The order of the records is probably not influential. You can optimize something by simplifying the query, another little something by precalculating values, and some more by storing the data with the minimum required precision.

I have been running some tests with about 10,000 randomly generated postcodes, and I'm seeing a (roughly) 25% performance increase with all of the above and this index:

```
CREATE INDEX postcodes_ndx ON postcodes(postcode, latitude, longitude);
```

Your results will depend on what other data is present in each row, as well as platform and other parameters.

Consider also the possibility of leveraging MySQL's spatial extensions. Otherwise, you might try storing an off-the-cuff UTM position for each postcode (as long as you're not covering an area as wide as Russia), and restricting the first table to those values within a square three miles on a side, centered on `$postcode`

. This will immediately reduce the retrieved rows by a couple of orders of magnitude, proportionately increasing the query speed.

I started with a JOIN instead of the subselects:

```
SELECT
(@rownum := @rownum + 1) AS No,
A.postcode AS Postcode,
A.latitude AS Latitude,
A.longitude AS Longitude,
ACOS(
SIN(B.latitude * PI() / 180) * SIN(A.latitude * PI() / 180) +
COS(B.latitude * PI() / 180) * COS(A.latitude * PI() / 180) *
COS((B.longitude - A.longitude) * PI() / 180)
) * 180 / PI() * 60 * 1.1515
AS Distance
FROM postcodes AS A,
(SELECT * FROM postcodes WHERE postcode = $postcode) AS B,
(SELECT @rownum := 0) AS No
HAVING Distance <= 0.5 /*miles*/
ORDER BY Distance ASC;
```

Also, I think you are storing latitude and longitude with way too much precision.

Once you have locations with three digits plus six decimals, that's about an inch precision, and the math formula you're using has an error superior to that.

You might also be able to squeeze some performance by storing latitude and longitude in radiants instead of degrees; that way you save most of the `PI()/180`

calculations. You can do that with a trigger, and store two extra columns with `lat_rad`

and `lng_rad`

(they need each about three decimals more than lat and lng).

You can also precalculate some of the values, e.g. the arccos you can multiply directly by `3958.57`

instead of `180/PI()*60*1.1515`

.

You can also move some of the trig calculations inside the JOIN:

```
SELECT A.postcode AS Postcode,
A.latitude AS Latitude,
A.longitude AS Longitude,
ACOS(
sinlat * SIN(A.latitude * PI() / 180)
+ coslat * COS(A.latitude * PI() / 180)
* COS((B.longitude - A.longitude) * PI() / 180)
) * 3958.57 AS Distance
FROM postcodes AS A,
(SELECT latitude, longitude,
COS(latitude*PI()/180) AS coslat,
SIN(latitude*PI()/180) AS sinlat
FROM postcodes WHERE postcode = $postcode
) AS B HAVING Distance <= 0.5
ORDER BY Distance ASC;
```

Finally you can remove the `@rownum`

calculation and add it back in PHP:

```
$rownum = 1;
while($tuple = SQLFetchTuple($exec))
{
$tuple['No'] = $rownum++;
... same code as before...
}
```

## Trim down the first table

This *really* would benefit from spatial extensions, but we can force the first group of postcodes to bee *within a tenth of a degree* from the first.

Of course, unless you're at the Equator, the two distances won't be the same -- you can calculate a latitude and longitude delta corresponding to about two or three miles, to have a safe margin.

```
SELECT A.postcode AS Postcode,
A.latitude AS Latitude,
A.longitude AS Longitude,
ACOS(
sinlat * SIN(A.latitude * PI() / 180) +
coslat * COS(A.latitude * PI() / 180) * COS((B.longitude - A.longitude) * PI() / 180)
) * 3958.57 AS Distance
FROM postcodes AS A,
(SELECT latitude, longitude,
COS(latitude*PI()/180) AS coslat,
SIN(latitude*PI()/180) AS sinlat
FROM postcodes WHERE postcode = $postcode) AS B
WHERE
ABS(A.latitude - B.latitude ) < 0.1
AND ABS(A.longitude - B.longitude) < 0.1
HAVING Distance <= 0.5
```

ORDER BY Distance ASC;