Public Land Survey SystemThis feature layer, utilizing National Geospatial Data Asset (NGDA) data from the Bureau of Land Management data, displays the Public Land Survey System (PLSS) in the United States. Per BLM, "The BLM is required to perform cadastral surveys on all federal interest and Indian lands. As part of survey work, the BLM maintains an essential land grid, known as the rectangular survey system or Public Land Survey System (PLSS), which is the basis for identifying legal descriptions of land parcels."PLSS Township 7N 22EData downloaded: October 17, 2023Data source: BLM National Public Land Survey System PolygonsNGDAID: 10 (BLM National PLSS Public Land Survey System Polygons)OGC API Features Link: (Public_Land_Survey_System - OGC Features) copy this link to embed it in OGC Compliant viewersFor more information: About the Public Land Survey SystemSupport documentation: BLM National PLSS Public Land Survey System PolygonsFor feedback please contact: ArcGIScomNationalMaps@esri.comNGDA Data SetThis data set is part of the NGDA Cadastre Theme Community. Per the Federal Geospatial Data Committee (FGDC), Cadastre is defined as the "past, current, and future rights and interests in real property including the spatial information necessary to describe geographic extents. Rights and interests are benefits or enjoyment in real property that can be conveyed, transferred, or otherwise allocated to another for economic remuneration. Rights and interests are recorded in land record documents. The spatial information necessary to describe geographic extents includes surveys and legal description frameworks such as the Public Land Survey System, as well as parcel-by-parcel surveys and descriptions. Does not include federal government or military facilities."For other NGDA Content: Esri Federal Datasets

The United States Public Land Survey (PLS) divided land into one square mile units, termed sections. Surveyors used trees to locate section corners and other locations of interest (witness trees). As a result, a systematic ecological dataset was produced with regular sampling over a large region of the United States, beginning in Ohio in 1786 and continuing westward.
We digitized and georeferenced archival hand drawn maps of these witness trees for 27 counties in Ohio. This dataset consists of a GIS point shapefile with 11,925 points located at section corners, recording 26,028 trees (up to four trees could be recorded at each corner). We retain species names given on each archival map key, resulting in 70 unique species common names. PLS records were obtained from hand-drawn archival maps of original witness trees produced by researchers at The Ohio State University in the 1960’s. Scans of these maps are archived as “The Edgar Nelson Transeau Ohio Vegetation Survey” at The Ohio State University: http://hdl.handle.net/1811/64106.
The 27 counties are: Adams, Allen, Auglaize, Belmont, Brown, Darke, Defiance, Gallia, Guernsey, Hancock, Lawrence, Lucas, Mercer, Miami, Monroe, Montgomery, Morgan, Noble, Ottawa, Paulding, Pike, Putnam, Scioto, Seneca, Shelby, Williams, Wyandot. Coordinate Reference System: North American Datum 1983 (NAD83). This material is based upon work supported by the National Science Foundation under grants #DEB-1241874, 1241868, 1241870, 1241851, 1241891, 1241846, 1241856, 1241930.

In support of new permitting workflows associated with anticipated WellSTAR needs, the CalGEM GIS unit extended the existing BLM PLSS Township & Range grid to cover offshore areas with the 3-mile limit of California jurisdiction. The PLSS grid as currently used by CalGEM is a composite of a BLM download (the majority of the data), additions by the DPR, and polygons created by CalGEM to fill in missing areas (the Ranchos, and Offshore areas within the 3-mile limit of California jurisdiction).CalGEM is the Geologic Energy Management Division of the California Department of Conservation, formerly the Division of Oil, Gas, and Geothermal Resources (as of January 1, 2020).Update Frequency: As Needed

The 3D Land Surveying System market is experiencing robust growth, projected to reach a market size of $1752.7 million in 2025. While the provided CAGR is missing, considering the technological advancements driving automation in surveying and the increasing demand for precise data in infrastructure development and construction, a conservative estimate of a 7% CAGR from 2025 to 2033 is reasonable. This would indicate a significant expansion of the market, driven by factors such as the increasing adoption of advanced technologies like LiDAR and photogrammetry, rising infrastructure investments globally, and the need for efficient and accurate land data for urban planning and environmental monitoring. The market segmentation, encompassing fixed and mobile surveying systems and applications across surveying & mapping, construction, and other sectors, reveals diverse growth opportunities. The preference for mobile systems is likely to increase due to their portability and ease of use, while the construction sector is expected to be a major driver of market growth due to the rising number of construction projects globally. The regional distribution shows substantial potential across North America, Europe, and Asia-Pacific, reflecting the concentration of developed economies and significant infrastructure investments. However, developing regions in the Middle East & Africa and South America are also showing promising growth potential as infrastructure development and urbanization accelerate. Competitive dynamics involve a mix of established surveying firms and emerging technology providers, emphasizing both service-based and technology-driven solutions. The continued integration of AI and machine learning into surveying systems is likely to further enhance the efficiency and accuracy of land surveying, fueling market expansion in the coming years. This combination of technological innovation and growing infrastructural needs ensures a sustained upward trajectory for the 3D Land Surveying System market.

In support of new permitting workflows associated with anticipated WellSTAR needs, the CalGEM GIS unit extended the existing BLM PLSS Township & Range grid to cover offshore areas with the 3-mile limit of California jurisdiction. The PLSS grid as currently used by CalGEM is a composite of a BLM download (the majority of the data), additions by the DPR, and polygons created by CalGEM to fill in missing areas (the Ranchos, and Offshore areas within the 3-mile limit of California jurisdiction).CalGEM is the Geologic Energy Management Division of the California Department of Conservation, formerly the Division of Oil, Gas, and Geothermal Resources (as of January 1, 2020).Update Frequency: As Needed

This dataset represents the GIS Version of the Public Land Survey System including both rectangular and non-rectangular surveys. The primary source for the data is cadastral survey records housed by the BLM supplemented with local records and geographic control coordinates from states, counties as well as other federal agencies such as the USGS and USFS. The data has been converted from source documents to digital form and transferred into a GIS format that is compliant with FGDC Cadastral Data Content Standards and Guidelines for publication. This data is optimized for data publication and sharing rather than for specific 'production' or operation and maintenance. This data set includes the following: PLSS Fully Intersected (all of the PLSS feature at the atomic or smallest polygon level), PLSS Townships, First Divisions and Second Divisions (the hierarchical break down of the PLSS Rectangular surveys), and the Bureau of Census 2015 Cartographic State Boundaries. The Entity-Attribute section of this metadata describes these components in greater detail. Please note that the data on this site, although published at regular intervals, may not be the most current PLSS data that is available from the BLM. Updates to the PLSS data at the BLM State Offices may have occurred since this data was published. To ensure users have the most current data, please contact the BLM PLSS Data Set Manager.

Download .zipThis data set represents the GIS Version of the Public Land Survey System including both rectangular and non-rectangular surveys. The metadata describes the lineage, sources and production methods for the data content. The definitions and structure of this data is compliant with FGDC Cadastral Data Content Standards and Guidelines for publication. This coverage was originally created for the accurate location of the oil and gas wells in the state of Ohio. The original data set was developed as an ArcInfo coverage containing the original land subdivision boundaries for Ohio. Ohio has had a long and varied history of its land subdivisions that has led to the use of several subdivision strategies being applied. In general, these different schemes are composed of the Public Land Surveying System (PLSS) subdivisions and the irregular land subdivisions. The PLSS subdivisions contain townships, ranges, and sections. They are found in the following major land subdivisions: Old Seven Ranges, Between the Miamis (parts of which are known as the Symmes Purchase), Congress Lands East of Scioto River, Congress Lands North of Old Seven Ranges, Congress Lands West of Miami River, North and East of the First Principal Meridian, South and East of the First Principal Meridian, and the Michigan Meridian Survey. The irregular subdivisions include the Virginia Military District, the Ohio Company Purchase, the U.S. Military District, the Connecticut Western Reserve, the Twelve-Mile Square Reservation, the Two-Mile Square Reservation, the Refugee Lands, the French Grants, and the Donation Tract. This data set represents the GIS Version of the Public Land Survey System including both rectangular and non-rectangular surveys. The primary source for the data is local records and geographic control coordinates from states, counties as well as federal agencies such as the BLM, USGS and USFS. The data has been converted from source documents to digital form and transferred into a GIS format that is compliant with FGDC Cadastral Data Content Standards and Guidelines for publication. This data is optimized for data publication and sharing rather than for specific "production" or operation and maintenance. This data set includes the following: PLSS Fully Intersected (all of the PLSS feature at the atomic or smallest polygon level), PLSS Townships, First Divisions and Second Divisions (the hierarchical break down of the PLSS Rectangular surveys) PLSS Special surveys (non rectangular components of the PLSS) Meandered Water, Corners and Conflicted Areas (known areas of gaps or overlaps between Townships or state boundaries). The Entity-Attribute section of this metadata describes these components in greater detail.This data set is optimized for data publication and sharing rather than for specific "production" or operation and maintenance. This data set includes the following: PLSS Fully Intersected (all of the PLSS feature at the atomic or smallest polygon level), PLSS Townships, First Divisions and Second Divisions (the hierarchical break down of the PLSS Rectangular surveys) PLSS Special surveys (non rectangular components of the PLSS) Meandered Water, Corners and Conflicted Areas (known areas of gaps or overlaps between Townships or state boundaries). The Entity-Attribute section of this metadata describes these components in greater detail.Contact Information:GIS Support, ODNR GIS ServicesOhio Department of Natural ResourcesOffice of Information TechnologyGIS Records2045 Morse Rd, Bldg I-2Columbus, OH, 43229Telephone: 614-265-6462Email: gis.support@dnr.ohio.gov

The global land survey software market is experiencing robust growth, driven by increasing adoption of advanced technologies like GIS, cloud computing, and AI in surveying operations. The market's size in 2025 is estimated at $2.5 billion, exhibiting a Compound Annual Growth Rate (CAGR) of 8% from 2025 to 2033. This growth is fueled by several key factors. Firstly, the rising demand for precise and efficient land surveying in infrastructure development, urban planning, and construction projects is a significant driver. Secondly, the increasing availability of affordable and user-friendly software solutions is making land surveying technology more accessible to a broader range of users, from small surveying firms to individual professionals. Thirdly, the integration of advanced analytics capabilities within land survey software is enabling improved data analysis and decision-making, leading to better project outcomes and cost efficiencies. Finally, government initiatives promoting digitalization in land administration and mapping further contribute to market expansion. However, the market also faces certain restraints. The high initial investment cost associated with implementing advanced software and hardware can be a barrier for some smaller companies. Additionally, the need for specialized skills and training to effectively utilize these sophisticated tools can limit widespread adoption. Despite these challenges, the long-term outlook for the land survey software market remains positive, primarily due to the continuous advancements in technology and the growing demand for precise land information across various sectors. Key players such as Carlson Software, Microsurvey, GeoMax, Leica Geosystems, Topcon Positioning, Sokkia, Trimble, and Autodesk are actively contributing to market innovation through continuous product development and strategic partnerships. The market segmentation reflects the diverse applications of land survey software across different geographical regions and industries.

The global real estate surveying and mapping market is experiencing robust growth, driven by the burgeoning construction industry, increasing urbanization, and the rising demand for precise land information for real estate development projects. The market, segmented by application (urban planning, real estate development, others) and type (land surveying & mapping, house surveying & mapping, others), shows significant potential across various regions. While precise market sizing data isn't provided, considering the involvement of major players like Trimble, Fugro, and AECOM, and the rapid expansion in urban areas globally, a conservative estimate places the 2025 market value at approximately $15 billion. A Compound Annual Growth Rate (CAGR) of, say, 7% (a reasonable estimate given industry growth trends) projects significant expansion over the forecast period (2025-2033). This growth is fueled by technological advancements, particularly in Geographic Information Systems (GIS) and drone technology, enabling faster, more accurate, and cost-effective surveying and mapping. Furthermore, increasing government regulations and emphasis on sustainable development are pushing for better land management, further boosting market demand. Key restraints include the high initial investment costs associated with advanced surveying technologies and the need for skilled professionals capable of operating and interpreting data from these technologies. However, the long-term benefits of improved accuracy, efficiency, and reduced risk outweigh these initial hurdles. Regional variations exist, with North America and Europe currently dominating the market due to higher adoption rates of advanced technologies and established real estate sectors. However, rapid urbanization in Asia-Pacific and other developing regions is expected to drive substantial growth in these areas in the coming years. The market's future trajectory is positive, with opportunities for companies to innovate in data analytics and integrate AI for enhanced decision-making in real estate projects. This increased sophistication in data analysis translates to improved efficiency, reduced errors, and better-informed investment decisions.

An area defined by the Public Lands Survey System grid that is referenced by its tier and range numbers, and is normally a rectangle approximately 6 miles on a side with boundaries conforming to meridians and parallels. Metadata

The global land and sea surveying and mapping market is experiencing robust growth, driven by increasing infrastructure development, rising urbanization, and the growing need for precise geospatial data across various sectors. While the exact market size for 2025 is not provided, considering the presence of numerous established players like KSN, Partner Engineering and Science, and Tetra Tech, and a reasonably high number of regional players, a conservative estimate places the 2025 market size at approximately $15 billion. Assuming a Compound Annual Growth Rate (CAGR) of 7% (a figure reflective of the growth in related geospatial technology markets), the market is projected to reach approximately $23 billion by 2033. This growth trajectory is fueled by technological advancements such as the integration of drones, LiDAR, and GPS, improving data acquisition speed and accuracy. Furthermore, the increasing adoption of BIM (Building Information Modeling) and GIS (Geographic Information Systems) technologies are significantly boosting demand for high-quality surveying and mapping services. However, market growth faces some restraints. High initial investment costs associated with sophisticated equipment and specialized software can limit entry for smaller firms. Additionally, the need for highly skilled professionals and stringent regulatory compliance can pose challenges. The market is segmented by service type (topographic, hydrographic, cadastral, etc.), technology used (GPS, LiDAR, photogrammetry), and end-user industry (construction, energy, environmental management). The competitive landscape is characterized by a mix of large multinational corporations and smaller, specialized firms, leading to a dynamic market with ongoing innovation and consolidation. Regional variations in market growth will be influenced by factors such as infrastructure spending, government regulations, and economic conditions in specific regions.

Layers in this dataset represent Public Land Survey System subdivisions for Canadian County. Included are Townships, Sections, Quarter Sections and Government Lots. This data was created from 2019 to 2021 as part of a project to update county parcel data in partnership with ProWest & Associates (https://www.prowestgis.com/) and CEC Corporation (https://www.connectcec.com/). Corners were located to the quarter section level and additional corners were determined for the South Canadian River meanders based on the original government surveys. Quarter section corners were located using Certified Corner Records ( filed by Oklahoma licensed professional surveyors with the Oklahoma Department of Libraries where those records included coordinates. When a corner record could not be found or did not include coordinates, other interpolation methods were employed. These included connecting known corner record locations to unknown corners using data from filed subdivisions or from highway plans on record with the Oklahoma Department of Transportation. Where no corner records with coordinates were available and no interpolation methods could be used, aerial inspection was used to locate corners as the last option.Corner location accuracy varies as the method of locating the corner varies. For corners located using Certified Corner Records, accuracy is high depending on the age of the corner record and can possibly be less than 1 U.S. Foot. For corners located using interpolation methods, accuracy depends on the additional material used to interpolate the corner. In general, newer subdivisions and highway plans yield higher accuracy. For meander corners located using original government surveys, accuracy will be low due to the age of those surveys which date to the 1870's at the earliest. Additionally, corners that were located with aerials as the last available option cannot be assumed to be accurate.The data was built at the quarter section level first by connecting located corners and larger subdivisions were created from the quarter sections. For townships that extend into Grady County, township lines were only roughly located outside sections not in Canadian County.

Note: This is a large dataset. To download, go to ArcGIS Open Data Set and click the download button, and under additional resources select the shapefile or geodatabase option. A land survey point from a GCDB LX file, survey plat, or captured from a CFF land net coverage. Includes points generated by calculating an aliquot breakdown of a section.

The global surveying and mapping services market is experiencing robust growth, driven by increasing infrastructure development, urbanization, and the rising adoption of advanced technologies like GIS, LiDAR, and drones. This market is projected to reach a substantial size, with a Compound Annual Growth Rate (CAGR) indicating a significant expansion throughout the forecast period (2025-2033). While precise figures for market size and CAGR are not provided, based on industry analysis of similar sectors exhibiting comparable growth trajectories, a reasonable estimation suggests a market size exceeding $100 billion by 2033, with a CAGR of around 7-8%. This growth is fueled by several key drivers, including the burgeoning need for precise geospatial data in various sectors like construction, agriculture, mining, and environmental management. Government initiatives promoting infrastructure development and smart city projects further contribute to this market expansion. The market is segmented by service type (e.g., land surveying, hydrographic surveying, aerial mapping), technology used, and end-user industries. Leading players like PASCO Corporation, Fugro, AECOM, and Stantec are leveraging technological advancements and strategic partnerships to maintain their market share and expand their service offerings. However, challenges such as fluctuating raw material prices, stringent regulatory frameworks, and skilled labor shortages could potentially restrain market growth in certain regions. The increasing availability of low-cost satellite imagery and the emergence of innovative mapping solutions present both opportunities and competitive pressures within the industry. The adoption of cloud-based solutions for data storage and processing is expected to gain significant traction, further shaping the market landscape in the years to come. Regional variations in market growth are anticipated, with developed economies experiencing more moderate growth compared to developing nations with rapid infrastructure development.

Feature layer of locations corresponding to surveys that are produced by Vermont licensed land surveyors and submitted—as .pdf copies—to the Vermont Land Survey Library.Locations are attributed with information such as name of surveyor, date of survey, survey type (e.g., subdivision), and municipality. When the feature layer is opened in ArcGIS Online, the .pdf copies (as feature attachments) can be viewed/downloaded.Effective January 1, 2020 and as stated in27 V.S.A. § 341, surveys are required for property line changes in Vermont. Licensed land surveyors who produce the surveys are to submit a digital copy of them to the library in.pdf format (see27 V.S.A. §1401 and 27 V.S.A. §1403).The copies of surveys are for public reference only, with the originals that most often reside with the Municipality remaining the official documents. The purpose of the land survey library is to improve knowledge of who owns what lands where throughout Vermont.For more information about land surveying in Vermont, see theVermont Society of Land Surveyors (VSLS) and the Vermont Survey Law Manual (PDF).

This dataset is part of the Cadastral National Spatial Data Infrastructure (CadNSDI) publication dataset for rectangular and non‐rectangular Public Land Survey System (PLSS) data. This dataset represents the GIS Version of the Public Land Survey System including both rectangular and non-rectangular surveys. The primary source for the data is cadastral survey records housed by the BLM supplemented with local records and geographic control coordinates from states, counties as well as other federal agencies such as the USGS and USFS. The data has been converted from source documents to digital form and transferred into a GIS format that is compliant with FGDC Cadastral Data Content Standards and Guidelines for publication. This data is optimized for data publication and sharing rather than for specific "production" or operation and maintenance. This data set includes the following: PLSS Fully Intersected (all of the PLSS feature at the atomic or smallest polygon level), PLSS Townships, First Divisions and Second Divisions (the hierarchical break down of the PLSS Rectangular surveys) PLSS Special surveys (non-rectangular components of the PLSS) Meandered Water, Corners and Conflicted Areas (known areas of gaps or overlaps between Townships or state boundaries). The Entity-‐ Attribute section of this metadata describes these components in greater detail. The CadNSDI or the Cadastral Publication Data Standard is the cadastral data component of the NSDI. This is the publication guideline for cadastral data that is intended to provide a common format and structure and content for cadastral information that can be made available across jurisdictional boundaries, providing a consistent and uniform cadastral data to meet business need that includes connections to the source information from the data stewards. The data stewards determine which data are published and should be contacted for any questions on data content or for additional information. The cadastral publication data is data provided by cadastral data producers in a standard form on a regular basis. Cadastral publication data has two primary components, land parcel data and cadastral reference data. It is important to recognize that the publication data are not the same as the operation and maintenance or production data. The production data is structured to optimize maintenance processes, is integrated with internal agency operations and contains much more detail than the publication data. The publication data is a subset of the more complete production data and is reformatted to meet a national standard so data can be integrated across jurisdictional boundaries and be presented in a consistent and standard form nationally.

The land surveying instrument market, valued at $6107 million in 2025, is projected to experience robust growth, driven by increasing infrastructure development globally and the rising adoption of advanced technologies like robotic total stations and GNSS receivers. The market's Compound Annual Growth Rate (CAGR) of 5.8% from 2025 to 2033 indicates a significant expansion, fueled by the growing demand for precise and efficient surveying solutions across various sectors. Key application areas like construction and survey & mapping are primary growth drivers, benefiting from urbanization and the need for detailed spatial data. Technological advancements, including improved accuracy, automation, and data integration capabilities of instruments, further contribute to market expansion. While challenges such as high initial investment costs for advanced equipment and the need for skilled professionals might act as restraints, the overall market outlook remains positive due to consistent technological innovation and rising government investments in infrastructure projects worldwide. The market segmentation reveals a diverse landscape. Robotic total stations are anticipated to witness high demand owing to their enhanced efficiency and accuracy compared to their mechanical counterparts. GNSS receivers and GIS receivers are gaining traction due to their ability to provide real-time data and seamless integration with Geographical Information Systems. The 3D mobile mapping segment is expected to show significant growth, driven by the rising need for detailed 3D models in various applications, including urban planning and environmental monitoring. Geographically, North America and Europe currently hold significant market shares, but the Asia-Pacific region is projected to exhibit considerable growth potential in the coming years, driven by rapid urbanization and infrastructure development in countries like China and India. Leading companies like Hexagon, Trimble, Topcon, and others are actively engaged in developing and deploying innovative land surveying instruments to meet evolving market demands, fostering competition and technological advancement within the sector.

The global land surveying equipment market is experiencing robust growth, projected to reach a value of $12,540 million in 2025, exhibiting a Compound Annual Growth Rate (CAGR) of 6.0% from 2025 to 2033. This expansion is fueled by several key drivers. Increased infrastructure development globally, particularly in emerging economies, necessitates precise land surveying for construction projects, urban planning, and resource management. Furthermore, advancements in technology, such as the integration of GNSS (Global Navigation Satellite Systems) with other surveying instruments like total stations and UAVs (Unmanned Aerial Vehicles), are enhancing accuracy, efficiency, and data acquisition speed. The rising adoption of laser scanning and 3D modeling for creating detailed site models accelerates market growth. Government initiatives promoting sustainable infrastructure and digitalization are also contributing factors. However, the market faces some challenges, including the high initial investment costs associated with advanced equipment and the need for skilled professionals to operate and interpret the sophisticated data generated. Segmentation reveals that GNSS systems, total stations, and UAVs are significant contributors to market revenue. Applications across inspection, monitoring, volumetric calculations, and layout points further underscore the versatile nature of this technology within various industries. The competitive landscape is marked by both established global players like Topcon, Trimble, and Hexagon AB and regional manufacturers. This dynamic interplay stimulates innovation and ensures a diverse range of equipment options catering to specific project requirements and budget constraints. Future growth will likely be influenced by technological advancements in areas such as real-time kinematic (RTK) positioning, cloud-based data processing, and the integration of artificial intelligence for automated data analysis. The market's geographical distribution is expected to witness substantial growth in Asia-Pacific regions, driven by rapid urbanization and infrastructure development in countries like China and India. North America and Europe will maintain significant market share due to established surveying practices and high adoption rates of advanced technologies. The consistent CAGR suggests a promising outlook for the land surveying equipment market throughout the forecast period, underpinned by technological progress, increased infrastructure investment, and evolving surveying methodologies.

Download In State Plane Projection Here ** In addition to the Tax Parcel polygons feature class, the hyperlink download above also contains a parcel point data layer ** Parcel boundaries are developed from deeds, plats of subdivision and other legal documents going back to the mid 1800's, following generally accepted practices used in Public Land Survey System states, and following guidelines established by the Illinois Department of Revenue and the International Association of Assessment Officials. Lake County's parcel coverage is based on resolving the accumulated evidence of all of the legal documents surrounding a particular parcel or subdivision, and not the result of a countywide resurvey. These parcel boundaries are intended to be a visual inventory of property for tax and other administrative purposes; they are not intended to be used in place of an on-site survey or for the precise determination of property corners or PLSS features based on GIS coordinates. In Illinois, only a registered professional land surveyor is authorized to determine boundary locations. Included are the tax parcel boundaries, represented as polygons and centroids, for all changes resulting from legal records submitted to the Recorder of Deeds up to December 31st of the preceding year, as well as any court orders, municipal annexations and other transactions which impact the tax parcel boundaries. NOTE: The ONLY attribute included is the Property Index Number, or PARCEL_NUM. Additional assessment attribute data can be downloaded here This parcel layer is used for tax assessment purposes and for a variety of other local government functions. It changes often, both spatially and in its attribution, based on divisions or consolidations, the sale of property and other transactions. Example: PIN 08-17-304-014 can be interpreted as follows: Township 08, Section 17, Block 304, Parcel 014. Note that the first digit of block, "3" in this example, signifies that the parcel lies in quarter section 3. The quarter sections are labeled from 1 through 4, representing the northwest, northeast, southwest and southeast quarter sections, respectively. Update Frequency: This dataset is updated on a weekly basis.

This data layer is an element of the Oregon GIS Framework. This theme contains PLS lines for the State of Oregon. This PLS theme includes donation claims lands. Attributes in this theme show Township Range and Section values.