1. Recurrence Relations: Selected Exercises

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Exercise 10 (a)
A person deposits $1,000 in an account that yields 9% interest compounded annually.
Set up a recurrence relation for the amount in the account at the end of n years.
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Exercise 10 (a) Solution
A person deposits $1,000 in an account that yields 9% interest compounded annually.
Set up a recurrence relation for the amount in the account at the end of n years.
Let an represent the amount after n years.
an = an an-1 = 1.09an-1
a0 = 1000.
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Exercise 10 (b)
A person deposits $1,000 in an account that yields 9% interest compounded annually.
Find an explicit formula for the amount in the account at the end of n years.
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Exercise 10 (b) Solution
After 1 year, a1 = 1.09a0 = 1.09x1000 = 1000x1.091
After 2 years, a2 = 1.09a1
= 1.09( 1000x(1.09)1 )
= 1000x(1.09)2
After n years, an = 1000x(1.09)n
Since an is recursively defined, we prove the formula, for n ≥ 0, by mathematical induction
(The problem does not ask for proof).
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Exercise 10 (b) Solution
Basis n = 0: a0 = 1000 = 1000x(1.09)0 .
The 1st equality is the recurrence relation’s initial condition.
Induction hypothesis: an = 1000x1.09n.
Induction step: Show: an+1 = 1000x1.09n+1.
an+1 = 1.09an = 1.09 ( 1000x1.09n ) = 1000x1.09n+1.
The 1st equality: the definition of the recurrence relation.
The 2nd equality: the induction hypothesis.
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Exercise 10 (c)
A person deposits $1,000 in an account that yields 9% interest compounded annually.
How much money will the account contain after 100 years?
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Exercise 10 (c) Solution
The account contains a100 dollars after 100 years: a100 = 1000x = $5,529,041.
That is before taxes.
With 30% federal + 10% CA on interest earned, it becomes 1000x = $131,500 
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Exercise 20
A country uses as currency coins with pesos values of 1, 2, 5, & 10 pesos
Find a recurrence relation, an, for the # of payment sequences for n pesos.
E.g., a bill of 4 pesos could be paid with any of the following sequences:
1, 1, 1, 1
1,1, 2
1, 2, 1
2, 1, 1
2, 2
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Exercise 20 Solution
The sequences that start w/ a 1 peso coin differ from the sequences that don’t.
Use the sum rule: Partition the set of sequences, based on which kind of coin starts the sequence.
It could be a:
1 peso coin, in which case we have an-1 ways to finish the bill
2 peso coin, in which case we have an-2 ways to finish the bill
5 peso coin, in which case we have an-5 ways to finish the bill
10 peso coin, in which case we have an-10 ways to finish the bill
The recurrence relation is
an = an-1 + an-2 + an-5 + an-10 with 10 initial conditions, a1 = 1, a2 = 2, a3 = 3, a4 = 5, a5 = 9, a6 = 15, a7 = 26, a8 = 44, a9 = 75, a10 = 125.
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Exercise 30 (a)
A string that contains only 0s, 1s, & 2s is called a ternary string.
Find a recurrence relation for the # of ternary strings of length n that do not contain 2 consecutive 0s.
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Exercise 30 (a) Solution
Subtract the # of “bad” strings (contain 2 consecutive 0s), bn, , from the # of ternary strings, 3n.
To count bn, , use the sum rule:
Partition the set of strings, depending on what digit starts the string:
The string starts with a 1: bn-1 ways to finish the string.
The string starts with a 2: bn-1 ways to finish the string.
The string starts with a 0:
The remaining string starts with a 0: 3n-2 ways to finish the string.
The remaining string starts with a 1: bn-2 ways to finish the string.
The remaining string starts with a 2: bn-2 ways to finish the string.
Summing, bn = 2bn-1 + 2bn-2 + 3n-2
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Exercise 30 (b)
What are the initial conditions?
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Exercise 30 (b) Solution
What are the initial conditions?
b0 = b1 = 0.
Why do we need 2 initial conditions?
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Exercise 30 (c)
How many ternary strings of length 6 contain 2 consecutive 0s?
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Exercise 30 (c) Solution
The number of such strings is the value of b6.
Using bn = 2bn-1 + 2bn-2 + 3n-2, we compute:
b0 = b1 = 0. (Initial conditions)
b2 = 2b1 + 2b = 2x0 + 2x = 1
b3 = 2b2 + 2b = 2x1 + 2x = 5
b4 = 2b3 + 2b = 2x5 + 2x = 21
b5 = 2b4 + 2b = 2x21 + 2x = 79
b6 = 2b5 + 2b = 2x79 + 2x = 281.
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Exercise 40
Find a recurrence relation, en, for the # of bit strings of length n with an even # of 0s.
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Exercise 40 Solution
Strings are sequences: Order matters: There is a 1st bit. Use the sum rule: Partition the desired set of bit strings, based on the string’s 1st bit: Strings with an even # of 0s that begin with 1: en-1 Strings with an even # of 0s that begin with 0: 2n-1 - en-1 Summing, en = en-1 + 2n-1 - en-1 = 2n-1
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End
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Exercise 40 Solution
Strings are sequences: Order matters: There is a 1st bit.
Use the sum rule:
Partition the desired set of bit strings, based on the string’s 1st bit:
Strings with an even # of 0s that begin with 1: en-1
Strings with an even # of 0s that begin with 0: 2n-1 - en-1
Summing, en = en-1 + 2n-1 - en-1 = 2n-1
Does this answer suggest an alternate explanation?
Does this question relate to our study binomial coefficients?
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21. Use the Binomial Theorem
( x + y )n = Σj=0 to n C( n, j )xn-jyj =
C( n, 0 )xny0 + C( n,1 )xn-1y1 + … + C( n, j )xn-jyj + … + C( n, n )x0yn.
Evaluate at x = 1, y = -1:
(1 – 1)n = Σj=0 to n C( n, j )1n-j( -1 )j
= C( n, 0 ) - C( n,1 ) + C( n,2 ) - C( n,3 ) (-1)nC( n, n ).
C( n,1 ) + C( n,3 ) + C( n,5 ) = C( n, 0 ) + C( n,2 ) + C( n,4 ) = 2n-1
Example: C(4,0) + C(4,2) + C(4,4) = C(4,1) + C(4,3) = 23
The # of bit strings of length 4 that have an even number of 0s is 23.
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The variation we consider begins with people numbered 1, …, n, standing around a circle.
In each stage, every 2nd person still alive is killed until only 1 survives.
We denote the number of the survivor by J(n).
Determine the value of J(n) for 1  n  16.
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49 Solution
Put 5 people, named 1, 2, 3, 4, & 5, in a circle.
Starting with 1, kill every 2nd person until only 1 person is left.
The sequence of killings is:
So, J(5) = 3.
Continuing, for each value of n, results in the following table.
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49 Solution n
J(n) 1 9 3 2 10 5 11 7 4 12 13 6 14 15 8 16
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Use the values you found in Exercise 49 to conjecture a formula for J(n).
Hint: Write n = 2m + k, where m, k N & k < 2m .
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50 Solution n
J(n)
1 = 1
9 = 3
2 =
10 = 5
3 =
11 = 7
4 =
12 = 9
5 =
13 = 11
6 =
14 = 13
7 =
15 = 15
8 =
16 =
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50 Solution continued n
J(n)
1 =
1 = 2*0 + 1
9 =
3 = 2*1 + 1
2 =
10 =
5 = 2*2 + 1
3 =
11 =
7 = 2*3 + 1
4 =
12 =
9 = 2*4 + 1
5 =
13 =
11 = 2*5 + 1
6 =
14 =
13 = 2*6 + 1
7 =
15 =
15 = 2*7 + 1
8 =
16 =
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50 Solution continued
So, if n = 2m + k, where m, k N & k < 2m , then J(n) = 2k + 1.
Check this for J(17).
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29. Exercise 20 Solution continued
But, we also can use bills.
If the 1st currency object is a bill, it could be a
5 peso, in which case we have an-5 ways to finish the bill
10 peso, in which case we have an-10 ways to finish the bill
20 peso, in which case we have an-20 ways to finish the bill
50 peso, in which case we have an-50 ways to finish the bill
100 peso, in which case we have an-100 ways to finish the bill
Using both coins & bills, we have
an = an-1 + an-2 + an-5 + an-10
+ an-5 + an-10 + an-20 + an-50 + an-100
= an-1 + an-2 + 2an-5 + 2an an-20 + an-50 + an-100 ,
with 100 initial conditions, which I will not produce.
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