What I think you're asking about is sampling from a distribution.

Python's random module provides several distributions, the choice of which depends on what you want for your application. For example random.random() returns floating points uniformly distributed between 0.0 and 1.0.

## Uniform

You might want to sample costs uniformly from a band that gets higher with accuracy, like this:

```
cost = (random.random() * spread + min(accuracy, (1-spread))) * user_specified_value
```

Spread defines how wide the band is, and we draw uniformly within the band, sliding the band upward as accuracy increases stopping when we bump up against 100%.

Let's see how this looks, generating 1000 random samples:

The y axis here is cost. The x axis is just the order in which the samples were drawn and is meaningless. Here's what you get for low accuracy (0.01)

Dialing the accuracy up to 0.30, get's you random costs in this range:

And for highly accurate players (0.99), we get:

## Triangular distribution

Another way to scale up the costs would be to use a triangular distribution, something like this:

```
cost = random.triangular(0.0,max(0.01,accuracy),1.0)
```

This time, the x axis is accuracy, the cost, y, scales up gradually. Note that a highly accurate player can still get a low cost, but a low accuracy player never gets a high cost:

BTW, I used the plotting library matplotlib and the following code to generate these nifty plots.

```
import numpy as np
import matplotlib.pyplot as plt
import random
user_specified_value = 100.0
spread = 0.33
n = 1000
## uniform
accuracy = 0.01
costs = [0] * n
for i in range(0,n):
costs[i] = random.random() * user_specified_value * accuracy
plt.scatter(range(0,n), costs)
plt.ylim(0, 100)
## triangular
accuracy = [0] * n
costs = [0] * n
for i in range(0,n):
accuracy[i] = float(i)/n
costs[i] = random.triangular(0.0,max(0.01,accuracy[i]),1.0) * user_specified_value
plt.scatter(accuracy, costs)
```

`closer`

mean in this context? – Justin Jasmann Mar 25 at 17:13