Your second formula for distance looks almost right comparing with this page

```
a = sin²(Δφ/2) + cos φ1 ⋅ cos φ2 ⋅ sin²(Δλ/2)
c = 2 ⋅ atan2( √a, √(1−a) )
d = R ⋅ c
```

As far as I see, `asin`

should give the same result as `atan2`

formula in the second line for positive arguments in range 0..1.
If value of `a`

may lie slightly outside this interval, arcsine will give erroneous result, so

If atan2 is not available, c could be calculated from 2 ⋅ asin( min(1,
√a) ) (including protection against rounding errors).

Could you show an example of data points with mistakes?

Python code (ideone to play with)

```
import math
def eadist(lat1, lon1, lat2, lon2):
print(lat1, lon1, lat2, lon2)
d2r = math.pi / 180
R = 6378
dlat = (lat2 -lat1) * d2r
dlon = (lon2 -lon1) * d2r
a = (math.sin(dlat/2))**2 + math.cos(lat1*d2r)*math.cos(lat2*d2r) * (math.sin(dlon/2))**2
print("a=",a)
c = 2*math.asin(math.sqrt(a))
print("c=",c)
dist = c * R
return dist
print(eadist(45, 90, 45, 91))
print(eadist(45, 90, 46, 90))
print(eadist(45, 90, 46, 91))
print(eadist(45, 90, -45, -90))
```

gives correct results

```
45 90 45 91
a= 3.8076210902190215e-05
c= 0.012341263173265506
78.71257651908739 //1 degree by parallel
45 90 46 90
a= 7.615242180438042e-05
c= 0.017453292519943295
111.31709969219834 //1 degree by meridian
45 90 46 91
a= 0.0001135583120069672
c= 0.021313151879913415
135.93528269008777 //diagonal step
45 90 -45 -90
a= 1.0
c= 3.141592653589793
20037.0779445957 //antipodal point, a half of meridian length
```