Number of different values that obtain from a given set. Suppose S={1,2,…,7}, already we know that, S have 2^7 subsets.

cyrilicesj

cyrilicesj

Answered question

2022-09-04

Number of different values that obtain from a given set
Suppose S = { 1 , 2 , , 7 }, already we know that, S have 2 7 subsets. But the problem is, when we multiply elements of each subset S, how many different value we can obtain from multiplication of elements of each subsets? In 2 7 subsets, some of them are equal, for example, for subset of size 2, 3 × 4 = 6 × 2. Are there a simple way that eliminate the duplicate values for any subsets?

Answer & Explanation

enreciarpv

enreciarpv

Beginner2022-09-05Added 18 answers

Step 1
7 ! = 2 4 3 2 5 1 7 1 has ( 4 + 1 ) ( 2 + 1 ) ( 1 + 1 ) ( 1 + 1 ) = 60 divisors
Of these, the divisors who are multiples of 2 4 but not multiples of 3 are not possible to make (as 6 would have been needed for that last factor of 2 and would have brought a factor of 3 along with it) as well as the divisors who are multiples of 9 but not multiples of 2 are not possible (for a similar reason).
Step 2
There are 2 2 = 4 factors who are multiples of 2 4 but not multiples of 3 (seen by looking at factors of the form 2 4 3 0 5 z 7 w ) and similarly there are 2 2 = 4 factors who are multiples of 9 but not multiples of 2 (looking at 2 0 3 2 5 z 7 w ).
As such the total will be
60 4 4 = 52
Conner Singleton

Conner Singleton

Beginner2022-09-06Added 13 answers

Step 1
Since 1 has no effect in the multiplications you can put it aside. Put the number 6 aside for now. Factorize all the other numbers. The multiplication of the elements of any nonempty subset of {2,3,4,5,7} would be of the form
2 x × 3 y × 5 z × 7 w where x and y and z and w are whole numbers and 0 x 3 and 0 y 1 and 0 z 1 and 0 w 1. As a result of the multiplication principle, you can say that there are 4 × 2 × 2 × 2 = 32 such multiplications. Now what if we play the number 6 into the game?
Step 2
Then any multiplication would be of the form
2 x + 1 × 3 y + 1 × 5 z × 7 w
where x and y and z and w are whole numbers and 0 x 3 and 0 y 1 and 0 z 1and 0 w 1. However, if 0 x 2 and y = 0 no new state will be generated and vice versa so you should suppose either x = 3 or y = 1. You can deduce from the inclusion-exclusion principle that the number of the new states will be 2 × 2 × 2 + 4 × 2 × 2 2 × 2 = 20. So overall the answer would be 32 + 20 = 52.

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