Equidistant Cylindrical (Plate Carrée)

The simplest of all projections. Standard parallels (0° when omitted) may be specified that determine latitude of true scale (k=h=1).


Conformal cylindrical

Available forms

Forward and inverse

Defined area

Global, but best used near the equator

Implemented by

Gerald I. Evenden



Latitude of true scale. Defaults to 0.0


Center of the map : latitude of origin

Equidistant Cylindrical (Plate Carrée)


Because of the distortions introduced by this projection, it has little use in navigation or cadastral mapping and finds its main use in thematic mapping. In particular, the plate carrée has become a standard for global raster datasets, such as Celestia and NASA World Wind, because of the particularly simple relationship between the position of an image pixel on the map and its corresponding geographic location on Earth.

The following table gives special cases of the cylindrical equidistant projection.

Projection Name

(lat ts=) \(\phi_0\)

Plain/Plane Chart

Simple Cylindrical

Plate Carrée

Ronald Miller—minimum overall scale distortion


E.Grafarend and A.Niermann


Ronald Miller—minimum continental scale distortion


Gall Isographic


Ronald Miller Equirectangular


E.Grafarend and A.Niermann minimum linear distortion


Example using EPSG 32662 (WGS84 Plate Carrée):

$ echo 2 47 | proj +proj=eqc +lat_ts=0 +lat_0=0 +lon_0=0 +x_0=0 +y_0=0 +ellps=WGS84 +datum=WGS84 +units=m +no_defs
222638.98       5232016.07

Example using Plate Carrée projection with true scale at latitude 30° and central meridian 90°W:

$ echo -88 30 | proj +proj=eqc +lat_ts=30 +lat_0=90w
-8483684.61     13358338.90

Mathematical definition

The formulas describing the Equidistant Cylindrical projection are all taken from Snyder’s [Snyder1987].

\(\phi_{ts}\) is the latitude of true scale, that mean the standard parallels where the scale of the projection is true. It can be set with +lat_ts.

\(\phi_0\) is the latitude of origin that match the center of the map. It can be set with +lat_0.

Forward projection

\[x = \lambda \cos \phi_{ts}\]
\[y = \phi - \phi_0\]

Inverse projection

\[\lambda = x / cos \phi_{ts}\]
\[\phi = y + \phi_0\]

Further reading

  1. Wikipedia

  2. Wolfram Mathworld