ArcGIS for Desktop

  • Documentation
  • Pricing
  • Support

  • My Profile
  • Help
  • Sign Out
ArcGIS for Desktop

ArcGIS Online

The mapping platform for your organization

ArcGIS for Desktop

A complete professional GIS

ArcGIS for Server

GIS in your enterprise

ArcGIS for Developers

Tools to build location-aware apps

ArcGIS Solutions

Free template maps and apps for your industry

ArcGIS Marketplace

Get apps and data for your organization

  • Documentation
  • Pricing
  • Support
Esri
  • Sign In
user
  • My Profile
  • Sign Out

Help

  • Home
  • Get Started
  • Map
  • Analyze
  • Manage Data
  • Tools
  • More...

State Plane Coordinate System

  • Description
  • Projection method
  • Why use State Plane?
  • What is State Plane?
  • State Plane and the North American Datum
  • Unit of length
  • Examples of zone definitions
  • Uses and applications
  • Parameters

Description

State Plane Coordinate System (SPCS) is not a projection (also known as SPC, State Plane, and State). It is a coordinate system that divides the 50 states of the United States, Puerto Rico, and the U.S. Virgin Islands into more than 120 numbered sections, referred to as zones. Each zone has an assigned code number that defines the projection parameters for the region.

Projection method

Projection can be cylindrical or conic.

  • Learn about Lambert conformal conic methodology and properties
  • Learn about Transverse Mercator methodology and properties
  • Learn about the Hotine Oblique Mercator methodology and properties

Why use State Plane?

Government organizations and groups who work with them primarily use the State Plane Coordinate System. Most often, these are county or municipal databases. The advantage of using SPCS is that your data is in a common coordinate system with other databases covering the same area.

What is State Plane?

The State Plane Coordinate System was designed for large-scale mapping in the United States. It was developed in the 1930s by the U.S. Coast and Geodetic Survey to provide a common reference system to surveyors and mappers. The goal was to design a conformal mapping system for the country with a maximum scale distortion of one part in 10,000, then consider the limit of surveying accuracy.

Three conformal projections were chosen: the Lambert conformal conic for states that are longer east–west, such as Tennessee and Kentucky; the Transverse Mercator projection for states that are longer north–south, such as Illinois and Vermont; and the Hotine Oblique Mercator projection for the panhandle of Alaska, because it lays at an angle.

  • Learn more about the Lambert conformal conic projection
  • Learn more about the Transverse Mercator projection
  • Learn more about the Hotine Oblique Mercator projection

To maintain an accuracy of one part in 10,000, it was necessary to divide many states into zones. Each zone has its own central meridian or standard parallels to maintain the desired level of accuracy. The boundaries of these zones follow county boundaries. Smaller states, such as Connecticut, require only one zone, while Alaska is composed of 10 zones and uses all three projections.

This coordinate system is referred to here as the State Plane Coordinate System of 1927 (SPCS 27). It is based on a network of geodetic control points referred to as the North American Datum of 1927 (NAD 1927 or NAD27).

State Plane and the North American Datum

Technological advancements of the last 50 years have led to improvements in the measurement of distances, angles, and the earth's size and shape. This, combined with moving the origin of the datum from Meades Ranch in Kansas to the earth's center of mass for compatibility with satellite systems, made it necessary to redefine SPCS 27. The redefined and updated system is called the State Plane Coordinate System of 1983 (SPCS 83). The coordinates for points are different for SPCS 27 and SPCS 83. There are several reasons for this. For SPCS 83, all State Plane coordinates published by NGS are in metric units, the shape of the spheroid of the earth is slightly different, some states have changed the definition of their zones, and values of longitude and latitude are slightly changed.

Officially, SPCS zones are identified by their NGS code. When Esri implemented the NGS codes, they were part of a proposed Federal Information Processing Standard (FIPS). For that reason, Esri identifies the NGS zones as FIPS zones. That proposed standard was withdrawn, but Esri maintains the FIPS name for continuity.

Sometimes people use an older Bureau of Land Management (BLM) system. The BLM system is outdated and doesn't include codes for some of the new zones. The values also overlap. You should always use the NGS/FIPS codes.

The following zone changes were made from SPCS 27 to SPCS 83. The zone numbers listed below are FIPS zone numbers. In addition, false easting and northing, or origin, of most zones has changed.

  • California—California zone 7, SPCS 27 FIPS zone 0407, was eliminated and included in California zone 5, SPCS 83 FIPS zone 0405.
  • Montana—The three zones for Montana, SPCS 27 FIPS zones 2501, 2502, and 2503, were eliminated and replaced by a single zone, SPCS 83 FIPS zone 2500.
  • Nebraska—The two zones for Nebraska, SPCS 27 FIPS zones 2601 and 2602, were eliminated and replaced by a single zone, SPCS 83 FIPS zone 2600.
  • South Carolina—The two zones for South Carolina, SPCS 27 FIPS zones 3901 and 3902, were eliminated and replaced by a single zone, SPCS 83 FIPS zone 3900.
  • Puerto Rico and Virgin Islands—The two zones for Puerto Rico and the Virgin Islands, St. Thomas, St. John, and St. Croix, SPCS 27 FIPS zones 5201 and 5202, were eliminated and replaced by a single zone, SPCS 83 FIPS zone 5200.

Unit of length

The standard unit of measure for SPCS 27 is the U.S. survey foot. For SPCS 83, the most common unit of measure is the meter. There are two standard used in the U.S. to convert between feet and meters. Those states that support both feet and meters have legislated which feet-to-meters conversion they use. The difference between the two is only two parts in one million, but that can become noticeable when datasets are stored in double precision. The U.S. survey foot equals 1,200/3,937 m, or 0.3048006096 m. The international foot is 0.3048 meters.

Examples of zone definitions

Here are two examples of SPCS 83 parameters:

State

Alabama East

Tennessee

ZONE

3101

5301

FIPS Zone

0101

4100

Projection

Transverse Mercator

Lambert conformal conic

Standard Parallels

35°15' 36°25'

Central Meridian

-85°50'

-86°00'

Scale Factor Reduction at Central Meridian

1:25,000

1:15,000

Latitude of Origin

30°30'

34°20'

Longitude of Origin

-85°50'

-86°00'

False Easting

200,000

600,000

False Northing

0

0

Example SPCS 83 parameters

Uses and applications

Used for standard USGS 7½ and 15 minute quad sheets.

Used for most federal, state, and local large-scale mapping projects in the United States.

Parameters

Workstation

  • Use the ZONE or FIPSZONE subcommands to specify the State Plane zone.

Related Topics

  • Hotine Oblique Mercator
  • Lambert Conformal Conic
  • Transverse Mercator
  • List of supported map projections
Feedback on this topic?

ArcGIS for Desktop

  • Home
  • Documentation
  • Pricing
  • Support

ArcGIS Platform

  • ArcGIS Online
  • ArcGIS for Desktop
  • ArcGIS for Server
  • ArcGIS for Developers
  • ArcGIS Solutions
  • ArcGIS Marketplace

About Esri

  • About Us
  • Careers
  • Insiders Blog
  • User Conference
  • Developer Summit
Esri
© Copyright 2016 Environmental Systems Research Institute, Inc. | Privacy | Legal