I have data with latitude and longitude stored in my SQLite database, and I want to get the nearest locations to the parameters I put in (ex. My current location - lat/lng, etc.).

I know that this is possible in MySQL, and I've done quite some research that SQLite needs a custom external function for the Haversine formula (calculating distance on a sphere), but I haven't found anything that is written in Java and works.

Also, if I want to add custom functions, I need the org.sqlite .jar (for org.sqlite.Function), and that adds unnecessary size to the app.

The other side of this is, I need the Order by function from SQL, because displaying the distance alone isn't that much of a problem - I already did it in my custom SimpleCursorAdapter, but I can't sort the data, because I don't have the distance column in my database. That would mean updating the database every time the location changes and that's a waste of battery and performance. So if someone has any idea on sorting the cursor with a column that's not in the database, I'd be grateful too!

I know there are tons of Android apps out there that use this function, but can someone please explain the magic.

By the way, I found this alternative: Query to get records based on Radius in SQLite?

It's suggesting to make 4 new columns for cos and sin values of lat and lng, but is there any other, not so redundant way?

  • Did you check if org.sqlite.Function works for you (even if the formula is not correct)? Sep 12, 2010 at 15:50
  • No, I found a (redundant) alternative (edited post) that sounds better than adding a 2,6MB .jar in the app. But I'm still searching for a better solution. Thanks!
    – Jure
    Sep 12, 2010 at 16:09
  • Whats the return distance unit type?
    – user959001
    Oct 7, 2011 at 7:08
  • Here is a full implementation for building a SQlite query on Android based on distance between your location and the object's location.
    – EricLarch
    Mar 2, 2012 at 16:37

5 Answers 5


1) At first filter your SQLite data with a good approximation and decrease amount of data that you need to evaluate in your java code. Use the following procedure for this purpose:

To have a deterministic threshold and more accurate filter on data, It is better to calculate 4 locations that are in radius meter of the north, west, east and south of your central point in your java code and then check easily by less than and more than SQL operators (>, <) to determine if your points in database are in that rectangle or not.

The method calculateDerivedPosition(...) calculates those points for you (p1, p2, p3, p4 in picture).

enter image description here

* Calculates the end-point from a given source at a given range (meters)
* and bearing (degrees). This methods uses simple geometry equations to
* calculate the end-point.
* @param point
*           Point of origin
* @param range
*           Range in meters
* @param bearing
*           Bearing in degrees
* @return End-point from the source given the desired range and bearing.
public static PointF calculateDerivedPosition(PointF point,
            double range, double bearing)
        double EarthRadius = 6371000; // m

        double latA = Math.toRadians(point.x);
        double lonA = Math.toRadians(point.y);
        double angularDistance = range / EarthRadius;
        double trueCourse = Math.toRadians(bearing);

        double lat = Math.asin(
                Math.sin(latA) * Math.cos(angularDistance) +
                        Math.cos(latA) * Math.sin(angularDistance)
                        * Math.cos(trueCourse));

        double dlon = Math.atan2(
                Math.sin(trueCourse) * Math.sin(angularDistance)
                        * Math.cos(latA),
                Math.cos(angularDistance) - Math.sin(latA) * Math.sin(lat));

        double lon = ((lonA + dlon + Math.PI) % (Math.PI * 2)) - Math.PI;

        lat = Math.toDegrees(lat);
        lon = Math.toDegrees(lon);

        PointF newPoint = new PointF((float) lat, (float) lon);

        return newPoint;


And now create your query:

PointF center = new PointF(x, y);
final double mult = 1; // mult = 1.1; is more reliable
PointF p1 = calculateDerivedPosition(center, mult * radius, 0);
PointF p2 = calculateDerivedPosition(center, mult * radius, 90);
PointF p3 = calculateDerivedPosition(center, mult * radius, 180);
PointF p4 = calculateDerivedPosition(center, mult * radius, 270);

strWhere =  " WHERE "
        + COL_X + " > " + String.valueOf(p3.x) + " AND "
        + COL_X + " < " + String.valueOf(p1.x) + " AND "
        + COL_Y + " < " + String.valueOf(p2.y) + " AND "
        + COL_Y + " > " + String.valueOf(p4.y);

COL_X is the name of the column in the database that stores latitude values and COL_Y is for longitude.

So you have some data that are near your central point with a good approximation.

2) Now you can loop on these filtered data and determine if they are really near your point (in the circle) or not using the following methods:

public static boolean pointIsInCircle(PointF pointForCheck, PointF center,
            double radius) {
        if (getDistanceBetweenTwoPoints(pointForCheck, center) <= radius)
            return true;
            return false;

public static double getDistanceBetweenTwoPoints(PointF p1, PointF p2) {
        double R = 6371000; // m
        double dLat = Math.toRadians(p2.x - p1.x);
        double dLon = Math.toRadians(p2.y - p1.y);
        double lat1 = Math.toRadians(p1.x);
        double lat2 = Math.toRadians(p2.x);

        double a = Math.sin(dLat / 2) * Math.sin(dLat / 2) + Math.sin(dLon / 2)
                * Math.sin(dLon / 2) * Math.cos(lat1) * Math.cos(lat2);
        double c = 2 * Math.atan2(Math.sqrt(a), Math.sqrt(1 - a));
        double d = R * c;

        return d;


I used and customized this reference and completed it.

  • Check out Chris Veness great webpage if you are looking for a Javascript implementation of this concept above. movable-type.co.uk/scripts/latlong.html
    – barneymc
    Sep 21, 2014 at 17:20
  • @Menma x is latitude and y is longitude. radius: the radius of the circle that is shown in the picture.
    – Bob
    Sep 9, 2015 at 9:19
  • the solution given above is correct and works. Try it ... :) Nov 3, 2015 at 8:31
  • 1
    This is an approximate solution! It gives you highly approximate results via a fast, index-friendly SQL query. It will give wrong result in some extreme circumstances. Once you have gotten small number of approximate result within area of several kilometers, use slower, more precise methods to filter those results. Do not use it to filter with very large radius or if your app is going to be frequently used at equator! Mar 28, 2018 at 9:46
  • 1
    But I don't get it. CalculateDerivedPosition is transforming the lat,lng coordinate in to a cartesian one and then you in the SQL query, you are comparing these cartesian values with the lat,long values. Two different geometrical coordinates? How does this work? Thanks. May 17, 2019 at 5:45

Chris's answer is really useful (thanks!), but will only work if you are using rectilinear coordinates (eg UTM or OS grid references). If using degrees for lat/lng (eg WGS84) then the above only works at the equator. At other latitudes, you need to decrease the impact of longitude on the sort order. (Imagine you're close to the north pole... a degree of latitude is still the same as it is anywhere, but a degree of longitude may only be a few feet. This will mean that the sort order is incorrect).

If you are not at the equator, pre-calculate the fudge-factor, based on your current latitude:

<fudge> = Math.pow(Math.cos(Math.toRadians(<lat>)),2);

Then order by:

((<lat> - LAT_COLUMN) * (<lat> - LAT_COLUMN) + (<lng> - LNG_COLUMN) * (<lng> - LNG_COLUMN) * <fudge>)

It's still only an approximation, but much better than the first one, so sort order inaccuracies will be much rarer.

  • 3
    That's a really interesting point about the longitudal lines converging at the poles and skewing the results the nearer you get. Nice fix. Oct 17, 2011 at 3:59
  • 1
    this seems to work cursor = db.getReadableDatabase().rawQuery("Select nome, id as _id, " + "( " + latitude + " - lat) * ( " + latitude +"- lat) + ( " + longitude + "- lon) * ( " + longitude + "- lon) * " + fudge + " as distanza " + " from cliente "+ " order by distanza asc", null);
    – max4ever
    Aug 31, 2012 at 11:08
  • should ((<lat> - LAT_COLUMN) * (<lat> - LAT_COLUMN) + (<lng> - LNG_COLUMN) * (<lng> - LNG_COLUMN) * <fudge>) be less than distance or distance^2?
    – Bob
    Oct 21, 2012 at 7:32
  • Isn't the fudge factor in radians and the columns in degrees? Shouldn't them be converted to the same unit? Dec 11, 2012 at 18:46
  • 1
    No, the fudge factor is a scaling factor which is 0 at the poles and 1 at the equator. It's neither in degrees, nor radians, it's just a unitless number. The Java Math.cos function requires an argument in radians, and I assumed <lat> was in degrees, hence the Math.toRadians function. But the resulting cosine has no units.
    – Teasel
    Jan 16, 2013 at 18:24

I know this has been answered and accepted but thought I'd add my experiences and solution.

Whilst I was happy to do a haversine function on the device to calculate the accurate distance between the user's current position and any particular target location there was a need to sort and limit the query results in order of distance.

The less than satisfactory solution is to return the lot and sort and filter after the fact but this would result in a second cursor and many unnecessary results being returned and discarded.

My preferred solution was to pass in a sort order of the squared delta values of the long and lats:

((<lat> - LAT_COLUMN) * (<lat> - LAT_COLUMN) +
 (<lng> - LNG_COLUMN) * (<lng> - LNG_COLUMN))

There's no need to do the full haversine just for a sort order and there's no need to square root the results therefore SQLite can handle the calculation.


This answer is still receiving love. It works fine in most cases but if you need a little more accuracy, please check out the answer by @Teasel below which adds a "fudge" factor that fixes inaccuracies that increase as the latitude approaches 90.

  • Great answer. Could you explain how did it work and what is this algorithm called?
    – iMatoria
    Oct 16, 2011 at 15:47
  • 3
    @iMatoria - This is just a cut down version of pythagoras famous theorem. Given two sets of coordinates, the difference between the two X values represents one side of a right angled triangle and the difference between the Y values is the other. To get the hypotenuse (and therefore the distance between the points) you add the squares of these two values together and then square root the result. In our case we don't do the last bit (the square rooting) because we can't. Fortunately this is not necessary for a sort order. Oct 17, 2011 at 3:51
  • 6
    In my app BostonBusMap I used this solution to show stops closest to the current location. However you need to scale the longitude distance by cos(latitude) to have the latitude and longitude roughly equal. See en.wikipedia.org/wiki/… Sep 17, 2012 at 0:38

In order to increase performance as much as possible I suggest improve @Chris Simpson's idea with the following ORDER BY clause:


In this case you should pass the following values from code:

<L> = center_lat^2 + center_lon^2
<A> = 2 * center_lat
<B> = 2 * center_lon

And you should also store LAT_LON_SQ_SUM = LAT_COL^2 + LON_COL^2 as additional column in database. Populate it inserting your entities into database. This slightly improves performance while extracting large amount of data.


Try something like this:

    //locations to calculate difference with 
    Location me   = new Location(""); 
    Location dest = new Location(""); 

    //set lat and long of comparison obj 

    //init to circumference of the Earth 
    float smallest = 40008000.0f; //m 

    //var to hold id of db element we want 
    Integer id = 0; 

    //step through results 

        //set lat and long of destination obj 

        //grab distance between me and the destination 
        float dist = me.distanceTo(dest); 

        //if this is the smallest dist so far 
        if(dist < smallest){ 
            //store it 
            smallest = dist; 

            //grab it's id 
            id = _myCursor.getInt(_myCursor.getColumnIndexOrThrow(DataBaseHelper._FIELD_ID)); 

After this, id contains the item you want from the database so you can fetch it:

    //now we have traversed all the data, fetch the id of the closest event to us 
    _myCursor = _myDBHelper.fetchID(id); 

    //get lat and long of nearest location to user, used to push out to map view 
    _mLatNearest  = _myCursor.getFloat(_myCursor.getColumnIndexOrThrow(DataBaseHelper._FIELD_LATITUDE)); 
    _mLongNearest = _myCursor.getFloat(_myCursor.getColumnIndexOrThrow(DataBaseHelper._FIELD_LONGITUDE)); 

Hope that helps!

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