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Fundamental Principles of Counting
1. Multiplication Principle

If first operation can be performed in m ways and then a second operation can be performed in n ways. Then, the two operations taken together can be performed in mn ways. This can be extended to any finite number of operations.

2. Addition Principle

If first operation can be performed in m ways and another operation, which is independent of the first, can be performed in n ways. Then, either of the two operations can be performed in m + n ways. This can be extended to any finite number of exclusive events.

Factorial

For any natural number n, we define factorial as n ! or n = n(n – 1)(n – 2) … 3 x 2 x 1 and 0!= 1!= 1

Permutation

Each of the different arrangement which can be made by taking some or all of a number of things is called a permutation.

Mathematically  The number of ways of arranging n distinct objects in a row taking r (0 ≤ r ≤ n) at a time is denoted by P(n ,r) or npr

Properties of Permutation

     Permutation: Detailed Explanation | Mathematics (Maths) Class 11 - Commerce
Permutation: Detailed Explanation | Mathematics (Maths) Class 11 - Commerce

Important Results on’Permutation

  1. The number of permutations of n different things taken r at a time, allowing repetitions is nr.
  2.  The number of permutations of n different things taken all at a time is nPn= n! .
  3. The number of permutations of n things taken all at a time, in which p are alike of one kind, q are alike of second kind and r are alike of third kind and rest are different is n!/(p!q!r!)
  4. The number of permutations of n things of which p1 are alike of one kind p2 are alike of second kind, p3 are alike of third kind,…, Pr are alike of rth kind such that p1 + p2 + p3 +…+pr = n is n!/P1!P2!P3!….Pr!
  5. Number of permutations of n different things taken r at a time,
     when a particular thing is to be included in each arrangement is r.n – 1Pr – 1.
     when a particular thing is always excluded, then number of arrangements = n – 1Pr
  6. Number of permutations of n different things taken all at a time, when m specified things always come together is m!(n – m + 1)!.
  7. Number of permutations of n different things taken all at a time, when m specified things never come together is n! – m! x (n – m + 1)!.

Division into Groups

(i) The number of ways in which (m + n) different things can be divided into two groups which contain m and n things respectively [(m + n)!/m ! n !].

This can be extended to (m + n + p) different things divided into three groups of m, n, p things respectively [(m + n + p)!/m!n! p!].

(ii) The number of ways of dividing 2n different elements into two groups of n objects each is [(2n)!/(n!)2] , when the distinction can be made between the groups, i.e., if the order of group is important. This can be extended to 3n different elements into 3 groups is [(3n)!/((n!)3].

(iii) The number of ways of dividing 2n different elements into two groups of n object when no distinction can be made between the groups i.e., order of the group is not important is [(2n)!/2!(n!)2].

This can be extended to 3n different elements into 3 groups is [(3n)!/3!(n!)3].

The number of ways in which mn different things can be divided equally it into m groups, if order of the group is not important is [(mn)!/(n!)m!].

(v) If the order of the group is important, then number of ways of dividing mn different things equally into m distinct groups is mn [(mn)!/(n!)m]

(vi) The number of ways of dividing n different things into r groups is [rn — rC1(r — 1)nrC2(r — 2)n — rC3(r – 3)n + …].

(vii) The number of ways of dividing n different things into r groups taking into account the order of the groups and also the order of things in each group is n+r-1Pn = r(r + l)(r + 2) … (r + n – 1).

(viii) The number of ways of dividing n identical things among r persons such that each gets 1, 2, 3, … or k things is the coefficient of xn – r in the expansion of (1 + x + x2 + … + Xk-1)r.

Circular Permutation

In a circular permutation, firstly we fix the position of one of the objects and then arrange the other objects in all possible ways.

(i) Number of circular permutations at a time is (n -1)!. If clockwise taken as different. of n and different things taken anti-clockwise orders all are

(ii) Number of circular permutations of n different things taken all at a time, when clockwise or anti-clockwise order is not different 1/2(n – 1)!.

(iii) Number of circular permutations of n different things taken r at a time, when clockwise or anti-clockwise orders are take as different is nPr/r

(iv) Number of circular permutations of n different things taken r at a time, when clockwise or anti-clockwise orders are not different is nPr/2r.

(v) If we mark numbers 1 to n on chairs in a round table, then n persons sitting around table is n!.

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FAQs on Permutation: Detailed Explanation - Mathematics (Maths) Class 11 - Commerce

1. What is a permutation?
A permutation is an arrangement of objects or elements in a specific order. It is a way of selecting and ordering elements from a set, without repetition, to form a sequence or arrangement.
2. How do you calculate the number of permutations?
To calculate the number of permutations, you can use the formula: P(n, r) = n! / (n - r)! Where "n" represents the total number of objects or elements, and "r" represents the number of objects or elements chosen for the arrangement. The exclamation mark denotes the factorial function.
3. What is the difference between a permutation and a combination?
The main difference between a permutation and a combination is that in a permutation, the order of elements matters, while in a combination, the order does not matter. In other words, a permutation considers arrangements, while a combination considers selections. For example, if you have the numbers 1, 2, and 3, a permutation would include arrangements like 1-2-3, 2-1-3, 3-1-2, etc., whereas a combination would only include selections like 1-2-3, without considering the order.
4. Can repetitions be allowed in permutations?
No, in permutations, repetitions are not allowed. Each element can only be used once in a permutation. If repetitions were allowed, it would be considered a different concept called "permutation with repetition" or "permutation with replacement." For example, if you have the letters A, B, and C, a permutation without repetition would be ABC, while a permutation with repetition would include arrangements like AAA, AAB, BBA, etc.
5. In how many ways can you arrange the letters of the word "MISSISSIPPI"?
To calculate the number of ways to arrange the letters of the word "MISSISSIPPI," you need to consider the repetitions of each letter. The word contains 11 letters in total, with 4 repeats of "I," 4 repeats of "S," and 2 repeats of "P." Using the formula for permutations with repetition, the total number of arrangements would be: P(11, 4, 4, 2) = 11! / (4! * 4! * 2!) = 34,650 ways.
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