Set of functions in WPS web services, allowing access to the documentation of GIS layers (model, alias, relationships, list values) from the Bordeaux Métropole GIS database.

This dictionary is accessible via an interface on ‘http://data.bordeaux-metropole.fr/dicopub/#/dico’

Webservice WPS

Operation

WPS is a real-time access service. For more details, refer to the FAQ.

WebService URL:

https://data.bordeaux-metropole.fr/wps?key=[VOTRECLE]&SERVICE=WPS&VERSION=1.0.0&REQUEST=EXECUTE&IDENTIFIER=[NOMCOUCHE]

Replace [yourcle] with the software key that was provided to you by Bordeaux Métropole. To order one (valid for WMS, WFS, WPS and CUB APIs), click here If you would like to see more information about OGC web services click on this link

Layer Name

Name of the layer to provide to your client:

Layer name| Description

—|— dico_domains | domains are super-categories of themes.Themes are logical groupings of layers. This function allows you to list the available domains and the themes contained dico_themes | themes are logical groupings of layers. This function allows you to list the available themes and the layers contained

dico_layers | this function allows you to list the available layers and their attributes

dico_propagation | this function allows to list the propagation of layers

dico_search

| this function allows you to search the dictionary

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This dictionary is accessible via an interface on ‘http://data.bordeaux-metropole.fr/dicopub/#/dico’

Webservice WPS

Operation

WPS is a real-time access service. For more details, refer to the FAQ.

WebService URL:

https://data.bordeaux-metropole.fr/wps?key=[VOTRECLE]&SERVICE=WPS&VERSION=1.0.0&REQUEST=EXECUTE&IDENTIFIER=[NOMCOUCHE] Replace [yourcle] with the software key that was provided to you by Bordeaux Métropole.To order one (valid for WMS, WFS, WPS and CUB APIs), click here

If you would like to see more information about OGC web services click on this link

Layer Name

Name of the layer to provide to your client:

Layer name| Description —|— dico_domains | domains are super-categories of themes. Themes are logical groupings of layers.This function allows you to list the available domains and the themes contained

dico_themes | themes are logical groupings of layers.This function allows you to list the available themes and the layers contained

dico_layers

| this function allows you to list the available layers and their attributes

dico_propagation | this function allows to list the propagation of layers

dico_search | this function allows you to search the dictionary

**

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The global arborist software market was valued at USD 350.79 Million in 2022 and is projected to reach USD 881.04 Million by 2030, registering a CAGR of 12.2% for the forecast period 2023-2030. Factors Affecting Arborist Software Market Growth

Growing awareness of tree care coupled with benefits of arborist software

With increased awareness of environmental conservation and the importance of urban green spaces, there's a rising demand for professional tree care services. Growing environmental education coupled with technology adoption in tree management helps to drive the arborist software demand. Arborist software helps urban planners, municipalities, and property owners effectively manage and care for trees in cities and suburbs. Arborist software streamlines various tasks like tree inventory management, maintenance scheduling, and communication with clients. This leads to improved efficiency and productivity for arborists.

The Restraining Factor of Arborist Software:

Data Security, privacy concerns;

Data security and privacy concerns are indeed significant factors that can impact the adoption of arborist software. Arborist software often stores information about clients' properties, contact details, and potentially even financial information. Many arborist software solutions use location data to map and manage trees. This location data could be misused if it falls into the wrong hands.

Market Opportunity:

Rising need to improve tree inventory practices;

The rising need to improve tree inventory practices is driven by several factors, including urbanization, environmental awareness, and advancements in technology. As cities grow and expand, urban planners need accurate tree inventory data to ensure that trees are integrated into urban design. Tree inventory helps prevent conflicts between infrastructure development and tree preservation. Arborists software helps to create and maintain digital inventories of trees, including information about species, location, size, health, and maintenance history. In addition, features like Geographic Information Systems (GIS), remote sensing, and mobile data collection technologies have made it easier to create, update, and manage tree inventories.

The COVID-19 impact on Arborist Software Market

The COVID-19 pandemic had various impacts on industries and markets, including the arborist software market. During lockdowns and restrictions, some tree care activities might have been deprioritized due to the sudden focus on healthcare sector. However, the pandemic accelerated digital transformation across industries. Arborists who were previously reliant on manual processes might have recognized the benefits of adopting software for tasks like inventory management, reporting, and client communication. Introduction of Arborist Software

An arborist is a professional who specializes in the cultivation, management, and study of trees, shrubs, and other woody plants. Arborists are trained in tree care practices, including planting, pruning, disease and pest management, and overall tree health maintenance. Arborist software are tools used to assist arborists in their work. These software solutions can provide various functionalities to help arborists manage and maintain trees effectively. Arborists can use software to create and maintain digital inventories of trees, including information about species, location, size, health, and maintenance history. Some common features of arborist software include tree inventory management, health assessment, risk assessment, mapping and GIS integration etc.

OverviewHERE Technologies is the world’s leading location data and technology company offering a location-centric platform that is open and secure with privacy at its core. With HERE Location Services and APIs, you gain access to a variety of tools, data, modeling, and more. By selecting HERE location data, you are selecting the most accurate, fresh, and robust data. HERE’s open platform environments empowers you to achieve better outcomes - faster journeys, more efficient supply chains, stronger digital infrastructures, and better city planning.  For over two decades, Esri and HERE have been a driving force in solving customer challenges using the untapped power of location data. With our combined geospatial expertise, ready-to-use solution tools and location intelligence capabilities, you can make faster business decisions and improve operational efficiencies while delivering on your customer and community needs. Esri’s GIS software, powered by HERE’s fresh and robust location data, allows you to easily integrate with existing enterprise IT systems to deliver powerful, predictive location solutions and geospatial visualization capabilities. Visit here.comServicesOverview: HERE Professional Services From ideation to execution of your location-based development project, HERE Professional Services will enable you accelerate time to value. We bring unparalleled depth and breadth of experience with HERE’s leading location data and technology platform to streamline product development, efficiently manage migration/integration efforts and to help you bring your project to life. Our HERE Professional Services team is here to help you: - Identify and define location solutions to address your specific business problems. - Facilitate end-to-end realization of your desired state. - Create, extract, and transform HERE map and location content according to your needs and in different GIS environments. - Assist you in leading the steps of ingesting, transforming, analyzing, and publishing data. HERE Technical Support Plans Offering multiple levels of support, HERE Technical Support plans give you access to the tools and resources to keep you on track with your location-enabled projects. - All plans include access to online documentation, - Convenient on-demand HERE online support portal / ticketing system to create and manage tickets. - Response within 4-72 hours, depending on your selected plans.Services Provided: Application Development, Business Case Development, Data Conversion/Migration, Data Model & Database Design, GIS Strategy and Planning, Hosting Services, Implementation, Needs and Requirements, System Architecture and Design, System Integration, Training Services

The global sales mapping software market, valued at $2337.7 million in 2025, is poised for substantial growth. The market's expansion is fueled by several key drivers. Increasing adoption of cloud-based solutions offers scalability and cost-effectiveness, attracting both large enterprises and SMEs. Furthermore, the rising need for efficient territory management and optimized sales force productivity drives demand for sophisticated mapping software. Integration with CRM systems streamlines sales processes, providing a single source of truth for customer data and sales performance. The market is segmented by software type (GIS, CRM integration, and other) and application (large enterprises and SMEs). The geographic segmentation reveals strong growth potential across North America and Europe, driven by early adoption and well-established tech infrastructure. However, Asia-Pacific is expected to witness significant expansion in the coming years due to increasing digitalization and the growth of e-commerce. Competitive pressures are present, with numerous vendors offering varying levels of functionality and pricing. However, continued innovation in areas like AI-driven sales route optimization and predictive analytics is likely to further propel market growth. While precise CAGR data is missing, considering the dynamic nature of the software market and the factors driving growth, a conservative estimate of 10-15% CAGR over the forecast period (2025-2033) appears reasonable. This reflects a healthy market expansion driven by ongoing technological advancements and the increasing strategic importance of sales force optimization for businesses across various industries. The market's maturity level and the presence of established players suggest a moderate growth trajectory, avoiding overly optimistic projections. The restraints might include high initial investment costs for some solutions and the need for effective training and integration to realize full benefits, potentially slowing down adoption among some smaller businesses. However, the overall market outlook remains optimistic, with significant opportunities for both established and emerging vendors.

Can your desktop computer crunch the large GIS datasets that are becoming increasingly common across the geosciences? Do you have access to or the know-how to take advantage of advanced high performance computing (HPC) capability? Web based cyberinfrastructure takes work off your desk or laptop computer and onto infrastructure or "cloud" based data and processing servers. This talk will describe the HydroShare collaborative environment and web based services being developed to support the sharing and processing of hydrologic data and models. HydroShare supports the upload, storage, and sharing of a broad class of hydrologic data including time series, geographic features and raster datasets, multidimensional space-time data, and other structured collections of data. Web service tools and a Python client library provide researchers with access to HPC resources without requiring them to become HPC experts. This reduces the time and effort spent in finding and organizing the data required to prepare the inputs for hydrologic models and facilitates the management of online data and execution of models on HPC systems. This presentation will illustrate the use of web based data and computation services from both the browser and desktop client software. These web-based services implement the Terrain Analysis Using Digital Elevation Model (TauDEM) tools for watershed delineation, generation of hydrology-based terrain information, and preparation of hydrologic model inputs. They allow users to develop scripts on their desktop computer that call analytical functions that are executed completely in the cloud, on HPC resources using input datasets stored in the cloud, without installing specialized software, learning how to use HPC, or transferring large datasets back to the user's desktop. These cases serve as examples for how this approach can be extended to other models to enhance the use of web and data services in the geosciences.

Slides for AGU 2015 presentation IN51C-03, December 18, 2015

This layer provides slope values calculated dynamically from the elevation data (within the current extents) using the server-side slope function applied to a Terrain layer. The values are integer and represent the angle of the downward sloping terrain (0 to 90 degrees). Note slope is a function of the pixel size of the request, so at smaller scales the slope values are smaller as pixel sizes increase. WARNING: Slope is computed in the projection specified by the client software. The server resamples the elevation data to the requested projection and pixel size and then computes slope. Slope should be requested in a projection that maintains correct scale in x and y directions for the area of interest. Using geographic coordinates will give incorrect results. For the WGS84 Mercator and WGS Web Mercator (auxiliary sphere) projections used by many web applications, a correction factor has been included to correct for latitude-dependent scale changes.What can you do with this layer?Use for Visualization: No. This image service provides numeric values indicating terrain characteristics. Due to the limited range of values, this service is not generally appropriate for visual interpretation, unless the client application applies an additional color map. For use in visualization, use the Terrain: Slope Map. Use for Analysis: Yes. This layer provides numeric values indicating the average slope angle within a raster cell, calculated based on the defined cell size. Cell size has an effect on the slope values.For more details such as Data Sources, Mosaic method used in this layer, please see the Terrain layer. This layer allows query, identify, and export image requests. The layer is restricted to a 5,000 x 5,000 pixel limit in a single export image request.

This layer is part of a larger collection of elevation layers that you can use to perform a variety of mapping analysis tasks.

This layer provides aspect values calculated dynamically using the server-side aspect function applied to a Terrain layer. The values are float, and represent the orientation of the downward sloping terrain in degrees (0 to 359.9), clockwise from north. Cells in the input raster that are flat with zero slope are assigned an aspect of -1.WARNING: Aspect is computed in the projection specified by the client software. The server resamples the data to the required projection and then computes aspect. The default projection for web applications is Mercator in which scale increases equally in x and y by latitude, so aspect computations are not affected. Using geographic coordinates will give distorted results. It is advised to check the client application projection prior to obtaining aspect values. What can you do with this layer?Use for Visualization: No. This layer provides numeric values indicating terrain characteristics, and is not generally appropriate for visual interpretation, unless the client application applies an additional color map. For visualization use the Terrain: Aspect Map.Use for Analysis: Yes. This layer provides numeric values indicating the orientation of the terrain within a raster cell, calculated based on the defined cell size.For more details such as Data Sources, Mosaic method used in this layer, please see the Terrain layer.This layer is part of a larger collection of elevation layers that you can use to perform a variety of mapping analysis tasks.

This web service provides key ecological data layers in the New York Bight via the Internet and which can be loaded into client side GIS software. The web service includes spatial data for seabirds, deep sea corals, bathymetry and surficial sediments. These diverse data were requested by the New York Department of State to support offshore spatial planning. To the extent possible data is provided at the finest spatial scales survey data will support and use predictive spatial models to translate survey data into seamless data coverages.

The GeoPinpoint Suite software attaches geographic coordinates to records in a client database by means of matching certain database fields against a DMTI proprietary geo-reference database. The geo- reference database is comprised of digital street geometry, street address ranges, postal coordinates, point of interest and other reference databases to ensure that data is “geocoded” as accurately as possible. When data is “geocoded”, co-ordinates can be transferred into a Geographic Information Systems (GIS) such as MapInfo, ArcInfo, ArcView and other software systems that support the importation of geographic co-ordinate locations. GeoPinpointTM Suite positions your data using a powerful and innovative geo-location process called geocoding. GeoPinpoint Suite attaches X and Y coordinates to your facility, customer or prospect address data for map visualization, analysis or location based applications. The GeoPinpoint Suite takes advantage of a new modular design that allows the software to encompass future module enhancements without jeopardizing its performance or usability. Based on the nationwide precision and the robust street address content of CanMap® Streetfiles, GeoPinpoint Suite has been engineered to geocode your data with a high degree of accuracy.

This layer provides slope percent rise values calculated dynamically from the elevation data (within the current extents) using the server-side slope function applied to the Terrain layer. Percent of slope is determined by dividing the amount of elevation change by the amount of horizontal distance covered (sometimes referred to as "the rise divided by the run"), and then multiplying the result by 100. The values range from 0 to essentially infinity. When the slope angle equals 45 degrees, the rise is equal to the run. Expressed as a percentage, the slope of this angle is 100 percent. As the slope approaches vertical (90 degrees), the percentage slope approaches infinity.

WARNING: Slope is computed in the projection specified by the client software. The server resamples the elevation data to the requested projection and pixel size and then computes slope. Slope should be requested in a projection that maintains correct scale in x and y directions for the area of interest. Using geographic coordinates will give incorrect results. For the WGS84 Mercator and WGS Web Mercator (auxiliary sphere) projections used by many web applications, a correction factor has been included to correct for latitude-dependent scale changes.What can you do with this layer?Use for Visualization: No. This image service provides numeric values indicating terrain characteristics. Due to the limited range of values, this service is not generally appropriate for visual interpretation, unless the client application applies an additional color map. Use for Analysis: Yes. This layer provides numeric values indicating slope percent, calculated based on the defined cell size. Cell size has an effect on the slope values.For more details such as Data Sources, Mosaic method used in this layer, please see the Terrain layer. This layer allows query, identify, and export image requests. The layer is restricted to a 5,000 x 5,000 pixel limit in a single export image request.This layer is part of a larger collection of elevation layers that you can use to perform a variety of mapping analysis tasks.

This Open Geospatial Consortium (OGC) compliant Web Map Service (WMS) includes a mosaic of historical USGS topographic maps of New Jersey surveyed from 1881 to 1924. This product is to be used for reference purposes only. The original historical paper maps were distorted or damaged to varying degrees due to age and use. During visual testing, it appeared that spatial inaccuracies in the images exceed 200 feet in several locations. The digital product has not been corrected for distortion nor vertical displacement. Consequently, this product does not meet the National Standard for Spatial Data Accuracy (NSSDA). The mosaic was produced by scanning 15 minute (1:62,500 scale) historical USGS topographic paper maps at 600 dpi and saving them as Tagged Image File Format (TIFF) images. The scanned TIFFs have an approximate pixel resolution of 17 feet. The map images were georeferenced to a fishnet in their native coordinate system and then reprojected to NAD83 NJ State Plane coordinates for use in this service. In most client software, the default spatial reference system of the service will be Geographic Coordinates, WGS84. Several other coordinate systems are supported natively by the WMS (see Supplemental Information).

Digital orthophotography of New Jersey, distributed as a Web Map Service (WMS). There are numerous layers in the service, one displaying the 2007 3 natural color bands, another displaying 2007 3 band false color infrared (near IR). The native data set spatial reference system is State Plane Coordinate System NAD83 Coordinates, U.S. Survey Feet. In most client software, the default spatial reference system of the service will be Geographic Coordinates, WGS84. Several other coordinate systems are supported (see Distribution Information section).Multi-spectral digital orthophotography was produced at a scale of 1:2400 (1" = 200') with a 1 foot pixel resolution for the State of New Jersey totaling approximately 8,162 square miles. The GeoTIFF tiles delivered to the State of New Jersey were then converted to lossless JPEG2000 files, which are used in this service.Aerial photography of the entire State of New Jersey was captured during March-May, 2007. Two flight dates (4-30-07 and 5-3-07 were rejected from the original 2007 flight due to excessive leaf conditions. Spring 2008 re-flights were planned and acquired in three missions dating: April 3rd, 10th, and 15th of 2008. The final orthophotos for parts of Warren, Hunterdon, Sussex, Passaic, Essex, Union, and all of Bergen and Hudson Counties were created utilizing both years of imagery.

Douglas County, Kansas natural color, six inch resolution, and rectified orthoimagery. Aerial imagery reference basemap projected in WGS84 coordinate systems, with zoom levels configured for ArcGIS Online | Google Maps | Bing Maps for use in mapping applications.Digital orthophotography produced from aerial photography captured in Spring of 2022 as requested by Douglas County Kansas, Shawnee County Kansas, Jefferson County Kansas, City of Topeka Kansas, and the City of Lawrence Kansas. Collected 03-15-2022, 03-16-2022, 03-19-2022.Data meets ASPRS @ 1:100 scale, limiting RMSE within 1.0'. Surdex collected ground survey and airborne GPS data at the time of image acquisition and was used exclusively to control the product to ground coordinates.Aircraft was deployed to eastern Kansas in early March 2022 for digital image acquisition during requested time frame. Ac Cessna Conquest equipped with a Leica ADS100 (Digital Mapping Camera) captured 4 band imagery over the entire project area of interest. Imagery was captured at an altitude of 6,200' above mean terrain, allowing 0% cloud conditions. Three of the four bands (RGB natural color) of raw camera data were processed by Surdex using Leica X Pro software coupled with Surdex proprietary image handling software for color correction and dodging. Post processing of Airborne and Ground GPS data was performed with Waypoint Consulting's GrafNav software. Aerial Triangulation was completed using Leica X Pro Automatic Triangulation and rectification of imagery to the client supplied DEM was completed using Surdex proprietary software . Image mosaicking, QC and final tiled products were produced using proprietary Surdex software.