Urban Remote Sensing. Группа авторов

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Название Urban Remote Sensing
Автор произведения Группа авторов
Жанр География
Серия
Издательство География
Год выпуска 0
isbn 9781119625858



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Even for small area collections, lidar data are broken up into tiles, much like orthoimagery, to reduce the computational burden of handling the data. Not surprisingly, visualizing and processing these datasets can be difficult. Geographical Information System (GIS) and remote sensing software packages, though, continue to improve at integrating these datasets with other geospatial information. Due to these issues, conversion from point cloud to raster format persists to simplify the data into a more useable format (also, most analysis tools process raster data instead of raw point clouds).

Photos depict 3D lidar-derived visualizations of downtown Austin, Texas looking northwest using raw point cloud data from 2015 (a), and extruded building footprints from 2006 (b). Schematic illustration of lidar data processing workflows, data products, and analysis approaches for urban remote sensing.

      Lidar‐derived raster surfaces, referred to generally as DEMs, provide a more approachable way in which to utilize lidar data. Note that DEMs are created with other elevation data and are not lidar‐specific datasets. Specific types of DEMs include the following:

       Digital Terrain Model (DTM): a raster representing the bare Earth surface. Absolute elevation values from mean sea level are stored in pixels.

       Digital Surface Model (DSM): a raster representing the bare Earth surface as well as all surface features such as buildings, tree canopies, etc. Absolute elevation values from mean sea level are stored in pixels. For this chapter, we elect not to use the DSM acronym for this dataset because it conflicts with another acronym we use in upcoming sections.

       Digital Height Model (DHM): a raster surface containing all features like the DSM but with relative elevation values from ground‐level stored in pixels. DHMs are also referred to as Normalized Digital Surface Models (nDSMs).

      As for built‐up analyses using lidar‐derived raster data (refer back to Figure 2.3), the DHM provides the ideal dataset because it is normalized and conveys building height data from ground level. Pixel values for buildings, therefore, are representative and useful. Using building footprints (vector polygons), individual building heights can be extracted and extruded to visualize only the built‐up environment as solid objects (see Figure 2.2). Building footprints are highly useful ancillary data for urban analyses and are often freely available through local cadastral mapping sources or can be generated using the DHM (and other data such as aerial imagery) through Object‐Based Image Analysis (OBIA). OBIA segmentation provides a semi‐automatic procedure to create vector polygons of ground features. In the urban environment, especially where buildings are quite tall and protrude from the surrounding landscape features, OBIA segmentation is effective (Teo and Shih 2013). Imagery‐lidar fusion (i.e. adding the DHM data as an additional band within an image stack) improves the accuracy of OBIA classification results within urban areas compared to imagery alone (Ellis and Mathews 2019). Lidar intensity information is also useful as an additional band for further differentiation of surface features in OBIA analyses.