Water Detection in Satellite Images Based on Fractal Dimension

Del-Pozo-Velázquez, Javier; Chamorro‐Posada, Pedro; Aguiar-Pérez, Javier M.; Pérez-Juárez, María A.; Casaseca‐de‐la‐Higuera, Pablo

doi:10.3390/fractalfract6110657

Cited by 5 publications

(2 citation statements)

References 31 publications

(35 reference statements)

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“…Yue [20] emphasized that the thermal field profile length and the logarithm of scale have scaling characteristics only within a certain scale, which is consistent with the conclusion of this study. The use of fractal theory and remote sensing data to analyze the urban thermal environment is not limited to thermal image analysis and includes urban landscape form analysis, land use detection, reconstruction simulation, and others [21][22][23][24]. Zhou [25] conducted a representative study on impervious surfaces and thermal environment fractals in typical oasis cities in arid zones (Urumqi, Korla, Karamay, and Hami), and noted that the fractal dimension of the binary image of an impervious surface index with a normalized difference is scale-invariant only at some thresholds.…”

Section: Discussionmentioning

confidence: 99%

A scaling region identification method for the divider dimension of urban thermal environments

Tao,

2024

J. Phys.: Conf. Ser.

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A scaling region identification method for divider dimensions using the coefficient of determination is proposed to improve the estimation accuracy of the divider dimension in the study of urban thermal environment differentiation characteristics. The effectiveness of this method was verified by analyzing the urban surface thermal field differentiation characteristics by applying the estimated divider dimensions of Nanjing’s thermal environment surfaces and transect lines. The research results show that the urban thermal environment has fractal characteristics only within a certain temperature threshold range. When the constraint of scaling regions is considered, the calculated divider dimension of the surface thermal field surface increases, reflecting the more complex fractal structure of the thermal field. For each temperature grade, the “trough” position of the thermal field divider dimension surface estimated by the line-divider method is near the determination level of the high-temperature region based on robust statistics, allowing the spatial extent of the urban heat island (UHI) to be determined based on the “trough” feature of the thermal field divider dimension surface.

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Section: Discussionmentioning

confidence: 99%

A scaling region identification method for the divider dimension of urban thermal environments

Tao,

2024

J. Phys.: Conf. Ser.

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“…This method can extract the features of eddy currents on a two-dimensional cross-section [22,23]. Del-Pozo-Velazquez et al [24] processed high-resolution satellite images based on image segmentation, quadtree algorithm and fractal dimension method to detect surface water. Ma et al [25] proposed a segmentation method of mouse cortical synaptic fissure on an EM image stack based on the fractal dimension.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Fractal Characteristics of Karman Vortex for NACA0009 Hydrofoil

et al. 2023

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A Karman vortex is a phenomenon of fluid flow that can cause fluctuation and vibration. As a result, it leads to fatigue damage to structures and induces safety accidents. Therefore, the analysis of the shedding law and strength of the Karman vortex is significant. To further understand the laws of turbulent Karman vortex shedding and strength, this study conducts a numerical vorticity simulation of a Karman vortex at the trailing edge of a hydrofoil based on the two-dimensional simplified model of the NACA0009 hydrofoil under different Reynolds numbers. Combined with image segmentation technology, the fractal characteristics of a turbulent Karman vortex at the trailing edge of a hydrofoil are extracted, the number and total area of vortex cores are calculated, and the fractal dimension of the vortex is obtained. The results show that the fractal dimension can characterize the change in vortex shape and strength under different Reynolds numbers, and that the fractal analysis method is feasible and effective for the shedding analysis of a turbulent Karman vortex.

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