# Calculating shortest path between 2 points on a flat map of the Earth

How do you draw the curve representing the shortest distance between 2 points on a flat map of the Earth?

Of course, the line would not be a straight line because the Earth is curved. (For example, the shortest distance between 2 airports is curved.)

EDIT: THanks for all the answers guys - sorry I was slow to choose solution :/

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Do you want to model Earth as a simple sphere or as its true shape (flattened on the poles)? It's pretty easy if you simplify it to a sphere. –  Michael Myers Dec 8 '09 at 16:31
What projection are you wanting to use? Or, could you clarify the question some? –  retracile Dec 8 '09 at 16:33
What you are trying to do is to plot a (segment of a) great circle on a map with a given projection. Try Googling the first and then the second term. –  High Performance Mark Dec 8 '09 at 16:37
Duplicate: stackoverflow.com/questions/23569/… –  ire_and_curses Dec 8 '09 at 16:39
There's obviously a lot of confusion about what you are asking. Drawing the shortest path and calculating the shortest distance are two very different problems. Which do you want help with? –  Donnie DeBoer Dec 8 '09 at 17:33

I get this sort of information from the Aviation Formulary.

In this case:

Distance between points

The great circle distance d between two points with coordinates {lat1,lon1} and {lat2,lon2} is given by:

`d=acos(sin(lat1)*sin(lat2)+cos(lat1)*cos(lat2)*cos(lon1-lon2))`

A mathematically equivalent formula, which is less subject to rounding error for short distances is:

```d=2*asin(sqrt((sin((lat1-lat2)/2))^2 + cos(lat1)*cos(lat2)*(sin((lon1-lon2)/2))^2))```

And

Intermediate points on a great circle

In previous sections we have found intermediate points on a great circle given either the crossing latitude or longitude. Here we find points (lat,lon) a given fraction of the distance (d) between them. Suppose the starting point is (lat1,lon1) and the final point (lat2,lon2) and we want the point a fraction f along the great circle route. f=0 is point 1. f=1 is point 2. The two points cannot be antipodal ( i.e. lat1+lat2=0 and abs(lon1-lon2)=pi) because then the route is undefined. The intermediate latitude and longitude is then given by:

``````    A=sin((1-f)*d)/sin(d)
B=sin(f*d)/sin(d)
x = A*cos(lat1)*cos(lon1) +  B*cos(lat2)*cos(lon2)
y = A*cos(lat1)*sin(lon1) +  B*cos(lat2)*sin(lon2)
z = A*sin(lat1)           +  B*sin(lat2)
lat=atan2(z,sqrt(x^2+y^2))
lon=atan2(y,x)
``````
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Paul, you said, "which is less subject to rounding error for short distances". How short a distance is this good for? I need something that will be accurate for 100M to 1000M distances. –  KevinDTimm Dec 8 '09 at 16:37
@kevin - I was quoting the Aviation Formulary. I have no idea what he considered short, but I always use the "less subject to rounding error" version for my flight planner. –  Paul Tomblin Dec 8 '09 at 16:45
Thanks! The intermediate points on the great cirlce is exactly what I needed. Btw , sorry for not being too clear on the question - my knowlege in this area is currently vague at best. –  helloworlder Dec 16 '09 at 3:50