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 Page 1


6.3 Solutions in Non-negative Integers
De?nition 6.3.1. [Solution in nonnegative integers] Recall that N
0
:= N?{0}. A point
p = (p
1
,...,p
k
)?N
k
0
with p
1
+···+p
k
=n is called a solution of the equation x
1
+···+x
k
=n
in nonnegative integers or a solution of x
1
+··· +x
k
= n in N
0
. Two solutions (p
1
,...,p
k
)
and (q
1
,...,q
k
) are said to be the same if p
i
= q
i
, for each i = 1,...,k. Thus, (5,0,0,5) and
(0,0,5,5) are two di?erent solutions of x+y+z+t = 10 inN
0
.
Example 6.3.2. Determine the number of
1. words which uses 3 A’s and 6 B’s.
2. arrangements of 3 A’s and 6 B’s.
3. distinct strings that can be formed using 3 A’s and 6 B’s.
4. solutions of the equation x
1
+x
2
+x
3
+x
4
= 6, where each x
i
?N
0
and 0=x
i
= 6.
5. ways of placing 6 indistinguishable balls into 4 distinguishable boxes.
6. 3 subsets of an 9-set.
Solution: Observe that all the problems correspond to forming strings using +’s (or|’s
or bars) and 1’s (or balls or dots) in place of A’a and B’s, respectively?
Page 2


6.3 Solutions in Non-negative Integers
De?nition 6.3.1. [Solution in nonnegative integers] Recall that N
0
:= N?{0}. A point
p = (p
1
,...,p
k
)?N
k
0
with p
1
+···+p
k
=n is called a solution of the equation x
1
+···+x
k
=n
in nonnegative integers or a solution of x
1
+··· +x
k
= n in N
0
. Two solutions (p
1
,...,p
k
)
and (q
1
,...,q
k
) are said to be the same if p
i
= q
i
, for each i = 1,...,k. Thus, (5,0,0,5) and
(0,0,5,5) are two di?erent solutions of x+y+z+t = 10 inN
0
.
Example 6.3.2. Determine the number of
1. words which uses 3 A’s and 6 B’s.
2. arrangements of 3 A’s and 6 B’s.
3. distinct strings that can be formed using 3 A’s and 6 B’s.
4. solutions of the equation x
1
+x
2
+x
3
+x
4
= 6, where each x
i
?N
0
and 0=x
i
= 6.
5. ways of placing 6 indistinguishable balls into 4 distinguishable boxes.
6. 3 subsets of an 9-set.
Solution: Observe that all the problems correspond to forming strings using +’s (or|’s
or bars) and 1’s (or balls or dots) in place of A’a and B’s, respectively?
DRAFT
ABBBABABB
ABBBBBAAB
BBABBBABA
+111+1+11 = 0+3+1+2
+11111++1 = 0+5+0+1
11+111+1+ = 2+3+1+0
|• • •| • |• •
|• • • • •|| •
• •|• • •|•|
Figure 6.2: Understanding the three problems
Note that the A’s are indistinguishable among themselves and the same holds for B’s.
Thus, we need to ?nd 3 places, from the 9 = 3+6 places, for the A’s. Hence, the answer
is C(9,3). The answer will remain the same as we just need to replace A’s with +’s (or
|’s) and B’s with 1’s (or balls) in any string of 3 A’s and 6B’s. See Figure 6.2 or note that
four numbers can be added using 3 +’s or four adjacent boxes can be created by putting
3 vertical lines or|’s.
In general, we have the following result.
Theorem 6.3.3. [solutions in N
0
] The number of solutions of x
1
+··· + x
r
= n in N
0
is
C(n+r-1,n).
Proof. Each solution (x
1
,...,x
r
) may be viewed as an arrangement of n dots and r-1 bars.
‘Put x
1
many dots; put a bar; put x
2
many dots; put another bar; continue; and end by
putting x
r
many dots.’
For example, (0,2,1,0,0) is associated to|••|•|| and vice-versa. Thus, there are C(n+r-
1,r-1) arrangements of n dots and r-1 bars.
Theorem 6.3.4. (a) The number of solutions of x
1
+···+x
r
=n in nonnegative integers is
C(n+r,n).
(b) The number of terms in the algebraic expansion of (x
1
+···+x
r
)
n
is C(n+r-1,n).
Proof. (a)Anysolutionofx
1
+···+x
r
=nuniquelycorrespondstoasolutionofx
1
+···+x
r
+y =
n in nonnegative integers..
(b)Notethateachterminthealgebraicexpansionof(x
1
+···+x
r
)
n
hastheformx
i
1
1
x
i
2
2
···x
ir
r
,
withi
1
+i
2
+···+i
r
=n. Thus,eachtermuniquelycorrespondstoasolutionofi
1
+i
2
+···+i
r
=n
in nonnegative integers.
Theorem6.3.5. [r-multiset] The number of r-multisets of elements of [n] is C(n+r-1,n-1).
Proof. Let A be an r-multiset. Let d
i
be the number of copies of i in A. Then, any solution of
d
1
+···+d
n
=r in nonnegative integers gives A uniquely. Hence, the conclusion.
Alternate. Put A ={arrangements of n-1 dots and r bars}. Put B ={r-multisets of [n]}.
For a?A, de?ne f(a) to be the multiset
f(a) ={d(i)+1| where d(i) is the number of dots to the left of the i-th bar}.
For example,||••|•|| gives us{1,1,3,4,4}. Itiseasy tode?neg :B?Asothatf(g(b)) =b,for
eachb?B andg(f(a)) =a,foreacha?A. Thus,bythebijectionprinciple(seeTheorem2.3.8),
|A| =|B|. Also, we know that|A| =C(n+r-1,n-1) and hence the required result follows.
Page 3


6.3 Solutions in Non-negative Integers
De?nition 6.3.1. [Solution in nonnegative integers] Recall that N
0
:= N?{0}. A point
p = (p
1
,...,p
k
)?N
k
0
with p
1
+···+p
k
=n is called a solution of the equation x
1
+···+x
k
=n
in nonnegative integers or a solution of x
1
+··· +x
k
= n in N
0
. Two solutions (p
1
,...,p
k
)
and (q
1
,...,q
k
) are said to be the same if p
i
= q
i
, for each i = 1,...,k. Thus, (5,0,0,5) and
(0,0,5,5) are two di?erent solutions of x+y+z+t = 10 inN
0
.
Example 6.3.2. Determine the number of
1. words which uses 3 A’s and 6 B’s.
2. arrangements of 3 A’s and 6 B’s.
3. distinct strings that can be formed using 3 A’s and 6 B’s.
4. solutions of the equation x
1
+x
2
+x
3
+x
4
= 6, where each x
i
?N
0
and 0=x
i
= 6.
5. ways of placing 6 indistinguishable balls into 4 distinguishable boxes.
6. 3 subsets of an 9-set.
Solution: Observe that all the problems correspond to forming strings using +’s (or|’s
or bars) and 1’s (or balls or dots) in place of A’a and B’s, respectively?
DRAFT
ABBBABABB
ABBBBBAAB
BBABBBABA
+111+1+11 = 0+3+1+2
+11111++1 = 0+5+0+1
11+111+1+ = 2+3+1+0
|• • •| • |• •
|• • • • •|| •
• •|• • •|•|
Figure 6.2: Understanding the three problems
Note that the A’s are indistinguishable among themselves and the same holds for B’s.
Thus, we need to ?nd 3 places, from the 9 = 3+6 places, for the A’s. Hence, the answer
is C(9,3). The answer will remain the same as we just need to replace A’s with +’s (or
|’s) and B’s with 1’s (or balls) in any string of 3 A’s and 6B’s. See Figure 6.2 or note that
four numbers can be added using 3 +’s or four adjacent boxes can be created by putting
3 vertical lines or|’s.
In general, we have the following result.
Theorem 6.3.3. [solutions in N
0
] The number of solutions of x
1
+··· + x
r
= n in N
0
is
C(n+r-1,n).
Proof. Each solution (x
1
,...,x
r
) may be viewed as an arrangement of n dots and r-1 bars.
‘Put x
1
many dots; put a bar; put x
2
many dots; put another bar; continue; and end by
putting x
r
many dots.’
For example, (0,2,1,0,0) is associated to|••|•|| and vice-versa. Thus, there are C(n+r-
1,r-1) arrangements of n dots and r-1 bars.
Theorem 6.3.4. (a) The number of solutions of x
1
+···+x
r
=n in nonnegative integers is
C(n+r,n).
(b) The number of terms in the algebraic expansion of (x
1
+···+x
r
)
n
is C(n+r-1,n).
Proof. (a)Anysolutionofx
1
+···+x
r
=nuniquelycorrespondstoasolutionofx
1
+···+x
r
+y =
n in nonnegative integers..
(b)Notethateachterminthealgebraicexpansionof(x
1
+···+x
r
)
n
hastheformx
i
1
1
x
i
2
2
···x
ir
r
,
withi
1
+i
2
+···+i
r
=n. Thus,eachtermuniquelycorrespondstoasolutionofi
1
+i
2
+···+i
r
=n
in nonnegative integers.
Theorem6.3.5. [r-multiset] The number of r-multisets of elements of [n] is C(n+r-1,n-1).
Proof. Let A be an r-multiset. Let d
i
be the number of copies of i in A. Then, any solution of
d
1
+···+d
n
=r in nonnegative integers gives A uniquely. Hence, the conclusion.
Alternate. Put A ={arrangements of n-1 dots and r bars}. Put B ={r-multisets of [n]}.
For a?A, de?ne f(a) to be the multiset
f(a) ={d(i)+1| where d(i) is the number of dots to the left of the i-th bar}.
For example,||••|•|| gives us{1,1,3,4,4}. Itiseasy tode?neg :B?Asothatf(g(b)) =b,for
eachb?B andg(f(a)) =a,foreacha?A. Thus,bythebijectionprinciple(seeTheorem2.3.8),
|A| =|B|. Also, we know that|A| =C(n+r-1,n-1) and hence the required result follows.
Example 6.3.6. 1. There are 5 kindsof ice-creams available in our market complex. In how
many ways can you buy 15 of them for a party?
Ans: Suppose you buy x
i
ice-creams of the i-th type. Then, the problem is the same as
?nding the number of solutions of x
1
+···+x
5
= 15 in nonnegative integers.
2. How many solutions inN
0
are there to x+y+z = 60 such that x= 3,y= 4,z= 5?
Ans: (x,y,z)issuchasolutionifandonlyif(x-3,y-4,z-5)isasolutiontox+y+z = 48
inN
0
. So, answer is C(50,2).
3. How many solutions in N
0
are there to x+y +z = 60 such that 20= x= 3,30= y=
4,40=z= 5?
Ans: We are looking for solution in N
0
of x+y +z = 48 such that x= 17,y= 26 and
z= 35. Let A ={(x,y,z)?N
3
0
|x+y+z =48}, A
x
={(x,y,z)?N
3
0
|x+y+z = 48,x=
18}, A
y
={(x,y,z)?N
3
0
| x+y+z = 48,y= 27} and A
z
={(x,y,z)?N
3
0
| x+y+z =
48,z= 36}. We know that|A| =C(50,2). Our answer is then C(50,2)-|A
x
?A
y
?A
z
|.
Very soon we will learn to ?nd the value of|A
x
?A
y
?A
z
|.
Page 4


6.3 Solutions in Non-negative Integers
De?nition 6.3.1. [Solution in nonnegative integers] Recall that N
0
:= N?{0}. A point
p = (p
1
,...,p
k
)?N
k
0
with p
1
+···+p
k
=n is called a solution of the equation x
1
+···+x
k
=n
in nonnegative integers or a solution of x
1
+··· +x
k
= n in N
0
. Two solutions (p
1
,...,p
k
)
and (q
1
,...,q
k
) are said to be the same if p
i
= q
i
, for each i = 1,...,k. Thus, (5,0,0,5) and
(0,0,5,5) are two di?erent solutions of x+y+z+t = 10 inN
0
.
Example 6.3.2. Determine the number of
1. words which uses 3 A’s and 6 B’s.
2. arrangements of 3 A’s and 6 B’s.
3. distinct strings that can be formed using 3 A’s and 6 B’s.
4. solutions of the equation x
1
+x
2
+x
3
+x
4
= 6, where each x
i
?N
0
and 0=x
i
= 6.
5. ways of placing 6 indistinguishable balls into 4 distinguishable boxes.
6. 3 subsets of an 9-set.
Solution: Observe that all the problems correspond to forming strings using +’s (or|’s
or bars) and 1’s (or balls or dots) in place of A’a and B’s, respectively?
DRAFT
ABBBABABB
ABBBBBAAB
BBABBBABA
+111+1+11 = 0+3+1+2
+11111++1 = 0+5+0+1
11+111+1+ = 2+3+1+0
|• • •| • |• •
|• • • • •|| •
• •|• • •|•|
Figure 6.2: Understanding the three problems
Note that the A’s are indistinguishable among themselves and the same holds for B’s.
Thus, we need to ?nd 3 places, from the 9 = 3+6 places, for the A’s. Hence, the answer
is C(9,3). The answer will remain the same as we just need to replace A’s with +’s (or
|’s) and B’s with 1’s (or balls) in any string of 3 A’s and 6B’s. See Figure 6.2 or note that
four numbers can be added using 3 +’s or four adjacent boxes can be created by putting
3 vertical lines or|’s.
In general, we have the following result.
Theorem 6.3.3. [solutions in N
0
] The number of solutions of x
1
+··· + x
r
= n in N
0
is
C(n+r-1,n).
Proof. Each solution (x
1
,...,x
r
) may be viewed as an arrangement of n dots and r-1 bars.
‘Put x
1
many dots; put a bar; put x
2
many dots; put another bar; continue; and end by
putting x
r
many dots.’
For example, (0,2,1,0,0) is associated to|••|•|| and vice-versa. Thus, there are C(n+r-
1,r-1) arrangements of n dots and r-1 bars.
Theorem 6.3.4. (a) The number of solutions of x
1
+···+x
r
=n in nonnegative integers is
C(n+r,n).
(b) The number of terms in the algebraic expansion of (x
1
+···+x
r
)
n
is C(n+r-1,n).
Proof. (a)Anysolutionofx
1
+···+x
r
=nuniquelycorrespondstoasolutionofx
1
+···+x
r
+y =
n in nonnegative integers..
(b)Notethateachterminthealgebraicexpansionof(x
1
+···+x
r
)
n
hastheformx
i
1
1
x
i
2
2
···x
ir
r
,
withi
1
+i
2
+···+i
r
=n. Thus,eachtermuniquelycorrespondstoasolutionofi
1
+i
2
+···+i
r
=n
in nonnegative integers.
Theorem6.3.5. [r-multiset] The number of r-multisets of elements of [n] is C(n+r-1,n-1).
Proof. Let A be an r-multiset. Let d
i
be the number of copies of i in A. Then, any solution of
d
1
+···+d
n
=r in nonnegative integers gives A uniquely. Hence, the conclusion.
Alternate. Put A ={arrangements of n-1 dots and r bars}. Put B ={r-multisets of [n]}.
For a?A, de?ne f(a) to be the multiset
f(a) ={d(i)+1| where d(i) is the number of dots to the left of the i-th bar}.
For example,||••|•|| gives us{1,1,3,4,4}. Itiseasy tode?neg :B?Asothatf(g(b)) =b,for
eachb?B andg(f(a)) =a,foreacha?A. Thus,bythebijectionprinciple(seeTheorem2.3.8),
|A| =|B|. Also, we know that|A| =C(n+r-1,n-1) and hence the required result follows.
Example 6.3.6. 1. There are 5 kindsof ice-creams available in our market complex. In how
many ways can you buy 15 of them for a party?
Ans: Suppose you buy x
i
ice-creams of the i-th type. Then, the problem is the same as
?nding the number of solutions of x
1
+···+x
5
= 15 in nonnegative integers.
2. How many solutions inN
0
are there to x+y+z = 60 such that x= 3,y= 4,z= 5?
Ans: (x,y,z)issuchasolutionifandonlyif(x-3,y-4,z-5)isasolutiontox+y+z = 48
inN
0
. So, answer is C(50,2).
3. How many solutions in N
0
are there to x+y +z = 60 such that 20= x= 3,30= y=
4,40=z= 5?
Ans: We are looking for solution in N
0
of x+y +z = 48 such that x= 17,y= 26 and
z= 35. Let A ={(x,y,z)?N
3
0
|x+y+z =48}, A
x
={(x,y,z)?N
3
0
|x+y+z = 48,x=
18}, A
y
={(x,y,z)?N
3
0
| x+y+z = 48,y= 27} and A
z
={(x,y,z)?N
3
0
| x+y+z =
48,z= 36}. We know that|A| =C(50,2). Our answer is then C(50,2)-|A
x
?A
y
?A
z
|.
Very soon we will learn to ?nd the value of|A
x
?A
y
?A
z
|.
6.4 Set Partitions
De?nition 6.4.1. [Set partition] A partition of a set S is a collection of pairwise disjoint
nonempty subsets whose union is S.
Example 6.4.2. (a)

{1,2},{3},{4,5,6}
	
,

{1,3},{2},{4,5,6}
	
and

{1,2,3,4},{5},{6}
	
are
both partitions of [6] into 3 subsets.
(b) There are 2
n-1
-1 partitions of [n], n= 2 into two subsets. To see this, observe that for
each nontrivial subset A?P([n]), the set{A,A
c
} is a partition of [n] into two subsets.
Since, the total number of nontrivial subsets ofP([n]) equals 2
n
-2, the required result
follows.
(c) Number of allocations of 7 students into 7 di?erent project groups so that each group has
one student, is 7! = C(7;1,1,1,1,1,1,1) butthenumberof partitions of a setof 7students
into 7 subsets is 1.
Page 5


6.3 Solutions in Non-negative Integers
De?nition 6.3.1. [Solution in nonnegative integers] Recall that N
0
:= N?{0}. A point
p = (p
1
,...,p
k
)?N
k
0
with p
1
+···+p
k
=n is called a solution of the equation x
1
+···+x
k
=n
in nonnegative integers or a solution of x
1
+··· +x
k
= n in N
0
. Two solutions (p
1
,...,p
k
)
and (q
1
,...,q
k
) are said to be the same if p
i
= q
i
, for each i = 1,...,k. Thus, (5,0,0,5) and
(0,0,5,5) are two di?erent solutions of x+y+z+t = 10 inN
0
.
Example 6.3.2. Determine the number of
1. words which uses 3 A’s and 6 B’s.
2. arrangements of 3 A’s and 6 B’s.
3. distinct strings that can be formed using 3 A’s and 6 B’s.
4. solutions of the equation x
1
+x
2
+x
3
+x
4
= 6, where each x
i
?N
0
and 0=x
i
= 6.
5. ways of placing 6 indistinguishable balls into 4 distinguishable boxes.
6. 3 subsets of an 9-set.
Solution: Observe that all the problems correspond to forming strings using +’s (or|’s
or bars) and 1’s (or balls or dots) in place of A’a and B’s, respectively?
DRAFT
ABBBABABB
ABBBBBAAB
BBABBBABA
+111+1+11 = 0+3+1+2
+11111++1 = 0+5+0+1
11+111+1+ = 2+3+1+0
|• • •| • |• •
|• • • • •|| •
• •|• • •|•|
Figure 6.2: Understanding the three problems
Note that the A’s are indistinguishable among themselves and the same holds for B’s.
Thus, we need to ?nd 3 places, from the 9 = 3+6 places, for the A’s. Hence, the answer
is C(9,3). The answer will remain the same as we just need to replace A’s with +’s (or
|’s) and B’s with 1’s (or balls) in any string of 3 A’s and 6B’s. See Figure 6.2 or note that
four numbers can be added using 3 +’s or four adjacent boxes can be created by putting
3 vertical lines or|’s.
In general, we have the following result.
Theorem 6.3.3. [solutions in N
0
] The number of solutions of x
1
+··· + x
r
= n in N
0
is
C(n+r-1,n).
Proof. Each solution (x
1
,...,x
r
) may be viewed as an arrangement of n dots and r-1 bars.
‘Put x
1
many dots; put a bar; put x
2
many dots; put another bar; continue; and end by
putting x
r
many dots.’
For example, (0,2,1,0,0) is associated to|••|•|| and vice-versa. Thus, there are C(n+r-
1,r-1) arrangements of n dots and r-1 bars.
Theorem 6.3.4. (a) The number of solutions of x
1
+···+x
r
=n in nonnegative integers is
C(n+r,n).
(b) The number of terms in the algebraic expansion of (x
1
+···+x
r
)
n
is C(n+r-1,n).
Proof. (a)Anysolutionofx
1
+···+x
r
=nuniquelycorrespondstoasolutionofx
1
+···+x
r
+y =
n in nonnegative integers..
(b)Notethateachterminthealgebraicexpansionof(x
1
+···+x
r
)
n
hastheformx
i
1
1
x
i
2
2
···x
ir
r
,
withi
1
+i
2
+···+i
r
=n. Thus,eachtermuniquelycorrespondstoasolutionofi
1
+i
2
+···+i
r
=n
in nonnegative integers.
Theorem6.3.5. [r-multiset] The number of r-multisets of elements of [n] is C(n+r-1,n-1).
Proof. Let A be an r-multiset. Let d
i
be the number of copies of i in A. Then, any solution of
d
1
+···+d
n
=r in nonnegative integers gives A uniquely. Hence, the conclusion.
Alternate. Put A ={arrangements of n-1 dots and r bars}. Put B ={r-multisets of [n]}.
For a?A, de?ne f(a) to be the multiset
f(a) ={d(i)+1| where d(i) is the number of dots to the left of the i-th bar}.
For example,||••|•|| gives us{1,1,3,4,4}. Itiseasy tode?neg :B?Asothatf(g(b)) =b,for
eachb?B andg(f(a)) =a,foreacha?A. Thus,bythebijectionprinciple(seeTheorem2.3.8),
|A| =|B|. Also, we know that|A| =C(n+r-1,n-1) and hence the required result follows.
Example 6.3.6. 1. There are 5 kindsof ice-creams available in our market complex. In how
many ways can you buy 15 of them for a party?
Ans: Suppose you buy x
i
ice-creams of the i-th type. Then, the problem is the same as
?nding the number of solutions of x
1
+···+x
5
= 15 in nonnegative integers.
2. How many solutions inN
0
are there to x+y+z = 60 such that x= 3,y= 4,z= 5?
Ans: (x,y,z)issuchasolutionifandonlyif(x-3,y-4,z-5)isasolutiontox+y+z = 48
inN
0
. So, answer is C(50,2).
3. How many solutions in N
0
are there to x+y +z = 60 such that 20= x= 3,30= y=
4,40=z= 5?
Ans: We are looking for solution in N
0
of x+y +z = 48 such that x= 17,y= 26 and
z= 35. Let A ={(x,y,z)?N
3
0
|x+y+z =48}, A
x
={(x,y,z)?N
3
0
|x+y+z = 48,x=
18}, A
y
={(x,y,z)?N
3
0
| x+y+z = 48,y= 27} and A
z
={(x,y,z)?N
3
0
| x+y+z =
48,z= 36}. We know that|A| =C(50,2). Our answer is then C(50,2)-|A
x
?A
y
?A
z
|.
Very soon we will learn to ?nd the value of|A
x
?A
y
?A
z
|.
6.4 Set Partitions
De?nition 6.4.1. [Set partition] A partition of a set S is a collection of pairwise disjoint
nonempty subsets whose union is S.
Example 6.4.2. (a)

{1,2},{3},{4,5,6}
	
,

{1,3},{2},{4,5,6}
	
and

{1,2,3,4},{5},{6}
	
are
both partitions of [6] into 3 subsets.
(b) There are 2
n-1
-1 partitions of [n], n= 2 into two subsets. To see this, observe that for
each nontrivial subset A?P([n]), the set{A,A
c
} is a partition of [n] into two subsets.
Since, the total number of nontrivial subsets ofP([n]) equals 2
n
-2, the required result
follows.
(c) Number of allocations of 7 students into 7 di?erent project groups so that each group has
one student, is 7! = C(7;1,1,1,1,1,1,1) butthenumberof partitions of a setof 7students
into 7 subsets is 1.
DRAFT
(d) In how many ways can I write
n
{1,2},{3,4},{5,6},{7,8,9},{10,11,12}
o
on a piece of
paper, with the condition that sets have to be written in a row in increasing size?
Ans: Let us write a few ?rst.
n
{1,2},{3,4},{5,6},{7,8,9},{10,11,12}
o
correct
n
{2,1},{3,4},{5,6},{7,8,9},{10,11,12}
o
correct
n
{5,6},{3,4},{1,2},{10,11,12},{9,7,8}
o
correct
n
{2,3},{1,4},{5,6},{7,8,9},{10,11,12}
o
incorrect, not the same partition
n
{2,1},{3,4},{7,8,9},{5,6},{10,11,12}
o
incorrect, not satisfying the condition
There are 3!(2!)
3
×2!(3!)
2
ways. Notice that from each written partition, if I remove the
brackets I get an arrangement of elements of [12].
(e) How many arrangements do I generate from a partition with p
i
subsets of size n
i
, n
1
<
··· <n
k
?
Ans: p
1
!(n
1
!)
p
1
···p
k
!(n
k
!)
p
k
=
k
Y
i=1
[p
i
!(n
i
)
p
i
].
Theorem 6.4.3. [Set partition] The number of partitions of [n] with p
i
subsets of size n
i
,
n
1
<··· <n
k
is
n!
(n
1
!)
p
1
p
1
!···(n
k
!)
p
k
p
k
!
.
Proof. Note that each such partition generates
k
Q
i=1
[p
i
!(n
i
)
p
i
] arrangement of elements of [n].
Conversely, for each arrangement of elements of [n] we can easily construct a partition of the
above type which can generate this arrangement. Thus, the proof is complete.
De?nition 6.4.4. Stirling numbers of the second kind, denotedS(n,r), is the number of
partitions of [n] into r-subsets (r-parts). By convention, S(n,r) = 1, if n = r and 0, whenever
either ‘n> 0 and r = 0’ or ‘n<r’.
Theorem 6.4.5. [recurrence for S(n,r)] S(n+1,r) =S(n,r-1)+rS(n,r).
Proof. Write an r-partition of [n+1] and erase n+1 from it. That is, if{n+1} is an element
of an r-partition, then the number of such partitions become S(n,r-1); else n+1 appears in
one of the element of an r-partition of [n], which gives the number rS(n,r).
Example 6.4.6. Determine the number of ways of putting n distinguishable/distinct balls into
r indistinguishable boxes with the restriction that no box is empty.
Ans: Let A be the set of n distinct balls and let the balls in i-th box be B
i
, 1=i=r.
1. Since each box is non-empty, each B
i
is non-empty.
2. Also, each ball is in some box and hence
r
S
i=1
B
i
=A.
Read More
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FAQs on Permutations and combinations (Part - 2)- Algebra, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is the difference between permutations and combinations?
Ans. Permutations and combinations are both concepts in combinatorics, but they differ in their arrangements of elements. In permutations, the order of elements matters, while in combinations, the order does not matter. For example, if we have three elements A, B, and C, the permutations would be ABC, ACB, BAC, BCA, CAB, and CBA, while the combinations would be AB, AC, BC.
2. How do we calculate the number of permutations?
Ans. The number of permutations of a set of n elements taken r at a time can be calculated using the formula P(n,r) = n!/(n-r)!. Here, n! denotes the factorial of n, which is the product of all positive integers less than or equal to n. For example, if we want to find the number of permutations of 5 elements taken 3 at a time, we would use the formula P(5,3) = 5!/(5-3)! = 5!/2! = 60.
3. How do we calculate the number of combinations?
Ans. The number of combinations of a set of n elements taken r at a time can be calculated using the formula C(n,r) = n!/(r!(n-r)!). This formula takes into account that the order of elements does not matter in combinations. For example, if we want to find the number of combinations of 5 elements taken 3 at a time, we would use the formula C(5,3) = 5!/(3!(5-3)!) = 5!/(3!2!) = 10.
4. Can you explain the concept of factorial in permutations and combinations?
Ans. Factorial is a mathematical operation denoted by an exclamation mark (!). It represents the product of all positive integers less than or equal to a given number. In permutations and combinations, factorials are used to calculate the number of arrangements or combinations possible. For example, 5! (read as "5 factorial") is equal to 5 x 4 x 3 x 2 x 1, which is 120.
5. How are permutations and combinations used in real-life situations?
Ans. Permutations and combinations have various applications in real-life situations. They are used in probability calculations, such as finding the number of possible outcomes in a game or lottery. They are also used in statistics to analyze data and make predictions. For example, combinations are used in poker to calculate the number of possible hands. Additionally, permutations and combinations are applied in cryptography, computer science, and algorithms to solve problems efficiently.
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