6

I have this problem in front of me and I can't figure out how to solve it. It's about the series 0,1,1,2,5,29,866... (Every number besides the first two is the sum of the squares of the previous two numbers (2^2+5^2=29)). In the first part I had to write an algorithm (Not a native speaker so I don't really know the terminology) that would receive a place in the series and return it's value (6 returned 29) This is how I wrote it:

public static int mod(int n)
{
    if (n==1)
        return 0;
    if (n==2)
        return 1;
    else
        return (int)(Math.pow(mod(n-1), 2))+(int)(Math.pow(mod(n-2), 2));
}

However, now I need that the algorithm will receive a number and return the total sum up to it in the series (6- 29+5+2+1+1+0=38) I have no idea how to do this, I am trying but I am really unable to understand recursion so far, even if I wrote something right, how can I check it to be sure? And how generally to reach the right algorithm?

Using any extra parameters is forbidden.

Thanks in advance!

  • Put the funcion call inside a loop, no? or does it have to be recursive? – Óscar López Dec 6 '17 at 20:06
  • Has to be recursive. – איתן לוי Dec 6 '17 at 20:09
  • The example doesn't look right. 6-29+5+2+1+1+0 is not 38, and I'm wondering, how did that 6- end up there? – Óscar López Dec 6 '17 at 20:13
  • I meant that if n=6 it return 38. – איתן לוי Dec 6 '17 at 20:14
  • 1
    So you are saying that you have to calculate sum(n) = mod(n) + sum(n-1) with mod(n) = mod(n-1)^2 + mod(n-2)^2, but you have to do it with exactly one method with exactly one parameter? You can't create mod and sum as separate methods, or any other helper methods, and you can't add extra parameters as is often done for recursive methods. Did I understand that right? That constraints are that restrictive? – Andreas Dec 6 '17 at 20:30
4

We want:

mod(1) = 0
mod(2) = 0+1
mod(3) = 0+1+1
mod(4) = 0+1+1+2
mod(5) = 0+1+1+2+5
mod(6) = 0+1+1+2+5+29

and we know that each term is defined as something like:

   2^2+5^2=29

So to work out mod(7) we need to add the next term in the sequence x to mod(6).

Now we can work out the term using mod:

 x = term(5)^2 + term(6)^2
 term(5) = mod(5) - mod(4)
 term(6) = mod(6) - mod(5)
 x = (mod(5)-mod(4))^2 + (mod(6)-mod(5))^2

So we can work out mod(7) by evaluating mod(4),mod(5),mod(6) and combining the results.

Of course, this is going to be incredibly inefficient unless you memoize the function!

Example Python code:

def f(n):
    if n<=0:
        return 0
    if n==1:
        return 1
    a=f(n-1)
    b=f(n-2)
    c=f(n-3)
    return a+(a-b)**2+(b-c)**2

for n in range(10):
    print f(n)

prints:

0
1
2
4
9
38
904
751701
563697636866
317754178345850590849300
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  • 1
    @TNguyen I've added an implementation – Peter de Rivaz Dec 6 '17 at 21:13
  • Very nice approach - much more elegant than the hack I used! – sprinter Dec 6 '17 at 21:20
2

How about this? :)

class Main {

  public static void main(String[] args) {
    final int N = 6; // Your number here.
    System.out.println(result(N));
  }

  private static long result(final int n) {
    if (n == 0) {
      return 0;
    } else {
      return element(n) + result(n - 1);
    }
  }

  private static long element(final int n) {
    if (n == 1) {
      return 0L;
    } else if (n == 2) {
      return 1L;
    } else {
      return sqr(element(n - 2)) + sqr(element(n - 1));
    }
  }

  private static long sqr(final long x) {
    return x * x;
  }
}

Here is the idea that separate function (element) is responsible for finding n-th element in the sequence, and result is responsible for summing them up. Most probably there is a more efficient solution though. However, there is only one parameter.

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  • OP has said that adding extra method is not allowed. Stupid constraint in my opinion, but that's what OP said. – Andreas Dec 6 '17 at 21:09
  • Well, had fun solving anyways :) Going with one method seems to be quite advanced approach. – PresentProgrammer Dec 6 '17 at 21:16
2

I can think of a way of doing this with the constraints in your comments but it's a total hack. You need one method to do two things: find the current value and add previous values. One option is to use negative numbers to flag one of those function:

int f(int n) {
    if (n > 0)
        return f(-n) + f(n-1);
    else if (n > -2)
        return 0;
    else if (n == -2)
        return 1;
    else
        return f(n+1)*f(n+1)+f(n+2)*f(n+2);
}

The first 8 numbers output (before overflow) are:

0
1
2
4
9
38
904
751701

I don't recommend this solution but it does meet your constraints of being a single recursive method with a single argument.

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  • That is an impressive solution! – PresentProgrammer Dec 6 '17 at 21:10
  • this is incorrect: 0 -> 0 1 -> 0*0 + 1*1 = 1 2 -> 1*1 + 1*1 = 2 3 -> 2*2 + 1*1 = 5 4 -> 5*5 + 2*2 = 29 5-> 29*29 + 5*5 = 866 ... – zlakad Dec 6 '17 at 21:15
  • @zlakad any further details? – sprinter Dec 6 '17 at 21:16
  • @zlakad you haven't read the question properly. You are showing the terms but OP wants the sum of all terms. – sprinter Dec 6 '17 at 22:07
  • @sprinter I apologize - I didn't read the question to the end. – zlakad Dec 6 '17 at 22:51
0

Here is my proposal.

We know that:

f(n) = 0; n < 2

f(n) = 1; 2 >= n <= 3

f(n) = f(n-1)^2 + f(n-2)^2; n>3

So:

f(0)= 0
f(1)= 0
f(2)= f(1) + f(0) = 1
f(3)= f(2) + f(1) = 1
f(4)= f(3) + f(2) = 2
f(5)= f(4) + f(3) = 5
and so on

According with this behaivor we must implement a recursive function to return:

Total = sum f(n); n= 0:k; where k>0

I read you can use a static method but not use more than one parameter into the function. So, i used a static variable with the static method, just for control the execution of loop:

class Dummy 
{

    public static void main (String[] args) throws InterruptedException {

        int n=10;

        for(int i=1; i<=n; i++)
        {
            System.out.println("--------------------------");
            System.out.println("Total for n:" + i +" = " + Dummy.f(i));
        }
    }

    private static int counter = 0;
    public static long f(int n)
    {   
        counter++;

        if(counter == 1)
        {
            long total = 0;
            while(n>=0)
            {    
                total +=  f(n);
                n--;
            }
            counter--;
            return total;
        }

        long result = 0;
        long n1=0,n2=0;

        if(n >= 2 && n <=3)
            result++; //Increase 1
        else if(n>3)
        {
            n1 = f(n-1);
            n2 = f(n-2);

            result = n1*n1 + n2*n2;
        }

        counter--;
        return result;
    }
}

the output:

--------------------------
Total for n:1 = 0
--------------------------
Total for n:2 = 1
--------------------------
Total for n:3 = 2
--------------------------
Total for n:4 = 4
--------------------------
Total for n:5 = 9
--------------------------
Total for n:6 = 38
--------------------------
Total for n:7 = 904
--------------------------
Total for n:8 = 751701
--------------------------
Total for n:9 = 563697636866
--------------------------
Total for n:10 = 9011676203564263700

I hope it helps you.

UPDATE: Here is another version without a static method and has the same output:

class Dummy 
{

    public static void main (String[] args) throws InterruptedException {

        Dummy app = new Dummy();
        int n=10;

        for(int i=1; i<=n; i++)
        {
            System.out.println("--------------------------");
            System.out.println("Total for n:" + i +" = " + app.mod(i));
        }
    }

    private static int counter = 0;
    public long mod(int n)
    {   
        Dummy.counter++;

        if(counter == 1)
        {
            long total = 0;
            while(n>=0)
            {    
                total +=  mod(n);
                n--;
            }
            Dummy.counter--;
            return total;
        }

        long result = 0;
        long n1=0,n2=0;

        if(n >= 2 && n <=3)
            result++; //Increase 1
        else if(n>3)
        {
            n1 = mod(n-1);
            n2 = mod(n-2);

            result = n1*n1 + n2*n2;
        }

        Dummy.counter--;
        return result;
    }
}
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0

Non-recursive|Memoized You should not use recursion since it will not be good in performance. Use memoization instead.

def FibonacciModified(n):
    fib = [0]*n
    fib[0],fib[1]=0,1
    for idx in range(2,n):
        fib[idx] = fib[idx-1]**2 + fib[idx-2]**2
    return fib

if __name__ == '__main__':
    fib = FibonacciModified(8)
    for x in fib:
        print x

Output:

0
1
1
2
5
29
866
750797

The above will calculate every number in the series once[not more than that]. While in recursion an element in the series will be calculated multiple times irrespective of the fact that the number was calculated before.

http://www.geeksforgeeks.org/program-for-nth-fibonacci-number/

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