定义性能评定指标对维纳滤波去卷积、非负最小二乘、理查德森-露西去卷积、盲源去卷积4种常用去卷积算法的信号复原能力进行对比分析,并对去卷积信号提取方法的信号检测能力进行验证。试验结果表明,理查德森-露西去卷积算法能够显著提高测深信号分辨率,且算法适应性强,成功率高;相比传统的峰值检测方法,去卷积信号提取方法具有更高的信号检测率、精度和更广的测深范围。  相似文献   

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