Topic: Repeated and Non-Repeated Substitutions
Theorem 1. For the number of repeated substitutions =
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Theorem 1. For the number of repeated substitutions
= the formula is , here number of elements ,k -number of species. 1 - example. Two a. consists of one b and two c letters plot all the duplicates for the tuple. In this example, there are three (k = 3) and the number of letters is five (n = 5). = 2 (two α). = 1 (one b ) and = 2 (two c ). The first two interchange the positions of the letter (as well as the last two letters). if we replace, new replacements will not be created. All repetitive number of permutations All thirty of these permutations are listed below: aahcc, aachc, aacch, abacc. abcac, abcca , acubc.acacb, acbac, acbca, accab, accba , baacc, bacac, bacca, bcaac, beаса, bccaa . eaabc, caacb, cabac, cabca, cacab, cacba , cbaac, cbaca, ebeaa, ccaab.ccaba, ccbaa Non-repeated substitutions Based on the concept of a set. the place in question here we remind you that the substitutions do not repeat elements. Therefore, such substitutions are unique (not repeated) positions can also be called substitutions. All permutations for a given set of n elements it is accepted to denote the number by . For a set with one element {a}, there is only one position of the form a it is obvious that there is a substitution: Permutations from the elements of the two-element set {a,b} using the permutation a for the set {a} with one element we organize as follows: if element b is written after element a, then ab has substitution, and if written before ba has substitution we will be So, according to the multiplication rule, there are two permutations: Permutations are arranged for the three-element set {a,b,c} ab and ba are constructed for a two-element set {a,b} substitutions can be used c of the given set with three different ways of replacing the element ab and ba can be placed: after their elements, elcments between and before elements. Using the multiplication rule, three six different positions for the set with elements {a ,b ,c} we determine the formation of substitutions. They are: abc. acb, cab, hac. bca, cba. Given the four-element set {a,b,c,d}, the three-element set {a,b,c} d to each of the six substitutions made for the set Note that there are four ways to place the element then, according to the multiplication rule, we find Here are all the permutations: abcd, abdc, adbc. dabc , acbd, acdb, adcb, dacb , cabd, cadb, cdab, dcab . bacd, badc, bdac, dbac , bcad, hcda, bdca, dbca , cbad, chda, cdba, dcba. we find Here are all the permutations: Continuing in this way, “n is all space for a collection of elements all natural numbers with number of permutations from one to n It can be assumed that it is equal to the product of: . This the correctness of the hypothesis is proved in the following theorem 1. Determining the product of the first n natural numbers in the form of n accepted, that is, from the sign in such a sense first K. Kramp published in 1808 on algebra used in the manual. When n = 1 in the expression , only the number 1 is involved, therefore, 1!=1 is accepted as a definition. From this except when n = 0 and n! the expression loses its meaning altogether. However, 0!=1 is accepted as a definition. Download 161.77 Kb. Do'stlaringiz bilan baham: 
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