# Tag Info

## New answers tagged fibonacci

1

I suspect this is the troublesome line: MOV R0,#Stdout Because of where it is, it only gets executed after an even number is printed - if R0 contains the wrong value initially, the "2" is probably being printed to the wrong place. By the time you get to the next value ("8"), R0 has been set (and presumably nothing else touches it so it stays that way) so ...

3

You should declare sum and result outside for loop. Try this: function fibonacciSum(){ var i; var fib = new Array (); fib[0] = 0; fib[1] = 1; var sum = 0; var result = 0; for(i=2; i<=10; i++){ fib[i] = fib[i-2] + fib[i-1]; var number = fib[i]; if (number % 2 == 0) { result = sum ...

2

In your solution, each run of the for loop resets "sum" with the line: var sum = 0;. Set it to 0 outside the loop. function fibonacciSum(){ var i; var fib = new Array (); fib[0] = 0; fib[1] = 1; var sum = 0; for(i=2; i<=10; i++){ fib[i] = fib[i-2] + fib[i-1]; var number = parseInt(fib[i]); ...

3

var sum = 0; This is in your loop resetting the sum on every iteration. It has to be outside the loop.

0

May this Help def fibo(n): result = [] a, b = 0, 1 while b < n: result.append(b) a, b = b, b + a return result

1

Fibonacci series start with 1. At that part code checks whether the given value is smaller than or equals to 1 or not. 1 1 2 3 5 8 13 ... As you can see the Fibonacci function is a partial function:

1

Let's break this down a bit: (n <= 1) and 1 or (fib(n - 1) + fib(n - 2)) This is a way that python programmers used to emulate the conditional ternary operator that is typically available in C but not in Python. So basically the condition shows that if n is less than equal to 1, return 1, or do fib(n - 1) + fib(n - 2). Second question: This has to ...

0

This may help you. def fib_upto(max) i1, i2 = 1, 1 while i1 <= max yield i1 i1, i2 = i2, i1+i2 end end fib_upto(5) {|f| print f, " "}

3

I was intrigued by two aspects of Niklas B.'s answer: the speed of the computation (even for huge numbers), and the tendency of the results to have small prime factors. These hint that the solution can be computed as a product of small terms, and that indeed turns out to be the case. To explain what's going on, I need some notation and terminology. For ...

1

You are encountering integer overflow, meaning that you are trying to calculate a number that is outsize of the bounds of INT_MAX and INT_MIN. In the case of an unsigned number, it just overflows to zero and starts over, while in the case of a signed integer, it rolls over to INT_MIN. In both cases this is referred to as integer overflow or integer ...

2

When you get to the 47th value, the numbers go out of int range. The maximum int value is 2,147,483,647 and the 46th number is just below at 1,836,311,903. The 47th number exceeds the maximum with 2,971,215,073. Also, as LeonardBlunderbuss mentioned, you are exceeding the range of the vector with the for loop that you have. Vectors start with 0, and so by ...

1

F(n) / \ F(n-1) F(n-2) / \ / \ F(n-2) F(n-3) F(n-3) F(n-4) / \ F(n-3) F(n-4) Important point to note is this algorithm is exponential because it does not store the result of ...

1

F(n) / \ F(n-1) F(n-2) / \ / \ F(n-2) F(n-3) F(n-3) F(n-4) / \ F(n-3) F(n-4) Notice that many computations are repeated! Important point to note is this algorithm is exponential ...

5

Let's prove some stuff about numbers: Lemma 1: Let n ≥ 1 be an integer and Fib(i) be the largest Fibonacci number with Fib(i) ≤ n. Then in a representation of n as a sum of Fibonacci numbers with distinct indices, either Fib(i) or Fib(i - 1) appears, but not both. Proof: We can show by induction that the sum Fib(1) + Fib(2) + ... + Fib(i - 2) = Fib(i) - 1. ...

0

One of naive possibilities in python (works up to 10^6 in reasonable time) def nfibhelper(fibm1,fibm2,n): fib = fibm1 + fibm2 if fib > n: return 0 r=0 if n == fib : r+=1 return r + nfibhelper(fibm2,fib,n-fib) + nfibhelper(fibm2,fib,n) def F(n): return nfibhelper(1,0,n) ##1 will be used twice as fib

1

You can find the lexicographically largest 0/1 representation in Fibonacci-base by taking the largest Fibonacci number less than or equal your number, subtract that and then take the next largest Fibonacci number less than or equal to the remainder, etc. Then the question is how to find all other 0/1 representations in Fibonacci-base from the ...

0

This is an old question, but just in case someone happens to pass by this might be helpful. If you need a efficient method to get the nth Fibonacci number, we have a O(1) time complexity procedure. It is based on Binet's formula, which I think our friends over at math.se will be better at proving, so feel free to follow that link. The formula itself is, ...

1

From awesomemath.org > It's a long known fact, that Fibonacci sequence modulo N is periodic (Not that long known fact is that the period is called Pisano Period) Thus, to calculate F(C(N,R)) % m, one needs to calculate F(pi(C(N,R))) % m. CnR can be calculated mod PI at least by forming two arrays for nominators and denominators, consisting of numbers ...

2

Let f(n) be the number of calls to Fib(2) when computing Fib(n). Then, f(2) = 1, f(3) = 1, and for k > 3, f(k) = f(k-1) + f(k-2). This is the same recurrence relation as Fib itself, and you get the solution f(k) = Fib(k-1). For the particular case k=7, you get the solution Fib(6) = 8. This generalises: the number of calls to Fib(m) when computing Fib(n) ...

1

For the fun of it, in Python: def fib(n): def fib2(n): count[n] = count.get(n,0)+1 if n < 2: return n else: return fib2(n-1) + fib2(n-2) count = {} return fib2(n), [(c, count[c]) for c in sorted(count)] print(fib(7)) prints => (13, [(0, 8), (1, 13), (2, 8), (3, 5), (4, 3), (5, 2), (6, ...

4

Typically I'd be against posting an answer to a homework question like this, but everything posted so far seems to be overcomplicating things. As said in the comments above, you should just use recursion to solve the problem like you would do iteratively. Here's the iterative solution: def fib(n): a, b = 0, 1 while n > 0: a, b = b, a+b n -= ...

0

To solve this in linear time, you must use a dynamic programming technique known as memoization. The algorithm for Fibonacci in pseudo-code, using memoization, looks like this: memoryMap[n] func fib(int n) if (n is in memoryMap) then return memoryMap[n] if (n <= 1) then memoryMap[n] = n else memoryMap[n] = fib(n-1) + ...

0

I am not a programmer, but here's an adaptation to Leffler's code without the IF-criterion. It should work for MAX_VALUES above 2 (given there are no mistakes in programming syntax), based on a pattern I found in the even-only fibonacci series: 0,2,8,34,144,610,2584... so interestingly: f_n2 = 4*f_n1 + f_n0. This also means this program only needs 1/3rd of ...

1

The proof answers are good, but I always have to do a few iterations by hand to really convince myself. So I drew out a small calling tree on my whiteboard, and started counting the nodes. I split my counts out into total nodes, leaf nodes, and interior nodes. Here's what I got: IN | OUT | TOT | LEAF | INT 1 | 1 | 1 | 1 | 0 2 | 1 | 1 | 1 ...

2

Here's an implementation of your pseudocode in Python (almost copy-paste): def Fib(n): if n == 0 or n == 1: f = n else: f = Fib(n-1) + Fib(n - 2) return f print Fib(7) Now, I add the following lines: if n == 2: print 'Fib(2)' and the result is: Fib(2) Fib(2) Fib(2) Fib(2) Fib(2) Fib(2) Fib(2) Fib(2) 13 Which means ...

0

I was not going to post the actual algorithm (see my comment to his question earlier), but then I saw an unnecessarily complex version being posted. In contrast, I'll post the concise implementation. Note this one returns the sequence starting with 1,1,2. Another variant starts with 0,1,1,2 but is otherwise equivalent. The function assumes an input value of ...

1

Here is one method, note that this also includes the negafibonacci sequence; private static Map<Integer, BigInteger> fibCache = new HashMap<Integer, BigInteger>(); public static BigInteger fib(int n) { // Uses the following identities, fib(0) = 0, fib(1) = 1 and fib(2) = 1 // All other values are calculated through recursion. ...

1

Type long long is guaranteed to be at least 64 bits (and is exactly 64 bits on every implementation I've seen). Its maximum value, LLONG_MAX is at least 263-1, or 9223372036854775807, which is 19 decimal digits -- so long longis more than big enough to represent 15-digit numbers. Just use type long long consistently. In your code, you have one variable of ...

1

Change your for loop to this: for( n=2; n<num; n++ ) That'll solve your problem. Explanation: Since you've already determined that 1 or 2 will give you a 1, start your loop @ 2. Loop through until n becomes larger than the entered number. This will solve the problem you were having.

2

You're stopping the loop when n reaches beyond prev, so you aren't getting the correct number. Stop it when you've passed num instead: for(n = 1; n <= num; n++) { Example run: Input number: 6 21

0

If you want to get the fiboniki number times the user has given input then you need to iterate in for loop. for( n=1; n<=num; n++ ) { sum = prev + next; prev = next; next = sum; System.out.println(sum); } Also to print the number you need to put it in ...

0

Similar: def fibonacci(n): f=[1]+[0] for i in range(n): f=[sum(f)] + f[:-1] print f[1]

1

You have to create an array, for example: int[] simpleArray; simpleArray = new int[numToPrint]; At the place of System.out.println(lokaT); System.out.println(nuverandiT); Put: simpleArray[0] = lokaT; simpleArray[1] = nuverandiT; And inside your loop, you put instead this: System.out.println(nuverandiT); This: simpleArray[i] = nuverandiT;

0

I'm guessing when you say 'print out into an array' you really mean you just want to store the values in an array. In that case, Before your for loop: int[] array = new int[numToPrint]; And inside your for loop: array[i-2] = nuverandiT; If you wanted to print the numbers once they've been stored in an array, you would probably want to loop through it ...

2

Actually O(2^n) is overshooting it a bit (but still correct, since big-O is an upper bound), it's more like ~θ(1.6^n). Try to picture a recursion tree. Every node splits into 2, and the depth of the tree is n, so it ends up as about O(2^n). Similarly, the O(3^n) example, every node splits into 3, and the depth is still n. But for O(3^n), I'd rather ...

2

This previous answer should persuade you about Fibonacci's sequence algorithm time complexity. Then, based on that same answer principle, your new sequence algorithm can be represented as T(n) = T(n-1) + T(n-2) + T(n-3) = ( T(n-2)+T(n-3)+T(n-4) )+( T(n-3)+T(n-4)+T(n-5) )+( T(n-4)+T(n-5)+T(n-6) ) = ... you see that each node creates 3 new nodes. That ...

3

The community can answer your specific question, but a better solution is to help you develop some debugging skills. When something doesn't work, you need to drill down and find out where the failure is. Since you're new to ARM assembly, try doing small chunks at a time and then putting them together to form the complete program. Can you write a program ...

2

This is the most elegant solution i've encountered: def is_fibonacci(n): phi = 0.5 + 0.5 * math.sqrt(5.0) a = phi * n return n == 0 or abs(round(a) - a) < 1.0 / n The code is not mine, was posted by @sven-marnach. The original post: check-input-that-belong-to-fibonacci-numbers-in-python

0

nth term in fibonacci series is: where and Using the above identity in, the series can be generated using list comprehension: [int(((((1 + math.sqrt(5)) / 2) ** x) - (((1 - math.sqrt(5)) / 2) ** (x))) / math.sqrt(5)) for x in range(n)] //where n is the number of terms in the series

1

You may need to brush up your python basics, there is a lot of nonsense in your code. That being said this code puts the first 700 fibonacci numbers in a list (you should use meaningful variable names!) fibonacci_numbers = [0, 1] for i in range(2,700): fibonacci_numbers.append(fibonacci_numbers[i-1]+fibonacci_numbers[i-2]) Note: If you're using Python ...

2

You may want this: In [77]: a = 0 ...: b = 1 ...: while b < 700: ...: a, b = b, a+b ...: print a, b 1 1 1 2 2 3 3 5 5 8 8 13 13 21 21 34 34 55 55 89 89 144 144 233 233 377 377 610 610 987 If you wanna store the results in a list, use list.append: In [81]: a = 0 ...: b = 1 ...: fibo=[a, b] ...: while b < 70: ...

0

Expanding on @Michael's comment. Immediate values in ARM data processing instructions may be any positive integer with a 32 bit binary representation whose 1s fit into a 2 bit aligned 8 bit block (which may wrap around at bit 0). Some examples 0b00000000111111110000000000000000 ; valid 0b10010000000000000000000000000011 ; valid ...

1

This solution uses the Iterator interface. When run it calculates all fibonacci numbers in the long range. The accepted answer is doubly exponential time since it's O(n^2) for each call. On my computer changing n to 93 to do the same as my program it will use several hours to compute the same list this code does in 0.09 seconds. import java.util.Iterator; ...

1

I think the standard solution for Fibonacci would look like the following: public class Fibonacci { public long fibo(long n){ if(n == 0) return 0; if(n == 1) return 1; else return fibo(n-1) + fibo(n-2); } public static void main(String...args){ int n = 20; ...

0

I've figured that this can be done by using Newton- Raphson method, i have replaced the code in the function isperfect() with Newton-Raphson formula code, removed assertion and it worked. Thanks for all your help. Here's the final code: def isperfect(n): x = n y = (x + n // x) // 2 while y < x: x = y y = (x + n // x) // 2 ...

1

Well you have know limit, because you have to know how many numbers you want to print. public class Fibonacci { public int limit = 10; public int left=0, right=1; public int next; public void countNextFibo(int limit) { if(this.limit==0) { return; } else { System.out.print(left+", "); ...

0

I have written a small code to compute Fibonacci for large number which is faster than conversational recursion way. I am using memorizing technique to get last Fibonacci number instead of recomputing it. public class FabSeries { private static Map memo = new TreeMap<>(); public static BigInteger fabMemorizingTech(BigInteger n) { BigInteger ...

1

The runtime error is apparently due to an exception, but Codechef does not provide any more information. It could be various things including divide by zero, memory exhaustion, assertion failure, ... Although your program works for many common numbers, it doesn't handle all the inputs that the Codechef constraints allow. In particular, the number to be ...

0

This is going to be a very efficient way of doing it. In [65]: import scipy.optimize as so from numpy import * In [66]: def fib(n): s5=sqrt(5.) return sqrt(0.2)*(((1+s5)/2.)**n-((1-s5)/2.)**n) def apx_fib(n): s5=sqrt(5.) return sqrt(0.2)*(0.5*(1+s5))**n def solve_fib(f): _f=lambda x, y: (apx_fib(x)-y)**2 return so.fmin_slsqp(_f,0., ...

2

The simplest way to do that is: fib a b = a: fib b (a+b) This stems from the inductive definition of the Fibonacci series: suppose we have a function that can produce a stream of Fibonacci numbers from Fi onwards, given Fi and Fi+1. What could that function look like? Well, Fi is given, and the rest of the stream can be computed using this function to ...

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