Expectations hypothesis

Last updated June 22, 2019

The expectations hypothesis of the term structure of interest rates (whose graphical representation is known as the yield curve) is the proposition that the long-term rate is determined purely by current and future expected short-term rates, in such a way that the expected final value of wealth from investing in a sequence of short-term bonds equals the final value of wealth from investing in long-term bonds.

In finance, the yield curve is a curve showing several yields or interest rates across different contract lengths for a similar debt contract. The curve shows the relation between the interest rate and the time to maturity, known as the "term", of the debt for a given borrower in a given currency. For example, the U.S. dollar interest rates paid on U.S. Treasury securities for various maturities are closely watched by many traders, and are commonly plotted on a graph such as the one on the right which is informally called "the yield curve". More formal mathematical descriptions of this relation are often called the term structure of interest rates.

This hypothesis assumes that the various maturities are perfect substitutes and suggests that the shape of the yield curve depends on market participants' expectations of future interest rates. These expected rates, along with an assumption that arbitrage opportunities will be minimal, is enough information to construct a complete yield curve. For example, if investors have an expectation of what 1-year interest rates will be next year, the 2-year interest rate can be calculated as the compounding of this year's interest rate by next year's interest rate. More generally, returns (1 + yield) on a long-term instrument are equal to the geometric mean of the returns on a series of short-term instruments, as given by

(1+i_{lt})^{n}=(1+i_{st}^{\text{year 1}})(1+i_{st}^{\text{year 2}})\cdots (1+i_{st}^{\text{year n}}),

where lt and st respectively refer to long-term and short-term bonds, and where interest rates i for future years are expected values. This theory is consistent with the observation that yields usually move together. However, it fails to explain the persistence in the non-horizontal shape of the yield curve.

Definition

The expectation hypothesis states that the current price of an asset is equal to the sum of expected discounted future dividends conditional on the information known now. Mathematically if there are discrete dividend payments $d_{t}$ at times $t=1,2,...$ and with risk-free rate $r$ then the price at time $t$ is given by

P_{t}=\sum _{n=t+1}^{\infty }\left({\frac {1}{1+r}}\right)^{n-t}\mathbb {E} [d_{n}\mid {\mathcal {F}}_{t}]

where ${\mathcal {F}}_{t}$ is a filtration which defines the market at time $t$ .^[1]

In the theory of stochastic processes, a subdiscipline of probability theory, filtrations are used to model the information that is available at a given point and therefore play an important role in the formalization of random processes.

In particular, the price of a coupon bond, with coupons given by $m_{t}$ at time $t$ , is given by

A coupon payment on a bond is the annual interest payment that the bondholder receives from the bond's issue date until it matures.

P_{t}=\sum _{n=t+1}^{\infty }m_{n}B(t,n)={\frac {m_{t+1}}{1+r(t,t+1)}}+{\frac {1}{1+r(t,t+1)}}\mathbb {E} [P_{t+1}\mid {\mathcal {F}}_{t}]

where $r(t,T)$ is the short-term interest rate from time $t$ to time $T$ and $B(t,T)$ is the value of a zero-coupon bond at time $t$ and maturity $T$ with payout of 1 at maturity. Explicitly, the price of a zero-coupon bond is given by

Zero-coupon bond a bond where the face value is repaid at the time of maturity.

A zero-coupon bond is a bond where the face value is repaid at the time of maturity. Note that this definition assumes a positive time value of money. It does not make periodic interest payments, or have so-called coupons, hence the term zero-coupon bond. When the bond reaches maturity, its investor receives its par value. Examples of zero-coupon bonds include U.S. Treasury bills, U.S. savings bonds, long-term zero-coupon bonds, and any type of coupon bond that has been stripped of its coupons.

B(t,T)=\mathbb {E} [(1+r(t,t+1))^{-1}\cdots (1+r(T-1,T))^{-1}\mid {\mathcal {F}}_{t}]={\frac {1}{1+r(t,t+1)}}\mathbb {E} [B(t+1,T)\mid {\mathcal {F}}_{t}]

.^[1]

Shortcomings

The expectation hypothesis neglects the risks inherent in investing in bonds (because forward rates are not perfect predictors of future rates). In particular this can be broken down into two categories:

It has been found that the expectation hypothesis has been tested and rejected using a wide variety of interest rates, over a variety of time periods and monetary policy regimes.^[2] This analysis is supported in a study conducted by Sarno,^[3] where it is concluded that while conventional bivariate procedure provides mixed results, the more powerful testing procedures, for example expanded vector autoregression test, suggest rejection of the expectation hypothesis throughout the maturity spectrum examined. A common reason given for the failure of the expectation hypothesis is that the risk premium is not constant as the expectation hypothesis requires, but is time-varying. However, research by Guidolin and Thornton (2008) suggest otherwise.^[2] It is postulated that the expectation hypothesis fails because short-term interest rates are not predictable to any significant degree.

While traditional term structure tests mostly indicate that expected future interest rates are ex post inefficient forecasts, Froot (1989) has an alternative take on it.^[4] At short maturities, the expectation hypothesis fails. At long maturities, however, changes in the yield curve reflect changes in expected future rates one-for-one.

Related Research Articles

Discounting is a financial mechanism in which a debtor obtains the right to delay payments to a creditor, for a defined period of time, in exchange for a charge or fee. Essentially, the party that owes money in the present purchases the right to delay the payment until some future date. The discount, or charge, is the difference between the original amount owed in the present and the amount that has to be paid in the future to settle the debt.

In economics and finance, present value (PV), also known as present discounted value, is the value of an expected income stream determined as of the date of valuation. The present value is always less than or equal to the future value because money has interest-earning potential, a characteristic referred to as the time value of money, except during times of negative interest rates, when the present value will be more than the future value. Time value can be described with the simplified phrase, "A dollar today is worth more than a dollar tomorrow". Here, 'worth more' means that its value is greater. A dollar today is worth more than a dollar tomorrow because the dollar can be invested and earn a day's worth of interest, making the total accumulate to a value more than a dollar by tomorrow. Interest can be compared to rent. Just as rent is paid to a landlord by a tenant without the ownership of the asset being transferred, interest is paid to a lender by a borrower who gains access to the money for a time before paying it back. By letting the borrower have access to the money, the lender has sacrificed the exchange value of this money, and is compensated for it in the form of interest. The initial amount of the borrowed funds is less than the total amount of money paid to the lender.

The Fisher equation in financial mathematics and economics estimates the relationship between nominal and real interest rates under inflation. It is named after Irving Fisher, who was famous for his works on the theory of interest. In finance, the Fisher equation is primarily used in YTM calculations of bonds or IRR calculations of investments. In economics, this equation is used to predict nominal and real interest rate behavior.

A risk-free bond is a theoretical bond that repays interest and principal with absolute certainty. The rate of return would be the risk-free interest rate. It is primary security, which pays off 1 unit no matter state of economy is realized at time $. So its payoff is the same regardless of what state occurs. Thus, an investor experiences no risk by investing in such an asset.$

Rational pricing is the assumption in financial economics that asset prices will reflect the arbitrage-free price of the asset as any deviation from this price will be "arbitraged away". This assumption is useful in pricing fixed income securities, particularly bonds, and is fundamental to the pricing of derivative instruments.

Bond valuation is the determination of the fair price of a bond. As with any security or capital investment, the theoretical fair value of a bond is the present value of the stream of cash flows it is expected to generate. Hence, the value of a bond is obtained by discounting the bond's expected cash flows to the present using an appropriate discount rate.

In finance, the duration of a financial asset that consists of fixed cash flows, for example a bond, is the weighted average of the times until those fixed cash flows are received. When the price of an asset is considered as a function of yield, duration also measures the price sensitivity to yield, the rate of change of price with respect to yield or the percentage change in price for a parallel shift in yields.

In finance, bond convexity is a measure of the non-linear relationship of bond prices to changes in interest rates, the second derivative of the price of the bond with respect to interest rates. In general, the higher the duration, the more sensitive the bond price is to the change in interest rates. Bond convexity is one of the most basic and widely used forms of convexity in finance.

The current yield, interest yield, income yield, flat yield, market yield, mark to market yield or running yield is a financial term used in reference to bonds and other fixed-interest securities such as gilts. It is the ratio of the annual interest payment and the bond's current clean price:

A short-rate model, in the context of interest rate derivatives, is a mathematical model that describes the future evolution of interest rates by describing the future evolution of the short rate, usually written $.$

In financial mathematics, the Hull–White model is a model of future interest rates. In its most generic formulation, it belongs to the class of no-arbitrage models that are able to fit today's term structure of interest rates. It is relatively straightforward to translate the mathematical description of the evolution of future interest rates onto a tree or lattice and so interest rate derivatives such as bermudan swaptions can be valued in the model.

In finance, a bond option is an option to buy or sell a bond at a certain price on or before the option expiry date. These instruments are typically traded OTC.

Fixed income analysis is the valuation of fixed income or debt securities, and the analysis of their interest rate risk, credit risk, and likely price behavior in hedging portfolios. The analyst might conclude to buy, sell, hold, hedge or stay out of the particular security.

The Heath–Jarrow–Morton (HJM) framework is a general framework to model the evolution of interest rate curves – instantaneous forward rate curves in particular. When the volatility and drift of the instantaneous forward rate are assumed to be deterministic, this is known as the Gaussian Heath–Jarrow–Morton (HJM) model of forward rates. For direct modeling of simple forward rates the Brace–Gatarek–Musiela model represents an example.

The Z-spread, ZSPRD, zero-volatility spread or yield curve spread of a mortgage-backed security (MBS) is the parallel shift or spread over the zero-coupon Treasury yield curve required for discounting a pre-determined cash flow schedule to arrive at its present market price. The Z-spread is also widely used in the credit default swap (CDS) market as a measure of credit spread that is relatively insensitive to the particulars of specific corporate or government bonds.

In the fields of actuarial science and financial economics there are a number of ways that risk can be defined; to clarify the concept theoreticians have described a number of properties that a risk measure might or might not have. A coherent risk measure is a function $that satisfies properties of monotonicity, sub-additivity, homogeneity, and translational invariance.$

Fixed-income attribution is the process of measuring returns generated by various sources of risk in a fixed income portfolio, particularly when multiple sources of return are active at the same time.

In finance, a T-forward measure is a pricing measure absolutely continuous with respect to a risk-neutral measure but rather than using the money market as numeraire, it uses a bond with maturity T. The use of the forward measure was pioneered by Farshid Jamshidian (1987), and later used as a means of calculating the price of options on bonds.

A dual-currency note (DC) pays coupons in the investor's domestic currency with the notional in the issuer’s domestic currency. A reverse dual-currency note (RDC) is a note which pays a foreign interest rate in the investor's domestic currency. A power reverse dual-currency note (PRDC) is a structured product where an investor is seeking a better return and a borrower a lower rate by taking advantage of the interest rate differential between two economies. The power component of the name denotes higher initial coupons and the fact that coupons rise as the foreign exchange rate depreciates. The power feature comes with a higher risk for the investor, which characterizes the product as leveraged carry trade. Cash flows may have a digital cap feature where the rate gets locked once it reaches a certain threshold. Other add-on features include barriers such as knockouts and cancel provision for the issuer. PRDCs are part of the wider Structured Notes Market.

References

1 2 Gourieroux, Christian; Jasiak, Joann (2001). Financial Econometrics: Problems, Models, and Methods. Princeton University Press. p. 164. ISBN 978-0691088723.
1 2 Guidolin, M.; Thornton, D. (2008). "Predictions of Short-Term Rates and the Expectations Hypothesis of the Term Structure of Interest Rates". European Central Bank Working Paper Series: 977.
↑ Sarno, L.; Thornton, D.; Valente, G. (2007). "The Empirical Failure of the Expectations Hypothesis of the Term Structure of Bond Yields". Journal of Financial and Quantitative Analysis 42 (1): 81–100. doi:10.1017/S0022109000002192.
↑ Froot, K. (1989). "New Hope for the Expectations Hypothesis of the Term Structure of Interest Rates". The Journal of Finance. 44 (2): 283–305. doi:10.1111/j.1540-6261.1989.tb05058.x.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Gourieroux-1] 1 2 Gourieroux, Christian; Jasiak, Joann (2001). Financial Econometrics: Problems, Models, and Methods. Princeton University Press. p. 164. ISBN 978-0691088723.

[Guidolin-2] 1 2 Guidolin, M.; Thornton, D. (2008). "Predictions of Short-Term Rates and the Expectations Hypothesis of the Term Structure of Interest Rates". European Central Bank Working Paper Series: 977.

[Sarno-3] Sarno, L.; Thornton, D.; Valente, G. (2007). "The Empirical Failure of the Expectations Hypothesis of the Term Structure of Bond Yields". Journal of Financial and Quantitative Analysis 42 (1): 81–100. doi:10.1017/S0022109000002192.

[Froot-4] Froot, K. (1989). "New Hope for the Expectations Hypothesis of the Term Structure of Interest Rates". The Journal of Finance. 44 (2): 283–305. doi:10.1111/j.1540-6261.1989.tb05058.x.

Expectations hypothesis

Contents

Definition

Shortcomings

Related Research Articles

References