I guess it's about 3 years too late for the OP, but I happened across this question while researching a similar topic, so here's my tuppence worth.

According to www.movable-type.co.uk/scripts/latlong.html there are 3 ways of calculating distance across the Earth's surface, these being, from easiest to most complex (and thus from least to most accurate): Equirectangular Approximation, Spherical Law of Cosines and the Haversine Formula. The site also provides JavaScript. This is the function for Equirectangular approximation:

```
function _lineDistanceC(lat1, lon1, lat2, lon2) {
var R = 6371; // km
lat1 = lat1.toRad();
lon1 = lon1.toRad();
lat2 = lat2.toRad();
lon2 = lon2.toRad();
var x = (lon2-lon1) * Math.cos((lat1+lat2)/2);
var y = (lat2-lat1);
return Math.sqrt(x*x + y*y) * R;
}
```

This is my attempt at a SQL equivalent:

```
drop function if exists lineDistanceC;
delimiter //
CREATE FUNCTION lineDistanceC (la1 DOUBLE, lo1 DOUBLE, la2 DOUBLE, lo2 DOUBLE) RETURNS DOUBLE
BEGIN
SET @r = 6371;
SET @lat1 = RADIANS(la1);
SET @lon1 = RADIANS(lo1);
SET @lat2 = RADIANS(la2);
SET @lon2 = RADIANS(lo2);
SET @x = (@lon2-@lon1) * COS((@lat1+@lat2)/2);
SET @y = (@lat2 - @lat1);
RETURN (SQRT((@x*@x) + (@y*@y)) * @r);
END
//
delimiter ;
```

I have no idea how accurate this formula is, but the site seems very credible and definitely worth a visit for more detail. Using the coordinates in the question, the results (in kilometres) from the above JavaScript and SQL are 0.14834420231840376 and 0.1483442023182845, which makes them the same to a fraction of a millimetre, but not, curiously, the 147 metres that the OP was expecting. Enjoy.