This sound very similar to knapsack problem. For your case, I would suppose the following dynamic programming solution.

For each solution (i.e. assignment of students to groups) let us define its "cost" to be the number of missed preferences. (If preferences also have weights, you can also account for them in definition of "cost".)

Now we'll have `ans[i][j]`

to be the optimal cost of assigning *the first* `i`

students into groups so that the first group has `j`

students (and the second therefore has `i-j`

). We will populate the `ans`

array using dynamics programming. For each `i`

and `j`

consider two cases: you put `i`

th student to first group or to second.

For the first case, the cost will be `(cost of putting i-th student to group 1)+ans[i-1][j-1]`

, becase after you put `i`

th student to group 1, you have to assign `i-1`

students to groups so that 1st group has `j-1`

students.

For the second case, the cost similarly will be `(cost of putting i-th student to group 2)+ans[i-1][j]`

.

So the resulting DP formula is

```
ans[i][j]=min(cost[i][1]+ans[i-1][j-1], cost[i][2]+ans[i-1][j])
```

In case `j=0`

only the second term remains, in case `i=j`

only the first.

This will be not `O(N^3)`

, but `O(N^2)`

solution.