I was trying to find the longest palindrome in a string. The brute force solution takes O(n^3) time. I read that there is a linear time algorithm for it using suffix trees. I am familiar with suffix trees and am comfortable building them. How do you use the built suffix tree to find the longest palindrome.

I believe you need to proceed this way: Let y_{1}y_{2} ... y_{n} be your string (where y_{i} are letters). Create the generalized suffix tree of S_{f} = y_{1}y_{2} ... y_{n}$ and S_{r} = y_{n}y_{n  1} ... y_{1}# (reverse the letters and choose different ending characters for S_{f} ($) and S_{r} (#))... where S_{f} stands for "String, Forward" and S_{r} stands for "String, Reverse". For every suffix i in S_{f}, find the lowest common ancestor with the suffix n  i + 1 in S_{r}. What runs from the root till this lowest common ancestor is a palindrome, because now the lowest common ancestor represents the longest common prefix of these two suffixes. Recall that: (1) A prefix of a suffix is a substring. (2) A palindrome is a string identical to its reverse. (3) So the longest contained palindrome within a string is exactly the longest common substring of this string and its reverse. (4) Thus, the longest contained palindrome within a string is exactly the longest common prefix of all pairs of suffixes between a string and its reverse. This is what we're doing here. EXAMPLE Let's take the word banana. S_{f} = banana$ S_{r} = ananab# Below is the generalised suffix tree of S_{f} and S_{r}, where the number at the end of each path is the index of the corresponding suffix. There's a small mistake, the a common to all the 3 branches of Blue_4's parent should be on its entering edge, beside n: The lowest interior node in the tree is the longest common substring of this string and its reverse. Looking at all the interior nodes in the tree you will therefore find the longest palindrome. The longest palindrome is found between between Green_0 and Blue_1 (i.e., banana and anana) and is anana EDIT I've just found this paper that answers this question. 


The Linear solution can be found in this Way :: Prequisities: (1).You must know how to construct the suffix array in O(N) or O(NlogN) time. (2).You must know how to find the standard LCP Array ie. LCP between adjacent Suffixes i and i1 ie . LCP [i]=LCP(suffix i in sorted array, suffix i1 in sorted array) for (i>0). Let S be the Original String and S' be the reverse of Original String. Lets take S="banana" as an example. Then its Reverse string S'=ananab. Step 1: Concatenate S + # + S' to get String Str ,where # is an alphabet not present in original String.
Step 2: Now construct the Suffix Array of the string Str. In this example ,the suffix array is:
Please Note that a suffix array is an array of integers giving the starting positions of suffixes of a string in lexicographical order.So the Array that holds Index of starting position is a suffix Array. That is SuffixArray[]={6,5,11,3,9,1,7,12,0,4,10,2,8}; Step 3: As you had managed to construct the Suffix Array ,Now find the Longest Common Prefixes Between the adjacent suffixes.
Thus LCP array LCP={0,0,1,1,3,3,5,0,1,0,2,2,4}. Where LCP[i]=Length of Longest Common Prefix between Suffix i and suffix (i1). (for i>0) Step 4: Now you have constructed a LCP array ,Use the following Logic.
Execution Example ::
Just Make a Note :: The if condition in Step 4 basically refers that ,in each iteration(i) ,if I take the suffixes s1(i) and s2(i1) then ,"s1 must contains # and s2 must not contain # " OR "s2 must contains # and s1 must not contains # ".


DP solution:


