Discrete Mathematics Chapter 4 Induction and Recursion 大大大大 大大大大大 大大大 (Lingling Huang)
Discrete Mathematics
Chapter 4 Induction and Recursion
大葉大學 資訊工程系 黃鈴玲 (Lingling Huang)
Ch4-2
4.1 Mathematical Induction( 數學歸納法 )
Note : Mathematical induction can be used only to
prove results obtained in some other way. It is
not a tool for discovering formulae or theorems.
(p.265)
P(n) : a propositional function (e.g. n 2≦ n) A proof by mathematical induction (MI) that P(n) is true for every nZ+ consists of two steps : 1. Basis step : The proposition P(1) is shown to be true.( 若 n 從 0 開始則證 P(0) 為真 ) 2. Inductive step : the implication P(k) → P(k+1) is shown to be true for every kZ+
Ch4-3
Example 2. Use MI to prove that the sum of the first n odd positive integers is n2.
Note. 不用 MI 就可以得証 :
Pf : Let P(n) denote the proposition that Basis step : P(1) is true , since 1=12
Inductive step : Suppose that P(k) is true for a positive integer k, i.e., 1+3+5+…+(2k1)=k2
Note that 1+3+5+…+(2k1)+(2k+1) = k2+2k+1= (k+1)2
∴ P(k+1) is true By induction, P(n) is true for all nZ+
2
11
)1(2)12( nnnnniin
i
n
i
2
1
)12( nin
i
Ch4-4
Example 5. Use MI to prove the inequality n < 2n for all nZ+
pf : Let P(n) be the proposition “ n < 2n ”. Basis step : P(1) is true since 1 < 21 . Inductive step : Assume that P(k) is true for a positive integer k,
i.e., k < 2k.
Consider P(k+1) : k + 1 < 2k + 1 2k + 2k =2k + 1 ∴ P(k+1) is true. By MI, P(n) is true for all nZ+.
Ch4-5
kH k
1...
3
1
2
11
21
2
nH n
Example 7. The harmonic numbers Hk, k =1,2,3,…, are
defined by . Use MI to show that
Pf : Let P(n) be the proposition that “ ”.
Basis step : P(0) is true, since .
Inductive step : Assume that P(k) is true for some k,
i.e.,
Consider P(k+1) :
whenever n is a nonnegative integer.
2/12
nH n
2/011120 HH
2/12
kH k
Ch4-6
∴P(k+1) is true. By MI, P(n) is true for all nZ+.
12 2
1
22
1
12
1
2
1
3
1
2
111
kkkkkH
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1
22
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Exercise : 7, 13
Ch4-7
4.2 Strong Induction( 強數學歸納法 )
Basis step 相同 Inductive step : Assume all the statements P(1),
P(2), …, P(k) are true. Show that P(k+1) is also true.
Ch4-8
Example 2. Show that if nZ and n >1, then n can be written as the product of primes.Pf : Let P(n) be the proposition that n can be written as the product of primes. Basis : P(2) is true, since 2 is a prime number Inductive : Assume P(2), P(3), …, P(k) are true. Consider P(k + 1) : Case 1 : k + 1 is prime P(k+1) is true Case 2 : k + 1 is composite, i.e., k + 1 = ab where 2 a b < k+1 By the induction hypothesis, both a and b can be written as the product of primes. P(k+1) is true. By Strong MI, P(k) is true if kZ and k >1.
Note: 此題無法僅用 MI 證
Ch4-9
Example 4. Prove that every amount of postage of 12 cents or more can be formed using just 4-cent and 5-cent stamps.Pf : Let P(n) be the statement that the postage of n cents can formed using just 4-cent and 5-cent stamps. Basis : P(12) is true, since 12 = 4 3; P(13) is true, since 13 = 4 2 + 5 1; P(14) is true, since 14 = 4 1 + 5 2; P(15) is true, since 15 = 5 3; Inductive : Assume P(12), P(13), …, P(k) are true. Consider P(k+1) : Suppose k3 = 4 m + 5 n. Then k+1 = 4 (m1) + 5 n. P(k+1) is true. By Strong MI, P(n) is true if nZ and n 12.
Exercise : 7
(k3 12)
Ch4-10
4.3 Recursive Definitions. Def. The process of defining an object in terms of itself
is called recursion( 遞迴 ).
e.g. We specify the terms of a sequence using
(1) an explicit formula:
an=2n, n=0,1,2,…
(2) a recursive form:
a0=1,
an+1=2an , n=0,1,2,…
Example 1. Suppose that f is defined recursively by f(0)=3 , f(n+1)=2f(n)+3 Find f(1), f(2), f(3), f(4).
Ch4-11
Example 2. Give an inductive (recursive) definition of the factorial function F(n) = n!.
Sol :
initial value : F(0) = 1
recursive form : F(n+1) = (n+1)! = n! (n+1)
= F(n) (n+1)
Def1, Example 5. The Fibonacci numbers f0, f1, f2…,are defined by : f0 = 0 , f1 = 1 , fn = fn1 + fn2 , for n = 2,3,4,… what is f4 ?Sol : f4 = f3 + f2 = (f2 + f1) + (f1 + f0) = f2 + 2 = (f1 + f0) + 2 = 3
Ch4-12
Example 6. Show that fn > n2 , where 32
51
n ,
Pf: ( By Strong MI ) Let P(n) be the statement fn >n2 . Basis: f3 = 2 > so that P(3) and P(4) are true. Inductive: Assume that P(3), P(4), …, P(n) are true. We must show that P(n+1) is true. fn+1 = fn + fn1 > n2 + n3 = n3( +1) ∵ +1= 2
∴ fn+1 > n3 2 = n1
We get that P(n+1) is true. By Strong MI , P(n) is true for all n 3
2
533 2
4
f
Ch4-13
※Recursively defined sets.Example 7. Let S be defined recursively by 3S x+yS if xS and yS. Show that S is the of positive integers divisible by 3 (i.e., S = { 3, 6, 9, 12, 15, 18, … }Pf: Let A be the set of all positive integers divisible by 3. We need to prove that A=S. (i) A S : (By MI) Let P(n) be the statement that 3nS … (ii) S A : ( 利用 S 的定義 ) (1) 3 A , (2) if xA,yA, then 3|x and 3|y. 3|(x+y) x+yA ∴S A
S = A
Ch4-14
Definition 2. The set of strings over an alphabet is denoted by *. The empty string is denoted by , , and wx* whenever w* and x.eg. = { a, b, c }
* = { , a , b , c , aa , ab , ac , ba , bb , bc, … abcabccba, …}
Example 9. Give a recursive definition of l(w), the length of the string w*
Sol :
initial value : l()=0
recursive def : l(wx)=l(w)+1 if w*, x.
a b c
Ch4-15
Exercise 3, 7, 13, 48, 49
Exercise 39. When does a string belong to the set A of bit strings defined recursively by
A
0x1A if xA.Sol :
A={, 01 , 0011, 000111, …}
∴ 當 bit string = 000…011…1 時 A n 個 n 個
01
Ch4-16
Ackermann’s function
A(m, n) = 2n if m = 0
0 if m 1 and n = 0
2 if m 1 and n = 1
A(m1, A(m, n1)) if m 1 and n 2
Exercise 49 Show that A(m,2)=4 whenever m 1
Pf :
A(m,2) = A(m1, A(m,1)) = A(m1,2) whenever m 1.
A(m,2) = A(m1,2) = A(m2,2) = … = A(0,2) = 4.
Ch4-17
4.4 Recursive algorithms. ※ Sometimes we can reduce the solution to a problem with a particular set of input to the solution of the same problem with smaller input values.
eg. gcd(a,b) = gcd(b mod a, a) (when a < b)
Def 1. An algorithm is called recursive if it solves a problem by reducing it to an instance of the same problem with smaller input.
Ch4-18
Example 2. Give a recursive algorithm for computing an, where aR \ {0}, nN.
Sol : recursive definition of an : initial value : a0=1 recursive def : an = a an1.
Algorithm 2. Procedure power( a : nonzero real number, n : nonnegative integer ) if n = 0 then power(a, n):=1 else power(a, n):= a * power(a, n1).
∴
Ch4-19
Example 4. Find gcd(a,b) with 0a<bSol :
Algorithm 4. procedure gcd(a,b : nonnegative integers with a<b) if a=0 then gcd(a,b) := b else gcd(a,b) := gcd(b mod a, a).
Example 5. Search x in a1, a2,…,an by Linear SearchSol : Alg. 5
procedure search (i, j, x: integers) if ai = x then location := i else if i = j then location := 0 else search(i+1, j, x)
從 ai,ai+1,…aj 中找 x
callsearch(1, n, x)
Ch4-20
Example 6. Search x from a1,a2,…,an by binary search (recursive version).
Sol : Alg. 5 procedure binary_search (x , i , j: integers) m := (i+j) / 2 if x = am then location := m else if (x < am and i < m) then binary_search(x, i, m1) else if (x > am and j > m) then binary_search(x, m+1, j) else location := 0
call binary_search(x, 1, n)
search x from ai, ai+1, …, aj
表示左半邊 ai, ai+1, …, am1
至少還有一個元素
Ch4-21
Example 1. Give the value of n!, nZ+
Sol :Note : n! = n (n1)!
Alg. 1 (Recursive Procedure) procedure factorial (n: positive integer) if n = 1 then factorial (n) := 1 else factorial (n) := n factorial (n1)
Alg. (Iterative Procedure) procedure iterative_factorial (n : positive integer) x := 1 for i := 1 to n x := i x { x = n! }
Ch4-22
※ iterative alg. 的計算次數通常比 recursive alg.少
※ Find Fibonacci numbers
(Note : f0=0, f1=1, fn=fn1+fn2 for n2)
Alg. 7 (Recursive Fibonacci) procedure Fibonacci (n : nonnegative integer) if n = 0 then Fibonacci (0) := 0 else if n = 1 then Fibonacci (1) := 1 else Fibonacci (n) := Fibonacci (n1)+Fibonacci (n2)
Ch4-23
Alg.8 (Iterative Fibonacci) procedure iterative_fibonacci (n: nonnegative integer) if n = 0 then y := 0 // y = f0
else begin x := 0 y := 1 // y = f1
for i := 1 to n1 begin z := x + y x := y y := z end end {y is fn }
Exercise : 11, 35
i = 1 i = 2 i = 3
z f2 f3 f4
x f1 f2 f3
y f2 f3 f4