# Coordinate trigonometry - calculate midpoint in arc for flightpath

I am trying to draw flightpaths on a map using SVGs. I'm using d3 on top of Leaflet, but the frameworks used shouldn't make a difference to my problem - it's trig.

http://fiddle.jshell.net/zw8TR/26

The way I'm trying to do this is by creating a quadratic bezier curve (I'm open to other/easier ways if you know of any). What I need to calculate is 1 control point, perpendicular to the midpoint of each line. This point should always bias to a higher y value / latitude than the midpoint, to create an arc which looks like a flightpath.

In my demo above, I found it's easier to debug exactly where the control point is by adding some extra temporary points. As you can see, some of my control points are facing downwards, and none look to be properly perpendicular.

I have a feeling the problem boils down to this line:

``````var theta = Math.atan2(t_area_y, t_area_x) * 180 / Math.PI;
``````

I'm not handling negative coordinates properly. I have tried to hack in a nasty set of if gates to handle this.

I have tried to comment the fiddle nicely to explain what's going on. Once I know the point, it should be a simple case of creating a custom interpolation in d3.

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Have you seen this: bl.ocks.org/mbostock/5851933 and this: bl.ocks.org/mbostock/5928813 ? Maybe those could be helpful –  tomtomtom Feb 4 at 13:37
Yeah I have looked at those. Following those examples I could only get straight lines, maybe because I'm using Leaflet/Mercator projection? –  daviestar Feb 4 at 13:43
They would look more like arcs if they were longer and going in parallel to the equator. If you look closely, you can see that your paths are a little bit curved. –  Lars Kotthoff Feb 4 at 14:00
Hey Lars, not sure I follow what you mean. The control point should not be perpendicular to the original line, but to the equator? Yes, I noticed on the longer KL-Melbourne route the midpoint looks off. Could be because I'm moving from positive latitude to negative.. will investigate. –  daviestar Feb 4 at 14:06
No, I was talking about the default great arcs -- yes, the midpoint is off, but this is by design. It's just not as visible in your routes as it is in the example. –  Lars Kotthoff Feb 4 at 14:19

This is actually easier than you think if you use a custom line generator. Instead of adding the control points to the feature, you just add them during the computation of the path. The code looks like this:

``````feature.attr("d", function(d) {
var s, prev;
d.geometry.coordinates.forEach(function(c) {
var proj = map.latLngToLayerPoint(new L.LatLng(c[1], c[0]));
if(s) {
var length = Math.sqrt(Math.pow(proj.x - prev.x, 2), Math.pow(proj.y - prev.y, 2)),
midx = prev.x + (proj.x - prev.x) / 2,
midy = prev.y + (proj.y - prev.y) / 2 - length * 0.2 * (Math.abs(proj.x - prev.x) / length);
s += "Q" + midx + "," + midy + " " + proj.x + "," + proj.y;
} else {
s = "M" + proj.x + "," + proj.y;
}
prev = proj;
});
return s;
});
``````

Let's go through it step by step. The main thing is that I'm keeping track of the coordinates of the previous point to be able to compute the control point. First, `s` will be null and the `else` branch is taken -- simply move to that point (the start point) without drawing a line. For all subsequent points, the actual computation takes place.

First, we compute the distance between the two points (previous and current), `length`. Computing the `x` coordinate of the control point is straightforward, as no offset is required. The y coordinate is a bit trickier -- the first part is the same, then the offset is added. The size of the offset is 20% of the length of the path here (to make wider arcs for longer paths), adjust as necessary. This needs to be multiplied by the cosine of the angle to the `x` axis, but fortunately we don't need to compute the angle explicitly -- it is defined by the relation between the distance between the points and the difference in `x` coordinates (the arc cosine of that angle). So we can just take that relation directly and multiply by it. As you want arcs to point up (i.e. negative `y` offset), we're taking the absolute value of the `x` coordinate differences. Without that, some of the control points would be pointing down.

Complete example here.

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That's really impressive Lars, thanks! again! I've been working on this in the evenings for almost 2 weeks and you nail it in 20 minutes :) I should give you a credit on this project! –  daviestar Feb 4 at 15:01
My pleasure. I started thinking along similar lines as your current code, but it turned out that in the end everything falls into place quite neatly and you don't need a lot of the intermediate stuff. –  Lars Kotthoff Feb 4 at 15:02