I need to implement a Geo proximity search in my application but I'm very confused regarding the correct formula to use. After some searches in the Web and in StackOverflow I found that the solutions are:

- Use the
**Haversine Formula** ~~Use the~~**Great-Circle Distance Formula**- Use a
**Spatial Search Engine**in the Database

Option #3 is really not an option for me ATM. Now I'm a little confused since I always though that the Great-Circle Distance Formula and Haversine Formula were **synonymous** but apparently I was wrong?

The above screen shot was taken from the awesome **Geo (proximity) Search with MySQL** paper, and uses the following functions:

```
ASIN, SQRT, POWER, SIN, PI, COS
```

I've also seen variations from the ** same formula (Spherical Law of Cosines)**, like this one:

```
(3956 * ACOS(COS(RADIANS(o_lat)) * COS(RADIANS(d_lat)) * COS(RADIANS(d_lon) - RADIANS(o_lon)) + SIN(RADIANS(o_lat)) * SIN(RADIANS(d_lat))))
```

That uses the following functions:

```
ACOS, COS, RADIANS, SIN
```

I am not a math expert, but are these formulas the same? I've come across some **more variations, and formulas** (such as the **Spherical Law of Cosines** and the **Vincenty's formulae** - which seems to be the most accurate) and that makes me even more confused...

I need to choose a good general purpose formula to implement in PHP / MySQL. Can anyone explain me the differences between the formulas I mentioned above?

**Which one is the fastest to compute?****Which one provides the most accurate results?****Which one is the best in terms of speed / accuracy of results?**

I appreciate your insight on these questions.

Based on theonlytheory answer I tested the following Great-Circle Distance Formulas:

- Vincenty Formula
- Haversine Formula
- Spherical Law of Cosines

The **Vincenty Formula** is dead slow, however **it's pretty accurate (down to 0.5 mm)**.

The **Haversine Formula** is way faster than the Vincenty Formula, I was able to run 1 million calculations in about 6 seconds which is pretty much acceptable for my needs.

The **Spherical Law of Cosines Formula** revealed to be **almost twice as fast** as the Haversine Formula, and **the precision difference is neglectfulness** for most usage cases.

Here are some test locations:

**Google HQ**(`37.422045`

,`-122.084347`

)**San Francisco, CA**(`37.77493`

,`-122.419416`

)**Eiffel Tower, France**(`48.8582`

,`2.294407`

)**Opera House, Sydney**(`-33.856553`

,`151.214696`

)

**Google HQ - San Francisco, CA:**

- Vincenty Formula:
`49 087.066 meters`

- Haversine Formula:
`49 103.006 meters`

- Spherical Law of Cosines:
`49 103.006 meters`

**Google HQ - Eiffel Tower, France:**

- Vincenty Formula:
`8 989 724.399 meters`

- Haversine Formula:
`8 967 042.917 meters`

- Spherical Law of Cosines:
`8 967 042.917 meters`

**Google HQ - Opera House, Sydney:**

- Vincenty Formula:
`11 939 773.640 meters`

- Haversine Formula:
`11 952 717.240 meters`

- Spherical Law of Cosines:
`11 952 717.240 meters`

As you can see there is **no noticeable difference** between the Haversine Formula and the Spherical Law of Cosines, however both have **distance offsets as high as 22 kilometers** compared to the Vincenty Formula because it uses an ellipsoidal approximation of the earth instead of a spherical one.

`AB=sqrt(pow(($Xb-$Xa),2)+pow(($Yb-$Ya),2)));`

, i never understood exactly what it do.. hope can help you ;) – Strae Jan 19 '10 at 23:12`orig.lat - dest.lat`

faulty with coordinates`[-180, 180]`

? What happens if`orig.lat = -170`

and`dest.lat = 170`

? The distance is 340 deg? No, it's actually just 20. How do you solve that if you're working with actual earth (atlas) coordinates? – Rudie May 16 '11 at 16:442more comments