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If I am given a sequence X = {x1,x2,....xm}, then I will have (2^m) subsequences. Can anyone please explain how can I arrive at this formula intuitively? I can start with 3 elements, then 4 and then 5 and arrive to this formula, but I don't think I understand. Where did the '2' come from? I am not dividing in half or anything here. Thank-you for the help.

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Is this homework? It sounds like homework to me. – GWW Mar 2 '11 at 18:35
3  
@GWW: I never had homework that said, "explain how this result can be arrived at intuitively". "Prove it's correct", sure. – Steve Jessop Mar 2 '11 at 18:38
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Lol..no. This is related to my algorithms course and I am studying for a homework, but this is a statement given in the book. I am trying to understand the concept behind the math, so that I can work on my own for new problems. Thanks for helping. – rgamber Mar 2 '11 at 19:03
up vote 10 down vote accepted

First of all, what you are talking about is called a set. Second, it is correct that the number of distinct sub-sets that can be generated out of a set is equal to 2^m where m is the number of elements in that set. We can arrive at this result if we take an example of 3 elements:

S = {a, b, c}

Now to generate every sub-set we can model the presence of an element using a binary digit:

xxx where x is either 0 or 1

Now lets enumerate all possibilities:

000 // empty sub-set
001
010
011
100
101
110
111 // the original set it self!

Lets take 011 as an example. The first digit is 0 then, a is not in this subset, but b and c do exist because their respective binary digits are 1's. Now, given m(e.g 3 in the above example) binary digits, how many binary numbers(sub-sets) can be generated? You should answer this question by now ;)

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6  
Pedantry alert: In a set, the ordering is not important. In a sequence, the ordering is important, but it's a single chosen ordering. So, they're not quite the same thing, but the answer to the number of subsets / subsequences is. The two problems map to each other. – John Mar 2 '11 at 18:50
    
Yes. I was asking this in the context of a sequence. Thanks @John! – rgamber Mar 2 '11 at 20:22

To anyone who is actually looking for a substring (as the title or URL might lead you to believe):

Subset: 2^n (Order doesn't matter in sets)
Subsequence: 2^n (Since we keep the original ordering, this is the same.)
Substring: n(n+1) * 1/2 (Elements must be consecutive)
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While this might be a valuable contribution, it doesn't answer the original poster's question, so it's best to post it as a comment rather than an answer. – Alexey Feldgendler Nov 25 '12 at 21:34

The value x_i can either be in the subsequence, or not. This is just like a bit. There are 2^m combinations for turning on / turning off the m numbers in the sequence.

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Where did the 2 come from? Every time you add one more element you double the number of possibilities.

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For any sequence X = {x1,x2,....xm}, there will be (2^m) sub-sequences, because you can "choose" sub-sequences of length 0,1,2,...,m ,i.e., mathematically it is

"C(m,0) + C(m,1) + ... C(m,m)" which leads to 2^m.

For e.g., say the string is "abc", then

C(3,0) = 1, ""

C(3,1) = 3, "a", "b", "c"

C(3,2) = 3, "ab", "bc", "ac"

C(3,3) = 1, "abc"

number of subsequences are 8 i.e., 2^3.

For more details visit http://en.wikipedia.org/wiki/Binomial_coefficient#Series_involving_binomial_coefficients

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Each subsequence is defined by choosing between selecting or not selecting each of the m elements. As there are m elements, each with two possible states, you get 2^m possibilities.

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I think what you are describing is not a sequence but a combination which is defined by a different formula. – Argote Mar 2 '11 at 18:41
    
Not at all. Maybe "possibilities" should be beter writen as "possible subsequences". – anumi Mar 2 '11 at 18:44
    
I'll side with anumi on this one. – John Mar 2 '11 at 18:53

For each element in a sequence of length m, you can either select it or leave it. Thus, there are 2 ways to deal with each element. Therefore, the total no. of ways to deal with all the m elements is 2*2*2...... m times = 2^m times.

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Each element is either in a subsequence or not. Therefore, starting with the first x1 there are two sets of subsets: those with x1 included and those without. Same can be done with the smaller sub-problem {x2,...,xm}. Therefore you finally yield 2^m.

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Basically you will have twice as many subsequences for each new number since you'll have (2^(m-1)) "equivalent" subsequences that are shifted one space to the right (assuming horizontal ordering and adding in the right) plus the subsequence of all elements.

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