Probability of Survival [closed]

Question

There is an island represented by a matrix. You are somewhere on the island at location (x,y). If you jump n times, what is the probability you will survive? Survival means after n jumps you must be on the island.

My solution: I applied flood fill algorithm in which I allowed to move in all directions (i.e. N, W, E, S) and checked if before n jumps I was off the island then increment the failure counter, otherwise increment the success counter.

After iterating all the possible paths, the answer is ((success)/(success + failure)). It takes exponential time.

My question from you is can we do this problem in polynomial time, by using dynamic programming or any other programming technique? If yes, can you give me the concept behind that technique?

EDIT: MY CODE

#include<iostream>

using namespace std;

double probability_of_survival(int n, int m, int x, int y, int jumps) {
    int success = 0;
    int failure = 0;
    probability_of_survival_utility_func(n, m, x, y, 0, jumps, &sucess, &failure);
    return (double)((success)/(failure+success));
}

void probability_of_survival_utility_func(int n, int m, int x, int y, int jump_made, int jumps, int *success, int *failure) {
    if(x > m || x < 0 || y > n || y < 0) { (*failure)++; return;}
    if(jump_made == jumps) { (*success)++; return;}
    probability_of_survival_utility_func(n, m, x+1, y, jump_made++, jumps, success, failure);
    probability_of_survival_utility_func(n, m, x, y+1, jump_made++, jumps, success, failure);
    probability_of_survival_utility_func(n, m, x-1, y, jump_made++, jumps, success, failure);
    probability_of_survival_utility_func(n, m, x, y-1, jump_made++, jumps, success, failure);
}

Answer 1

The problem is neatly described by a Markov matrix. Translate the problem into a graph the following way. Map the rows of the matrix onto the coordinates, that is, for every possible (x,y) -> i. Build a symmetric adjacency matrix A such that (i,j)=1 if and only if the sites (x1,y1)->i, (x2,y2)->j are connected. All death sites will map to a single site and have the property such that A[i,i]=1, A[i,j!=i]=0 i.e it is an adsorbing states. Row normalize the matrix. With a starting vector p=[0,0,0,...,1,...,0,0] where the one corresponds to the starting position take the product:

 (A**k) . p

And sum over the live sites, this will give you the survival probability. For analysis, the number of note here is n, the number of alive sites on the island. Complexity is neatly bound, the most expensive operation is matrix exponentiation A**k. Naively this can be done in O(n**3 * k), but I suspect that you can diagonalize the matrix first at a cost of O(n**3) and exponentiate the eigenvalues.

Visual Example:

An island, with a red start point and it's adjacency matrix:

the calculated survival probability as a function of steps:

Python Implementation:

from numpy import *

# Define an example island
L = zeros((6,6),dtype=int)
L[1,1:2] = 1
L[2,1:4] = 1
L[3,1:5] = 1
L[4,2:4] = 1

# Identify alive sites
alive = zip(*where(L))
N = len(alive)

# Map the entries onto an index for easy access
ID = dict(zip(alive, range(N)))

# Create adj. matrix, the final index is the dead site
def connect(x, horz, vert):
    s = (x[0]+horz, x[1]+vert)
    if s not in ID: A[ID[x], N] += 1
    else          : A[ID[x], ID[s]] += 1
    
A = zeros((N+1,N+1))
for x in alive:
    connect(x,  1, 0)
    connect(x, -1, 0)
    connect(x,  0, 1)
    connect(x,  0,-1)

# Define the dead site as adsorbing, and row normalize
A[N,N] = 1
A /= A.sum(axis=1)[:,newaxis]


# Define the initial state
inital = (3,2)
p0 = zeros(N+1)
p0[ID[inital]] = 1

# Compute survival prob. as a function of steps
steps = 20
A2 = A.copy()
S = zeros(steps)
for t in xrange(steps):
    S[t] = 1-dot(A2.T,p0)[-1]
    A2   = dot(A2, A)

# Plot results
import pylab as plt
plt.subplot(121)
LSHOW = L.copy()
LSHOW[inital] = 2
plt.imshow(LSHOW,interpolation='nearest')
plt.subplot(122)
plt.imshow(A,interpolation='nearest')
plt.figure()
plt.plot(range(steps), S,'ro--')
plt.show()

Answer 2

f(x,y,0) = 0     if (x,y) is not in the island
           1     otherwise

f(x,y,i) = 0     if (x,y) is not in the island
           otherwise: 1/4 * f(x+1,y,i-1) + 
                      1/4 * f(x-1,y,i-1) + 
                      1/4 * f(x,y+1,i-1) + 
                      1/4 * f(x,y-1,i-1)

Using Dynamic programming you can create 2n+1 x 2n+1 x n+1 3-dimensional array,and filling it according to this formula, starting from i=0 and making you way up until i=n.

Your solution at the end is f(0,0,n) in the array. (Remmeber to set the original (x,y) as (0,0) in your coordinates, and make the needed adjustments).

Complexity is O(n^3) - the size of the matrix.

Note, this solution is pseudo-polynomial, so if any future answers shows this problem is NP-Hard (no idea if it is) - it does not contradict it.

P.S. For real implementations - if you need exact answer - be very careful when using double precision numbers - especially for large number of steps, since the carried numerical error might become significant.