This dataset is intended to provide seamless, integrated bedrock geologic mapping of the U.S. Intermountain West region and is funded by the National Cooperative Geologic Mapping Program of the U.S. Geological Survey. Bedrock geology are included in this data release as an independent dataset at a variable resolution from 1:50,000 to 1:100,000 scale. No original interpretations are presented in this data set; rather, all interpretive data are assimilated from referenceable publications. Initial contributions to this data release are along an east-west transect that parallels 37-degrees north latitude extending from the Rio Grande Rift and Great Plains in the east to the Basin and Range and Sierra Nevada to the west. Other areas of the Intermountain West region will be incorporated over time. Data are presented as downloadable file geodatabase (*.gdb) and as features services that can be directly ingested into GIS software for analysis. This dataset is intended to be versioned regularly as new geologic map data is integrated. The data structure follows the Seamless Integrated Geologic Mapping extension (SIGMa) (Turner and others, 2022) to the Geologic Map Schema (GeMS) (USGS, 2020). U.S. Geological Survey National Cooperative Geologic Mapping Program, 2020, GeMS (Geologic Map Schema)—A standard format for the digital publication of geologic maps: U.S. Geological Survey Techniques and Methods, book 11, chap. B10, 74 p., https://doi.org/10.3133/tm11B10. Turner, K.J., Workman, J.B., Colgan, J.P., Gilmer, A.K., Berry, M.E., Johnstone, S.A., Warrell, K.F., Dechesne, M., VanSistine, D.P., Thompson, R.A., Hudson, A.M., Zellman, K.L., Sweetkind, D., and Ruleman, C.A., 2022, The Seamless Integrated Geologic Mapping (SIGMa) extension to the Geologic Map Schema (GeMS): U.S. Geological Survey Scientific Investigations Report 2022–5115, 33 p., https://doi.org/10.3133/ sir20225115.

Map Direct focus to show Integrated Habitat Network (IHN) regions. Please refer to https://floridadep.gov/water/mining-mitigation/content/integrated-habitat-network for more information. Originally created 12/07/2006, and moved to Map Direct Lite on 03/17/2015. Please contact GIS.Librarian@floridadep.gov for more information.

The global navigation map market is experiencing robust growth, driven by increasing adoption of location-based services across various sectors. Our analysis projects a market size of $15 billion in 2025, exhibiting a Compound Annual Growth Rate (CAGR) of 12% from 2025 to 2033. This significant expansion is fueled by several key factors. The automotive industry's reliance on advanced driver-assistance systems (ADAS) and autonomous vehicles is a primary driver, demanding high-precision and regularly updated map data. Furthermore, the proliferation of mobile devices with integrated GPS and mapping applications continues to stimulate market growth. The burgeoning enterprise solutions segment, utilizing navigation maps for logistics, fleet management, and delivery optimization, contributes significantly to overall market value. Government and public sector initiatives promoting smart cities and infrastructure development further fuel demand. Technological advancements, such as the integration of LiDAR and improved GIS data, enhance map accuracy and functionality, attracting more users and driving market expansion. The market segmentation reveals substantial contributions from various application areas. The automotive segment is projected to maintain its dominance throughout the forecast period, followed closely by the mobile devices and enterprise solutions segments. Within the type segment, GIS data holds a significant market share due to its versatility and application across various sectors. However, LiDAR data is experiencing rapid growth, driven by its high precision and suitability for autonomous driving applications. Geographic regional analysis indicates strong market presence in North America and Europe, primarily driven by advanced technological infrastructure and high adoption rates. However, the Asia-Pacific region is poised for substantial growth, fueled by rapid urbanization, increasing smartphone penetration, and government investments in infrastructure development. Competitive landscape analysis reveals a blend of established players and emerging technology companies, signifying an increasingly dynamic and innovative market environment.

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Digital Map Market Size 2025-2029

The digital map market size is forecast to increase by USD 31.95 billion at a CAGR of 31.3% between 2024 and 2029.

The market is driven by the increasing adoption of intelligent Personal Digital Assistants (PDAs) and the availability of location-based services. PDAs, such as smartphones and smartwatches, are becoming increasingly integrated with digital map technologies, enabling users to navigate and access real-time information on-the-go. The integration of Internet of Things (IoT) enables remote monitoring of cars and theft recovery. Location-based services, including mapping and navigation apps, are a crucial component of this trend, offering users personalized and convenient solutions for travel and exploration. However, the market also faces significant challenges.
Ensuring the protection of sensitive user information is essential for companies operating in this market, as trust and data security are key factors in driving user adoption and retention. Additionally, the competition in the market is intense, with numerous players vying for market share. Companies must differentiate themselves through innovative features, user experience, and strong branding to stand out in this competitive landscape. Security and privacy concerns continue to be a major obstacle, as the collection and use of location data raises valid concerns among consumers.

What will be the Size of the Digital Map Market during the forecast period?

Explore in-depth regional segment analysis with market size data - historical 2019-2023 and forecasts 2025-2029 - in the full report.
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In the market, cartographic generalization and thematic mapping techniques are utilized to convey complex spatial information, transforming raw data into insightful visualizations. Choropleth maps and dot density maps illustrate distribution patterns of environmental data, economic data, and demographic data, while spatial interpolation and predictive modeling enable the estimation of hydrographic data and terrain data in areas with limited information. Urban planning and land use planning benefit from these tools, facilitating network modeling and location intelligence for public safety and emergency management.

Spatial regression and spatial autocorrelation analyses provide valuable insights into urban development trends and patterns. Network analysis and shortest path algorithms optimize transportation planning and logistics management, enhancing marketing analytics and sales territory optimization. Decision support systems and fleet management incorporate 3D building models and real-time data from street view imagery, enabling effective resource management and disaster response. The market in the US is experiencing robust growth, driven by the integration of Geographic Information Systems (GIS), Global Positioning Systems (GPS), and advanced computer technology into various industries.

How is this Digital Map Industry segmented?

The digital map industry research report provides comprehensive data (region-wise segment analysis), with forecasts and estimates in 'USD million' for the period 2025-2029, as well as historical data from 2019-2023 for the following segments.

Application

  Navigation
  Geocoders
  Others


Type

  Outdoor
  Indoor


Solution

  Software
  Services


Deployment

  On-premises
  Cloud


Geography

  North America

    US
    Canada


  Europe

    France
    Germany
    UK


  APAC

    China
    India
    Indonesia
    Japan
    South Korea


  Rest of World (ROW)

By Application Insights

The navigation segment is estimated to witness significant growth during the forecast period. Digital maps play a pivotal role in various industries, particularly in automotive applications for driver assistance systems. These maps encompass raster data, aerial photography, government data, and commercial data, among others. Open-source data and proprietary data are integrated to ensure map accuracy and up-to-date information. Map production involves the use of GPS technology, map projections, and GIS software, while map maintenance and quality control ensure map accuracy. Location-based services (LBS) and route optimization are integral parts of digital maps, enabling real-time navigation and traffic data.

Data validation and map tiles ensure data security. Cloud computing facilitates map distribution and map customization, allowing users to access maps on various devices, including mobile mapping and indoor mapping. Map design, map printing, and reverse geocoding further enhance the user experience. Spatial analysis and data modeling are essential for data warehousing and real-time navigation. The automotive industry's increasing adoption of connected cars and long-term evolution (LTE) technologies have fueled the demand for digital maps. These maps enable driver assistance app

It’s a crisp fall morning in Portland. A local barista opens her shop and pulls out her phone to check delivery routes for fresh beans. She taps the familiar red-and-white pin icon—Google Maps. Across the globe in Tokyo, a student uses Street View to navigate to his university. Meanwhile, a...

Navigation Map Market Outlook

The global navigation map market size was valued at USD 20.5 billion in 2023 and is projected to reach USD 45.8 billion by 2032, exhibiting a Compound Annual Growth Rate (CAGR) of 9.3% during the forecast period. The primary growth factor propelling this market is the increasing integration of advanced mapping technologies in automotive and mobile device industries, aimed at enhancing navigation and user experience.

One of the key drivers of the navigation map market is the rapid technological advancements in digital mapping and Geographic Information Systems (GIS). Innovations such as real-time traffic updates, augmented reality (AR) navigation, and highly detailed 3D maps are significantly enhancing the functionality and user experience of navigation systems. These advancements are crucial for the development of autonomous driving technologies, which rely heavily on precise and real-time mapping data. The proliferation of smartphones equipped with GPS capabilities has also expanded the demand for high-quality digital maps, further fueling market growth.

Another significant growth factor is the increasing demand for navigation solutions in the automotive industry. As automakers strive to enhance driver safety and convenience, the integration of advanced navigation systems has become a standard feature in modern vehicles. The advent of connected cars, which communicate with external systems for real-time traffic and route information, is further driving the need for sophisticated navigation maps. Additionally, the growing trend of ride-hailing and logistics services has necessitated the use of accurate and efficient navigation solutions to optimize routes and improve operational efficiency.

The commercial sector is also contributing to the growth of the navigation map market. Businesses are increasingly relying on advanced mapping solutions to streamline their operations, manage logistics, and enhance customer service. For instance, companies in the e-commerce and delivery services sectors use navigation maps to ensure timely and efficient deliveries. Moreover, the government and public sector are adopting navigation maps for urban planning, disaster management, and public safety applications. These diverse applications across various sectors are collectively driving the demand for navigation maps, thereby contributing to market expansion.

Regionally, North America holds a significant share of the navigation map market, driven by the presence of major technology companies and high adoption rates of advanced navigation solutions. The Asia Pacific region is expected to exhibit the highest growth rate during the forecast period, attributed to the rapid urbanization, increasing smartphone penetration, and growing automotive industry in countries like China and India. Europe also represents a substantial market share, supported by stringent regulations on vehicle safety and the presence of leading automotive manufacturers. The Middle East & Africa and Latin America are gradually adopting advanced navigation technologies, presenting potential growth opportunities in these regions.

The evolution of High Precision Map technology is revolutionizing the navigation map market, particularly in the realm of autonomous vehicles and advanced driver-assistance systems. These maps provide an unparalleled level of detail, including lane-level accuracy and precise positioning, which are essential for the safe and efficient operation of self-driving cars. High Precision Maps are not only crucial for navigation but also for enhancing the overall driving experience by integrating real-time data and predictive analytics. This technology allows vehicles to anticipate road conditions, optimize routes, and improve fuel efficiency, thereby contributing to the broader goals of sustainability and safety in the automotive industry.

Product Type Analysis

The navigation map market is segmented into digital maps and paper maps, each catering to different user preferences and applications. Digital maps are the dominant segment, driven by the widespread use of smartphones, tablets, and in-car navigation systems. Digital maps offer real-time updates, interactive features, and the ability to integrate with other applications, making them highly popular among users. The continuous advancements in digital mapping technologies, such as 3D mapping, AR navigation, and real-time traffic information, are further enhancing the appeal and functionality of digi

The 3D Integrated Mobile Map market is experiencing robust growth, projected to reach a value of $49,770 million in 2025 and maintain a Compound Annual Growth Rate (CAGR) of 8.0% from 2025 to 2033. This expansion is driven by several key factors. The increasing adoption of mobile devices equipped with advanced mapping capabilities, coupled with the rising demand for precise location-based services across various sectors, is fueling market growth. Furthermore, the integration of 3D mapping technology with augmented reality (AR) and virtual reality (VR) applications is opening up new avenues for innovation and creating immersive user experiences. This is particularly evident in sectors like aviation (airlines, airports, and aircraft warehousing) where real-time, accurate 3D maps are crucial for improved navigation, safety, and operational efficiency. The growth is also facilitated by continuous advancements in sensor technologies, data processing capabilities, and the wider availability of high-quality 3D map data. Companies like Betria Interactive, Panasonic, and Rockwell Collins are actively contributing to market growth through their innovative product offerings and strategic partnerships. The market is segmented by type (IFE System, Mobile Terminal) and application (Airport, Airline, Aircraft Warehouse, Others), reflecting the diverse range of applications driving market expansion. Geographic expansion is also a strong contributor, with North America and Asia Pacific expected to be key regional markets. The market's sustained growth trajectory is expected to continue throughout the forecast period, driven by increasing investments in infrastructure development, particularly in smart cities and autonomous vehicles, which heavily rely on precise and detailed 3D mapping. Furthermore, the integration of 3D mobile maps with other technologies, such as the Internet of Things (IoT) and cloud computing, will unlock new opportunities for data analysis and predictive capabilities, further enhancing the market's value proposition. However, challenges such as data security concerns and the high initial investment costs associated with implementing 3D mapping technologies could potentially moderate market growth. Nevertheless, the long-term outlook for the 3D Integrated Mobile Map market remains positive, reflecting the significant potential for technological advancement and widespread adoption across various industries.

Introduction and Rationale: Due to our increasing understanding of the role the surrounding landscape plays in ecological processes, a detailed characterization of land cover, including both agricultural and natural habitats, is ever more important for both researchers and conservation practitioners. Unfortunately, in the United States, different types of land cover data are split across thematic datasets that emphasize agricultural or natural vegetation, but not both. To address this data gap and reduce duplicative efforts in geospatial processing, we merged two major datasets, the LANDFIRE National Vegetation Classification (NVC) and USDA-NASS Cropland Data Layer (CDL), to produce an integrated land cover map. Our workflow leveraged strengths of the NVC and the CDL to produce detailed rasters comprising both agricultural and natural land-cover classes. We generated these maps for each year from 2012-2021 for the conterminous United States, quantified agreement between input layers and accuracy of our merged product, and published the complete workflow necessary to update these data. In our validation analyses, we found that approximately 5.5% of NVC agricultural pixels conflicted with the CDL, but we resolved a majority of these conflicts based on surrounding agricultural land, leaving only 0.6% of agricultural pixels unresolved in our merged product. Contents: Spatial data

Attribute table for merged rasters

Technical validation data

Number and proportion of mismatched pixels Number and proportion of unresolved pixels Producer's and User's accuracy values and coverage of reference data Resources in this dataset:Resource Title: Attribute table for merged rasters. File Name: CombinedRasterAttributeTable_CDLNVC.csvResource Description: Raster attribute table for merged raster product. Class names and recommended color map were taken from USDA-NASS Cropland Data Layer and LANDFIRE National Vegetation Classification. Class values are also identical to source data, except classes from the CDL are now negative values to avoid overlapping NVC values. Resource Title: Number and proportion of mismatched pixels. File Name: pixel_mismatch_byyear_bycounty.csvResource Description: Number and proportion of pixels that were mismatched between the Cropland Data Layer and National Vegetation Classification, per year from 2012-2021, per county in the conterminous United States.Resource Title: Number and proportion of unresolved pixels. File Name: unresolved_conflict_byyear_bycounty.csvResource Description: Number and proportion of unresolved pixels in the final merged rasters, per year from 2012-2021, per county in the conterminous United States. Unresolved pixels are a result of mismatched pixels that we could not resolve based on surrounding agricultural land (no agriculture with 90m radius).Resource Title: Producer's and User's accuracy values and coverage of reference data. File Name: accuracy_datacoverage_byyear_bycounty.csvResource Description: Producer's and User's accuracy values and coverage of reference data, per year from 2012-2021, per county in the conterminous United States. We defined coverage of reference data as the proportional area of land cover classes that were included in the reference data published by USDA-NASS and LANDFIRE for the Cropland Data Layer and National Vegetation Classification, respectively. CDL and NVC classes with reference data also had published accuracy statistics. Resource Title: Data Dictionary. File Name: Data_Dictionary_RasterMerge.csv

The 3D Integrated Mobile Map market is experiencing robust growth, projected to reach a market size of $85.3 million in 2025. While the precise Compound Annual Growth Rate (CAGR) isn't provided, considering the technological advancements in mobile mapping and the increasing adoption across aviation and logistics sectors, a conservative estimate of 15% CAGR from 2025 to 2033 is reasonable. This growth is fueled by several key drivers. The aviation industry's increasing reliance on real-time, precise location data for improved navigation, air traffic management, and enhanced safety measures is a significant factor. Similarly, the logistics sector benefits from optimized route planning, improved efficiency, and reduced operational costs through the use of these maps. Furthermore, the integration of 3D mapping with mobile terminals simplifies data access and usability for field personnel, accelerating decision-making. The market segmentation, encompassing IFE systems, mobile terminals, and applications across airports, airlines, and aircraft warehouses, points to a diverse range of users and applications driving market expansion. Key players like Betria Interactive, Panasonic, and Rockwell Collins are actively shaping market innovation and competition. This competitive landscape, combined with ongoing technological advancements, will likely sustain the market's growth trajectory. Growth is expected to be particularly strong in regions like North America and Europe, driven by early adoption and well-established aviation and logistics infrastructure. However, the Asia-Pacific region is poised for significant expansion as air travel and logistics networks continue to expand rapidly in this region. While challenges such as high initial investment costs and data security concerns might act as restraints, the overall market outlook remains positive given the strategic importance of enhanced situational awareness and optimized operations in both aviation and logistics sectors. The projected market size in 2033, extrapolated from the 2025 value and the assumed 15% CAGR, is expected to be well above $250 million, demonstrating the considerable potential of the 3D Integrated Mobile Map market.

A PDF map that shows the Integrated Care Boards in England and Wales as at April 2023. The map shows the Integrated Care Boards that became operative in England as at April 2023. (File Size - 453 KB)

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.

The interactive map creation tools market is experiencing robust growth, driven by increasing demand for visually engaging data representation across diverse sectors. The market's value is estimated at $2 billion in 2025, exhibiting a Compound Annual Growth Rate (CAGR) of 15% from 2025 to 2033. This growth is fueled by several factors, including the rising adoption of location-based services, the proliferation of readily available geographic data, and the growing need for effective data visualization in business intelligence and marketing. The individual user segment currently holds a significant share, but corporate adoption is rapidly expanding, propelled by the need for sophisticated map-based analytics and internal communication. Furthermore, the paid use segment is anticipated to grow more quickly than the free use segment, reflecting the willingness of businesses and organizations to invest in advanced features and functionalities. This trend is further amplified by the increasing integration of interactive maps into various platforms, such as business intelligence dashboards and website content. Geographic expansion is also a significant growth driver. North America and Europe currently dominate the market, but the Asia-Pacific region is showing significant promise due to rapid technological advancements and increasing internet penetration. Competitive pressures remain high, with established players such as Google, Mapbox, and ArcGIS StoryMaps vying for market share alongside innovative startups offering specialized solutions. The market's restraints are primarily focused on the complexities of data integration and the technical expertise required for effective map creation. However, ongoing developments in user-friendly interfaces and readily available data integration tools are mitigating these challenges. The future of the interactive map creation tools market promises even greater innovation, fueled by developments in augmented reality (AR), virtual reality (VR), and 3D visualization technologies. We expect to see the emergence of more sophisticated tools catering to niche requirements, further driving market segmentation and specialization. Continued investment in research and development will also play a crucial role in pushing the boundaries of what's possible with interactive map creation. The market presents opportunities for companies to develop tools which combine data analytics and interactive map design.

The global navigation electronic map market is experiencing robust growth, driven by the increasing adoption of advanced driver-assistance systems (ADAS) and autonomous vehicles. The market's expansion is fueled by the rising demand for precise and up-to-date map data for navigation applications across various sectors, including automotive, logistics, and mobile devices. Technological advancements, such as high-definition (HD) mapping and the integration of real-time traffic data, are further propelling market growth. Major players like ESRI, Google, and TomTom are actively investing in research and development to enhance map accuracy, functionality, and coverage, fostering competition and innovation within the sector. The market is segmented by map type (2D, 3D, HD), application (automotive, mobile, others), and region, with regional variations reflecting differing levels of technological adoption and infrastructure development. While data security and privacy concerns present challenges, the overall market outlook remains positive, projecting significant expansion over the forecast period (2025-2033). We estimate the market size in 2025 to be around $15 billion, with a projected CAGR of 12% leading to substantial market expansion by 2033. The continuous integration of mapping technologies into various platforms and applications contributes significantly to market expansion. The shift towards connected vehicles and the growing popularity of location-based services (LBS) are creating substantial demand for accurate and comprehensive navigation electronic maps. This necessitates improved data accuracy, real-time updates, and the integration of AI-driven features for enhanced user experience. Furthermore, the increasing focus on infrastructure development and the adoption of smart city initiatives are creating additional opportunities for map providers to offer tailored solutions. However, challenges like maintaining data accuracy across vast geographic areas and managing the associated costs of data acquisition and processing remain. Competition among established players and emerging startups drives innovation and the development of cost-effective solutions, shaping the market landscape. Specific regional growth will vary based on factors such as technological advancement, economic growth, and government regulations.

Integrated range maps were created by combining expert opinion, in the form of polygons from expert field guides (Glassberg 2017, 2018), with relative predicted habitat suitability from MaxEnt models using data from the Global Biodiversity Information Facility (GBIF) records. For species with limited point occurrence records, we used pseudo-presence points within the expert range. With these resulting integrated range maps, we calculated an estimated range for each species by clipping their range rasters to only cells with predicted suitability >0.20 and converting the remaining cells to a smoothed polygon. We then generated a 'butterfly environment index' which is the mean relative predicted habitat suitability for all species whose ranges encompass a site (i.e. it is the mean suitability of a site for species that may be expected to occur there). The integrated range maps were generated to support projects investigating macroscale patterns in butterfly biodiversity in North America, or for species-specific projects that require spatial information for focal species (e.g. where they are likely to occur, estimated extent of occurrence, etc.). The data could also be used for prioritizing regions that may be home to a high diversity of species, or are good habitat for the species that occur within a region. The integrated ranges should be treated as estimates of species distributions, rather than absolute cutoffs in range. The raster values should not be interpreted as probability of occurrence, but rather as relative predicted suitability which also incorporates distance from the expert range to reduce the influence of potentially spurious observations.

File list README.xml - metadata for all species integrated range maps integrated-ranges.zip - a compressed folder containing all 750 integrated range maps, including those generated with pseudo-presence points, as rasters in .tiff format species_richness.tif - a raster of estimated species richness generated by overlaying polygons created at the 0.20 threshold as described in the associated manuscript continental-BEI.tiff - a raster of estimated relative predicted habitat suitability where values are inclusive of all 750 species (i.e. including species that are not expected to occur in a region) as described in the associated manuscript local-BEI.tiff - a raster of estimated relative predicted habitat suitability for species that are expected to occur locally (i.e. only including species that are expected to occur in a region) as described in the associated manuscript

This open-file report presents the results of the USGS Mineral Resources Program activity to compile a national-scale geologic map database to support national and regional level projects, including mineral resource and geo-environmental assessments. The only comprehensive sources of regional- and national-scale geologic maps are state geologic maps with scales ranging from 1:100,000 to 1:1,000,000. Digital versions of these state maps form the core of what is presented here. Because no adequate geologic map exists for the state of Alaska, it is being compiled in regional blocks that also form part of this national database. It is expected that this series will completed by approximately the end of 2007. These maps and databases are being released in blocks of states or, in the case of Alaska, as compiled blocks of 1:250,000-scale quadrangles as chapters in this series. For Alaska, formal maps as well as databases are being published here, whereas for the conterminous U.S. only state databases and preview graphics are presented, because published maps for most states already exist. For Alaska these regional compilations will form the base for compiling a new geologic map of the state. As documented in Chapter A, standards for the conterminous U.S. are somewhat different than those for Alaska and Hawaii.

A 300 x 600 m integrated terrain unit map (ITUM) was produced at 1:500 scale inside the 350 x 650 m Martinelli grid, and the 1:500 digital elevation model (DEM). Vegetation was mapped using Komarkova's (1979) classification system (Braun-Blanquet) units. All map units were mapped to 1g8-inch minimum map-polygon-size resolution. The map is part of the Martinelli grid geographic information system (GIS). Many GIS projects use an approach in which existing mapped information is digitized into the GIS database directly from the original sources. The maps may have different map scale, map-unit resolutions, dates of data collection, and classification systems. When these different sources are combined in a GIS, artifacts may arise due to boundary mismatches and scale incompatibility (Dangermond and Harnden 1990). Integrated geobotanical mapping can minimize many of these problems. This method simultaneously maps vegetation and other terrain features that are interpreted on a common air-photo base (Everett et al. 1978, Walker et al. 1980). We use the term geobotany in its traditional European sense to refer to the study of plant communities and their relationships to geology, landforms, and soils (Braun-Blanquet 1932). Terrain geomorphic boundaries are used to guide the delineation on aerial photographs of most major vegetation boundaries similiar to the landscape-guided vegetation mapping approach developed in Europe (Zonneveld 1988) and the integrated terrain unit mapping approach developed by the Environmental System Research Institute in Redlands, CA (Dangermond and Harnden 1990). Additional information concerning the Niwot Ridge LTER GIS can be found in Walker et al. (1993).

The global market for 3D Integrated Moving Map Applications is experiencing robust growth, driven by increasing demand for advanced navigation and situational awareness solutions across various sectors. This burgeoning market is projected to reach a value of $2.5 billion in 2025, exhibiting a Compound Annual Growth Rate (CAGR) of 15% from 2025 to 2033. Several factors contribute to this expansion, including the rising adoption of sophisticated in-vehicle infotainment systems, the growing integration of 3D mapping technology in aviation and defense applications, and the increasing need for real-time, precise location data in logistics and transportation management. The market is segmented by application (automotive, aviation, maritime, etc.), technology (GPS, inertial navigation systems, etc.), and geographic region. Companies like Betria Interactive, Panasonic, PaxEx.Aero, GeoFusion, Rockwell Collins, and ASELSAN are key players shaping the competitive landscape through continuous innovation and strategic partnerships. The forecast period (2025-2033) will witness significant technological advancements, including the incorporation of augmented reality (AR) and virtual reality (VR) capabilities, enhancing user experience and situational awareness. Further growth is expected through the integration of 5G connectivity and improved data processing capabilities. However, challenges such as high initial investment costs, data security concerns, and the need for robust infrastructure development could potentially restrain market growth to some extent. Nevertheless, the overall outlook remains positive, with continued expansion anticipated across various geographical regions, particularly in North America and Asia-Pacific, fueled by increasing government investments in infrastructure development and advanced navigation technologies. The historical period (2019-2024) provides a solid base for future projections, suggesting a sustained upward trajectory.

This dataset is intended to provide seamless, integrated, surficial geologic mapping of the U.S. Intermountain West region and is supported by the National Cooperative Geologic Mapping Program of the U.S. Geological Survey. Surficial geology included as part of this data release as independent of bedrock geologic mapping and is compiled at a variable resolution from 1:50,000 to 1:250,000 scale. No original interpretations are presented in this dataset; rather, all interpretive data are assimilated from referenceable publications. Initial contributions to this data release are along an east-west transect that parallels 37-degrees north latitude extending from the Rio Grande Rift and Great Plains in the east to the Basin and Range and Sierra Nevada to the west. Other areas of the Intermountain West region will be incorporated over time. Data are presented as a downloadable file geodatabase (*.gdb) and as features services that can be directly ingested into GIS software for analysis. This dataset is intended to be versioned regularly as new geologic map data is integrated. The data structure follows the Seamless Integrated Geologic Mapping extension (SIGMa) (Turner and others, 2022) to the Geologic Map Schema (GeMS) (USGS, 2020). U.S. Geological Survey National Cooperative Geologic Mapping Program, 2020, GeMS (Geologic Map Schema)—A standard format for the digital publication of geologic maps: U.S. Geological Survey Techniques and Methods, book 11, chap. B10, 74 p., https://doi.org/10.3133/tm11B10. Turner, K.J., Workman, J.B., Colgan, J.P., Gilmer, A.K., Berry, M.E., Johnstone, S.A., Warrell, K.F., Dechesne, M., VanSistine, D.P., Thompson, R.A., Hudson, A.M., Zellman, K.L., Sweetkind, D., and Ruleman, C.A., 2022, The Seamless Integrated Geologic Mapping (SIGMa) extension to the Geologic Map Schema (GeMS): U.S. Geological Survey Scientific Investigations Report 2022–5115, 33 p., https://doi.org/10.3133/ sir20225115.

The Professional Map Services market is experiencing robust growth, projected to reach $1003.7 million in 2025. While the exact CAGR isn't provided, considering the rapid technological advancements in GIS, AI-powered mapping, and the increasing reliance on location-based services across various sectors, a conservative estimate of the CAGR for the forecast period (2025-2033) would be between 8% and 12%. This growth is fueled by several key drivers. The burgeoning adoption of smart city initiatives necessitates detailed and accurate mapping solutions. Furthermore, the increasing demand for precise navigation systems in the transportation and logistics industries, coupled with the rising popularity of location-based marketing and advertising, significantly contribute to market expansion. The integration of advanced technologies like AI and machine learning into mapping solutions is further enhancing accuracy, efficiency, and functionality, driving market growth. The market is segmented by service type (consulting and advisory, deployment and integration, support and maintenance) and application (utilities, construction, transportation, government, automotive, others), reflecting the diverse needs of various industries. The competitive landscape is characterized by a mix of established players like Esri, Google, TomTom, and Mapbox, alongside emerging innovative companies. Geographic expansion, particularly in developing economies with rapidly urbanizing populations, presents a significant opportunity for growth. However, challenges such as data security concerns and the high cost of advanced mapping technologies could act as potential restraints. The market's future growth hinges on continuous technological advancements and the expansion of data accessibility. The increasing adoption of cloud-based mapping solutions is streamlining data management and improving collaboration. Furthermore, the growing integration of map data into various applications, such as autonomous vehicles and augmented reality experiences, is creating new market avenues. Regulatory changes and data privacy regulations will play a crucial role in shaping the market landscape in the coming years. The diverse application segments ensure market resilience, as growth in one sector can offset potential slowdowns in another. The ongoing expansion into new geographical territories, particularly in Asia-Pacific and other developing regions, presents substantial growth opportunities for market participants.

State Water Resources Control Board Division of Water Quality staff have developed this map to graphically display the waterbodies assessed in the 2018 California Integrated Report. This map contains waterbodies assessed for 305(b) categorization, including those placed on the 303(d) list of impaired waters.Map Layers and Table:2018 Integrated Report Streams, Rivers, and Beaches: Spatial representation of the assessed linear waterbodies in California.2018 Integrated Report Lakes, Bays, and Reservoirs: Spatial representation of the non-linear (polygon) waterbodies in California. The layers can also be accessed here: https://gispublic.waterboards.ca.gov/portalserver/rest/services/Hosted/CA_2018_Integrated_Report_Assessed_Lines_and_Polys/FeatureServerHow to Use the Map:Navigate to your point of interest by either using the search bar in the upper left-hand corner of the map or by zooming in on the map. You may enter a waterbody name or address into the search bar. Click on a waterbody of interest, such as a river, lake, or beach, and a pop-up box will appear with a summary of the pollutant assessments conducted for that waterbody. Select the ellipsis ("...") in a pop-up window or the layers to view the attribute table. This table can be further filtered and exported in a tabular format. Click on the layers icon in the upper right hand corner to toggle map layers on and off.Click on the filter button in the upper right corner to filter for a specific Regional Board and to select for 303(d) listed waterbodies only. Note, this should be done for both layers.More details on each waterbody can be found by scrolling to the bottom of a waterbody pop-up and selecting “Waterbody Fact Sheet- More information”.Pop Up Description:WBID: Unique identifier for each waterbody used in the Integrated Report. Waterbody Name: Name of the mapped waterbody assessed for the Integrated Report. Waterbody Type: Type of water (Coastal & Bay Shoreline, Freshwater Wetland, Tidal Wetland, Saline Lake, River & Stream, Ocean, Lake and Reservoir, Estuary, and Bay & Harbor).Regional Board: Which Regional Water Quality Control Board has jurisdiction over the waterbody. Waterbody Condition Category: Integrated Report 305(b) Category for the waterbody.Waterbody Listing Status: If the waterbody has been placed on the 303(d) list as impaired for one or more pollutant, it will be identified as "Listed". If it was assessed for one or more pollutant and not determined to be impaired, it will be identified as "Not Listed". Listed Pollutants: Pollutants identified as impairing the waterbody's support of beneficial uses. The Decision ID is included in parentheses. Listings Addressed by a TMDL: Pollutant impairments in the waterbody being addressed by an adopted Total Maximum Daily Load (TMDL)Listings Addressed by Action other than TMDL: Pollutant impairments in the waterbody being addressed by actions other than a TMDL. These may also be referred to as Category “4b” decisions.Pollutants Assessed, Not Listed: Pollutant assessments that did not result in a 303(d) impairment decision for the waterbody.Waterbody Fact Sheet: Link to the Waterbody Fact Sheet for the waterbody, which includes waterbody/pollutant assessment information. For additional data and information about the 2018 Integrated Report assessments, please visit our Data Download page: (coming soon!)For more information about the Integrated Report (the 305(b) Report and the 303(d) List), how it is created, or how this information is used, please see the program webpage: https://www.waterboards.ca.gov/water_issues/programs/water_quality_assessment/Please contact the SWRCB Water Quality Assessment Program with any questions, at WQAssessment@waterboards.ca.gov. Origin Date: July 2, 2021Last edited: July 28, 2021