Deep learning approaches for delineating wetlands on historical topographic maps

Historical topographic maps are an important source of a visual record of the landscape, showing geographical elements such as terrain, elevation, rivers and water bodies, roads, buildings, and land use and land cover (LULC). Historical maps are scanned to their digital representation, a raster imag...

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Bibliographic Details
Published in:Transactions in GIS 2024-08, Vol.28 (5), p.1400-1411
Main Authors: Vynikal, Jakub, Müllerová, Jana, Pacina, Jan
Format: Article
Language:English
Subjects:
Artificial neural networks
Clustering
Deep learning
Digital imaging
Digital mapping
Information processing
Land cover
Land use
Machine learning
Neural networks
Object recognition
Pattern recognition
Raster scanning
Rivers
Semantic segmentation
Topographic mapping
Topographic maps
Topography
Visual discrimination learning
Wetlands
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Summary:Historical topographic maps are an important source of a visual record of the landscape, showing geographical elements such as terrain, elevation, rivers and water bodies, roads, buildings, and land use and land cover (LULC). Historical maps are scanned to their digital representation, a raster image. To quantify different classes of LULC, it is necessary to transform scanned maps to their vector equivalent. Traditionally, this has been done either manually, or by using (semi)automatic methods of clustering/segmentation. With the advent of deep neural networks, new horizons opened for more effective and accurate processing. This article attempts to use different deep‐learning approaches to detect and segment wetlands on historical Topographic Maps 1: 10000 (TM10), created during the 50s and 60s. Due to the specific symbology of wetlands, their processing can be challenging. It deals with two distinct approaches in the deep learning world, semantic segmentation and object detection, represented by the U‐Net and Single‐Shot Detector (SSD) neural networks, respectively. The suitability, speed, and accuracy of the two approaches in neural networks are analyzed. The results are satisfactory, with the U‐Net F1 score reaching 75.7% and the SSD object detection approach presenting an unconventional alternative.
ISSN:1361-1682
1467-9671
DOI:10.1111/tgis.13193