Create 2D and 3D maps to analyze flooding in Venice, Italy.

The global Digital HD Map market is experiencing robust growth, projected to reach $1558.9 million in 2025 and exhibiting a remarkable Compound Annual Growth Rate (CAGR) of 24.4% from 2025 to 2033. This expansion is driven by the increasing demand for precise location data across various sectors. The automotive industry, particularly autonomous vehicles, is a major catalyst, relying heavily on highly detailed and accurate maps for navigation and safety features. Furthermore, the burgeoning use of augmented reality (AR) and virtual reality (VR) applications, coupled with the expanding smart city initiatives globally, fuels the market's growth trajectory. The rise of advanced driver-assistance systems (ADAS) and the integration of digital maps into connected car platforms also contribute significantly to this market's expansion. Competition within the market is fierce, with established players like Google, TomTom, and HERE Technologies competing alongside emerging innovative companies. The market segmentation by map type (2D HD Map, 3D HD Map) and application (Commercial Use, Military Use, Others) reflects the diverse range of applications and associated technological advancements shaping this dynamic landscape. Different regions contribute varying levels of market share, with North America and Asia-Pacific anticipated to lead due to significant technological advancements and higher adoption rates. The market's growth is not without its challenges. Data acquisition and maintenance costs remain a significant hurdle, especially for maintaining the accuracy and timeliness of high-resolution map data. Ensuring data security and privacy, particularly with the increased use of location data in various applications, presents another substantial challenge. Regulatory frameworks governing the use and collection of such data vary across different geographies, creating complexities for businesses operating internationally. Despite these challenges, the long-term prospects for the Digital HD Map market remain positive, driven by continuous technological innovations, increasing investment in autonomous driving technologies, and the expanding need for precise location intelligence across diverse industry verticals. The market is expected to see further consolidation through mergers and acquisitions as companies strive to enhance their capabilities and market share.

2D Web Map depicting the Yorkgate Mall (1 York Gate Blvd, North York, ON M3N 3A1) “Parking Area”. Basic Property Condition Assessment (BPCA) and secondary “Crack and Fracture” Inspection conducted by ACCESSiFLY and Gravity Engineering Inc. on Tuesday, May 11, 2021 during a Transport Canada & NAVCanada approved "RPAS Flight" utilizing a DJI Mavic Pro 2 & Draganfly Commander Airframe equipped with a SONY Q100 Optical DSLR & FLIR Vue Pro-R 19mm 30hz, 640x512 Aerial Thermal Imager. Secondary terrestrial imaging conducted via LiDAR/Laser Scan using a Faro Focus.

The $\Delta \chi^2_{\text{crit},x}$ map accounts for the fact that the $\Delta \chi^2$ values of the oscillation fit do not follow...

Author: Megan Banaski (mbanaski@esri.com) and Max Ozenberger (mozenberger@esri.com)Last Updated: 1/1/2024Intended Environment: WebPurpose:Exercise B2: Build a Starter 2D Map or Build a Starter 3D Map This lab is part of GitHub repository that contains short labs that step you through the process of developing a web application with ArcGIS API for JavaScript.The labs start from ground-zero and work through the accessing different aspects of the API and how to begin to build an application and add functionality.Requirements: Here are the resources you will use for the labs.ArcGIS for Developers - Account, Documentation, Samples, Apps, DownloadsEsri Open Source Projects - More source codeA simple guide for setting up a local web server (optional)Help with HTML, CSS, and JavaScript

The electronic map market is experiencing robust growth, driven by increasing adoption of location-based services (LBS), the proliferation of smartphones and connected devices, and the expanding use of GPS technology across various sectors. The market's value, estimated at $15 billion in 2025, is projected to experience a Compound Annual Growth Rate (CAGR) of 12% from 2025 to 2033, reaching approximately $45 billion by 2033. Key drivers include the rising demand for precise navigation systems in the automotive industry, the surge in e-commerce and delivery services relying on efficient route optimization, and the growing importance of location intelligence for urban planning and resource management. Furthermore, advancements in mapping technologies, such as 3D mapping and augmented reality (AR) integration, are further fueling market expansion. While data security and privacy concerns represent a potential restraint, the overall outlook remains positive, fueled by continuous technological advancements and increasing reliance on location data across numerous applications. The market is segmented by various factors, including map type (2D, 3D, etc.), application (navigation, GIS, etc.), and end-user (automotive, government, etc.). Leading companies like ESRI, Google, TomTom, and HERE Technologies are actively shaping the market landscape through innovation and strategic partnerships. Regional variations in market penetration exist, with North America and Europe currently holding a significant share. However, Asia-Pacific is expected to witness the fastest growth due to rapid urbanization and increasing smartphone penetration. The competitive landscape is characterized by both established players and emerging technology companies vying for market share through technological advancements, improved data accuracy, and enhanced user experience. The forecast period of 2025-2033 promises significant opportunities for growth, driven by the continuous integration of electronic maps into various aspects of daily life and the emerging importance of location data in diverse industries.

The high-precision real-time map market is experiencing robust growth, driven by the increasing demand for autonomous driving, advanced driver-assistance systems (ADAS), and precise location-based services. The market's expansion is fueled by technological advancements in sensor technologies (LiDAR, radar, cameras), improved mapping techniques, and the proliferation of connected vehicles. Key applications include automotive driving, tracking & positioning, and mobile phones, with the automotive sector currently dominating due to the surge in autonomous vehicle development. The 3D segment is projected to witness significant growth, exceeding the 2D and 2.5D segments in the coming years, owing to its ability to provide more detailed and accurate representations of the environment, crucial for autonomous navigation and precise location services. Geographic regions like North America and Europe are currently leading the market, driven by early adoption of autonomous vehicle technologies and well-established infrastructure for data collection and processing. However, rapid technological advancements and government initiatives supporting autonomous driving are driving market expansion in the Asia-Pacific region, with China and India emerging as key growth markets. While data security and privacy concerns present potential restraints, the overall market outlook remains positive, with a projected compound annual growth rate (CAGR) indicating substantial market expansion through 2033. Competition among major players like TomTom, Google, and Baidu is intensifying, leading to continuous innovation and the development of more sophisticated and accurate mapping solutions. The market segmentation by type (2D, 2.5D, 3D) reveals a clear shift towards higher-dimensionality maps. While 2D maps still hold a significant share, 3D mapping technology is rapidly gaining traction due to its enhanced capabilities for autonomous navigation and detailed environmental modeling. The application-based segmentation underscores the importance of the automotive sector, particularly autonomous vehicles, as the primary driver of market growth. However, other sectors like mobile phones and tracking & positioning are also contributing significantly, fostering a diversified market landscape. The ongoing development of 5G and edge computing infrastructure further accelerates the market's growth by facilitating real-time data processing and transmission, enhancing the accuracy and responsiveness of high-precision real-time maps. The competitive landscape is characterized by both established mapping companies and emerging technology providers, driving innovation and potentially leading to further market consolidation in the coming years.

$\Delta \chi^2$ map of phase-I+II data calculated by the two-dimensional method. To be used in combination with the $\Delta \chi^2_{\text{crit},x}$...

The global Navigation Electronic Map market is experiencing robust growth, projected to reach a market size of $14,750 million in 2025. While the exact CAGR isn't provided, considering the rapid advancements in technology, increasing adoption of GPS-enabled devices, and the expanding use of navigation systems across personal, commercial, and military sectors, a conservative estimate of the CAGR between 2025 and 2033 would be around 8%. This translates to substantial market expansion over the forecast period. Key drivers include the proliferation of smartphones with integrated navigation capabilities, the rising demand for precise location-based services, and the increasing sophistication of mapping technologies, such as the transition from 2D to 3D mapping. The market is segmented by map type (2D and 3D) and application (personal, commercial, and military). The commercial segment is expected to dominate due to its widespread use in logistics, fleet management, and ride-sharing services. Growth is further fueled by the integration of navigation maps with augmented reality (AR) and artificial intelligence (AI) to enhance user experience. However, factors such as data security concerns, licensing costs, and the need for continuous map updates pose challenges to the market's growth. The competitive landscape is marked by a mix of established players like Google, TomTom, and HERE, and regional players catering to specific geographic needs. Geographical expansion, particularly in emerging economies with increasing smartphone penetration, presents significant opportunities for market expansion. The market's strong growth is fueled by several factors. The integration of advanced features like real-time traffic updates, voice guidance, and offline map access significantly enhances user experience and drives adoption. The increasing use of navigation systems in autonomous vehicles is also a significant factor driving market expansion. The commercial sector, encompassing logistics, transportation, and delivery services, shows high growth potential due to the need for efficient route optimization and fleet management. Government initiatives promoting smart city development and infrastructure projects also contribute positively. Furthermore, continuous innovations in mapping technologies, such as high-resolution satellite imagery and improved data processing techniques, ensure the continued relevance and sophistication of navigation electronic maps. The competitive landscape is dynamic, with companies focusing on developing advanced features, strategic partnerships, and geographic expansion to secure market share.

This dataset contains binary "filmstrip" imagery files of PMS-2D data obtained aboard the NCAR Electra aircraft during the Mesoscale Alpine Programme (MAP) project.

It contains the orography of the municipality of Valencia, represented by level curves, including its method of creation, date and type of curve. Official vector cartographic series of reference at scale 1:500, 1:1000 and 1:2000 in 2D, elaborated by the Cartography Section of the Planning Service., which represents the topographical reality of the TM of Valencia. It is a combination of photogrammetric refunds from the August 2018 flight, 2006 flights and GNSS measurements. Geodetic Reference System ETRS89, UTM projection in spindle 30. Vertical datum: the altitudes refer to the average level of the Mediterranean Sea in Alicante. EPSG code:25830. Planimetric accuracy 10-50 centimeters. The continuous cartographic base is structured for exploitation using Geographic Information Systems. The geographical phenomena that make up the series are structured in these 6 thematic units: orography, hydrography, constructions and buildings, transport networks and toponymy. All of them contain the following fields: Creation: creation method (photogrammetric restoration, GNSS measurement, orthophoto digitisation), date of creation (flight date or date of data collection), scale (information generation scale).The data model of the BCV05 of the ICV was followed. The phenomena have been represented following the catalogue of phenomena of the CV05 series. In the case of elements not covered by the BCV05 model, it has been expanded by generating a data model for larger scales that can be requested at cartoinf@valencia.es. It contains the orography of the municipality of Valencia, represented by level curves, including its method of creation, date and type of curve. Official vector cartographic series of reference at scale 1:500, 1:1000 and 1:2000 in 2D, elaborated by the Cartography Section of the Planning Service., which represents the topographical reality of the TM of Valencia. It is a combination of photogrammetric refunds from the August 2018 flight, 2006 flights and GNSS measurements. Geodetic Reference System ETRS89, UTM projection in spindle 30. Vertical datum: the altitudes refer to the average level of the Mediterranean Sea in Alicante. EPSG code: 25830. Planimetric accuracy 10-50 centimeters. The continuous cartographic base is structured for exploitation using Geographic Information Systems. The geographical phenomena that make up the series are structured in these 6 thematic units: orography, hydrography, constructions and buildings, transport networks and toponymy. All of them contain the following fields: Creation: creation method (photogrammetric restoration, GNSS measurement, orthophoto digitisation), date of creation (flight date or date of data collection), scale (information generation scale).The data model of the BCV05 of the ICV was followed. The phenomena have been represented following the catalogue of phenomena of the CV05 series. In the case of elements not covered by the BCV05 model, it has been expanded by generating a data model for larger scales that can be requested at cartoinf@valencia.es.

2D topographic cartography at 1:500 and 1:1000 scales of the municipality of Sabadell.

The global 3D mapping and modeling market is expected to grow significantly in the next few years as demand increases for detailed and accurate representations of physical environments in three-dimensional space. Estimated to be valued at USD 38.62 billion in the year 2025, the market was expected to grow at a CAGR of 14.5% from 2025 to 2033 and was estimated to reach an amount of USD 90.26 billion by the end of 2033. The high growth rate is because of improvement in advanced technologies with the development of high-resolution sensors and methods of photogrammetry that make possible higher-resolution realistic and immersive 3D models.Key trends in the market are the adoption of virtual and augmented reality (VR/AR) applications, 3D mapping with smart city infrastructure, and increased architecture, engineering, and construction utilization of 3D models. Other factors are driving the growing adoption of cloud-based 3D mapping and modeling solutions. The solutions promise scalability, cost-effectiveness, and easy access to 3D data, thus appealing to business and organizations of all sizes. Recent developments include: Jun 2023: Nomoko (Switzerland), a leading provider of real-world 3D data technology, announced that it has joined the Overture Maps Foundation, a non-profit organization committed to fostering collaboration and innovation in the geospatial domain. Nomoko will collaborate with Meta, Amazon Web Services (AWS), TomTom, and Microsoft, to create interoperable, accessible 3D datasets, leveraging its real-world 3D modeling capabilities., May 2023: The Sanborn Map Company (Sanborn), an authority in 3D models, announced the development of a powerful new tool, the Digital Twin Base Map. This innovative technology sets a new standard for urban analysis, implementation of Digital Cities, navigation, and planning with a fundamental transformation from a 2D map to a 3D environment. The Digital Twin Base Map is a high-resolution 3D map providing unprecedented detail and accuracy., Feb 2023: Bluesky Geospatial launched the MetroVista, a 3D aerial mapping program in the USA. The service employs a hybrid imaging-Lidar airborne sensor to capture highly detailed 3D data, including 360-degree views of buildings and street-level features, in urban areas to create digital twins, visualizations, and simulations., Feb 2023: Esri, a leading global provider of geographic information system (GIS), location intelligence, and mapping solutions, released new ArcGIS Reality Software to capture the world in 3D. ArcGIS Reality enables site, city, and country-wide 3D mapping for digital twins. These 3D models and high-resolution maps allow organizations to analyze and interact with a digital world, accurately showing their locations and situations., Jan 2023: Strava, a subscription-based fitness platform, announced the acquisition of FATMAP, a 3D mapping platform, to integrate into its app. The acquisition adds FATMAP's mountain-focused maps to Strava's platform, combining with the data already within Strava's products, including city and suburban areas for runners and other fitness enthusiasts., Jan 2023: The 3D mapping platform FATMAP is acquired by Strava. FATMAP applies the concept of 3D visualization specifically for people who like mountain sports like skiing and hiking., Jan 2022: GeoScience Limited (the UK) announced receiving funding from Deep Digital Cornwall (DDC) to develop a new digital heat flow map. The DDC project has received grant funding from the European Regional Development Fund. This study aims to model the heat flow in the region's shallower geothermal resources to promote its utilization in low-carbon heating. GeoScience Ltd wants to create a more robust 3D model of the Cornwall subsurface temperature through additional boreholes and more sophisticated modeling techniques., Aug 2022: In order to create and explore the system's possibilities, CGTrader worked with the online retailer of dietary supplements Hello100. The system has the ability to scale up the generation of more models, and it has enhanced and improved Hello100's appearance on Amazon Marketplace.. Key drivers for this market are: The demand for 3D maps and models is growing rapidly across various industries, including architecture, engineering, and construction (AEC), manufacturing, transportation, and healthcare. Advances in hardware, software, and data acquisition techniques are making it possible to create more accurate, detailed, and realistic 3D maps and models. Digital twins, which are virtual representations of real-world assets or systems, are driving the demand for 3D mapping and modeling technologies for the creation of accurate and up-to-date digital representations.

. Potential restraints include: The acquisition and processing of 3D data can be expensive, especially for large-scale projects. There is a lack of standardization in the 3D mapping modeling industry, which can make it difficult to share and exchange data between different software and systems. There is a shortage of skilled professionals who are able to create and use 3D maps and models effectively.. Notable trends are: 3D mapping and modeling technologies are becoming essential for a wide range of applications, including urban planning, architecture, construction, environmental management, and gaming. Advancements in hardware, software, and data acquisition techniques are enabling the creation of more accurate, detailed, and realistic 3D maps and models. Digital twins, which are virtual representations of real-world assets or systems, are driving the demand for 3D mapping and modeling technologies for the creation of accurate and up-to-date digital representations..

Area along the York/Durham boundary which is the York-Durham Wellhead Protection Area Q1-Q2. Data created by Works Department. ROP Consolidation September 3, 2024.

This work presents datasets that can be used for getting a good understanding of an essential geoscience content knowledge that describe earth's coordinate systems. This include coordinate system used for spherical/spheroidal earth with latitudes and longitudes and their subsequent transformations to 2d maps on a variety of media (paper as well as digital) using the process of map projections. The datasets include PDF documents that are embedded with 3d models, animations and mathematical equations. The dataset has separate PDF documents for geographic (for spherical earth) and projected (2d) coordinate systems. Additionally, the data set include individual 3d models that can be used in various digital systems (including apps) and the animations in mp4 format that can be watched on most of the modern digital devices.

It contains information about works that are carried out in the municipality of Valencia, including its method of creation, date and type of work carried out. Official vector cartographic series of reference at scale 1:500, 1:1000 and 1:2000 in 2D, elaborated by the Cartography Section of the Planning Service., which represents the topographical reality of the TM of Valencia. It is a combination of photogrammetric refunds from the August 2018 flight, 2006 flights and GNSS measurements. Geodetic Reference System ETRS89, UTM projection in spindle 30. Vertical datum: the altitudes refer to the average level of the Mediterranean Sea in Alicante. EPSG code:25830. Planimetric accuracy 10-50 centimeters. The continuous cartographic base is structured for exploitation using Geographic Information Systems. The geographical phenomena that make up the series are structured in these 6 thematic units: orography, hydrography, constructions and buildings, transport networks and toponymy. All of them contain the following fields: Creation: creation method (photogrammetric restoration, GNSS measurement, orthophoto digitisation), date of creation (flight date or date of data collection), scale (information generation scale).The data model of the BCV05 of the ICV was followed. The phenomena have been represented following the catalogue of phenomena of the CV05 series. In the case of elements not covered by the BCV05 model, it has been expanded by generating a data model for larger scales that can be requested at cartoinf@valencia.es. It contains information about works that are carried out in the municipality of Valencia, including its method of creation, date and type of work carried out. Official vector cartographic series of reference at scale 1:500, 1:1000 and 1:2000 in 2D, elaborated by the Cartography Section of the Planning Service., which represents the topographical reality of the TM of Valencia. It is a combination of photogrammetric refunds from the August 2018 flight, 2006 flights and GNSS measurements. Geodetic Reference System ETRS89, UTM projection in spindle 30. Vertical datum: the altitudes refer to the average level of the Mediterranean Sea in Alicante. EPSG code: 25830. Planimetric accuracy 10-50 centimeters. The continuous cartographic base is structured for exploitation using Geographic Information Systems. The geographical phenomena that make up the series are structured in these 6 thematic units: orography, hydrography, constructions and buildings, transport networks and toponymy. All of them contain the following fields: Creation: creation method (photogrammetric restoration, GNSS measurement, orthophoto digitisation), date of creation (flight date or date of data collection), scale (information generation scale).The data model of the BCV05 of the ICV was followed. The phenomena have been represented following the catalogue of phenomena of the CV05 series. In the case of elements not covered by the BCV05 model, it has been expanded by generating a data model for larger scales that can be requested at cartoinf@valencia.es.

Use the Atlas template to provide app users with tools to explore layers in a group with lightweight mapping and data exploration capabilities. Add a group of content for your app audience to explore with measurement tools and the option to view in 2D or 3D. Allow users to add layers, adjust transparency, view data as a table, and export your map as an image or PDF. Examples: Present students with a group of topical content they can use to create a simple map. Provide a set of layers that city residents can view and measure to understand local initiatives. Share climate impact data that users can explore without an ArcGIS account. Data requirements The Atlas template has no data requirements. Key app capabilities Add layer - Allows users to explore layers and descriptions, then to add layers to the map. Open map - Allows users to explore map descriptions and open maps in the app. 2D/3D toggle - Changes if the map is shown in 2D or 3D. Only 2D web maps and layer types are supported. Measurement tools - Provide tools that measure distance and area and find and convert coordinates. 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.

Market Size and Growth: The global digital cartography market is projected to reach a value of USD 26.4 billion by 2033, expanding at a CAGR of 13.2% from 2025 to 2033. The increasing demand for accurate and real-time geospatial data, particularly in the commercial and military sectors, is a major driver of market growth. Advancements in technology, such as the rise of 3D mapping and the integration of artificial intelligence, are also contributing to the market's expansion. Key Trends and Market Segmentation: Growth in the digital cartography market is being fueled by several key trends, including the increasing adoption of smartphones and tablets, the rise of autonomous vehicles, and the growing use of geospatial data in business intelligence. The market is segmented based on application (personal use, commercial use, military use, others) and type (2D, 3D). Key players in the global digital cartography market include Google, Microsoft, Apple, Mapbox, and DigitalGlobe. Digital cartography is the creation of maps using digital tools and technologies. It is a rapidly growing field, driven by the increasing availability of digital data and the growing need for accurate and up-to-date maps. The digital cartography market is expected to grow from USD 7.2 billion in 2022 to USD 21.6 billion by 2029, at a compound annual growth rate (CAGR) of 16.7% during the forecast period.

This data set presents the municipal cartography at 1:5000 scale, in SHP format, geodetic reference system ETRS-89, in 2D. The cartographic information is updated according to the municipal photogrammetric flight of the year 2016. In the geoportal of the Madrid City Council, the information and complete services of this data set are available through the following link: Cartography 1:5000 2016 You can also consult the municipal cartography through the Urban Viewer. Source: Geoportal Madrid City Council .