On the Optimal Representation of Vector Location using Fixed-Width Multi-Precision Quantizers

Sahr, Kevin

doi:10.5194/isprsarchives-xl-4-w2-1-2013

Cited by 10 publications

(3 citation statements)

References 20 publications

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“…Algorithmically there is one significant difference between rectangular and hexagonal processing: creating pyramids. The implementation does not use traditional hexagon aperture techniques (Sahr, ), but partitions each cell into six triangles, and weights them in order to calculate downsampled cell values (Figure ). As a consequence, cell orientations do not change, the number of cells is reduced quadratically at each level, and irregular hexagons with equal internal angles are also supported.…”

Section: Raster Processing With Javascriptmentioning

confidence: 99%

Possibilities of using raster data in client‐side web maps

Farkas

2019

Transactions in GIS

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Transactions in GIS. 2020;24:72-84. wileyonlinelibrary.com/journal/tgis | INTRODUC TI ONRapid development of technology in recent decades has not only introduced new possibilities in GIS and cartography, but also transformed them. The main focus has shifted from traditional mapping and analysis of spatial data to new, digitally better-supported approaches. For example, experts can now produce three-dimensional models from digital images, have to deal with different types of big data, and are finding ways to apply machine learning to Abstract Companies and individual developers have recently put serious effort into improving web mapping libraries. A significant front in this development is hardware-accelerated vector graphics. Owing to those efforts, and the continuously evolving World Wide Web, users can visualize large vector layers, and even animate them. On the other hand, this rapid development cannot be observed with raster data. There are some data abstraction libraries for reading raster files, although web mapping libraries do not use them to offer raster capabilities. Since there are no mature raster management pipelines on the web, this study explores two inherently different techniques for handling raster data.One of them uses the traditional, texture-based method.The other is a hybrid technique rendering raster layers as vectors, overcoming some limitations of the raster model.While the traditional technique gives a smooth user experience, the hybrid method shows promising results for rendering hexagonal coverages.

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Section: Raster Processing With Javascriptmentioning

confidence: 99%

Possibilities of using raster data in client‐side web maps

Farkas

2019

Transactions in GIS

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“…The fractal patterns usually have very complex shapes, and thus, they are not appropriate for point clustering. There are three reasonable variants of multi-resolution hexagonal grids often used in the Discrete Global Grid Systems [21][22][23]41,54]. Generally, the grids of aperture 3 and 4 are preferred (see Figure 6) to avoid the problems with fractal shapes.…”

Section: Hexagonal Curve Selectionmentioning

confidence: 99%

“…Several papers discussed the problems of different grid systems and their mutual conversion to combine their best properties [21][22][23], but they all miss the correct hierarchical 1-to-7 refinement in the hexagonal grid ( Figure 2) for a correct hexagonal SFC. During the last years, the hexagons have gained increased interest in scientific areas including geographic information systems [19][20][21][22][23]40,41], data clustering and querying [36,38,39,42,43], data visualization [44,45], computer graphics [46] and computer or sensor networks [24,25]. Recently, the transportation network company Uber Technologies Inc. introduced a discrete global grid system [11] based on multi-resolution hexagonal grids.…”

Section: Introductionmentioning

confidence: 99%

Hierarchical Hexagonal Clustering and Indexing

et al. 2019

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Space-filling curves (SFCs) represent an efficient and straightforward method for sparse-space indexing to transform an n-dimensional space into a one-dimensional representation. This is often applied for multidimensional point indexing which brings a better perspective for data analysis, visualization and queries. SFCs are involved in many areas such as big data analysis and visualization, image decomposition, computer graphics and geographic information systems (GISs). The indexing methods subdivide the space into logic clusters of close points and they differ in various parameters including the cluster order, the distance metrics, and the pattern shape. Beside the simple and highly preferred triangular and square uniform grids, the hexagonal uniform grids have gained high interest especially in areas such as GISs, image processing and data visualization for the uniform distance between cells and high effectiveness of circle coverage. While the linearization of hexagons is an obvious approach for memory representation, it seems there is no hexagonal SFC indexing method generally used in practice. The main limitation of hexagons lies in lacking infinite decomposition into sub-hexagons and similarity of tiles on different levels of hierarchy. Our research aims at defining a fast and robust hexagonal SFC method. The Gosper fractal is utilized to preserve the benefits of hexagonal grids and to efficiently and hierarchically linearize points in a hexagonal grid while solving the non-convex shape and recursive transformation issues of the fractal. A comparison to other SFCs and grids is conducted to verify the robustness and effectiveness of our hexagonal method.

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