I am trying to come up with a dynamic programming algorithm that finds the largest sub matrix within a matrix that consists of the same number:
example:
{5 5 8}
{5 5 7}
{3 4 1}
Answer : 4 elements due to the matrix
5 5
5 5
I am trying to come up with a dynamic programming algorithm that finds the largest sub matrix within a matrix that consists of the same number: example:
Answer : 4 elements due to the matrix



This is a question I already answered here (and here, modified version). In both cases the algorithm was applied to binary case (zeros and ones), but the modification for arbitrary numbers is quite easy (but sorry, I keep the images for the binary version of the problem). You can do this very efficiently by two pass linear Algorithm (pictures depict binary case): Say you want to find largest rectangle of free (white) elements. Here follows the two pass linear 1) in a first pass, go by columns, from bottom to top, and for each element, denote the number of consecutive elements available up to this one: repeat, until: Pictures depict the binary case. In case of arbitrary numbers you hold 2 matrices  first with the original numbers and second with the auxiliary numbers that are filled in the image above. You have to check the original matrix and if you find a number different from the previous one, you just start the numbering (in the auxiliary matrix) again from 1. 2) in a second pass you go by rows, holding data structure of potential rectangles, i.e. the rectangles containing current position somewhere at the top edge. See the following picture (current position is red, 3 potential rectangles  purple  height 1, green  height 2 and yellow  height 3): For each rectangle we keep its height Pseudocode of 2nd pass (nonbinary version with arbitrary numbers):
The function for closing rectangles:
This way you can also get all maximum rectangles. So in the end you get: And what the complexity will be? You see that the function So the whole complexity is 


A dynamic solution: Define a new matrix case 1: none of the right or bottom neighbour elements in the original matrix are equal to the current one, i.e: case 2: the neighbour element to the right is equal to the current one but the bottom one is different, the value of case 3: the neighbour element to the bottom is equal but the right one is different, case 4: both neighbours are equal: the size of the largest matrix that has the upper left corner at the bottom row and the rightmost column elements are treated as if their neighbours to the bottom and to the right respectively are different in your example, the resulting matrix
being 


Modification to the above answer: Define a new matrix A wich will store in A[i,j] two values: the width and the height of the largest submatrix with the left upper corner at i,j, fill this matrix starting from the bottom right corner, by rows bottom to top. You'll find four cases: case 1: none of the right or bottom neighbour elements in the original matrix are equal to the current one, i.e: M[i,j] != M[i+1,j] and M[i,j] != M[i,j+1] being M the original matrix, in this case, the value of A[i,j] is 1x1 case 2: the neighbour element to the right is equal to the current one but the bottom one is different, the value of A[i,j].width is A[i+1,j].width+1 and A[i,j].height=1 case 3: the neighbour element to the bottom is equal but the right one is different, A[i,j].width=1, A[i,j].height=A[i,j+1].height+1 case 4: both neighbours are equal: Three rectangles are considered: 1. A[i,j].width=A[i,j+1].width+1; A[i,j].height=1;
The one with the max area in the above three cases will be considered to represent the rectangle at this position. The size of the largest matrix that has the upper left corner at i,j is A[i,j].width*A[i,j].height so you can update the max value found while calculating the A[i,j] the bottom row and the rightmost column elements are treated as if their neighbours to the bottom and to the right respectively are different. 

