Term Structure of Interest Rates

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Term Structure of Interest Rates

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Title: Term Structure of Interest Rates

1
Term Structure of Interest Rates

Earlier, we assumed a single interest rate. Now
we relax this assumption and consider different
interest rates by periods. The result will be
more realistic models and analysis.

Factors affecting bond yield to maturity
- quality (lower quality ? higher yield
expected)
- time to maturity long bonds tend to offer
higher yields than short bonds of the same
quality (more risk in long bonds)
Inverted Yield Curve. Sometimes long bonds have
lower yields than short bonds. Short-term rates
may increase rapidly, but investors may believe
the increase is temporary, so that long-term
yields remain near their previous levels.

Important question to consider in studying a
bond. How does its yield and maturity compare
with others in its risk class? A bond which is
far from the curve is usually there for a good
reason bond-specific call features, or concerns
about insolvency.

Term Structure
Term structure provides a more basic theory than
is available by just using a yield curve. It
provides more insight into interest rates than
the yield curve does.
Basic Idea. The interest rate charged (or paid)
for money depends on the length of time that the
money is held.
The spot rate st is the rate of interest,
expressed in yearly terms, charged (or paid) for
money held from the present until time t. Both
interest and principal are paid at time t.

Examples
1) One-year spot rate, s1 5.
You deposit 1,000 in a bank today. At the end
of a year the bank pays you 1,000 ? 1.05
1,050.
2) Two-year spot rate, s2 5.5
You deposit 1,000 in a bank today. At the end
of 2 years the bank pays you 1,000 ? 1.0552
1,113.03.
3) t-year spot rate, st
You deposit 1,000 in a bank today. At the end
of t years the bank pays you 1,000 ? (1st)t

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Discount Factors and Present Value
For each spot rate st there is a discount factor
dt. The discount factor is the reciprocal of the
growth factor the spot rate defines.
If, using the spot rate st, an amount M grows to
M gt M in t years, then M dt ? M. The
discount factor is the factor by which future
cash flows must be multiplied to obtain an
equivalent present value. That is, dt 1/gt .
Given CFS (x0, x1, , xn)
PV x0 d1 x1 d2 x2 dn xn.

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Determining the Spot Rate
If we know the prices of a series of zero-coupon
bonds with various maturity dates, we can use
their yields to define the spot rates. Such
information may be sparse, or unavailable.
However there are some other ways to determine
spot rates.

Example. Using one spot rate to compute
another.
The known interest rate of a 1-year Treasury bill
gives s1.
Now consider a 2-year bond, with price P, coupon
payments of C, and face value F. The price
should satisfy
P C/(1s1) (C F)/(1s2)2.
We can solve this equation for s2, since we know
all the other terms.
Similarly, if we find a 3-year bond, by knowing
s1 and s2 we can compute s3. Continuing in this
way, we can find s4, then s5, etc.

Solve for s2.
12

Example 4.3 Construction of a zero (p. 77).
Cancellation approach.
Bond A is a 10-year bond with a 10 coupon, and
PV of PVA. Bond B is a 10-year bond with an 8
coupon, and PV of PVB. Bonds A and B have prices
of 98.72 and 85.89 respectively.
A 10 years, 10, PA 98.72, normalized face
value 100
B 10 years, 8, PB 85.89, normalized face
value 100.

Buy uA units of bond A, uB units of bond B.
Bond A coupon value CA 1 ? 100
Bond B coupon value CB 0.8 ? 100
key idea choose uA, uB to get uA ? CA uB ? CB
, then uBB -uAA is a zero coupon bond because
coupon payments of the new instrument equal zero
With uA0.8 and uB1 we have uA ? CA uB ? CB

Price of new instrument equals
P uBPB -uAPA 1 ? 85.89 - 0.8 ? 98.72 6.914
Face value equals
F uBFB -uAFA1 ? 100 - 0.8 ? 100 20
Interest rate s10 can be found from the equation
6.914 20/(1s10)10 ? 6.914 20/(1s10)10
Conclude s10 11.2065

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Forward Rates

Example. A bank offers spot rates s1, s2.
1) We put 100 in a 2-year account. Its value at
the end of 2 years is 100 ? (1s2)2.
2) Alternatively, we put 100 in a 1-year account
today. We know its value in 1 year will be 100 ?
(1s1). We also arrange today to loan the
proceeds for 1 year, beginning in a year. The
loan will accrue interest at a rate of f which we
agree upon today. The rate f is called the
forward rate. At the end of 2 years we receive
100 ? (1s1) ? (1f).

Forward rates are interest rates for money to be
borrowed between two dates in the future, but
under terms agreed upon today.
Two alternatives
- returns 100 ? (1s2)2
- returns 100 ? (1s1) ? (1f )
By the comparison principle, we should get the
same return either way
(1s2)2 (1s1) ? (1f ) ? f (1s2)2
/(1s1) 1

Example 4.4. s1 7, s2 8.
f (1s2)2 /(1s1) 1 (1.08)2 /(1.07)
1 0.09009 ? 9.01.
An arbitrage argument justifies the comparison
principle.
This argument assumes no transaction costs, and
identical borrowing and lending rates. These are
not bad assumptions for large transactions and
highly competitive lending/borrowing markets.
Even if we do not make the arbitrage assumption,
the comparison principle is reasonable. If there
were a difference in rates between the two
alternatives, both investors and borrowers
involved in 2-year loans would choose the best
alternative. Market forces would tend to adjust
the rates.

Forward rate definition. The forward rate
between times t1 and t2 with t1 by f(t1,t2). It is the rate of interest, agreed
upon today, charged for borrowing money at time
t1 which is to be repaid (with interest) at time
t2.
Notation Comment. If t1 i, t2 j, we write
fij or fi,j instead of f(t1,t2).
Forward rates are usually expressed on an
annualized basis, just like spot rates and other
rates.

Remarks
The forward rate for lending may differ from that
for borrowing.
Calculated forward rates, determined from a set
of spot rates, are often called implied forward
rates.
A market forward rate is one charged in the
market.

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m periods per year
(1sj/m)j (1si/m)i ? (1fi,j/m)j-I
forward rate equals
fi,j m (1sj/m)j/(1si/m)i1/(j-i) - m
Continuous time
est? t? est t ef(t,t?) (t?-t)
forward rate equals
f(t,t?) st? t? st t/(t? t)

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Term Structure Explanations

Basic Question. Why are the yield curves, and
spot rate curves, almost never flat?
- If the curves were flat, they would be like
common interest rates.
- Why do they usually slope upwards?
Three standard answers to the question
- Expectations Theory
- Liquidity Preference (liquidity risk, interest
rate risk
s)
- Market Segmentation

Expectations Theory Explanation
Spot rates are determined by expectations of
what rates will be in the future.
- If the curve slopes upwards, it is because the
market believes that the 1-year rate will likely
go up next year. (e.g., inflation.)
- An expectation is only an average guess, not
definite information.
Expectations can be expressed in terms of forward
rates more precisely.

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Weaknesses of expectations theory
The market expects rates to increase whenever the
spot rate curve slopes upwards practically all
the time.
Rates do not go up as often as expectations would
imply.

Liquidity Preference (liquidity and interest
rate risk)
In this context, liquidity means investors
prefer short-term bonds to long-term bonds. They
may need to sell their bonds soon, and know
short-term bonds are less sensitive to interest
rate changes than long-term bonds. To induce
investors into long-term instruments, better
rates must be offered.
(Liquidity usually means that the investments can
be easily bought and sold. A 1-year treasury
note would be liquid real estate might not be.
Long-term bonds are in fact liquid in the sense
that they are easily bought or sold.)

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Moderated Version of Market Segmentation
Although the market is basically segmented,
individual investors are willing to shift
segments if the rates in an adjacent segment are
substantially more attractive than those of the
main target segment.
This willingness to shift means rates in adjacent
segments must bear some relationship to each
other, and be a curve instead of a jumble of
disjointed numbers.

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Short Rates
Short rates are the forward rates spanning a
single time period.
The set of short rates completely specifies a
term structure. Thus, they can be considered
just as fundamental as spot rates, which also
completely specify a term structure.

We can compute spot rates from short rates.
Interest earned from time 0 to time k is the same
as interest that would be earned by rolling over
an investment each year. That is,
(1sk)k (1r0)(1r1) ... (1rk-1)
If we knew the short rates, we could compute sk.
Example
(1s2) 2 (1r0)(1r1) ? (1.0645)2
(1.06)(1.069019)
See file FORWARDS.XLS with an example.

Invariance Theorem
This theorem basically says the following. If
interest rates evolve according to expectation
dynamics, and you invest a sum of money in F-I
securities in almost anyway whatsoever for n
years, then you get the same amount at the end of
year n. In other words, under expectation
dynamics, how you invest in F-I securities does
not much matter. Every investment strategy would
yield the same result as investing in a single
zero-coupon bond for n years.

Implications of Invariance Theorem.
The result is useful for structuring an actual
F-I portfolio. It implies that the only reason
for selecting a mixture of bonds must be due to
anticipated deviations from expectation dynamics
deviations of the realized short rates from
their originally implied values.
In a sense, expectation dynamics is the simplest
assumption about the future, because it implies
your investment results do not depend upon your
investment strategy.

Running Present Value
Running PV is an alternative, recursive approach
to computing PV.
- is the preferred calculation approach in later
chapters,
- uses concepts of expectation dynamics,
- does not require the assumption that rates
follow expectations dynamics.

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Example for insight
CFS (x0,x1,x2,x3,x4) with PV PV(0)
PV(0) ? x0 d1 x1 d2 x2 d3 x3 d4 x4
x0 d1x1 d2/d1 x2 d3/d1 x3
d4/d1 x4
x0 d1 PV(1)
recall dik dij djk, i

Continuing recursively we have
PV(4) x4
PV(3) x3 d34 PV(4)
PV(2) x2 d23 PV(3)
PV(1) x1 d12 PV(2)
PV(0) x0 d01 PV(1)

Thus running PV always uses short rates to
determine the discount factors.
rk fk,k1 is the short rate at time k.
dk,k1 1/(1fk,k1) 1/(1rk)
Reminder. The above rates are all computed
starting with the spot rates, sk
rk fk,k1 (1sk1)k1/(1sk)k - 1, for
all k,

Present value updating
PV(k) xk dk,k1 ? PV(k1), k 0, 1., ...,
n-1
dk,k1 1/(1fk,k1) 1/(1rk)
To carry out the computations in a recursive
manner the process is initiated at the final
time. One first calculates PV(n) xn and then
continue the process backward.

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Flat Spot Rates
If every spot rate sk r, then every forward
rate r. This means every dk,k1 1/(1r).
This means, for the CFS (x0,x1, ..., xn), RPV
gives
PV(n) xn
PV(k) xk dk,k1 ? PV(k1), k 0, 1., ...,
n-1
PV(k) xk 1/(1r) ? PV(k1), k 0, 1., ...,
n-1

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Floating Rate Bonds

A floating rate note or bond has
a fixed face value,
a fixed maturity,
its coupon payments are tied to current (short)
rates of interest.

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Comments
We do not know the exact value of future coupon
payments until 6 months before they are due.
This makes it look difficult to assess the value
of such a bond.
In fact, the value is easy to deduce.

Reminder. Yied of the par bond equals the
interest rate. Value of par bond at coupon
payment times equal to face value. A par bond
with a 10,000 face (or par value) pays 10,000
at maturity.
Theorem 4.1 Floating Rate Value. The value of
a floating rate bond is equal to par at any reset
point.

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Portfolio Duration Revisited

Earlier duration ideas were based on the idea of
a yield that was invariant with time. Changes in
yield,e.g., spot rate changes, can create risk.
In the term structure framework, we consider a
different, yet related measure of risk.
A flat spot rate curve would represent yield.
Changes in the yield would thus move the curve up
or down, creating parallel shifts.

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Shifting spot rate curve
Initial spot rates
s1, s2, ..., sn
Shifted spot rates
s1 ?, s2 ?, ..., sn ?

The term ? is the amount of the shift (? ? 0)

Fisher-Weil Duration (continuous compounding)
CFS (xt0, xt1, xt2, ..., xtn)
Spot Rate Curve st0, st1, st2, ..., stn
Present Value of CFS
PV xt0 e-st0 t0 xt1 e-st1 t1 xt2 e-st2 t2
... xtn e-stn tn
Fisher-Weil Duration DFW
(t0 xt0 e-st0 t0 t1 xt1 e-st1 t1 t2 xt2 e-st2
t2 ...
tn xtn e-stn tn) / PV

Fisher-Weil Duration uses
xt0 e-st0 t0/PV as the weight of t0,
xt1 e-st1 t1/PV as the weight of t1
xt2 e-st2 t2/PV as the weight of t2
...
xtn e-stn tn/PV as the weight of tn
These weights total to one. DFW is between the
minimum and maximum of the ti (when each weight
is nonnegative).

Price/Present Value of CFS as function of ?
P(?) xt0 e-(st0 ?) t0 xt1 e-(st1 ?) t1
... xtn e-(stn ?) tn
When ? 0 we get the current PV. The rate of
change of P(?) in the neighborhood of 0 is the
rate of change of the price as ? changes from 0.
Denote by PV?(0) the first derivative of P(?)
evaluated at ? 0. Since the derivative of eax
wrt x is aeax, we find
P?(0) - (t0 xt0 e-st0 t0 t1 xt1 e-st1 t1
t2 xt2 e-st2 t2 ...
tn xtn e-stn tn) DFW ? PV(0)

Calculating of sensitivities
Note it is essentially the same formula we found
for yield sensitivity in Ch. 3. ( (1/P) dP/d?
- DM ).

Discrete-Time Compounding
For the CFS (x0, x1, x2, ..., xn) with
compounding m times per year, and spot rate sk
for each period k, P(0) is the present
value/price of the CFS. When we add ? to each
spot rate in the equation for P(0) we get P(?).

Discrete-Time Compounding (Contd)
The derivative of P(?) evaluated at 0, P?(0), is
the rate of change of the price with respect to ?
when ? is currently 0

Quasi-modified duration
Quasi-modified duration satisfies
P?(0)/P(0) DQ.

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Immunization Revisited

The earlier approach in Chapter 3, when there is
only one interest rate, generalizes in a direct
manner to protect against a spot rate parallel
shift.

Example illustrating immunization approach
We have a 1 M obligation payable in 5 years
(Spot rate curve from Table 4.4, s5
9.7542855).
We wish to choose an immunized bond portfolio.
We consider 2 bonds, each with face value 100
Bond B1 12-year, 6 bond with price 65.95
Bond B2 5-year, 10 bond with price 101.66.

Approach (Matching equations, Goal Programming)
We want to find x1 and x2, the number of units of
bonds 1 and 2 respectively, to purchase to
immunize our portfolio.

Steps
Compute P1 65.95, P2 101.66, PVs of bonds
1 and 2.
Compute D1, D2, the quasi-modified durations of
bonds 1 and 2.
Compute PV, the present value of the obligation,
1 M/(1s5)5 627,903.01.
Compute D, the quasi-modifed duration of the
obligation, 5/(1s5) 4.56.
Solve the equations and get
x1 2,208.17, x2 4,744.03

Table 4.5. Immunization Results. The overall
portfolio is immunized against parallel shifts in
the spot rate curve.

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Steps
dt 1/(1st)t is the discount factor for year t
Multiply each cash flow by dt to get contribution
to PV
Total PV contributions to get PV for each bond
(65.95, 101.66).
-PV?1 gives the contributions to PV?1 multiply
each cash flow by t and by (1st)-(t1) to get
these contributions.
Total the -PV?1 contributions to get -PV?1
466.00
Divide 466 by 65.95 to get the duration for bond
1.
Similarly for bond 2.