There are many formulas which might satisfy your requiremements.

# Nested powers

One possibility:

```
$points = 10000 * pow(0.993575964272119, pow($rank, 3.16332422407427) - 1)
```

This gives you the following results:

```
f(1) = 10000
f(2) = 9500
f(4) = 6000
f(9) = 12.065
f(10) = 0.84341
f(200) = 0
```

So the three values you fixed (1, 2 and 4) are all satisfied, but the result for 200 indicates that this might not be exactly what you're looking for. The curve looks like this:

By the way, I found this using python and mpmath, by fixing the form of the formula and determining the numbers with the many digits numerically:

```
>>> import mpmath
>>> print(mpmath.findroot((lambda a,b: 10000*a**(2**b - 1) - 9500,
... lambda a,b: 10000*a**(4**b - 1) - 6000),
... (0.995, 2.7)))
[0.993575964272119]
[ 3.16332422407427]
```

If you decide on a different form of the function, this approach might be adapted.

# Exp of a polynomial

A possible different form with the desired properties would be this:

```
$points = exp(9.14265175282929 + $rank*(0.127179575914116 - $rank*0.0594909567672230))
```

This does not decrease quite as quickly as the one above:

```
f( 1) = 10000
f( 2) = 9500
f( 4) = 6000
f( 13) = 2.1002
f( 14) = 0.47852
f(200) = 0
```

It was obtained by solving this system of equations:

```
a + b + c = log(10000)
a + 2b + 4c = log( 9500)
a + 4b + 16c = log( 6000)
```

to obtain the coefficients *a* through *c* for the polynomial. One can add another degree to match `f(200)=2`

as well, but in that case, the last coefficient will become positive, which means that points will start to increase with rank for very large ranks.

If you want to match that `f(200)=2`

as well, you can do so using

```
$points = exp(max(8.86291000469285 - $rank*0.0408488141206645,
9.14265175282929 + $rank*(0.127179575914116 - $rank*0.0594909567672230)))
```

although this will result in a bend in your curve.

To compare these alternatives to the above:

`$points`

to be positive, or non-negative? Do you neet it to be integral? – MvG Nov 14 '12 at 18:23