OpenLayers
OpenLayers
Certain questions arise more often than others when users ask for help. This document tries to list some of the common questions that frequently get asked, e.g. on Stack Overflow.
If you think a question (and naturally its answer) should be added here, feel free to ping us or to send a pull request enhancing this document.
Table of contents:
Every map that you'll create with OpenLayers will have a view, and every view will have a projection. As the earth is three-dimensional and round but the 2D view of a map isn't, we need a mathematical expression to represent it. Enter projections.
There isn't only one projection, but there are many common ones. Each projection has different properties, in that it accurately represents distances, angles or areas. Certain projections are better suited for different regions in the world.
Back to the original question: OpenLayers is capable of dealing with most projections. If you do not explicitly set one, your map is going to use our default which is the Web Mercator projection (EPSG:3857). The same projection is used e.g. for the maps of the OpenStreetMap-project and commercial products such as Bing Maps or Google Maps.
This projection is a good choice if you want a map which shows the whole world, and you may need to have this projection if you want to e.g. use the OpenStreetMap or Bing tiles.
There is a good chance that you want to change the default projection of OpenLayers to something more appropriate for your region or your specific data.
The projection of your map can be set through the view-property. Here are some
examples:
import Map from 'ol/Map.js';
import View from 'ol/View.js';
// OpenLayers comes with support for the World Geodetic System 1984, EPSG:4326:
const map = new Map({
view: new View({
projection: 'EPSG:4326'
// other view properties like map center etc.
})
// other properties for your map like layers etc.
});
import Map from 'ol/Map.js';
import View from 'ol/View.js';
import proj4 from 'proj4';
import {register} from 'ol/proj/proj4.js';
import {get as getProjection} from 'ol/proj.js';
// To use other projections, you have to register the projection in OpenLayers.
// This can easily be done with [http://proj4js.org/](proj4)
//
// By default OpenLayers does not know about the EPSG:21781 (Swiss) projection.
// So we create a projection instance for EPSG:21781 and pass it to
// register to make it available to the library for lookup by its
// code.
proj4.defs('EPSG:21781',
'+proj=somerc +lat_0=46.95240555555556 +lon_0=7.439583333333333 +k_0=1 ' +
'+x_0=600000 +y_0=200000 +ellps=bessel ' +
'+towgs84=660.077,13.551,369.344,2.484,1.783,2.939,5.66 +units=m +no_defs');
register(proj4);
const swissProjection = getProjection('EPSG:21781');
// we can now use the projection:
const map = new Map({
view: new View({
projection: swissProjection
// other view properties like map center etc.
})
// other properties for your map like layers etc.
});
We recommend to lookup parameters of your projection (like the validity extent) over at epsg.io.
If you have set a center in your map view, but don't see a real change in visual output, chances are that you have provided the coordinates of the map center in the wrong (a non-matching) projection.
As the default projection in OpenLayers is Web Mercator (see above), the coordinates for the center have to be provided in that projection. Chances are that your map looks like this:
import Map from 'ol/Map.js';
import View from 'ol/View.js';
import TileLayer from 'ol/layer/Tile.js';
import OSM from 'ol/source/OSM.js';
const washingtonLonLat = [-77.036667, 38.895];
const map = new Map({
layers: [
new TileLayer({
source: new OSM()
})
],
target: 'map',
view: new View({
center: washingtonLonLat,
zoom: 12
})
});
Here [-77.036667, 38.895] is provided as the center of the view. But as Web
Mercator is a metric projection, you are currently telling OpenLayers that the
center shall be some meters (~77m and ~39m respectively) away from [0, 0]. In
the Web Mercator projection the coordinate is right in the gulf of guinea.
The solution is easy: Provide the coordinates projected into Web Mercator. OpenLayers has some helpful utility methods to assist you:
import Map from 'ol/Map.js';
import View from 'ol/View.js';
import TileLayer from 'ol/layer/Tile.js';
import OSM from 'ol/source/OSM.js';
import {fromLonLat} from 'ol/proj.js';
const washingtonLonLat = [-77.036667, 38.895];
const washingtonWebMercator = fromLonLat(washingtonLonLat);
const map = new Map({
layers: [
new TileLayer({
source: new OSM()
})
],
target: 'map',
view: new View({
center: washingtonWebMercator,
zoom: 8
})
});
The method fromLonLat() is available from version 3.5 onwards.
If you told OpenLayers about a custom projection (see above), you can use the following method to transform a coordinate from WGS84 to your projection:
import {transform} from 'ol/proj.js';
// assuming that OpenLayers knows about EPSG:21781, see above
const swissCoord = transform([8.23, 46.86], 'EPSG:4326', 'EPSG:21781');
Because of two different and incompatible conventions. Latitude and longitude
are normally given in that order. Maps are 2D representations/projections
of the earth's surface, with coordinates expressed in the x,y grid of the
Cartesian system.
As they are by convention drawn with west on the left and north at the top,
this means that x represents longitude, and y latitude. As stated above,
OpenLayers is designed to handle all projections, but the default view is in
projected Cartesian coordinates. It would make no sense to have duplicate
functions to handle coordinates in both the Cartesian x,y and lat,lon
systems, so the degrees of latitude and longitude should be entered as though
they were Cartesian, in other words, they are lon,lat.
If you have difficulty remembering which way round it is, use the language code
for English, en, as a mnemonic: East before North.
So you want to center your map on a certain place on the earth and obviously you need to have its coordinates for this. Let's assume you want your map centered on Schladming, a beautiful place in Austria. Head over to the wikipedia page for Schladming. In the top-right corner there is a link to GeoHack, which effectively tells you the coordinates are:
WGS84:
47° 23′ 39″ N, 13° 41′ 21″ E
47.394167, 13.689167
So the next step would be to put the decimal coordinates into an array and use it as center:
import Map from 'ol/Map.js';
import View from 'ol/View.js';
import TileLayer from 'ol/layer/Tile.js';
import OSM from 'ol/source/OSM.js';
import {fromLonLat} from 'ol/proj.js';
const schladming = [47.394167, 13.689167]; // caution partner, read on...
// since we are using OSM, we have to transform the coordinates...
const schladmingWebMercator = fromLonLat(schladming);
const map = new Map({
layers: [
new TileLayer({
source: new OSM()
})
],
target: 'map',
view: new View({
center: schladmingWebMercator,
zoom: 9
})
});
Running the above example will possibly surprise you, since we are not centered on Schladming, Austria, but instead on Abyan, a region in Yemen (possibly also a nice place). So what happened?
Many people mix up the order of longitude and latitude in a coordinate array. Don't worry if you get it wrong at first, many OpenLayers developers have to think twice about whether to put the longitude or the latitude first when they e.g. try to change the map center.
Ok, then let's flip the coordinates:
import Map from 'ol/Map.js';
import View from 'ol/View.js';
import TileLayer from 'ol/layer/Tile.js';
import OSM from 'ol/source/OSM.js';
import {fromLonLat} from 'ol/proj.js';
const schladming = [13.689167, 47.394167]; // longitude first, then latitude
// since we are using OSM, we have to transform the coordinates...
const schladmingWebMercator = fromLonLat(schladming);
const map = new Map({
layers: [
new TileLayer({
source: new OSM()
})
],
target: 'map',
view: new View({
center: schladmingWebMercator,
zoom: 9
})
});
Schladming is now correctly displayed in the center of the map.
So when you deal with EPSG:4326 coordinates in OpenLayers, put the longitude first, and then the latitude. This behaviour is the same as we had in OpenLayers 2, and it actually makes sense because of the natural axis order in WGS84.
If you cannot remember the correct order, just have a look at the method name
we used: fromLonLat; even there we hint that we expect longitude
first, and then latitude.
Suppose you want to load a KML file and display the contained features on the map. Code like the following could be used:
import VectorLayer from 'ol/layer/Vector.js';
import KMLSource from 'ol/source/KML.js';
const vector = new VectorLayer({
source: new KMLSource({
projection: 'EPSG:3857',
url: 'data/kml/2012-02-10.kml'
})
});
You may ask yourself how many features are in that KML, and try something like the following:
import VectorLayer from 'ol/layer/Vector.js';
import KMLSource from 'ol/source/KML.js';
const vector = new VectorLayer({
source: new KMLSource({
projection: 'EPSG:3857',
url: 'data/kml/2012-02-10.kml'
})
});
const numFeatures = vector.getSource().getFeatures().length;
console.log("Count right after construction: " + numFeatures);
This will log a count of 0 features to be in the source. This is because the
loading of the KML-file will happen in an asynchronous manner. To get the count
as soon as possible (right after the file has been fetched and the source has
been populated with features), you should use an event listener function on the
source:
vector.getSource().on('change', function(evt){
const source = evt.target;
if (source.getState() === 'ready') {
const numFeatures = source.getFeatures().length;
console.log("Count after change: " + numFeatures);
}
});
This will correctly report the number of features, 1119 in that particular
case.
Usually the map is automatically re-rendered, once a source changes (for example when a remote source has loaded).
If you actually want to manually trigger a rendering, you could use
map.render();
...or its companion method
map.renderSync();
You are using Map#forEachFeatureAtPixel or Map#hasFeatureAtPixel, but
it sometimes does not work for large icons or labels? The hit detection only
checks features that are within a certain distance of the given position. For large
icons, the actual geometry of a feature might be too far away and is not considered.
In this case, set the renderBuffer property of VectorLayer (the default value is 100px):
import VectorLayer from 'ol/layer/Vector.js';
const vectorLayer = new VectorLayer({
...
renderBuffer: 200
});
The recommended value is the size of the largest symbol, line width or label.
OpenLayers does not update the map when the container element is resized. This can be caused by progressive updates to CSS styles or manually resizing the map. When that happens, any interaction will become inaccurate: the map would zoom in and out, and end up not being centered on the pointer. This makes it hard to do certain interactions, e.g. selecting the desired feature.
There is currently no built-in way to react to element's size changes, as Resize Observer API is only implemented in Chrome.
There is however an easy to use polyfill:
import Map from 'ol/Map.js';
import ResizeObserver from 'resize-observer-polyfill';
const mapElement = document.querySelector('#map')
const map = new Map({
target: mapElement
})
const sizeObserver = new ResizeObserver(() => {
map.updateSize()
})
sizeObserver.observe(mapElement)
// called when the map is destroyed
// sizeObserver.disconnect()