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时间:2024-11-25
SEEM 3590: Investment Science
Lecture Notes 7: Term Structure of Interest Rates, Forward
Rate, and Swaps
YANG Chen
Fall 2024
1 / 18
Interest Rates in the Market
▶ Various types of rates in the market
▶ Treasury rates: return rates of Treasury bills, Treasury notes,
and Treasury bonds
▶ LIBOR (London Interbank Offered Rate): representing
borrowing costs between AA-rated financial institutions
▶ Repo (repurchase agreement) rate: overnight borrowing cost
▶ LIBOR rates were usually used as short-term risk-free rates by
derivative traders.
▶ The publication of U.S. LIBOR has been ceased since July
2023. Replacements of LIBOR include SOFR (Secured
Overnight Financing Rate) and SONIA (Sterling Overnight
Index Average).
▶ Nevertheless, other interbank offered rates are still used in the
world, such as EURIBOR (for EU) and HIBOR (for Hong
Kong).
2 / 18
Example: LIBOR Rates
Figure: The quotes of LIBOR Rates on April 04, 2013. Source: Wall Street
Journal. The rates are in percentage term and are quoted rates. For instance,
the 0.28040 quote for three-month LIBOR means the interest rate in three
months is 0.28040%/4.
3 / 18
Example: Treasury Rates
Figure: Treasury rates on April 04, 2013. Source:
https://www.treasury.gov/resource-center/data-chart-center/
interest-rates/pages/textview.aspx?data=yield. The rates are
calculated from the price quotes of on-the-run Treasury bills, Treasury notes,
and Treasury bonds. For the details of the calculation methodology, refer to
http://www.treasury.gov/resource-center/data-chart-center/
interest-rates/Pages/yieldmethod.aspx
4 / 18
Term Structure of Interest Rates
▶ In the market, the interest rates for different maturities are
different!
▶ Spot rates: the interest rates representing the borrowing cost
in the period starting from today to some future time called
maturity
▶ Example: the n-year spot rate refers to the interest rate of
borrowing cost within n years.
▶ Spot rates are also known as zero rates because they
represent the return rates of zero-coupon bonds.
▶ The dependence of spot rates on its term is called the term
structure of interest rates
5 / 18
Example: Term Structure of Interest Rates
0 2 4 6 8 10 12
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Time to Maturity (months)
Sp
ot
R
at
es
w
ith
C
on
tin
uo
us
C
om
po
un
di
ng
(%
)
Figure: The Term Structure of LIBOR Rates on April 04, 2013. Source:
Wall Street Journal.
6 / 18
Discount Factors and Short Rate
▶ The rates observed in the market are usually quoted rates.
▶ Denote “today” by t and “some future time” by T . Denote
y0(t, T ) as the spot rate with continuous compounding from t
to T .
▶ The discount factor, denoted by B(t, T ), from t to T , is the
time-t value of $1 at time T . Therefore,
B(t, T ) = e−y0(t,T )(T−t).
▶ The quantity
r(t) := lim
T↓t
y0(t, T )
is called short rate, representing the instantaneous borrowing
cost today.
7 / 18
Forward Rate Agreements
▶ Forward rate agreement (FRA) is an OTC agreement that a
certain interest rate will apply to either borrowing or lending a
certain principal during a specified future period of time:
▶ t: today
▶ T1: start date of the future period
▶ T2: end date of the future period
▶ y0(T1, T2): the spot rate observed in the market at time T1 for
the period between T1 and T2
▶ K: the rate agreed in the FRA (continuously compounded)
▶ N : the principal of the FRA
▶ Settlement date is T1; at this time, the payoff of the long
position of FRA is[
N · ey0(T1,T2)(T2−T1) −N · eK·(T2−T1)
]
· e−y0(T1,T2)(T2−T1).
▶ This time T1-payoff is equivalent to the following payoff at
time T2
N · ey0(T1,T2)(T2−T1) −N · eK·(T2−T1).
8 / 18
Valuing FRA By Spot Rates
▶ Consider Strategy I: short NeK·(T2−T1) ·B(t, T2) dollar
amount for the period [t, T2] at the spot rate y0(t, T2); invest
N ·B(t, T1) dollar amount for the period [t, T1] at the spot
rate y0(t, T1) and reinvest the principal plus interest at T1 for
the period [T1, T2] at the spot rate y0(T1, T2).
▶ Initial cost of Strategy I:
N ·B(t, T1)−NeK·(T2−T1) ·B(t, T2).
▶ Payoff at T2: N · ey0(T1,T2)(T2−T1) −N · eK·(T2−T1).
▶ No intermediate cash flow
▶ Consider Strategy II: buy and hold the FRA to the settlement
date and invest the payoff for the period [T1, T2] at spot rate.
▶ Initial cost of Strategy II: value of FRA at t.
▶ Payoff at T2: N · ey0(T1,T2)(T2−T1) −N · eK·(T2−T1).
▶ No intermediate cash flow
9 / 18
Forward Rate
▶ By no arbitrage assumption, the value of the FRA at time t is
N ·
[
B(t, T1)− eK·(T2−T1) ·B(t, T2)
]
.
▶ The particular K making the value of FRA zero is called the
continuously compounded forward rate today with the
forward period [T1, T2]:
K =
T2 − t
T2 − T1 y0(t, T2)−
T1 − t
T2 − T1 y0(t, T1)
▶ The instantaneous forward rate today with forward date T
is defined as the forward rate when T1 = T , T2 = T +∆T ,
and ∆T ↓ 0.
▶ Try it yourself: show that the instantaneous forward rate is
− ∂∂T lnB(t, T ).
10 / 18
Example: Continuously Compounded Forward Rate
Assume the spot interest rate with 3-month maturity is 6.0% and
the spot interest rate with 6-month maturity is 6.2% (both are
continuously compounded). What is the forward interest rate
with continuous compounding for the second quarter (that is,
the period from 3 months later to 6 month later)?
We use the equation for continuously compounded forward rate K
on page 10. According to the question,
T1 − t = 3/12 = 0.25, T2 − t = 6/12 = 0.5, T2 − T1 = 0.25,
y0(t, T1) = 6.0%, and y0(t, T2) = 6.2%.
Therefore, K = 6.4%.
11 / 18
Forward Rate
▶ In practice, the rate agreed in FRA can also be quoted with a
compounding frequency that reflects the length of the period
to which they apply. For instance, if the quoted rate is L for
the period [T1, T2], then the interest is L · (T2 − T1).
▶ The value of FRA is modified accordingly to
N · [B(t, T1)− (1 + L · (T2 − T1)) ·B(t, T2)] .
12 / 18
Interest Rate Swaps
▶ Interest rate swaps can be regarded as swaps of different
interest payments between two parties at multiple future
times.
▶ In a vanilla interest rate swap:
▶ One party agrees to pay the other party semiannual cash flows
equal to interest at a predetermined fixed rate on a notional
principal until the maturity of the swap.
▶ In return, it receives semiannual cash flows equal to interest at
a floating rate on the same notional for the same period of
time.
▶ In a vanilla interest rate swap on LIBOR, the floating rate in
each half-year period is chosen to be the LIBOR rate at
beginning of the period with maturity to be the end of the
period. The LIBOR is quoted with semiannual compounding.
▶ Interest rate swaps on other interbank offered rates (e.g.
EURIBOR, HIBOR) work similarly.
13 / 18
Example: A Vanilla Interest Rate Swap
Microsoft entered into a $100 million 3-year interest rate swap
with a financial institution, where a fixed rate of 5% per annum is
paid and LIBOR is received. Rates are quoted with semiannual
compounding. The contract was signed on Mar. 5, 2007.
The following table shows the cash flow streams (in millions of
dollars) to Microsoft during this 3-year period.
Date Six-month Floating cash Fixed cash Net cash
LIBOR (%) flow received flow paid flow
Mar. 5, 2007 4.20
Sep. 5, 2007 4.80 +2.10 −2.50 −0.40
Mar. 5, 2008 5.30 +2.40 −2.50 −0.10
Sep. 5, 2008 5.50 +2.65 −2.50 +0.15
Mar. 5, 2009 5.60 +2.75 −2.50 +0.25
Sep. 5, 2009 5.90 +2.80 −2.50 +0.30
Mar. 5, 2010 +2.95 −2.50 +0.45
14 / 18
Pricing Interest Rate Swaps
▶ The party paying interest at the floating rate is called
floating-rate payer and the party paying interest at the fixed
rate is called fixed-rate payer.
▶ Next, we find the value of a vanilla interest rate swap with
fixed rate S, notional N , and maturity T .
▶ Denote by T1 < T2 < . . . Tn = T the interest exchange dates
in the swap.
▶ Consider the following strategy: invest N dollars at six-month
LIBOR rate, extract the interest payment after six months,
invest the principal at six-month LIBOR rate for the next
six-month period, and keep rolling until the maturity of the
interest rate swap; short N · S2 ·B(t, Ti) dollars at the spot
rate with maturity Ti, i = 1, . . . , n and short N ·B(t, T )
dollars at the spot rate with maturity T .
15 / 18
Pricing Interest Rate Swaps
▶ The cash flow stream of the strategy is same as the cash flow
stream of the interest rate swap, so, by no arbitrage, it has
same value as the swap.
▶ Thus, the value of the swap (from the fixed-rate payer’s
perspective) is[
1−
(
B(t, T ) +
S
2
n∑
i=1
B(t, Ti)
)]
N.
16 / 18
Example: Pricing an Interest Rate Swap
Consider the swap entered by Microsoft in the previous example. The
discount factors observed when the contract was signed are
Maturity Date Discount factor
Sep. 5, 2007 0.9778
Mar. 5, 2008 0.9541
Sep. 5, 2008 0.9291
Mar. 5, 2009 0.9048
Sep. 5, 2009 0.8781
Mar. 5, 2010 0.8479
How much did Microsoft pay to or receive from the financial institution
when the contract was signed?
The value of the swap from the fixed-rate payer is[
1−
(
0.8479 +
5%
2
(0.9778 + · · ·+ 0.8479)
)]
× 100
= $1.4811 million.
Therefore, Microsoft, as the fixed-rate payer, paid $1.4811 million to the
floating-rate payer when signing the contract.
17 / 18
References
▶ The relevant parts in the textbooks are: [L] Chapter 4:
Sections 1-3
18 / 18
Lecture Notes 7: Term Structure of Interest Rates, Forward
Rate, and Swaps
YANG Chen
Fall 2024
1 / 18
Interest Rates in the Market
▶ Various types of rates in the market
▶ Treasury rates: return rates of Treasury bills, Treasury notes,
and Treasury bonds
▶ LIBOR (London Interbank Offered Rate): representing
borrowing costs between AA-rated financial institutions
▶ Repo (repurchase agreement) rate: overnight borrowing cost
▶ LIBOR rates were usually used as short-term risk-free rates by
derivative traders.
▶ The publication of U.S. LIBOR has been ceased since July
2023. Replacements of LIBOR include SOFR (Secured
Overnight Financing Rate) and SONIA (Sterling Overnight
Index Average).
▶ Nevertheless, other interbank offered rates are still used in the
world, such as EURIBOR (for EU) and HIBOR (for Hong
Kong).
2 / 18
Example: LIBOR Rates
Figure: The quotes of LIBOR Rates on April 04, 2013. Source: Wall Street
Journal. The rates are in percentage term and are quoted rates. For instance,
the 0.28040 quote for three-month LIBOR means the interest rate in three
months is 0.28040%/4.
3 / 18
Example: Treasury Rates
Figure: Treasury rates on April 04, 2013. Source:
https://www.treasury.gov/resource-center/data-chart-center/
interest-rates/pages/textview.aspx?data=yield. The rates are
calculated from the price quotes of on-the-run Treasury bills, Treasury notes,
and Treasury bonds. For the details of the calculation methodology, refer to
http://www.treasury.gov/resource-center/data-chart-center/
interest-rates/Pages/yieldmethod.aspx
4 / 18
Term Structure of Interest Rates
▶ In the market, the interest rates for different maturities are
different!
▶ Spot rates: the interest rates representing the borrowing cost
in the period starting from today to some future time called
maturity
▶ Example: the n-year spot rate refers to the interest rate of
borrowing cost within n years.
▶ Spot rates are also known as zero rates because they
represent the return rates of zero-coupon bonds.
▶ The dependence of spot rates on its term is called the term
structure of interest rates
5 / 18
Example: Term Structure of Interest Rates
0 2 4 6 8 10 12
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Time to Maturity (months)
Sp
ot
R
at
es
w
ith
C
on
tin
uo
us
C
om
po
un
di
ng
(%
)
Figure: The Term Structure of LIBOR Rates on April 04, 2013. Source:
Wall Street Journal.
6 / 18
Discount Factors and Short Rate
▶ The rates observed in the market are usually quoted rates.
▶ Denote “today” by t and “some future time” by T . Denote
y0(t, T ) as the spot rate with continuous compounding from t
to T .
▶ The discount factor, denoted by B(t, T ), from t to T , is the
time-t value of $1 at time T . Therefore,
B(t, T ) = e−y0(t,T )(T−t).
▶ The quantity
r(t) := lim
T↓t
y0(t, T )
is called short rate, representing the instantaneous borrowing
cost today.
7 / 18
Forward Rate Agreements
▶ Forward rate agreement (FRA) is an OTC agreement that a
certain interest rate will apply to either borrowing or lending a
certain principal during a specified future period of time:
▶ t: today
▶ T1: start date of the future period
▶ T2: end date of the future period
▶ y0(T1, T2): the spot rate observed in the market at time T1 for
the period between T1 and T2
▶ K: the rate agreed in the FRA (continuously compounded)
▶ N : the principal of the FRA
▶ Settlement date is T1; at this time, the payoff of the long
position of FRA is[
N · ey0(T1,T2)(T2−T1) −N · eK·(T2−T1)
]
· e−y0(T1,T2)(T2−T1).
▶ This time T1-payoff is equivalent to the following payoff at
time T2
N · ey0(T1,T2)(T2−T1) −N · eK·(T2−T1).
8 / 18
Valuing FRA By Spot Rates
▶ Consider Strategy I: short NeK·(T2−T1) ·B(t, T2) dollar
amount for the period [t, T2] at the spot rate y0(t, T2); invest
N ·B(t, T1) dollar amount for the period [t, T1] at the spot
rate y0(t, T1) and reinvest the principal plus interest at T1 for
the period [T1, T2] at the spot rate y0(T1, T2).
▶ Initial cost of Strategy I:
N ·B(t, T1)−NeK·(T2−T1) ·B(t, T2).
▶ Payoff at T2: N · ey0(T1,T2)(T2−T1) −N · eK·(T2−T1).
▶ No intermediate cash flow
▶ Consider Strategy II: buy and hold the FRA to the settlement
date and invest the payoff for the period [T1, T2] at spot rate.
▶ Initial cost of Strategy II: value of FRA at t.
▶ Payoff at T2: N · ey0(T1,T2)(T2−T1) −N · eK·(T2−T1).
▶ No intermediate cash flow
9 / 18
Forward Rate
▶ By no arbitrage assumption, the value of the FRA at time t is
N ·
[
B(t, T1)− eK·(T2−T1) ·B(t, T2)
]
.
▶ The particular K making the value of FRA zero is called the
continuously compounded forward rate today with the
forward period [T1, T2]:
K =
T2 − t
T2 − T1 y0(t, T2)−
T1 − t
T2 − T1 y0(t, T1)
▶ The instantaneous forward rate today with forward date T
is defined as the forward rate when T1 = T , T2 = T +∆T ,
and ∆T ↓ 0.
▶ Try it yourself: show that the instantaneous forward rate is
− ∂∂T lnB(t, T ).
10 / 18
Example: Continuously Compounded Forward Rate
Assume the spot interest rate with 3-month maturity is 6.0% and
the spot interest rate with 6-month maturity is 6.2% (both are
continuously compounded). What is the forward interest rate
with continuous compounding for the second quarter (that is,
the period from 3 months later to 6 month later)?
We use the equation for continuously compounded forward rate K
on page 10. According to the question,
T1 − t = 3/12 = 0.25, T2 − t = 6/12 = 0.5, T2 − T1 = 0.25,
y0(t, T1) = 6.0%, and y0(t, T2) = 6.2%.
Therefore, K = 6.4%.
11 / 18
Forward Rate
▶ In practice, the rate agreed in FRA can also be quoted with a
compounding frequency that reflects the length of the period
to which they apply. For instance, if the quoted rate is L for
the period [T1, T2], then the interest is L · (T2 − T1).
▶ The value of FRA is modified accordingly to
N · [B(t, T1)− (1 + L · (T2 − T1)) ·B(t, T2)] .
12 / 18
Interest Rate Swaps
▶ Interest rate swaps can be regarded as swaps of different
interest payments between two parties at multiple future
times.
▶ In a vanilla interest rate swap:
▶ One party agrees to pay the other party semiannual cash flows
equal to interest at a predetermined fixed rate on a notional
principal until the maturity of the swap.
▶ In return, it receives semiannual cash flows equal to interest at
a floating rate on the same notional for the same period of
time.
▶ In a vanilla interest rate swap on LIBOR, the floating rate in
each half-year period is chosen to be the LIBOR rate at
beginning of the period with maturity to be the end of the
period. The LIBOR is quoted with semiannual compounding.
▶ Interest rate swaps on other interbank offered rates (e.g.
EURIBOR, HIBOR) work similarly.
13 / 18
Example: A Vanilla Interest Rate Swap
Microsoft entered into a $100 million 3-year interest rate swap
with a financial institution, where a fixed rate of 5% per annum is
paid and LIBOR is received. Rates are quoted with semiannual
compounding. The contract was signed on Mar. 5, 2007.
The following table shows the cash flow streams (in millions of
dollars) to Microsoft during this 3-year period.
Date Six-month Floating cash Fixed cash Net cash
LIBOR (%) flow received flow paid flow
Mar. 5, 2007 4.20
Sep. 5, 2007 4.80 +2.10 −2.50 −0.40
Mar. 5, 2008 5.30 +2.40 −2.50 −0.10
Sep. 5, 2008 5.50 +2.65 −2.50 +0.15
Mar. 5, 2009 5.60 +2.75 −2.50 +0.25
Sep. 5, 2009 5.90 +2.80 −2.50 +0.30
Mar. 5, 2010 +2.95 −2.50 +0.45
14 / 18
Pricing Interest Rate Swaps
▶ The party paying interest at the floating rate is called
floating-rate payer and the party paying interest at the fixed
rate is called fixed-rate payer.
▶ Next, we find the value of a vanilla interest rate swap with
fixed rate S, notional N , and maturity T .
▶ Denote by T1 < T2 < . . . Tn = T the interest exchange dates
in the swap.
▶ Consider the following strategy: invest N dollars at six-month
LIBOR rate, extract the interest payment after six months,
invest the principal at six-month LIBOR rate for the next
six-month period, and keep rolling until the maturity of the
interest rate swap; short N · S2 ·B(t, Ti) dollars at the spot
rate with maturity Ti, i = 1, . . . , n and short N ·B(t, T )
dollars at the spot rate with maturity T .
15 / 18
Pricing Interest Rate Swaps
▶ The cash flow stream of the strategy is same as the cash flow
stream of the interest rate swap, so, by no arbitrage, it has
same value as the swap.
▶ Thus, the value of the swap (from the fixed-rate payer’s
perspective) is[
1−
(
B(t, T ) +
S
2
n∑
i=1
B(t, Ti)
)]
N.
16 / 18
Example: Pricing an Interest Rate Swap
Consider the swap entered by Microsoft in the previous example. The
discount factors observed when the contract was signed are
Maturity Date Discount factor
Sep. 5, 2007 0.9778
Mar. 5, 2008 0.9541
Sep. 5, 2008 0.9291
Mar. 5, 2009 0.9048
Sep. 5, 2009 0.8781
Mar. 5, 2010 0.8479
How much did Microsoft pay to or receive from the financial institution
when the contract was signed?
The value of the swap from the fixed-rate payer is[
1−
(
0.8479 +
5%
2
(0.9778 + · · ·+ 0.8479)
)]
× 100
= $1.4811 million.
Therefore, Microsoft, as the fixed-rate payer, paid $1.4811 million to the
floating-rate payer when signing the contract.
17 / 18
References
▶ The relevant parts in the textbooks are: [L] Chapter 4:
Sections 1-3
18 / 18
