MapLegendExtraction

This dataset contains high-resolution geological maps annotated with the bounding boxes of their embedded map legends, along with structured JSON representations of legend content. Designed for training models in legend detection, legend parsing, and map understanding.

League Of Legends Map Detection

## Overview

League Of Legends Map Detection is a dataset for object detection tasks - it contains Test annotations for 8,791 images.

## Getting Started

You can download this dataset for use within your own projects, or fork it into a workspace on Roboflow to create your own model.

  ## License

  This dataset is available under the [CC BY 4.0 license](https://creativecommons.org/licenses/CC BY 4.0).

Application for search and view legend of Geological maps at a scale of 1 : 50,000 (GEOČR50).

WQI Map Legend for the Water Quality Index Dashboard. This legend was created in an ArcGIS Pro layout, then captured as a JPG screenshot.

For complete collection of data and models, see https://doi.org/10.21942/uva.c.5290546.Original model developed in 2016-17 in ArcGIS by Henk Pieter Sterk (www.rfase.org), with minor updates in 2021 by Stacy Shinneman and Henk Pieter Sterk. Model used to generate publication results:Hierarchical geomorphological mapping in mountainous areas Matheus G.G. De Jong, Henk Pieter Sterk, Stacy Shinneman & Arie C. Seijmonsbergen. Submitted to Journal of Maps 2020, revisions made in 2021.This model creates tiers (columns) of geomorphological features (Tier 1, Tier 2 and Tier 3) in the landscape of Vorarlberg, Austria, each with an increasing level of detail. The input dataset needed to create this 'three-tier-legend' is a geomorphological map of Vorarlberg with a Tier 3 category (e.g. 1111, for glacially eroded bedrock). The model then automatically adds Tier 1, Tier 2 and Tier 3 categories based on the Tier 3 code in the 'Geomorph' field. The model replaces the input file with an updated shapefile of the geomorphology of Vorarlberg, now including three tiers of geomorphological features. Python script files and .lyr symbology files are also provided here.

ADMMR map collection: Geologic Map Legend; 36 x 22 in.

This is a guide that describes how to use the layer list and legend widgets in web maps where the functionality is available. Not all widgets or functionality is available in every web map.

Application for search items of geological map legend 1 : 25,000.

Danville Transit provides bus services to help residents and visitors travel around the city and surrounding areas. The primary role of Danville Transit is to offer affordable and reliable transportation for individuals who may not have access to private vehicles or prefer not to drive. The Danville Transit System map provides a visual representation of the routes, bus stops, and major transfer points for public transportation in the city of Danville, Virginia.

1:24,000 scale Geologic Map of the Crater Flat Area, Nevada. Detailed geologic mapping by James E. Faulds, John W. Bell, Daniel L. Feuerbach, and Alan R. Ramelli in 1994. Map includes description of 42 geologic units. The GIS work was in support of the U. S. Geological Survey COGEOMAP program. The Geodatabase specifies feature datasets and feature classes, together with feature attributes, subtypes and domains, suitable for the printed geologic map. In addition to basic geology (lithology, contacts and faults, etc.), the maps may include metamorphic overprints, cross-sections, and explanatory legend-graphics such as correlation charts, used to supplement columnar legends. This geologic map generally includes previously unpublished data obtained by the authors. However the mapping of Pliocene basalts by Crowe and others (1983) and Paleozoic-Proterozoic rocks by Monsen and others (1992) was incorporated into the southern part of the map area. Partial financial support for field work and map preparation was provided by the Nevada Agency of Nuclear Projects through the Center for Volcanic and Tectonic Studies, University of Nevada, Las Vegas; the Center for Neotectonic Studies, University of Nevada, Reno; and NSF grant EAR9120383 (awarded to Faulds). Base map: U. S. Geological Survey Crater Flat 7.5-minute Quadrangle, 1986. To download the map resource and associated report, and GIS zipped data sets, please see the links provided.

Use the Interactive Legend template to allow users to filter layers in your map by toggling the visibility of features based categories and ranges in the legend. Choose from paired feature-specific effects, such as bloom and blur, to distinguish between selected items in the legend and the remaining data. Choose from several options to emphasize selected items in the legend while other items remain on the map in muted colors. Examples: Form a better understanding of the spatial relationship between map features by changing the visibility of the content. Present economic data relevant to numerical range values of interest during a seminar. Analyze crime data to facilitate decision making of law enforcement distribution pertaining to specific crime categories. Data requirements The Interactive Legend template requires a feature layer to use all of its capabilities. The following drawing styles are supported: Location (Single Symbol) Types (Unique symbols) Counts and amounts (Size) - Classify Data Checked Counts and Amounts (Color) - Classify Data Checked Relationship Relationship and Size (Partially Interactive) Predominant Category Predominant Category and Size (Partially interactive) Types and Size (Partially interactive) Key app capabilities Layer effects - Use layer effects to differentiate between features included and excluded in a filter, and specify how features are emphasized and de-emphasized when a filter is applied using the legend. Zoom to button - Allow users to zoom to features selected in the legend. Feature count - Include a feature count for items that are selected in the legend Export - Capture an image (PDF, JPG, or PNG) from the app that a user can save. Time filter - Filter features in the map using time enabled layers Language switcher - Provide translations for custom text and create a multilingual app. Home, Zoom controls, Legend, Layer List, Search Supportability This web app is designed responsively to be used in browsers on desktops, mobile phones, and tablets. We are committed to ongoing efforts towards making our apps as accessible as possible. Please feel free to leave a comment on how we can improve the accessibility of our apps for those who use assistive technologies.

Data derived from the ATKIS Datenbestand:Legende for cascade

Geological map legend, North and North-East Greenland, 1:250 000

Soil Taxonomic Units in the map legend are named with the following convention: the four first letters abbreviate the taxon up to Subgroup level, a number differentiate among similar Subgroups, and the last two characters are linked to a lithostratigraphic unit. If defined, series are shown between brackets (Information source: Gómez-Miguel et al. 2015).

1:24,000 scale Geologic Map of the Delamar Lake Quadrangle, Lincoln County, Nevada, USGS GQ-1754. Detailed geologic mapping by Robert B. Scott, W C Swadley, and Steven W. Novak in 1993. Previous work includes the Geologic map of Tertiary rocks (Ekren, Orkild, Sargent, and Dixon, 1997); Preliminary Geologic map of the Delamar 3 SW quadrangle (Page, Swadley, and Scott, 1990); Preliminary Geologic map of the Vigo NW quadrangle (Scott, Harding, Swadley, Novak, and Pampeyan, 1991); Preliminary Geologic map of the Delamar 3 NE quadrangle (Scott, Novak, and Swadley, 1990a); Preliminary geologic map of the Delamar 3 NW quadrangle (Scott, Page, and Swadley, 1990b); Preliminary geologic map of the Pahroc Summit Pass and part of the Hiko SE quadrangle (Scott and Swadley, 1992); Preliminary geologic map of the Gregerson Basin quadrangle (Scott, Swadley, Page, and Novak, 1990); Preliminary Geologic map of the Delamar 3 SE quadrangle (Swadley, Page, Scott, and Pampeyan, 1990); Preliminary geologic map of the Delamar NW quadrangle (Swadley and Scott, 1990). Geologic Map of the Delamar 3 SE 7.5' quadrangle in Lincoln County, Nevada, with 0 cross sections and description of 44 units. The GIS work was in support of the U. S. Geological Survey COGEOMAP program. The Geodatabase specifies feature datasets and feature classes, together with feature attributes, subtypes and domains, suitable for a variety of geologic maps. In addition to basic geology (lithology, contacts and faults, etc.), the maps may include metamorphic overprints, cross sections, and explanatory legend-graphics such as correlation charts, used to supplement columnar legends. For more information about this resource or to download the map and associated legend text and GIS zipped data sets, please see the links provided.

Geospatial data about Otaki Soil Map Legend - ArcGIS Layer file. Export to CAD, GIS, PDF, CSV and access via API.

1:24,000 scale Geologic Map of the Southern Half of the Last Chance Range Quadrangle, Nye County, Nevada, Map OF2003-14. Detailed geologic mapping by Craig M. DePolo and Alan R. Ramelli of the Nevada Bureau of Mines and Geology in 2002. Field work done in 2002. Bedrock geology modified from Burchfiel and others (1982). Shows description of 23 units. The GIS work was in support of the U. S. Geological Survey COGEOMAP program. The Geodatabase specifies feature datasets and feature classes, together with feature attributes, subtypes and domains, suitable for the printed geologic map. In addition to basic geology (lithology, contacts and faults, etc.), the maps may include metamorphic overprints, cross-sections, and explanatory legend-graphics such as correlation charts, used to supplement columnar legends. Base map: U. S. Geological Survey Last Chance Range 7.5-minute Quadrangle.

A legend of a soil map, providing Vietnamese-English translations for different soil types.

The NY Bedrock Geology Map Sheet Master Legend, Map and Chart Series Number 15

This dataset contains a Questionnaire used to evaluate the quality of the Romanian Standard of colors for soil type map legends (StdCol) by map users and map designers. The Standard of colors resulted from the application of the specific method proposed by authors for developing reliably-distinguishable color schemes for legends of natural resource taxonomy-based maps. It was applied, in its turn, in developing the Dominant Soil Map of Romania at the 1:700,000 scale (DSM700).

The Questionnaire contains the description of the Standard of colors, the items whose readability are to be evaluated (the color pairs of the Standard, the Standard as a whole, and two map excerpts), the guidelines of evaluation, and the requested general information regarding the evaluator.

A table that presents the test/evaluation data that were obtained from 46 evaluators is given.