# Center a map in d3 given a geoJSON object

Currently in d3 if you have a geoJSON object that you are going to draw you have to scale it and translate it in order to get it to the size that one wants and translate it in order to center it. This is a very tedious task of trial and error, and I was wondering if anyone knew a better way to obtain these values?

So for instance if I have this code

``````var path, vis, xy;
xy = d3.geo.mercator().scale(8500).translate([0, -1200]);

path = d3.geo.path().projection(xy);

vis = d3.select("#vis").append("svg:svg").attr("width", 960).attr("height", 600);

d3.json("../../data/ireland2.geojson", function(json) {
return vis.append("svg:g")
.attr("class", "tracts")
.selectAll("path")
.data(json.features).enter()
.append("svg:path")
.attr("d", path)
.attr("fill", "#85C3C0")
.attr("stroke", "#222");
});
``````

How the hell do I obtain .scale(8500) and .translate([0, -1200]) without going little by little?

• Jan 25, 2015 at 23:36

My answer is close to Jan van der Laan’s, but you can simplify things slightly because you don’t need to compute the geographic centroid; you only need the bounding box. And, by using an unscaled, untranslated unit projection, you can simplify the math.

The important part of the code is this:

``````// Create a unit projection.
var projection = d3.geo.albers()
.scale(1)
.translate([0, 0]);

// Create a path generator.
var path = d3.geo.path()
.projection(projection);

// Compute the bounds of a feature of interest, then derive scale & translate.
var b = path.bounds(state),
s = .95 / Math.max((b[1][0] - b[0][0]) / width, (b[1][1] - b[0][1]) / height),
t = [(width - s * (b[1][0] + b[0][0])) / 2, (height - s * (b[1][1] + b[0][1])) / 2];

// Update the projection to use computed scale & translate.
projection
.scale(s)
.translate(t);
``````

After comping the feature’s bounding box in the unit projection, you can compute the appropriate scale by comparing the aspect ratio of the bounding box (`b[1][0] - b[0][0]` and `b[1][1] - b[0][1]`) to the aspect ratio of the canvas (`width` and `height`). In this case, I’ve also scaled the bounding box to 95% of the canvas, rather than 100%, so there’s a little extra room on the edges for strokes and surrounding features or padding.

Then you can compute the translate using the center of the bounding box (`(b[1][0] + b[0][0]) / 2` and `(b[1][1] + b[0][1]) / 2`) and the center of the canvas (`width / 2` and `height / 2`). Note that since the bounding box is in the unit projection’s coordinates, it must be multiplied by the scale (`s`).

For example, bl.ocks.org/4707858:

There’s a related question where which is how to zoom to a specific feature in a collection without adjusting the projection, i.e., combining the projection with a geometric transform to zoom in and out. That uses the same principles as above, but the math is slightly different because the geometric transform (the SVG "transform" attribute) is combined with the geographic projection.

For example, bl.ocks.org/4699541:

• I want to point out that there are a few errors in the above code, specifically in the indices of the bounds. It should look like: s = (0.95 / Math.max((b[1][0] - b[0][0]) / width, (b[1][1] - b[0][0]) / height)) * 500, t = [(width - s * (b[1][0] + b[0][0])) / 2, (height - s * (b[1][1] + b[0][1])) / 2];
– iros
Mar 21, 2013 at 18:55
• @iros - Looks like the `* 500` is extraneous here... also, `b[1][1] - b[0][0]` should be `b[1][1] - b[0][1]` in the scale calculation. Apr 4, 2013 at 20:06
• Bug report: meta.stackexchange.com/questions/184140/… Jun 12, 2013 at 17:24
• So: `b.s = b[0][1]; b.n = b[1][1]; b.w = b[0][0]; b.e = b[1][0]; b.height = Math.abs(b.n - b.s); b.width = Math.abs(b.e - b.w); s = .9 / Math.max(b.width / width, (b.height / height));` Aug 31, 2013 at 17:35
• It is because of a community like this that D3 is such a joy to work with. Awesome! Jul 8, 2014 at 9:04

The following seems to do approximately what you want. The scaling seems to be ok. When applying it to my map there is a small offset. This small offset is probably caused because I use the translate command to center the map, while I should probably use the center command.

1. Create a projection and d3.geo.path
2. Calculate the bounds of the current projection
3. Use these bounds to calculate the scale and translation
4. Recreate the projection

In code:

``````  var width  = 300;
var height = 400;

var vis = d3.select("#vis").append("svg")
.attr("width", width).attr("height", height)

d3.json("nld.json", function(json) {
// create a first guess for the projection
var center = d3.geo.centroid(json)
var scale  = 150;
var offset = [width/2, height/2];
var projection = d3.geo.mercator().scale(scale).center(center)
.translate(offset);

// create the path
var path = d3.geo.path().projection(projection);

// using the path determine the bounds of the current map and use
// these to determine better values for the scale and translation
var bounds  = path.bounds(json);
var hscale  = scale*width  / (bounds[1][0] - bounds[0][0]);
var vscale  = scale*height / (bounds[1][1] - bounds[0][1]);
var scale   = (hscale < vscale) ? hscale : vscale;
var offset  = [width - (bounds[0][0] + bounds[1][0])/2,
height - (bounds[0][1] + bounds[1][1])/2];

// new projection
projection = d3.geo.mercator().center(center)
.scale(scale).translate(offset);
path = path.projection(projection);

// add a rectangle to see the bound of the svg
vis.append("rect").attr('width', width).attr('height', height)
.style('stroke', 'black').style('fill', 'none');

vis.selectAll("path").data(json.features).enter().append("path")
.attr("d", path)
.style("fill", "red")
.style("stroke-width", "1")
.style("stroke", "black")
});
``````
• Hey Jan van der Laan I never thanked you for this response. This is a really good response to by the way if I could split out the bounty I would. Thank for it! Feb 19, 2013 at 2:34
• If I apply this I get bounds = infinity. Any idea on how this can be solved? Feb 10, 2015 at 20:05
• @SimkeNys This might the be the same problem as mentioned here stackoverflow.com/questions/23953366/… Try the solution mentioned there. Feb 11, 2015 at 8:29
• Hi Jan, thank you for your code. I tried your example with some GeoJson data but it didn't worked. Can you tell me what I'm doing wrong? :) I uploaded the GeoJson data: onedrive.live.com/… May 29, 2015 at 14:30
• In D3 v4 projection fitting is a built-in method: `projection.fitSize([width, height], geojson)` (API docs) - see @dnltsk 's answer below. May 4, 2018 at 8:25

With d3 v4 or v5 its getting way easier!

``````var projection = d3.geoMercator().fitSize([width, height], geojson);
var path = d3.geoPath().projection(projection);
``````

and finally

``````g.selectAll('path')
.data(geojson.features)
.enter()
.append('path')
.attr('d', path)
.style("fill", "red")
.style("stroke-width", "1")
.style("stroke", "black");
``````

Enjoy, Cheers

• I hope this answer gets voted up more. Been working with `d3v4` for a while and just discovered this method.
– Mark
Feb 5, 2017 at 14:10
• Where does `g` come from? Is that the svg container? Jun 29, 2017 at 12:27
• Tschallacka `g` should be `<g></g>` tag Aug 6, 2017 at 1:02
• Shame this is so far down and after 2 quality answers. It's easy to miss this and it's obviously way simpler than the other answers.
– Kurt
Nov 28, 2017 at 19:26
• Thank you. Works in v5 too! Oct 15, 2018 at 11:55

I'm new to d3 - will try to explain how I understand it but I'm not sure I got everything right.

The secret is knowing that some methods will operate on the cartographic space (latitude,longitude) and others on the cartesian space (x,y on the screen). The cartographic space (our planet) is (almost) spherical, the cartesian space (screen) is flat - in order to map one over the other you need an algorithm, which is called projection. This space is too short to deep into the fascinating subject of projections and how they distort geographic features in order to turn spherical into plane; some are designed to conserve angles, others conserve distances and so on - there is always a compromise (Mike Bostock has a huge collection of examples).

In d3, the projection object has a center property/setter, given in map units:

projection.center([location])

If center is specified, sets the projection’s center to the specified location, a two-element array of longitude and latitude in degrees and returns the projection. If center is not specified, returns the current center which defaults to ⟨0°,0°⟩.

There is also the translation, given in pixels - where the projection center stands relative to the canvas:

projection.translate([point])

If point is specified, sets the projection’s translation offset to the specified two-element array [x, y] and returns the projection. If point is not specified, returns the current translation offset which defaults to [480, 250]. The translation offset determines the pixel coordinates of the projection’s center. The default translation offset places ⟨0°,0°⟩ at the center of a 960×500 area.

When I want to center a feature in the canvas, I like to set the projection center to the center of the feature bounding box - this works for me when using mercator (WGS 84, used in google maps) for my country (Brazil), never tested using other projections and hemispheres. You may have to make adjustments for other situations, but if you nail these basic principles you will be fine.

For example, given a projection and path:

``````var projection = d3.geo.mercator()
.scale(1);

var path = d3.geo.path()
.projection(projection);
``````

The `bounds` method from `path` returns the bounding box in pixels. Use it to find the correct scale, comparing the size in pixels with the size in map units (0.95 gives you a 5% margin over the best fit for width or height). Basic geometry here, calculating the rectangle width/height given diagonally opposed corners:

``````var b = path.bounds(feature),
s = 0.9 / Math.max(
(b[1][0] - b[0][0]) / width,
(b[1][1] - b[0][1]) / height
);
projection.scale(s);
``````

Use the `d3.geo.bounds` method to find the bounding box in map units:

``````b = d3.geo.bounds(feature);
``````

Set the center of the projection to the center of the bounding box:

``````projection.center([(b[1][0]+b[0][0])/2, (b[1][1]+b[0][1])/2]);
``````

Use the `translate` method to move the center of the map to the center of the canvas:

``````projection.translate([width/2, height/2]);
``````

By now you should have the feature in the center of the map zoomed with a 5% margin.

• Is there a bl.ocks somewhere ? Aug 22, 2013 at 15:07
• Sorry, no bl.ocks or gist, what are you trying to do? Is it something like a click-to-zoom? Publish it and I can take a look at your code. Aug 22, 2013 at 16:54
• Bostock's answer and images provides links to bl.ocks.org examples which let me to copy engineer a whole code. Job done. +1 and thanks for your great illustrations! Sep 1, 2013 at 6:31
• What do I do when `b = d3.geo.bounds(feature)` returns `[Infinity, Infinity], [-Infinity, -Infinity]` ? Why does it return "infinity"? Jul 20, 2022 at 15:55

There is a center() method you can use that accepts a lat/lon pair.

From what I understand, translate() is only used for literally moving the pixels of the map. I am not sure how to determine what scale is.

• If you are using TopoJSON and want to center the whole map, you can run topojson with --bbox to include a bbox attribute in the JSON object. The lat/lon coordinates for the center should be [(b[0]+b[2])/2, (b[1]+b[3])/2] (where b is the bbox value). Jun 11, 2013 at 4:31

In addition to Center a map in d3 given a geoJSON object, note that you may prefer `fitExtent()` over `fitSize()` if you want to specify a padding around the bounds of your object. `fitSize()` automatically sets this padding to 0.

I was looking around on the Internet for a fuss-free way to center my map, and got inspired by Jan van der Laan and mbostock's answer. Here's an easier way using jQuery if you are using a container for the svg. I created a border of 95% for padding/borders etc.

``````var width = \$("#container").width() * 0.95,
height = \$("#container").width() * 0.95 / 1.9 //using height() doesn't work since there's nothing inside

var projection = d3.geo.mercator().translate([width / 2, height / 2]).scale(width);
var path = d3.geo.path().projection(projection);

var svg = d3.select("#container").append("svg").attr("width", width).attr("height", height);
``````

If you looking for exact scaling, this answer won't work for you. But if like me, you wish to display a map that centralizes in a container, this should be enough. I was trying to display the mercator map and found that this method was useful in centralizing my map, and I could easily cut off the Antarctic portion since I didn't need it.

To pan/zoom the map you should look at overlaying the SVG on Leaflet. That will be a lot easier than transforming the SVG. See this example http://bost.ocks.org/mike/leaflet/ and then How to change the map center in leaflet

• If adding another dependence is of concern, PAN and ZOOM can be done easily in pure d3, see stackoverflow.com/questions/17093614/… Jun 15, 2013 at 2:21
• This answer doesn't really deal with d3. You can pan/zoom the map in d3 also, leaflet is not necessary. (Just realised this an old post, was just browsing the answers) Dec 10, 2014 at 11:00

With mbostocks' answer, and Herb Caudill's comment, I started running into issues with Alaska since I was using a mercator projection. I should note that for my own purposes, I am trying to project and center US States. I found that I had to marry the two answers with Jan van der Laan answer with following exception for polygons that overlap hemispheres (polygons that end up with a absolute value for East - West that is greater than 1):

1. set up a simple projection in mercator:

projection = d3.geo.mercator().scale(1).translate([0,0]);

2. create the path:

path = d3.geo.path().projection(projection);

3.set up my bounds:

``````var bounds = path.bounds(topoJson),
dx = Math.abs(bounds[1][0] - bounds[0][0]),
dy = Math.abs(bounds[1][1] - bounds[0][1]),
x = (bounds[1][0] + bounds[0][0]),
y = (bounds[1][1] + bounds[0][1]);
``````

``````if(dx > 1){
var center = d3.geo.centroid(topojson.feature(json, json.objects[topoObj]));
scale = height / dy * 0.85;
console.log(scale);
projection = projection
.scale(scale)
.center(center)
.translate([ width/2, height/2]);
}else{
scale = 0.85 / Math.max( dx / width, dy / height );
offset = [ (width - scale * x)/2 , (height - scale * y)/2];

// new projection
projection = projection
.scale(scale)
.translate(offset);
}
``````

I hope this helps.

For people who want to adjust verticaly et horizontaly, here is the solution :

``````  var width  = 300;
var height = 400;

var vis = d3.select("#vis").append("svg")
.attr("width", width).attr("height", height)

d3.json("nld.json", function(json) {
// create a first guess for the projection
var center = d3.geo.centroid(json)
var scale  = 150;
var offset = [width/2, height/2];
var projection = d3.geo.mercator().scale(scale).center(center)
.translate(offset);

// create the path
var path = d3.geo.path().projection(projection);

// using the path determine the bounds of the current map and use
// these to determine better values for the scale and translation
var bounds  = path.bounds(json);
var hscale  = scale*width  / (bounds[1][0] - bounds[0][0]);
var vscale  = scale*height / (bounds[1][1] - bounds[0][1]);
var scale   = (hscale < vscale) ? hscale : vscale;
var offset  = [width - (bounds[0][0] + bounds[1][0])/2,
height - (bounds[0][1] + bounds[1][1])/2];

// new projection
projection = d3.geo.mercator().center(center)
.scale(scale).translate(offset);
path = path.projection(projection);

var bounds  = path.bounds(json);
offset[0] = offset[0] + (width - bounds[1][0] - bounds[0][0]) / 2;
offset[1] = offset[1] + (height - bounds[1][1] - bounds[0][1]) / 2;

projection = d3.geo.mercator().center(center)
.scale(scale).translate(offset);
path = path.projection(projection);

// add a rectangle to see the bound of the svg
vis.append("rect").attr('width', width).attr('height', height)
.style('stroke', 'black').style('fill', 'none');

vis.selectAll("path").data(json.features).enter().append("path")
.attr("d", path)
.style("fill", "red")
.style("stroke-width", "1")
.style("stroke", "black")
});
``````

How I centered a Topojson, where I needed to pull out the feature:

``````      var projection = d3.geo.albersUsa();

var path = d3.geo.path()
.projection(projection);

var tracts = topojson.feature(mapdata, mapdata.objects.tx_counties);

projection
.scale(1)
.translate([0, 0]);

var b = path.bounds(tracts),
s = .95 / Math.max((b[1][0] - b[0][0]) / width, (b[1][1] - b[0][1]) / height),
t = [(width - s * (b[1][0] + b[0][0])) / 2, (height - s * (b[1][1] + b[0][1])) / 2];

projection
.scale(s)
.translate(t);

svg.append("path")
.datum(topojson.feature(mapdata, mapdata.objects.tx_counties))
.attr("d", path)
``````