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AQP
AQP
·ncss-tech.github.io·
AQP
Limsreport
Limsreport
·nasis.sc.egov.usda.gov·
Limsreport
Data Acquisition
Data Acquisition
Learn everything about Data Acquisition, a key knowledge category of the GISCI Geospatial Core Technical Exam. Click to start studying.
Web Mapping Service (WMS): A WMS is a standard protocol developed by the Open Geospatial Consortium (OGC) in 1999.
Web Feature Service (WFS): A WFS provides essential tools for creating interactive maps with features like search capabilities, filtering, and sorting. Unlike WMS, a WFS gives access to vector data (not raster).
GeoServices REST Specification: The GeoServices REST Specification provides an open way for web clients to communicate with GIS servers by issuing requests to the server through structured URLs. The server responds with map images, text based geographic information, or other resources that satisfy the request.
·gisci.org·
Data Acquisition
tipg
tipg
Simple and Fast Geospatial OGC Features and Tiles API for PostGIS.
·developmentseed.org·
tipg
Geospatial API Fundamentals
Geospatial API Fundamentals
Geospatial APIs enable seamless access to spatial data, powering mapping, analysis, and urban analytics with standardized operations and protocols.
Geospatial APIs are software abstraction layers that provide standardized methods to query, analyze, and visualize spatial data from diverse sources. They support essential functionalities including 2D/3D map rendering, geocoding, coordinate transforms, and real-time sensor data integration. Modern designs employ RESTful architectures and OGC standards to enhance interoperability, performance, and scalability across geospatial applications.
A geospatial Application Programming Interface (API) is a software abstraction layer—typically a web service or client library—that exposes standardized operations for querying, rendering, analyzing, and modeling spatial data, including vector features, raster coverages, multi-dimensional sensor observations, and geospatial attributes. Geospatial APIs are foundational for scientific computing, urban analytics, planetary research, public health surveillance, and geospatial-AI workflows, enabling programmable access to distributed spatial resources and seamless integration across data repositories, sensor infrastructures, visualization platforms, and analytic pipelines.
·emergentmind.com·
Geospatial API Fundamentals
Adopting semantic types - Taxi
Adopting semantic types - Taxi
Learn how Taxi uses semantic typing to describe the meaning of data, not just its structure
Types are meant to be shared across systems, while models are system-specific. Your project structure should reflect this separation.
A well-implemented Taxi ecosystem has clear separation between shared semantics and system-specific implementations.
A mature implementation typically includes: ​ Shared Taxonomy Collection of semantic types Broadly shared across organization Version controlled and carefully governed Published as a reusable package ​ Service Implementations Models and service definitions using types from taxonomy System-specific structures Published to TaxiQL server (like Orbital) Each service depends on shared taxonomy ​ Data Consumers Import shared taxonomy only Don’t depend on service-specific models Query data using TaxiQL Receive data mapped to their needs ​
Best Practices ​ Type Development Focus on business concepts Keep types focused and single-purpose Document type meanings clearly Version types carefully ​ Model Development Use semantic types for fields Keep models service-specific Don’t share models between services ​ Service Integration Publish service contracts to TaxiQL server Use semantic types in operation signatures Let TaxiQL handle data mapping
Measuring Success Your implementation is successful when: Services can evolve independently Data integration requires minimal code New consumers can easily discover and use data Changes to one service don’t cascade to others Semantic meaning is preserved across systems
·taxilang.org·
Adopting semantic types - Taxi
rspatialdata
rspatialdata
·rspatialdata.github.io·
rspatialdata
Production PostGIS Vector Tiles: Caching | Crunchy Data Blog
Production PostGIS Vector Tiles: Caching | Crunchy Data Blog
Building maps that use dynamic tiles from the database is a lot of fun. You get the freshest data, you don't have to think about generating a static tile set, and you can do it with very minimal middleware, using pg_tileserv.
·crunchydata.com·
Production PostGIS Vector Tiles: Caching | Crunchy Data Blog
pg_featureserv
pg_featureserv
Because there are usually many functions in a Postgres database, the service only publishes functions defined in the schemas specified in the FunctionIncludes configuration setting. By default the functions in the postgisftw schema are published.
·access.crunchydata.com·
pg_featureserv
Spatial Parallel Computing by Hierarchical Data Partitioning
Spatial Parallel Computing by Hierarchical Data Partitioning
Geospatial data computation is parallelized by grid, hierarchy, or raster files. Based on future (Bengtsson, 2024 doi:10.32614/CRAN.package.future) and mirai (Gao et al., 2025 doi:10.32614/CRAN.package.mirai) parallel back-ends, terra (Hijmans et al., 2025 doi:10.32614/CRAN.package.terra) and sf (Pebesma et al., 2024 doi:10.32614/CRAN.package.sf) functions as well as convenience functions in the package can be distributed over multiple threads. The simplest way of parallelizing generic geospatial computation is to start from par_pad_*() functions to par_grid(), par_hierarchy(), or par_multirasters() functions. Virtually any functions accepting classes in terra or sf packages can be used in the three parallelization functions. A common raster-vector overlay operation is provided as a function extract_at(), which uses exactextractr (Baston, 2023 doi:10.32614/CRAN.package.exactextractr), with options for kernel weights for summarizing raster values at vector geometries. Other convenience functions for vector-vector operations including simple areal interpolation (summarize_aw()) and summation of exponentially decaying weights (summarize_sedc()) are also provided.
·docs.ropensci.org·
Spatial Parallel Computing by Hierarchical Data Partitioning
VRT -- GDAL Virtual Format — GDAL documentation
VRT -- GDAL Virtual Format — GDAL documentation
The VRT driver is a format driver for GDAL that allows a virtual GDAL dataset to be composed from other GDAL datasets with repositioning, and algorithms potentially applied as well as various kinds of metadata altered or added. VRT descriptions of datasets can be saved in an XML format normally given the extension .vrt.
·gdal.org·
VRT -- GDAL Virtual Format — GDAL documentation
gdalbuildvrt — GDAL documentation
gdalbuildvrt — GDAL documentation
gdalbuildvrt [--help] [--long-usage] [--help-general] [--quiet] [[-strict]|[-non_strict]] [-tile_index <field_name>] [-resolution user|average|common|highest|lowest|same] [-tr <xres> <yes>] [-input_file_list <filename>] [[-separate]|[-pixel-function <function>]] [-pixel-function-arg <NAME>=<VALUE>]... [-allow_projection_difference] [-sd <n>] [-tap] [-te <xmin> <ymin> <xmax> <ymax>] [-addalpha] [-b <band>]... [-hidenodata] [-overwrite] [-srcnodata "<value>[ <value>]..."] [-vrtnodata "<value>[ <value>]..."] [-a_srs <srs_def>] [-r nearest|bilinear|cubic|cubicspline|lanczos|average|mode] [-oo <NAME>=<VALUE>]... [-co <NAME>=<VALUE>]... [-ignore_srcmaskband] [-nodata_max_mask_threshold <threshold>] <vrt_dataset_name> [<src_dataset_name>]...
This program builds a VRT (Virtual Dataset) that is a mosaic of a list of input GDAL datasets. The list of input GDAL datasets can be specified at the end of the command line, put in a text file (one filename per line) for very long lists, or it can be a MapServer tileindex (see the gdaltindex utility). If using a tile index, all entries in the tile index will be added to the VRT.
·gdal.org·
gdalbuildvrt — GDAL documentation
Farm
Farm
Investing in farmland regeneration.
·farm.vc·
Farm
Topographic Map Colors - Coolors
Topographic Map Colors - Coolors
Get inspired by these beautiful i-am-looking-for-colors-for-topographic-maps color schemes and make something cool!
·coolors.co·
Topographic Map Colors - Coolors
Maps Color Palettes - Coolors
Maps Color Palettes - Coolors
Get inspired by thousands of beautiful color schemes and make something cool!
·coolors.co·
Maps Color Palettes - Coolors
OpenFreeMap
OpenFreeMap
OpenFreeMap – Open-Source Map Hosting lets you display custom maps on your website and apps for free.
·openfreemap.org·
OpenFreeMap
Home
Home
Pixi Documentation — Next-gen package manager for reproducible development setups
·pixi.prefix.dev·
Home