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I have the following 2 strings:

String A: Manchester United
String B: Manchester Utd

Both strings means the same, but contains different values.

How can I compare these string to have a "matching score" like, in the case, the first word is similar, "Manchester" and the second words contain similar letters, but not in the right place.

Is there any simple algorithm that returns the "matching score" after I supply 2 strings?

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1  
I like this question, something can be done with regex but the way question is asked seems more about IA. I wish my computer knew that when I say "Yellow" or "the color of the lemon" I mean the same thing :DD –  Davide Piras May 8 '12 at 9:23
1  
One way to measure the difference between two strings is to calculate the en.wikipedia.org/wiki/Levenshtein_distance. However - what you want sounds more like a comparison of meaning - which is far more difficult. –  Dave Bish May 8 '12 at 9:25
    
possible duplicate of How can I measure the similarity between 2 strings? –  ChrisF May 8 '12 at 9:29
1  
Folks, your answers need to include more than just a link. Link-only answers are strongly discouraged here. –  Cody Gray May 8 '12 at 9:29
    
The answer I gave to this question may be helpful: stackoverflow.com/questions/9014045/… –  Tim Medora May 8 '12 at 9:31

5 Answers 5

You could calculate the Levenshtein distance between the two strings and if it is smaller than some value (that you must define) you may consider them to be pretty close.

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Take a look at this article, which explains how to do it and gives sample code too :)

Fuzzy Matching (Levenshtein Distance)

Update:

Here is the method code that takes two strings as parameters and calculates the "Levenshtein Distance" of the two strings

public static int Compute(string s, string t)
    {
    int n = s.Length;
    int m = t.Length;
    int[,] d = new int[n + 1, m + 1];

    // Step 1
    if (n == 0)
    {
        return m;
    }

    if (m == 0)
    {
        return n;
    }

    // Step 2
    for (int i = 0; i <= n; d[i, 0] = i++)
    {
    }

    for (int j = 0; j <= m; d[0, j] = j++)
    {
    }

    // Step 3
    for (int i = 1; i <= n; i++)
    {
        //Step 4
        for (int j = 1; j <= m; j++)
        {
        // Step 5
        int cost = (t[j - 1] == s[i - 1]) ? 0 : 1;

        // Step 6
        d[i, j] = Math.Min(
            Math.Min(d[i - 1, j] + 1, d[i, j - 1] + 1),
            d[i - 1, j - 1] + cost);
        }
    }
    // Step 7
    return d[n, m];
    }
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Link only answers aren't good answers. Please explain why and how this answers the question. –  ChrisF May 8 '12 at 9:27

I've needed to do something like this and used Levenshtein distance.

I used it for a SQL Server UDF which is being used in queries with more than a million of rows (and texts of up to 6 or 7 words).

I found that the algorithm runs faster and the "similarity index" is more precise if you compare each word separately. I.e. you split each input string in words, and compare each word of one input string to each word of the other input string.

Remember that Levenshtein gives the difference, and you have to convert it to a "similarity index". I used something like distance divided by the length of the longest word (but with some variations)

You must also consider if there must be the same number of words in both inputs, or it can change, and if the order must be the same on both inputs, or it can change. Depending on this the algorithm changes.

I also weighted the longer words higher than the shorter words to get the global similarity index. (My algorithm took the longest of the two words in the compared pair, and gave a higher weight to the longest pairs than to the shortest ones, not exactly proportional to the pair length).

With this example, which uses different number of words:

  • compare "Manchester United" to "Manchester Utd FC"

If the same order of the words in both inputs is guaranteed, you should compare these pairs:

Manchester United
Manchester Utd    FC

Manchester-Manchester Utd-United FC: not compared

Manchester     United
Manchester Utd FC

Manchester-Manchester Utd: not compared United-FC

           Machester United
Manchester Utd       FC

Mancheter: not compared Manchester-Utd United-FC

Obviously, the highest score would be for the first set of pairs.

To compare words in the same order, you can use a loop to create a vector that represents the pairs to be compared like so (note: this represents a text of 5 words A,B,C,D,E, comapared to a text of 3 words a,b,c)

A,B,C,D,E  A,B,C,D,E  A,B,C,D,E  A,B,C,D,E  A,B,C,D,E  A,B,C,D,E
a,b,c      a,b,  c    a,b,    c  a,  b,c    a,  b,  c  a,    b,c
0 1 2      0 1   3    0 1     4  0   2 3    0   2   4  0     3 4

A,B,C,D,E  A,B,C,D,E  A,B,C,D,E  A,B,C,D,E
  a,b,c      a,b,  c    a,  b,c      a,b,c
  1 2 3      1 2   4    1   3 4      2 3 4

The numbers in the sample, are vectors that have the indices of the first set of words which must be comapred with the indices in the first set. i.e. v[0]=0, means compare index 0 of the short set (a) to index 0 of the long set (A), v[1]=2 means compare index 1 of the short (b) set to index 2 of the long set (C), and so on.

To calculate this vectors, simply start with 0,1,2. Move the latest index that can be moved until it can no longer be moved:

0,1,2 -> 0,1,3 -> 0,1,4 
No more moves possible, move the previous index, and restore the others
to the lowest possible values (move 1 to 2, restore 4 to 3)

0,2,3 -> 0,2,4
No more moves possible of the last, move the one before the last

0,3,4
No more moves possible of the last, move the onre before the last
Not possible, move the one before the one before the last, and reset the others:

1,2,3 -> 1,2,4

And so on.

Then calculate the similarity of the pairs repsented for each vector, and keep the highest score. You can specify a minimum similarity so that you calculate only the tuples until you find that minimum similarity. (If not minimun specified, if you find 100% similarity, stop comparing pairs).

If there can be changes in the order, you need to compare each word of the first set with each word of the second set, and take the highest scores for the combinations of results, which include all the words of the shortest pair ordered in all the possible ways, compared to different words of the second pair. For this you can populate the upper or lower triangle of a matrix of (n X m) elements, and then take the required elements from the matrix.

I tried Hamming distance and the results were lest accurate.

You must also normalize the word before comparison, like so:

  • if not case-sensitive convert all the words to upper or lower case
  • if not accent sensitive, remove accents in all the words
  • if you know that there are usual abbreviations, you can also normalized them, to the abbreviation to speed it up (i.e. convert united to utd, not utd to united)

To optmize the procedure, I cached whichever I could, i.e. the comparison vectors for different sizes (The vectors 0,1,2-0,1,3,-0,1,4-0,2,3, in the ABCDE-abc, ect. for lengths 3,5 would be calculated on first use and recycled for all the 3 words to 5 words incoming comparisons)

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Detecting duplicates sometimes might be a "little" more complicated than computing Levenshtein dinstance. Consider following example:

1. Jeff, Lynch, Maverick, Road, 181, Woodstock  
2. Jeff, Alf., Lynch, Maverick, Rd, Woodstock, NY

This duplicates can be matched by complicated clustering algorithms.

For further information you might want to check some research papers like "Effective Incremental Clustering for Duplicate Detection in Large Databases".

(Example is from the paper)

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What you are looking for is a string similarity measure. There are multiple ways of doing this:

  1. Edit Distances between two strings (as in Answer #1)
  2. Converting the strings into sets of characters (generally on bigrams or words) and then calculating Bruce Coefficient or Dice Coefficient on the two sets.
  3. Projecting the strings into term vectors (either on words or bigrams) and calculating the Cosine Distance between the two vectors.

I generally find the option #2 to be the easiest to implement and if your strings are phrases then you can simply tokenize them on word-boundaries. In all the above cases, you might want to first remove the stop words (common words like and, a,the etc) before tokenizing. Update: Links

Dice Coefficient

Cosine Similarity

Implementing Naive Similarity engine in C# *Warning: shameless Self Promotion

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It would be great if you pointed out where to find information on Bruce and Dice coefficient, and the Cosine distance. We, "normal people" don't know what they are. –  JotaBe May 8 '12 at 10:05

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