Algorithm to find optimal parameters [closed]

I need to write algorithm to test few variables that can take long range of values in example from 20 to 400. I want to find optimal values for those variables but i don't have a clue how to do it fast and elastic (i want to change numbers of variables)

what i want do ..

```v1 v2 v3 v..n
1  1  1  ..
1  1  2  ..
1  1  3  ..
1  1  4  ..
1  2  1  ..
1  2  2  ..
1  2  3  ..
1  2  4  ..
1  3  1  ..
1  3  2  ..
.. .. ..
```
-
This question is far too vague. I'm not entirely sure what you are actually trying to do here. –  Skizz Sep 1 '11 at 12:15
normally i use only 2 variables so for(i;i<400;i++) for(y;y<400;++) { check(i,y); my problem is to write code that can use many variables to test –  Xamael Sep 1 '11 at 12:16
... do you just want to loop through them all? –  quasiverse Sep 1 '11 at 12:18
How is `check(x1,x2,...,xN)` defined? Optimization is a quite well developed mathematical field. If `check` is convex and linear for instance, you could use something as simple as en.wikipedia.org/wiki/Simplex_algorithm –  carlpett Sep 1 '11 at 12:23
It would make more sense to describe the problem to which this is the answer (since this is not a computationally practicle answer). –  Skizz Sep 1 '11 at 12:24

closed as not a real question by Skizz, outis, sehe, Evgeny Kluev, Rowland ShawFeb 28 at 13:21

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

you are facing an NP-Hard problem, so you would probably want a heuristic solution, with one of the Articial Intelligence tools.

One approach is using a genetic algorithm, and iteratively converge a solution.

A different approach [my favorite!] is steepest ascent hill climbing [SAHC] first, we will define our utility function (let it be `u`). it can be the time it took the program to run, or any other utility you might have.
next,we define our 'world': `S is the group of all combinations`.
for each legal variation s of S, we define:
`next(s)={all possible combination we can get by changing one parameter by K}` [K is some predefined value]

all we have to do now is run SAHC with random restarts:

``````1. best<- INFINITY
2. while there is more time
3. choose random value for all variables.
4. NEXT <- next(s)
5. if min{ U(NEXT) } > u(s): //s is a local minimum
5.1. if u(s) < best: best <- u(s) //if s is better then the previous result - store it.
5.2. go to 2. //restart the hill climbing from a different random point.
6. else:
6.1. s <- min{ NEXT }
6.2. goto 4.
7. return best //when out of time, return the best solution found so far.
``````

(*) Note that in here, I assumed lower `u` is better, of course you can change it to have a positive utility function, where higher is better [this case is actually the hill climbing the algorithm is named for].

It is anytime algorithm, meaning it will get a better result as you give it more time to run, and eventually [at time infinity] it will find the optimal result.

EDIT:
The fact that this algorithm [and genetic algorithm as well] are Any-time, means that if a low amount of time will be given to them, they will find a result for you, but it will probably not be a good one. In order to get a good result, you will gave to give these algorithms some time [and the more, the better..]

-
The question asked for fast and you suggested genetic algorithm. <smile> You can have an upvote all the same but you might like to let the poster know that fast and GA don't usually appear in the same sentence! –  David Heffernan Sep 1 '11 at 12:28
@David Heffernan: I missed the 'fast' word. though both genetic algorithms and SAHC can be fast, but they will probably generate a bad result with low amount of time. I'll edit my answer to say it may take a while :) –  amit Sep 1 '11 at 12:30

If the algorithm depends on all variables in some intricate way (i.e., you can't test one variable at a time) you would typically require an exhaustive search to find the global optimum.

Assuming this is unfeasible I'd suggest you try something like simulated annealing.

If it's simply a matter of looping through all combinations, you could obviously do

``````for (int v1 = v1min; v1 <= v1max; v1++) {
for (int v2 = v2min; v2 <= v2max; v2++) {
for ( ... ) {
}
}
}
``````

However, since you say I want to change numbers of variables I suspect that you need something more general.

Here's one solution:

``````class CombinationIterator implements Iterator<int[]> {

int[][] limits;
int[] current;

public CombinationIterator(int[][] limits) {
this.limits = limits;

// Initialize all variables to their minimums.
current = new int[limits.length];
for (int i = 0; i < limits.length; i++)
current[i] = limits[i][0];
}

@Override
public boolean hasNext() {
return current != null;
}

@Override
public int[] next() {

if (current == null)
throw new IllegalStateException("No more combinations.");

int[] toReturn = current.clone();

for (int i = limits.length - 1; i >= -1; i--) {
if (i == -1) {
current = null;
break;
} if (current[i] < limits[i][1]) {
current[i]++;
break;
} else
current[i] = limits[i][0];
}

}

@Override
public void remove() {
throw new UnsupportedOperationException("Can't remove combinations");
}
}
``````

Which can be used like this:

``````class Test {
public static void main(String[] args) {
int[][] limits = {
{ 5, 7 },   // first  variable ranges from 5 to 7
{ 1, 3 }    // second variable ranges from 1 to 3
};

CombinationIterator iter = new CombinationIterator(limits);

while (iter.hasNext())
System.out.println(Arrays.toString(iter.next()));
}
}
``````

Here's an ideone.com demo

-