Geodetic Datums: NAD 27, NAD 83 and WGS84

NAD27 Shift to NAD83 (Image credit: NADCON - North American Datum Conversion Utility)

When you need to accurately enter coordinates in a GIS, the first step is that you uniquely define all locations on Earth. This means you need a reference frame for your coordinates becausewhere would you be on Earth without having reference to it?


Because the Earth is curved – and in GIS we deal with flat maps – we need to accommodate both the curved and flat views of the world. Surveyors and geodesists have accurately defined locations on Earth.

We begin modelling the Earth with an ellipse – which is different than a geoid. Over time, the ellipsoid has been estimated to the best of our ability through a massive collection of surface measurements.

When you combine these measurements, we arrive at a geodetic datum. Datums precisely specify each location on Earth’s surface in latitude and longitude or other coordinate systems. NAD 27, NAD 83 and WGS84 are examples of geodetic datums.

A Mammoth Collection of Survey Benchmarks
In order to create a geodetic datum, a mammoth collection of monument locations (survey benchmarks) were collected in the late 1800s. Surveyors installed brass or aluminum disks at each reference location.



Each monument location was connected using mathematical techniques like triangulation. The result of triangulation from the unified network of survey monuments was North American Datum of 1927 (NAD 27) and later the more accurate NAD 83, which is still used today. NAD 27 and NAD 83 provide a frame of reference for latitude and longitude locations on Earth.



Surveyors now rely almost exclusively on the Global Positioning System (GPS) to identify locations on the Earth and incorporate them into existing geodetic datums. Geocaching for survey benchmarks is another popular activity.

NAD27, NAD83 and WGS84 are commonly used geodetic datums in North America.

What is North American Datum 1927 (NAD27)?

Meades Ranch Triangulation Station, fundamental station for the North American Datum of 1927

NAD27 stands for North American Datum of 1927. NAD27 is the adjustment of long-baseline surveys to establish a network of standardized horizontal positions on North America. Most historical USGS topographic maps and projects by the US Army Corps of Engineers used NAD27 as a reference system.

A horizontal datum provides a frame of reference as a basis for placing specific locations at specific points on the spheroid. A horizontal datum is the model that is used to translate a spheroid / ellipsoid into locations on Earth with latitude and longitude lines. Geodetic datums form the basis of coordinates of all horizontal positions on Earth. All coordinates on Earth are referenced to a horizontal datum. The North American Datum of 1927 (NAD27) is one of the main three geodetic datums used in North America.

NAD27 uses all horizontal geodetic surveys collected at this time using a least-square adjustment. This datum uses the Clarke Ellipsoid of 1866 with a fixed latitude and longitude at Meade’s Ranch, Kansas. (39°13’26.686″ north latitude, 98°32’30.506″ west longitude)

Kansas was selected as a common reference point because it was near the center of the contiguous United States. The latitudes and longitudes of every other point in North America were based off its direction, angle and distance away from Meade’s Ranch. Any point with a latitude and longitude away from this reference point could be measured on the Clarke Ellipsoid of 1866.

Approximately 26,000 survey stations were gathered in the United States and Canada. At each station, surveyors collected latitudes and longitude coordinates. NOAA’s National Geodetic Survey used these survey stations and triangulation to form the NAD27 datum.

As time went on, surveyors benchmarked approximately 250,000 stations. This set of horizontal positions formed the basis for the North American Datum of 1983 (NAD83). In 1983, the NAD27 datum was eventually replaced with NAD83.

What is North American Datum 1983 (NAD83)?

Geocentric Datum

The North American datum of 1983 (NAD 83) is the most current datum being used in North America. It provides latitude and longitude and some height information using the reference ellipsoid GRS80. Geodetic datums like the North American Datum 1983 (NAD83) form the basis of coordinates of all horizontal positions for Canada and the United States.

The North American Datum of 1983 (NAD 83) is a unified horizontal or geometric datum and successor to NAD27 providing a spatial reference for Canada and the United States.

NAD83 corrects some of the distortions from NAD27 over distance by using a more sense set of positions from terrestrial and Doppler satellite data. NAD83 is a geocentric datum (referenced to the center of Earth’s mass) offset by about 2 meters.

Even today, horizontal geodetic datums are continuously being improved.

WGS84: Unifying a Global Ellipsoid Model with GPS

GPS Satellite

It wasn’t until the mainstream use of Global Positioning Systems (GPS) until a unified global ellipsoid model was developed. The radio waves transmitted by GPS satellites enable extremely precise Earth measurements across continents and oceans. Global ellipsoid models have been created because of the enhancement of computing capabilities and GPS technology.

This has led to the development of global ellipsoid models such as WGS72, GRS80 and WGS84 (current). The World Geodetic System(WGS84) is the reference coordinate system used by the Global Positioning System.

Never before have we’ve been able to estimate the ellipsoid with such precision because of the global set of measurements provided by GPS. It comprises of a reference ellipsoid, a standard coordinate system, altitude data and a geoid. Similar to NAD 83, it uses the Earth’s center mass as the coordinate origin. The error is believed to be less than 2 centimeters to the center mass.

Question: What is EPSG4326?

Answer: EPSG4326 is just the way to identify WGS84 using EPSG. Here is the spatial reference list.

Geodetic Datums: NAD83 versus NAD27

NAD83 corrects some of the distortions from NAD27 over distance by using a more dense set of positions from terrestrial and Doppler satellite data. Approximately 250,000 stations were used to develop the NAD83 datum. This compares to only 26,000 used in the NAD27 datum.

NAD83 Center of Mass

One of the primary difference is that NAD83 uses an Earth-centered reference, rather than a fixed station in NAD27. All coordinates were referenced to Kansas Meade’s Ranch (39°13’26.686″ north latitude, 98°32’30.506″ west longitude) for NAD27 datum. The National Geodetic Survey relied heavily on the use of Doppler satellite to locate the Earth’s center of mass. However, NAD83 is not geocentric with an offset of about two meters.

North American Datum of 1983 is based off the reference ellipsoid GRS80 which is physically larger than NAD27’s Clarke ellpsoid. The GRS80 reference ellipsoid has a semi-major axis of 6,378,137.0 meters and a semi-minor axis of 6,356,752.3 meters. This compares to the Clarke ellipsoid with a semi-major axis of 6,378,206.4 m and semi-minor axis of 6,356,583.8 meters.

The Varying Historical Accuracy of the Ellipsoid
Is the Earth Round? Earth bulges out more at the equator than at the poles by about 70,000 feet.

And since the beginning of the 19th century, the dimensions of the ellipsoid have been calculated at least 20 different times with considerably different accuracies.

The early attempts at measuring the ellipsoid used small amounts of data and did not represent the true shape of the Earth. In 1880, the Clarke ellipsoid was adopted as a basis for its triangulation computations. The first geodetic datum adopted for the United States was based on the Clarke ellipsoid with its starting point in Kansas known as Meades Ranch

Name	Year	Semi-Major Axis (Equator Radius)	Semi-Minor Axis (Polar Radius)	Users
Clarke	1866	6,378,206.4 m	6,356,583.8 m	North America
International (Hayford) Ellipsoid	1924	6,378,388.0 m	6,356,911.9 m	Most of the World
WGS72	1972	6,378,135.0 m	6,356,750.5 m	NASA
GRS80	1980	6,378,137.0 m	6,356,752.3 m	Worldwide
WGS84	1984	6,378,137.0 m	6,356,752.3 m	Current Worldwide

One Datum with Many Versions and Abbreviations
NAD83 had undergone several updates since 1986. There are several versions of NAD83. For example, the National Geodetic Survey has adjusted the NAD83 datum for times since the original geodetic datum estimation in 1986.

• NAD83 (1986): This version was intended to be geocentric and used the GRS80 ellipsoid.
• NAD83 (1991, HARN, HPGN): High Accuracy Reference Network (HARN) and High Precision Geodetic Network reworked geodetic datums from 1986-1997
• NAD83 (CORS96): Continually Operating Reference Stations (CORS) are comprised of permanently operating Global Positioning System (GPS) receivers
• NAD83 (CSRS, CACS): Canadian Spatial Reference System and Canadian Active ontrol System with GPS processing.
• NAD83 (NSRS 2007, 2011): National Spatial Reference System and current survey standard using multi-year adjusted locations based on GNSS from the CORS.

The Importance of Datum Transformations

Surveyor (NOAA Photo Library)

The coordinates for benchmark datum points are typically different between geodetic datums. For example, the latitude and longitude location in a NAD27 datum differs from that same benchmark in NAD83 or WGS84. This difference is known as adatum shift.

Depending on where you are in North America, NAD27 and NAD83 may differ in tens of meters for horizontal accuracy. The average correction between NAD27 and NAD83 is an average of 0.349″ northward and 1.822″ eastward.

It’s important to note that the physical location has not changed. Most monuments have not moved. Datum shifts happen because survey measurements improve, there are more of them and methods of geodesy change. This results in more accurate geodetic datums over time. The horizontal datums that form the basis of coordinates of all horizontal positions in North America improve.

Because maps were created in different geodetic datums throughout history, datum transformations are often necessary when using historical data. For example, USGS topographic maps generally were published using a NAD27 datum. A datum transformation would be required when worrying with other NAD83 data.

NAD27 Shift to NAD83 (Image credit: NADCON – North American Datum Conversion Utility)
When are Datum Transformations Needed?

Datum Transformation

A coordinate transformation is the conversion from a non-projected coordinate system to a coordinate system. A coordinate transformation is done through a series of mathematical equations.

The geodetic datum is an integral part of projections. All coordinates are referenced to a datum. A datum describes the shape of the Earth in mathematical terms. A datum defines the radius, inverse flattening, semi-major axis and semi-minor axis for an ellipsoid. The North American datum of 1983, NAD 83, is United States horizontal or geometric datum. It provides latitude and longitude and some height information.

Unfortunately NAD 83 is not the only datum you’ll encounter. Before the current datum was defined, many maps were created using different starting points. And even today, people continue to change geodetic datums in an effort to make them more accurate. A common problem is when different coordinate locations are stored in different reference systems. When combining data from different users or eras, it is important to transform all information to common geodetic datums.

Projected coordinate systems are based on geographic coordinates, which are in turn referenced to a datum. For example, State Plane coordinate systems can be referenced to either NAD83 and NAD27 geodetic datums.

The NAD27 datum was based on the Clarke Ellipsoid of 1866:
Semi-major axis: 6,378,206.4 m
Semi-minor axis: 6,356,583.8 m
Inverse flattening: 294.98


The NAD83 datum was based on theGeodetic Reference System (GRS80) Ellipsoid:
Semi-major axis: 6,378,137.0 m
Semi-minor axis: 6,356,752.3 m
Inverse flattening: 298.26


When you transform NAD83 and NAD27 geographic coordinates to projected State Plane coordinates, it is the same projection method. However, because the geodetic datums were different, the resulting projected coordinates will also be different. In this case, a datum transformation is necessary.


For any type of work where it’s important for coordinates to be consistent with each other, it is critical that the same geodetic datum is used. If you are marking property or land boundaries or building roads or planning for coastal inundation scenarios, you must know about and use the correct geodetic datums.

Source: GIS Geography

What is a Horizontal Datum Reference Frame?

A horizontal datum is a collection of specific points on the Earth’s surface that have been accurately identified according to their precise northerly or southerly location (latitude) and easterly or westerly location (longitude).

To create the network of horizontal positions, surveyors marked each of the positions they had identified with a brass, bronze, or aluminum disk known as a survey benchmark. Because surveyors wanted to see one marked position from another, the benchmarks were usually placed on mountaintops or at high elevations. If they were on flat land, surveyors would have towers built to help locate them.

In order to create a horizontal datum, these monument locations were connected using mathematical techniques like triangulation. The result of triangulation from the unified network of survey monuments was North American Datum of 1927 (NAD 27) and later the more accurate NAD 83, which is still used today. NAD 27 and NAD 83 provide a frame of reference for latitude and longitude locations on Earth.

What is a Horizontal Datum?
A horizontal (geometric) datum (or reference frame) forms a basis for computations of horizontal positions on the Earth.

Real world objects are defined by coordinate systems. Various coordinate reference systems exist. In each coordinate system, geographic locations or features are described mathematically using coordinate values. A geographic coordinate system defines three-dimensional coordinates based on the Earth’s surface. It contains an angular unit of measure, prime meridian and datum (which contains the spheroid).

Longitudes:
X-coordinates are between -180 and +180, which are called longitudes.




Longitude Coordinates

Latitudes:

Y-values are between -90 and +90 degrees, which are called latitudes.




Latitude Coordinates
Most horizontal datums define a zero line at the equator. The equator is where we measure north and south.

The Greenwich Meridian (or prime meridian) is a zero line of longitude from which we measure east and west. The zero line passes through the Royal Observatory in Greenwich, England – which is how it earned its name. In a geographical coordinate system, it is a line of longitude defined to be 0°.

Together, these lines provide a reference for latitude and longitude. This system is also known as a geographic grid

.

A datum describes the shape of the Earth. In mathematical terms, it defines the radius, major and minor axis and flattening for an ellipsoid. Datums are used in projections, monitoring the Earth’s crust, survey boundary delineation and more.

All coordinates are referenced to a datum – including the one you are standing on right now.


Locate ANYTHING on Earth with Coordinates
Coordinates are pairs (X, Y) or triplets (X, Y, Z) of values that are used to represent points and features on a two and three-dimensional space. The X-value represents the horizontal position and Y-value represents the vertical position. The Z-value generally refers to the elevation at that point location.


Latitude / Longitude Geographic Coordinate System

Geographic coordinate systems (latitudes and longitudes) are based on a spheroid surface. Spheroids are approximate locations on the surface of the earth. The datum defines the surface. The major axis (longest diameter of an ellipse) and minor axis (shortest diameter of an ellipse) and radius represent the position of the surface relative to the center of the earth.

What is a Coordinate Reference System?
Reference ellipsoids are mathematical models of the shape of the Earth with the major axis along the equatorial radius. A geographic coordinate system uses longitude and latitude expressed in decimal degrees. WGS 1984 and NAD 1983 are examples of datums.

Coordinates are pairs (X, Y) or triplets (X, Y, Z) of values that are used to represent points and features on a two and three-dimensional space.



Spherical coordinates (latitudes and longitudes) are often written as degrees-minutes-seconds (DMS). Minutes range from 0 to 60. For example, the geographic coordinate expressed in degrees-minutes-seconds for New York City is:

• Latitude: 40 degrees, 42 minutes, 51 seconds N
• Longitude: 74 degrees, 0 minutes, 21 seconds W

Geographic coordinate can also be expressed in decimal degrees. Here is New York City in decimal degrees:

• Latitude: 40.714
• Longitude: -74.006

What is an Ellipsoid in GIS?
Reference ellipsoids are mathematical models of the shape of the Earth with the shape of flattened sphere. The major axis of an ellipse is the equatorial radius. The minor axis is from the poles to the center. Reference ellipsoids are primarily used as a surface to specify point coordinates such as latitudes (north/south), longitudes (east/west) and elevations (height).

The most common reference ellipsoid in cartography and surveying is the World Geodetic System WGS 84. The Clarke Ellipsoid of 1866 and was recomputed in 1927 as NAD27. When comparing NAD27 and NAD84, latitude and longitude coordinates can be displaced on the degree of tens of meters (with the same latitude and longitude coordinates).


Reference Ellipsoid / Spheroid


How Do Horizontal Datums Relate to Ellipsoids?
Horizontal datums give us the capability to measure distances and directions across the surface of the earth. Most horizontal datums define a zero line at the equator from which we measure north and south (latitudes). There is also a zero line at the Greenwich Meridian from which we measure east and west (longitudes). Together these lines provide a reference for latitude and longitude expressed in decimal degrees. These latitudes and longitude positions (Geographic Coordinate Systems) are based on a spheroid or ellipsoid surfaces that approximate the surface of the earth – a datum.

All coordinates are referenced to a datum. A datum describes the shape of the Earth in mathematical terms. A datum defines the radius, inverse flattening, semi-major axis and semi-minor axis for an ellipsoid. Here is the WGS84 datum:

Semi-major axis: 6,378,137.0 m
Semi-minor axis: 6,356,752.3 m
Inverse flattening: 294.978698214




Earth is Flattened Because of Rotational Forces

Sir Isaac Newton and others proposed that the Earth flattens at the poles because of rotational forces. As the Earth spins on its axis, the centrifugal force causes the Earth to bulge out at the equator. This is why the Earth is better modeled as an ellipsoid, which is a sphere slightly flattened at the poles.

In the 19th and 20th centuries, different ellipsoids were adopted in various parts of the world. Surveys were being performed on different continents. Each survey produced different ellipsoidal parameters. For example, surveys in Australia yielded a “best” ellipsoid. Europe’s “best” ellipsoid was different South America and Asia. There wasn’t a unifying global ellipsoid. Each continental survey was isolated with it’s own ellipsoid parameters. There was no clear way how to combine these global survey measurements. There was a scarcity of survey points in specific areas and a lack of computational resources that prevented a global ellipsoid.


Earth Bulging at Equator


How Are Horizontal Datums Created?
Over the past two centuries, surveyors have measured extremely precise latitude and longitude locations on the Earth’s surface. These locations are called benchmarks and are identified with a brass or aluminum disk in the ground. Networks of benchmarks have been placed in higher altitude locations so they can be viewed from one-another.



In order to create a horizontal datum, several methods have been established to connect these benchmark locations. First-order triangulation was used to connect horizontal monuments into a unified network with the end result being North American Datum of 1927 (NAD27). But the network of points in 1927 was sparse in comparison.

The Elements of Geodesy: The Horizontal Datum. National Oceanic and Atmospheric Administration

In 1983, NAD83 replaced NAD27 because of its inaccuracies. According to NOAA, the geographic coordinates given relative to the NAD 27 datum might represent a position hundreds of meters different than those same coordinates given relative to the NAD 83 datum. The average correction between NAD27 and NAD84 is an average of 0.349″ northward an 1.822″ eastward.


NAD27 Shift to NAD83 (Image credit: NADCON – North American Datum Conversion Utility)

NAD27, NAD83 and WGS84 Are Commonly Datums in North America
In order to create a horizontal datum, monument locations were connected using mathematical techniques like triangulation. The result of triangulation from the unified network of survey monuments was North American Datum of 1927 (NAD 27) and later the more accurate NAD 83, which is still used today. NAD 27 and NAD 83 provide a frame of reference for latitude and longitude locations on Earth.


Meades Ranch Triangulation Station, fundamental station for the North American Datum of 1927


The North American datum of 1983 (NAD 83)is the most current datum being used in North America. It provides latitude and longitude and some height information. Several datums have existed over the years. Many maps were created using different datums and starting points in the past. For example, the North American datum of 1927 used Kansas as a starting point. Horizontal datums are continuously being improved even today.

Surveyors now rely almost exclusively on the Global Positioning System (GPS) to identify locations on the Earth and incorporate them into existing datums.

The North American Datum of 1927 (NAD27) is one of the main three horizontal datums used in North America. NAD27 uses the Clarke Ellipsoid of 1866 with a fixed latitude and longitude at Meade’s Ranch, Kansas (39° 13’26.686″ north latitude, 98° 32’30.506″ west longitude). This means that all points in North America used this fixed point as a reference measuring direction and distance away. All latitudes and longitudes could be measured on the Clarke Ellipsoid of 1866.

The North American Datum of 1983 (NAD 83) is a unified horizontal or geometric datum and successor to NAD27 providing a spatial reference for Canada and the United States. NAD83 corrects some of the distortions from NAD27 over distance by using a more sense set of positions from terrestrial and Doppler satellite data. NAD83 is a geocentric datum (referenced to the center of Earth’s mass) offset by about 2 meters.

The World Geodetic System (WGS84) is the reference coordinate system used by the Global Positioning System. It comprises of a reference ellipsoid, a standard coordinate system, altitude data and a geoid. Similar to NAD 83, it uses the Earth’s center mass as the coordinate origin. The error is believed to be less than 2 centimeters.

Fitting the Ellipsoid with the Geoid

Geoid (Image courtesy of NASA/JPL)
A horizontal coordinate system gives us the side-by-side that is our latitude and longitude. A vertical datum is another component of your typical horizontal coordinate system. We are on a three-dimensional planet which has ups-and-downs in addition to the side-to-side in a horizontal coordinate system on the surface. To handle the ups-and-downs, we have the vertical datum which gives a place to put the zero measurement. Mean sea level is often understood as the basis for our ups-and-downs. This is called the geoid.

Vertical datums are lumpy and irregular. This is because of the varying densities in the Earth in different places. There are gravity anomalies. Mean sea level is not a smooth thing that everyone likes to think it is. Geoids are not constant and they differ from place-to-place. Geoids have undulations as you move around on the Earth. The Earth is not as round as we like to pretend it is. We have lumps or undulations on them as they come back to us in the form of a geoid. The geoids put the lumps back into our nice smooth horizontal datum coordinate system.

Ellipsoid Height is the most basic version of up-and-down. The ellipsoid uses the size and shape of the horizontal datum such as WGS84. It gives a smooth surface without bumps or irregularities. The geoid is complex to describe it mathematically. Therefore, we fit different Ellipsoids to approximate it such as WGS84.

Flatten the Sphere with Map Projections

A projection on a map is basically the method by which the mapmaker translates a sphere or a globe into a two-dimensional representation. Projected coordinate systems converts the spheroid-based coordinates to a flat plane.

Imagine peeling an orange and flattening it on a two-dimensional surface. Universal Transverse Mercator coordinate system is an example of a map projection that divides the Earth into sixty zones. Each zone flattens the spheroid surface to a flat plane.

There are multiple ways to represent a sphere on a two-dimensional surface. Every projection has a strength and a weakness. It is up to the map maker to determine what projection it most favorable for its purpose.

The Mercator projection distortions and are so that it is no longer used in Atlases. For most of us, the projection is common enough that it looks fine for us. But if you take a closer look, Greenland is presented as having roughly as much land area as Africa. However, Africa (11.67 million square kilometers) is roughly 14 times larger than Greenland (2.16 million square kilometers)

Conclusion
Coordinates reference systems, geoids, latitudes and longitudes, projections, datums, ellipsoids…

Every GIS analyst needs a good base understanding of what they are and how it relates to location.

Because you can’t just put anything on a map without understanding its horizontal reference system.

Source: GIS Geography

What’s the difference between a gulf and a bay? Geography terms explained on map from 1870.

By Aleks Buczkowski



Geographic terms can be a little bit confusing. What’s the difference between a cape and a peninsula or a gulf and a bay? Are channel, strait, passage and sound the same thing? Defining these and other terms can be difficult event using a dictionary.

A map called “Bancrofts’ pictorial chart of geographical definition” from around 1870 found at the David Rumsey Collection is illustrating these terms with a text description. This pictorial map is showing typical topographic features like cities, villages, mountains, seas, islands etc. in a great level of detail. It’s truly amazing.

Source

Geography & Journalism : “40 Maps that explain our world”

By Muthukumar Kumar

Maps were perhaps the first drawings that humans drew on the sands of time but it is amazing to notice that maps still hold a very special place in our digital world as well. Maps for representing billionaires on the planet, Maps for showing the internet network, Maps here and Maps there! It is amazing to see the recent trend of representation almost all information in the form of a Map!

The Internet is full of these “fun to look and discuss” maps and we at Geoawesomeness covered some of these interesting and “sometimes” controversial maps that were making waves on the Internet like the “Stereotype Map“, “Emotions Map” and so on. A Staff at the WashingtonPostdecided to something more than that, he made a list of 40 Maps that explain our world. Surely the journalists’ these days love the concept of maps! If this trend continues, a degree in cartography could help you get a job at the media.

Guessing what these “40 Maps” could be about? Well, I’ll let you experience the list firsthand and would be interesting to hear what your favourite map was and if you agree with the list? Whether you agree with the information in the map is a different story altogether, I don’t agree with some of the representation the maps are depicting. Oops Spoiler Alert! Let me hold my thoughts right there!

Here’s my favourite map in the list – “Writing systems map of the world”. There is something amazing about this map! If you consider the population of the world and this map together, it is amazing to see that the most diverse place on the planet happens to be the most populous part of this little blue ball that is circling the sun! Coincidence or a little bit more than that, could be an interesting piece of research!

It’s such a diverse world out there!

What do you think? Let us know! Here’s the link to the article . 40 Maps that explain our world: bringing together geography & journalism!

Source: Washingtonpost

Geography of Jobs in the United States

BY ELIZABETH BORNEMAN




Where Are the Jobs? is an interactive map of the number of jobs in the US using 2010 data from the Census Bureau’s Longitudinal Employer-Household Dynamics study (LEHD). The map divides job types into various categories including manufacturing and trade, professional services, healthcare, education and government, and retail, hospitality and other services. Each dot in the graph represents a job recorded through state unemployment insurance and federal jobs.

Each job type is color coded to show where certain jobs are clustered in various parts of the United States. The geographical job map covers approximately 96% of jobs in the United States. The graphic was created by a Harvard PhD student named Robert Manduca and was inspired by a racial dot map that showed ethnic diversity across the United States. Since jobs can be more concentrated than populations of people the map is useful for determining where the highest concentration of jobs is in cities across the country.

MAP OF JOBS ACROSS THE US. EACH DOT REPRESENTS ONE JOB. COLORS: RED = MANUFACTURING AND TRADE, BLUE = PROFESSIONAL SERVICES, GREEN = HEALTHCARE, EDUCATION, AND GOVERNMENT, YELLOW = RETAIL, HOSPITALITY, AND OTHER SERVICES.

The map can be used to chart demographic information from census data to show where higher-income individuals live in relation to where their jobs are. This can be laid over a map of the more extensive parts of a city as well. For example, in New York City the map shows a high concentration of individuals who have high incomes living in expensive parts of town, like Manhattan. Lower paid jobs exist in areas like Brooklyn which is home to a lot of industry; Queens, meanwhile, is a diverse location as far as residents and jobs go.

MAP OF JOBS IN THE NEW YORK CITY AREA. EACH DOT REPRESENTS ONE JOB. COLORS: RED = MANUFACTURING AND TRADE, BLUE = PROFESSIONAL SERVICES, GREEN = HEALTHCARE, EDUCATION, AND GOVERNMENT, YELLOW = RETAIL, HOSPITALITY, AND OTHER SERVICES.

Areas in Northern California have a high concentration of electronic and technology related jobs while manufacturing and industrial labor employment opportunities are decreasing more and more each year. Employment is highly concentrated is downtown city centers but, as the job map reveals, most jobs still exist outside of major cities. Certain suburban areas also reveal high concentrations of employment which is normal. Industrial centers, shopping malls and business parks can employ many people in a variety of sectors.

The map has some gaps as places like Puerto Rico and the U.S. Virgin Islands aren’t covered. Additionally, Massachusetts data is also missing because that state hasn’t integrated its data into LEHD’s system. The data isn’t entirely inclusive; for instance, the four categories of job types exclude jobs that don’t fit those labels. Additionally, some federal jobs aren’t included because of security reasons and thus data in governmental centers like Washington, D.C. appear quite empty on the map. Overall, the map includes about 96% of civilian wage and salary jobs, per the estimate provided by the US Bureau of Labor Statistics.

The importance of job map can be used to chart the rise and fall of employment in the United States. Understanding where jobs are, where they’ve been and where they are moving to is as important as brushing up a resume or writing a new cover letter. How we can quantify the jobs that exist in the United States today can potentially help us understand recessions, job movement, and where opportunities are for a variety of job sectors.

References

Where Are the Jobs? Employment in America, 2010

Mapping Every Single Job in the U.S. (2015, July 14). The Atlantic’s City Lab.

Source

The ArcGIS Book: 10 Big Ideas about Applying Geography to Your World

Learn to Make GIS Web Maps, Work with Mobile Apps, and Do More, Using The ArcGIS Book from Esri

People around the world are discovering that online maps do more than direct consumers to stores or help travelers navigate from point A to point B. Web maps communicate important information that helps everyone make decisions. That's why Esri has published The ArcGIS Book: 10 Big Ideas about Applying Geography to Your World, an easy-to-comprehend guide to 10 big web mapping ideas and how to use the ArcGIS platform, Esri's geographic information system (GIS) technology, to put those ideas into action.

ArcGIS is a complete system for discovering, creating, consuming, and sharing geographic data, maps, and apps that fully operates on the web and mobile devices. "At Esri, we recognize that the web, cloud computing, smartphones, and tablets have forever transformed how GIS technology is applied," said Clint Brown, director of product engineering at Esri. "In response, ArcGIS has become a web GIS platform. We wanted to publish a book that not only describes how these trends have transformed GIS but also teaches people how to use the system."

Among the 10 big ideas covered in The ArcGIS Book are the online mapping revolution and its role in GIS; storytelling with maps; mapping in 3D; the social implications of web GIS; the power of spatially intelligent apps; and the emergence of mobile GIS on smartphones with, as the book says, "a live data sensor in your pocket."

In an interesting way and with interactive components, the book takes readers on a journey on how to create and share GIS web maps, use new smart mapping capabilities in ArcGIS to make beautiful and well-designed maps, do spatial analysis online, make 3D web scenes, work with mobile GIS, and do much more.

Each chapter also includes an ArcGIS Lesson that readers can access online. They can put what they learn to work using Esri-provided data and ArcGIS and get hands-on experience in all aspects of web GIS, including crafting a Story Map, solving problems with spatial analysis, editing geographic data, and building a 3D model. The book also inspires the enthusiastic and visionary mapper, providing links to hundreds of live examples of web maps and apps and videos of thought leaders describing some of the trends driving the industry.

TheArcGISBook.com hosts the Learn ArcGIS lessons and other supporting materials. "There is no better way to learn than by doing," Brown said.

Interspersed throughout The ArcGIS Book are short essays by thought leaders such as Esri president Jack Dangermond and Allen Carroll, program manager, storytelling for Esri, and the former chief cartographer at National Geographic.

The ArcGIS Book was written for a diverse audience, including GIS professionals just venturing into the new world of web GIS as well as web technologists, information workers, web designers, and others who increasingly recognize how maps play a pivotal role today in clearly communicating information. The book also serves as a perfect introduction to web GIS for managers and executives interested in understanding how maps can help them make sound business decisions for their organizations.

The ArcGIS Book was edited by Christian Harder, a writer at Esri and the author of several books about GIS including Understanding GIS: An ArcGIS Project Workbook, Second Edition, published in 2013 by Esri Press.

The ArcGIS Book is available in print (ISBN: 9781589484498, 152 pages, US$19.99), as a free downloadable PDF, and on an interactive website at TheArcGISBook.com. The book is available at online retailers worldwide, at esri.com/esripress, or by calling 1-800-447-9778. Outside the United States, visit esri.com/esripressorders for complete ordering options, or visit esri.com/distributors to contact your local Esri distributor. Interested retailers can contact Esri Press book distributor Ingram Publisher Services.

About Esri Press Esri Press publishes books on GIS, cartography, and related topics. The complete selection of GIS titles from Esri Press can be found on the web at esri.com/esripress.

About Esri Since 1969, Esri has been giving customers around the world the power to think and plan geographically. The market leader in GIS, Esri software is used in more than 350,000 organizations worldwide including each of the 200 largest cities in the United States, most national governments, more than two-thirds of Fortune 500 companies, and more than 7,000 colleges and universities. Esri applications, running on more than one million desktops and thousands of Web and enterprise servers, provide the backbone for the world's mapping and spatial analysis. Esri is the only vendor that provides complete technical solutions for desktop, mobile, server, and Internet platforms. Visit us at www.esri.com.

Esri, the Esri globe logo, GIS by Esri, ArcGIS, www.esri.com, and @esri.com are trademarks, registered trademarks, or service marks of Esri in the United States, the European Community, or certain other jurisdictions. Other companies and products mentioned herein may be trademarks or registered trademarks of their respective trademark owners.

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Carla Wheeler, Esri
Tel.: 909-793-2853, extension 1-2448
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