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MATH 2040 Introduction to Mathematical Finance. Instructor: Miss Liu Youmei. Chapter 3 Basic Annuities ( 年金). Definition of an annuity. Annuity-immediate. Annuity-due. Annuity values on any date. Perpetuity-immediate &perpetuity-due. Problem with unknown time.
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MATH 2040 Introduction to Mathematical Finance Instructor: Miss Liu Youmei
Chapter 3 Basic Annuities (年金) Definition of an annuity Annuity-immediate Annuity-due Annuity values on any date Perpetuity-immediate &perpetuity-due Problem with unknown time Problem with unknown rate of interest
Definition of an annuity • An annuity is a series of payments made at equal intervals of time (annually or otherwise). • Payments made for certain for a fixed period of time are called an annuity-certain. • In this chapter, we deal with annuities with: • The payment frequency and the interest conversion period are equal. • The payments are leveled (all equal to each other).
Annuity-immediate • Payments of 1 are made at the end of every year for n years. • The present value (at t = 0) of an annuity-immediate, where the annual effective rate of interest is i, shall be denoted as and is calculated as follows:
Accumulated value of annuity-immediate • The accumulated value (at t = n) of an annuity-immediate, where the annual effective rate of interest is i, shall be denoted by , and is calculated as follows:
First basic relationship • The first basic relationship is: • Consider an n-year investment where 1 is invested at time 0. • Also consider the stream of payments of i at the end of each year for n years and then 1 is refunded at time t = n. 1
First basic relationship – cont’d • The present value of these multiple payments (at time t = 0) is . • Hence we have • Note that
Second basic relationship • The second basic relationship is: PV = FV v n and PV(1 + i )n = FV • If the FV (future value) at time n, , is discounted back to time 0, then we will have the PV (present value), . • So
Second basic relationship – cont’d • If the PV at time 0, , is accumulated to time n, then we will have the FV, . • So
Third basic relationship • The third basic relationship is: • Suppose a loan of 1 is to be paid back over n years with equal annual payments of P made at the end of each year, then or • Alternatively, suppose the same loan of 1 is to be repaid by interest payments of i made at the end of each year, and the loan amount 1 is paid back at time n.
Third basic relationship – cont’d • In order to produce the loan amount at time n, annual payments of D, at the end of each year for n years, will be made into an account that credits interest at an annual effective rate of interest i. • The future value of all these payment D must be equal to 1, so we have or • The total payment will therefore be
Third basic relationship – cont’d • Note that • Therefore, a level annual payment on a loan is the same as • making an annual interest payment each year plus • making annual deposits that will accumulate to the loan amount.
Interest repayment option one • Given a loan of 1, there are 3 options in repaying the loan over the next n years. • Pay back the loan and all interest due at time n. • Total interest paid = A(n) – A(0) = Loan (1 + i)n Loan = Loan [(1 + i)n 1]
Interest repayment option two • Pay at the end of each year, the interest that comes due on the loan and then pay back the loan at time n. • Annual interest payment = i Loan Total interest paid = i Loan n = Loan (i n)
Interest repayment option three • Pay a level annual amount at the end of each year for the next n years. • Annual payment • Total payments • Total interest paid
Comparing interest repayment options • Option 1 and 2 is a comparison between compound v.s. simple interest. • Therefore, less interest is paid under option 2. This would make sense because if you pay off interest as it becomes due, the loan cannot grow as it does under option 1. • Option 2 and 3 is a mathematical comparison that shows less interest being paid under option 3. This can be proved by making use of the basic relationship
Example 3.1 • Find the present value of an annuity which pays $500 at the end of each half-year for 20 years if the rate of interest is 9% convertible semi-annually. • We can view the annuity as one that pays $500 at the end of each period for 40 periods with interest rate 4.5% per period. • So the answer is:
Example 3.2 • If a person invests $1000 at 8% p.a. convertible quarterly, how much can be withdrawn at the end of every quarter to use up the fund exactly at the end of 10 years? • Since the interest rate is 8% p.a. convertible quarterly, and withdrawals are made quarterly, we can view the problem as one with interest at 2% per period, and the fund is to be withdrawn in 40 periods. • So the answer is
Example 3.3 • Compare the total amount of interest that would be paid on a $1000 loan over a 10-year period, if the effective rate of interest is 9% per annum, under the following three repayment methods: • (1) The entire loan plus interest is paid in one lump-sum at the end of 10 years. • (2) Interest is paid each year and the principal is repaid at the end of 10 years. • (3) The loan was repaid by level payments over the 10 year period.
Example 3.3 (1) • (1) The entire loan plus interest is paid in one lump-sum at the end of 10 years. • The accumulated value of the loan at the end of 10 years is 1000(1.09)10 = 2367.36 • The total amount of interest paid is therefore: $2367.36 - 1000 = $1367.36
Example 3.3 (2) • (2) Interest is paid each year and the principal is repaid at the end of 10 years. • Interest paid each year is $1000 0.09 = $ 90 • Total interest for 10 years is $90 10 = $ 900.
Example 3.3 (3) • (3) The loan was repaid by level payments over the 10 year period. Let the level payment be R. Then Which gives So the total interest paid is 10 $155.82 $1000 = $588.20.
Example 3.3 - remark • The later the principal was repaid, the more is interest paid. • (1) The entire principal plus accumulated interest was paid at the end of 10 years, so the most interest was paid for this option. • (2) Interest is paid each year, less interest was paid on this option. • (3) The loan was repaid by level payments. In each payment, some interest and some principal were paid. So the least interest amount was paid for this option.
Annuity due(期初年金) • For annuity immediate, payments of 1 are made at the end of every year for n years. • In another type of annuity, called annuity due, payments of 1 are made at the beginning of every year for n years.
Annuity due • The present value (at t = 0) of an annuity-due, where the annual effective rate of interest is i, shall be denoted as and is calculated as follows:
Annuity due – cont’d • The accumulated value at t = n of an annuity-due, where the annual effective rate of interest is i, shall be denoted as and is calculated as follows:
Basic relationships -Annuity due • Similar to annuity immediate, there are also three basic relationships on annuity-due. • (1) • (2) PV(1 + i)n = FV and PV = FV v n • (3) • There are similar interpretation of all these relationships as those for annuity-immediate.
Basic relationships - Annuity due (1) • Consider an n-year investment where 1 is invested at time 0. • Suppose this investment produces • annual interest payments of d at the beginning of each year • the amount of 1 at t = n. • The present value of this is • It follows that • Note that
Basic relationships - Annuity due (2) • If the future value at time n, , is discounted back to time 0, then we obtained its present value, . • Similarly, if the present value at time 0, , is accumulated forward to time n, then we get . So
Basic relationships - Annuity due (3) • Consider a loan of 1, to be repaid back over n years with equal annual payments of P made at the beginning of each year. • Suppose an effective rate of interest, i, is used. • The present value of the single payment loan must be equal to the present value of the multiple payment stream, i.e.
Basic relationships - Annuity due (3) • Consider an alternative method of repaying the same loan of 1, where the annual interest due on the loan d, is paid at the beginning of each year for n years, and the loan amount 1 is paid at time n. • To produce the loan amount 1 at time n, annual payments, D, are deposited at the beginning of each year for n years so that it will grow with the same effective rate of interest as the loan. • The future value of the multiple deposits should equal the future value of 1 at time n. i.e. • The total annual payment is then
More basic relationships • In addition to the above three, there are also three additional basic relationships on annuities. • (4) and • (5) • (6)
Basic relationship (4) • An annuity-due starts one period ahead of an annuity-immediate, and as a result it earns interest for one more period. • That applies to both present value and accumulated value. • So we have • and
Basic relationship (5) • An annuity-due starts immediately. That results in an additional payment at time 0. • The remaining (n – 1) payments can be viewed as an annuity-immediate for (n – 1) years • Hence we get
Basic relationship (6) • The annuity due for (n – 1) years may be viewed as one that starts at the end of year one and finishes at the end of the (n – 1)-th year. • An additional payment of 1 at time n results in becoming n payments that now starts at the end of each year. • So we have
Example 3.4 • An investor wishes to accumulate $1000 in a fund at the end of 12 years. He plans to make deposits at the end of each year, the final payment to be made at the end of the 11-th year. What should the annual deposits be if the fund earns 7% effective? • Suppose the annual deposit is $ D. Number of payments made is 11, and we want to get the accumulated value of these 11 payments at the end of 12 years, so • Solving for D, we get D = 59.21
Annuity values on any date • There are several other dates to valuing annuities rather than at the beginning of the term (t = 0) or at the end of the term (t = n). • Present values more than one period before the first payment date • Accumulated values more than one period after the last payment date • Current value between the first and the last payment dates.
Values before first payment (1) • Consider a series of payments of 1 that are made at time t = 3, 4, 5, 6, 7, 8 and 9. • At t = 2, there exists 7 future payments whose present value is represented by . If this value is discounted back to time t = 0, then the value of this series of payments is (2 periods before the first end-of-the-year payment) is . • Alternatively, at t = 3, there exists 7 future payments whose present value is represented by . If this is discounted back to time t = 0, then the value of this series of payments (3 periods before the first beginning-of-the-year payment) is
Values before first payment (2) • Another way to examine this situation is to pretend there are 9 end of year payments. This can be done by adding 2 more payments to the existing 7. In this case, let the 2 additional payments be made at t = 1 and 2. • At time t = 0, the value of the 9 payments and the two added-on payments are and respectively. • Therefore the present value at t = 0 is • Note that this results in the formula: • A more general formula is: For positive integers m and n
Values before first payment (3) • With the annuity due version, suppose 3 more payments are added to the existing 7 payments. In this case, let the 3 additional payments be made at t = 0, 1 and 2. • At time t = 0, the value of the 10 payments and the three added-on payments are and respectively. • Therefore the present value at t = 0 is • Note that this results in the formula: • A more general formula is: For positive integers m and n
Values before first payment (4) • This type of annuity is often called a deferred annuity, since payments commence only after a deferred period. • A symbol for an annuity-immediate deferred for m periods with a term of n periods after the deferral period is . • And for annuity-due is . • Thus the above annuity could be labeled or .
Values after last payment (1) • At t = 9, there exists 7 past end-of-year payments whose accumulated value is represented by . If this value is accumulated forward to time t = 12, then the value of this series of payments (3 periods after the last end-of-year payments) is: • Alternatively, at t = 10, there exists 7 past beginning-of-year payments whose accumulated value is represented by . If this value is accumulated forward to time t = 12, then the value of this series of payments (2 periods after the lastbeginning-of-year payments) is:
Values after last payment (2) • Another way to examine this situation is to add three more payments to the existing 7 so that now there are 10 end-of-year payments. Let the 3 additional payments be made at t = 10, 11 and 12 (denoted as ). • At t = 12, there now exists 10 end-of-year payments whose accumulated value is represented by . This value would then be reduced by the value of the three added-on payments, i.e. . • Therefore the accumulated value at t = 12 is . • This results in • The general formula is:
Values after last payment (3) • To use the annuity due approach, we may add just 2 more payments to the existing 7 so that now there are 9 beginning-of-year payments. Let the 2 additional payments be made at t = 10 and 11 (denoted as ). • At t = 12, there now exists 9 beginning-of-year payments whose accumulated value is represented by . This value would then be reduced by the value of the two added-on payments, i.e. . • Therefore the accumulated value at t = 12 is . • This results in . • The general formula is .
Values between first and last dates (1) • The 7 payments can be represented by an annuity-immediate or by an annuity-due depending on the time that they are evaluated • For example, at t = 2, the present value of the 7 end-of-year payments is . At t = 9, the future value of these payments is . • At a point between t = 2 and t = 9, the present value and future value can be accumulated to or discounted back respectively. • Take t = 6, the present value would be accumulated forward 4 years, the accumulated value would be discounted back 3 years. • So we have • The general formula is