Probably the simplest approach is to take some cryptographic hash function and "seed" it with different sequences of bytes. For most practical purposes, the results should be independent, as this is one of the key properties a cryptographic hash function should have (if you replace any part of a message, the hash should be completely different).

I'd do something like:

```
// for each 0 <= i < k generate a sequence of random numbers
val randomSeeds: Array[Array[Byte]] = ... ; // initialize by random sequences
def hash(i: Int, value: Array[Byte]): Array[Byte] = {
val dg = java.security.MessageDigest.getInstance("SHA-1");
// "seed" the digest by a random value based on the index
dg.update(randomSeeds(i));
return dg.digest(value);
// if you need integer hash values, just take 4 bytes
// of the result and convert them to an int
}
```

**Edit:**
I don't know the precise requirements of the Count-Min Sketch, maybe a simple has function would suffice, but it doesn't seem to be the simplest solution.

I suggested a cryptographic hash function, because there you have quite strong guarantees that the resulting hash functions will be very different, and it's easy to implement, just use the standard libraries.

On the other hand, if you have two hash functions of the form `f1(x) = ax + b (mod p)`

and `f2(x) = cx + d (mod p)`

, then you can compute one using another (without knowing `x`

) using a simple linear formula `f2(x) = c / a * (f1(x) - b) + d (mod p)`

, which suggests that they aren't very independent. So you could run into unexpected problems here.