On September 13, 2011 Kamakura Corporation released the study “Inside the Kamakura Book of Yields: A Pictorial History of 50 Years of U.S. Treasury Forward Rates,” which was followed by the release on September 26, 2011 of “Inside the Kamakura Book of Yields, Volume II: A Pictorial History of 50 Years of U.S. Treasury Zero Coupon Bond Yields.” Finally, on October 5, 2011, Kamakura released the third volume in this series, “Inside the Kamakura Book of Yields, Volume III: A Pictorial History of 50 Years of U.S. Treasury Par Coupon Bond Yields.” This blog entry quantifies some of the key conclusions of this 50 year study of par coupon bond yields, which includes every business day of U.S. Treasury yields from January 2, 1962 through August 22, 2011.
Dickler, Jarrow and van Deventer’s “Inside the Kamakura Book of Yields” series is based on U.S. Treasury yields provided daily by the Board of Governors of the Federal Reserve System. Monthly forward rates1 are extracted from these yields using the maximum smoothness forward rate smoothing approach developed by Adams and van Deventer (Journal of Fixed Income, 1994) and corrected in van Deventer and Imai, Financial Risk Analytics (1997). Calculations were done using Kamakura Risk Manager version 7.3. The same data produces monthly forward rates, monthly zero coupon bond yields, and a semi-annual par coupon bond yield curve on a fully consistent basis.
Dickler, Jarrow and van Deventer summarized their conclusions from looking at 12,395 days of U.S. Treasury forward rate curves as follows:
- Forward rate curves and zero coupon bond yields display a richness of shapes that are not accurately captured by the academic literature on this topic.
- The evolution of the term structure of interest rates is driven by a larger number of risk factors than the 1, 2 or 3 factor models commonly employed in the academic literature.
- The maximum smoothness forward rate smoothing procedure is robust, generating smooth and stable forward rates even during periods of severe disruption in the financial markets, like the credit crisis of 2007-2008, the Russian debt crisis in 1998, and in the 1980-1982 period when interest rates were at historic highs.
- Large movements in forward rates, zero yields, and par coupon bond yields appear to be almost exclusively triggered by one of two events: a change in the maturities reported by the Federal Reserve, which adds or subtracts key information used in the smoothing process, or specific financial market events like the September 14, 2008 bankruptcy announcement by Lehman Brothers.
- In response to a “flight to quality” in the U.S. Treasury market, the 30 year bond yield declines more than yields at intermediate maturities, causing a hump in the forward rate curve and zero coupon bond yield curve that can persist for extensive lengths of time. This phenomenon is not readily captured by existing academic models of the term structure.
In the remainder of this blog, we ask whether the same conclusions apply equally well to the 12,395 days of monthly U.S. Treasury par coupon bond yields.
The Dickler, Jarrow and van Deventer paper “Inside the Kamakura Book of Yields: A Pictorial History of 50 Years of U.S. Treasury Forward Rates” is available at this link:
The Dickler, Jarrow and van Deventer paper “Inside the Kamakura Book of Yields, Volume II: A Pictorial History of 50 Years of U.S. Treasury Zero Coupon Bond Yields” is available at this link:
The Dickler, Jarrow and van Deventer paper “Inside the Kamakura Book of Yields, Volume III: A Pictorial History of 50 Years of U.S. Treasury Par Coupon Bond Yields” is available at this link:
The blog entry by Dickler and van Deventer “Inside the Kamakura Book of Yields: An Analysis of 50 Years of Daily U.S. Treasury Forward Rates” is available at this link:
The blog entry by Dickler and van Deventer “Inside the Kamakura Book of Yields: An Analysis of 50 Years of Daily U.S. Treasury Zero Coupon Bond Yields” is available at this link:
Dickler, Jarrow and van Deventer noted that the maturities at which the Federal Reserve provided yield data in its H15 statistical release changed fairly frequently over the 1962-2011 period:
The first issue considered by Dickler, Jarrow and van Deventer was the variability of shapes of the forward rate curve actually observed over this period of history. In this blog, we take an approach consistent with Heath, Jarrow and Morton: we take the forward rate curves and related zero coupon and par coupon bond yield curves as facts and ask what type of yield curve modeling would produce curves and curve movements consistent with that history.
Zero Coupon Bond Yield Curve Shapes
Over 12,395 days of data, what par coupon bond yield curve shapes have prevailed and how often have they prevailed? By number of occurrences, this chart summarizes the number of times the par coupon bond yield curve has been monotonically increasing or decreasing or humped:
Unlike the zero coupon bond yield curve history, which was never monotonically downward sloping, the par coupon bond yield curve has been monotonically downward sloping on 529 days during the 50 year period studied. This compares with 66 days in which the monthly forward rate curve was monotonically downward sloping. The par coupon bond yield curve was monotonically upward sloping on 4,050 days.
By probability of historical occurrence, we can summarize the data this way:
The par coupon bond yield curve has been humped on 63.06% of business days, compared to a figure of 93.32% for the monthly forward rate curve.
Complexity of Par Coupon Bond Yield Curve Shapes
A number of related questions arise. How complex are the shapes of the par coupon bond yield curve? When it shows a humped shape, is there just one hump or many? For the most part, commonly used academic term structure models implicitly assume that there are zero or very few humps in the zero coupon bond yield curve and associated par coupon bond yield. The analysis of 12,395 days of data show that there have been as many as 9 optima (local maximums or minimums) in the forward rate curve and that this is in part a result of the number of input maturities to the smoothing process. The chart below describes the results for the par coupon bond yield curve:
While there were fewer optima (local minima and maxima) for the par coupon bond yield curve than for the associated forward curve, a yield curve model would have to be capable of producing a par coupon yield curve with as many as 4 optima to capture 92 percent of the shapes that have occurred between January 2, 1962 and August 22, 2011. To accurately model 100% of the actual par coupon yield curve shapes, a functional form that can produce up to 7 optima would be necessary. The year 2010 was a year in which the Federal Reserve’s near zero interest rate policy created a forward rate curve with very few optima. The related par coupon bond yield curve for 2010 is shown here:
By contrast, 2009 was a year in which complex forward rate curves frequently prevailed due to the late 2008 collapse of Lehman Brothers, AIG, Wachovia, Washington Mutual and many others. The shapes of the associated par coupon bond yield curves are somewhat less complex. The par coupon bond yields for 2009 are shown in this graph:
The dramatic decline of long term forward rates in 2009, as explained by Dickler, Jarrow and van Deventer, comes about because a “flight to quality” tends to drive down 30 year U.S. Treasury yields much more than intermediate yields, forcing forward rates in the long maturities to drop by more. This is what happened in the fourth quarter of 2008, persisting through most of 2009. The impact of these forward rate moves is reflected in a more subtle way in the associated zero coupon bond yield curves and par coupon bond yields.
Most Frequent Maturities at Which Optima Occur
We then pose a related question: at what maturities (in months) are optima most likely to occur in the par coupon bond yield curve? The results are summarized in this graph:
As one might imagine, the optima are most likely to occur near key “knot points” in the data provided by the Federal Reserve. When one looks at the 3 month moving average of the probability of an optima, the peak probabilities come at the following months:
The most frequent optima are at months 24, 48, 96, 138, 186, and 258. These optima are close to knot points (data at which the Federal Reserve provides data) at months 24, 60, 84, 120, and 240.
Volatility of Par Coupon Bond Yields
The popular single factor term structure model of Vasicek (see van Deventer, Imai and Mesler, 2004) implies that zero coupon bond yields and forward rates will be more volatile at the shortest maturities, with volatility declining monotonically as the maturity lengthens. A simple graph of the high, low and average par coupon bond yields by month of maturity from 1962 to 2011 shows, however, that par coupon bond yields at the long end of the curve may in fact cover a wider range than par coupon bond yields at intermediate maturities:
The simple standard deviation of par coupon bond yields over the 1962-2011 period, however, generally declines as maturity lengthens, a much different volatility profile than the one for monthly forward rates. The jump in standard deviations from month 120 onward stems from the fact that no yields beyond 10 years in maturity were available until February 15, 1977.
The complexity of daily changes in par coupon bond yields is much greater than the simple standard deviation of the absolute level of par coupon bond yields. The graph below shows the standard deviation of daily changes in par coupon bond yields, both including and excluding the first day after a change in the Federal Reserve’s data regime. In the case of par coupon bond yields, the difference between standard deviations “with and without” the data after a regime change is quite large and an analysis of daily par coupon yield changes must eliminate the first day after a change in data regime to get an accurate view of the volatility of daily par coupon yield changes. The red line below shows the standard deviation of daily changes of the par coupon yield curve after eliminating the first data point after a data regime change. The longest term par coupon yield standard deviations are generally less than intermediate term yield standard deviations, which show a modest hump relative to short term yield standard deviations. This humped pattern is more obvious when reviewing the daily standard deviations of forward rates or zero coupon bond yields:
Smoothness of the Calculated Zero Coupon Bond Yield Curves
Adams and van Deventer (1994) adopt a common definition of smoothness used in engineering and computer graphics, the integral of the squared second derivative of the forward rate over the length of the forward rate curve. We can approximate this by taking the sum of the squared second differences of the (up to) 60 semi-annual par coupon bond yields on each of the 12,395 business days in the data set.
If we calculate Z[t] for t=1,12395 over our entire data set, we get a distribution of smoothness indices that shows an extremely high degree of smoothness. Because the data has a semi-annual periodicity instead of a monthly periodicity, we cannot compare the absolute level of the smoothness index with that for zero coupon bond yields or forward rates.2
Substantially all of our 12,395 observations show a smoothness index (using zero coupon bond yields expressed in percent) of less than 0.19. If we cap the number of observations, we see that none of the 12,395 observations has a smoothness statistic over 0.96:
The “least smooth” observations are those with the highest smoothing index Z. We list those dates here:
The 17 least smooth par coupon bond yield curves fall between August 23 and October 1, 1982. All but four of the 25 least smooth par coupon bond yield curves fall between August 20 and October 1, 1982. We graph the August-October 1982 period here:
By inspection, it is obvious that the lack of smoothness relative to other dates in the 1962-2011 period is due to the input interest rates, which cause a sharp rise and then flattening in the yield curve over this period. This is not something caused by the smoothing technique; it’s a function of the inputs from the Federal Reserve H15 statistical release for those dates.
Correlation among Forward Rates
The correlation among the 60 semi-annual par coupon bond yields can be calculated for those days between January 2, 1962 and August 22, 2011 for which data exists. The graph below shows that the correlation between the first 6 month par coupon bond yield and the 360 month par coupon bond yield is 89.9%, well above the 360 month forward rate correlation with the 1 month forward (spot) rate at 65%:
Kamakura’s analysis of this data set is continuing. Suggestions are welcome at firstname.lastname@example.org.
Adams, Kenneth J. and Donald R. van Deventer. “Fitting Yield Curves and Forward Rate Curves with Maximum Smoothness.” Journal of Fixed Income, June 1994.
Dai, Qiang and Kenneth J. Singleton, “Specification Analysis of Affine Term Structure Models,” The Journal of Finance, Volume LV, Number 5, October 2000.
Dai, Qiang and Kenneth J. Singleton, “Term Structure Dynamics in Theory and Reality,” The Review of Financial Studies, Volume 16, Number 3, Fall 2003.
Dickler, Daniel T., Robert A. Jarrow and Donald R. van Deventer, “Inside the Kamakura Book of Yields: A Pictorial History of 50 Years of U.S. Treasury Forward Rates,” Kamakura memorandum, September 13, 2011.
Dickler, Daniel T., Robert A. Jarrow and Donald R. van Deventer, “Inside the Kamakura Book of Yields, Volume II: A Pictorial History of 50 Years of U.S. Treasury Zero Coupon Bond Yields,” Kamakura memorandum, September 26, 2011.
Dickler, Daniel T., Robert A. Jarrow and Donald R. van Deventer, “Inside the Kamakura Book of Yields, Volume III: A Pictorial History of 50 Years of U.S. Treasury Par Coupon Bond Yields,” Kamakura memorandum, October 5, 2011.
Duffie, Darrell and Rui Kan, “Multi-factor Term Structure Models,” Philosophical Transactions: Physical Sciences and Engineering, Volume 347, Number 1684, Mathematical Models in Finance, June 1994.
Duffie, Darrell and Kenneth J. Singleton, “An Econometric Model of the Term Structure of Interest-Rate Swap Yields,” The Journal of Finance, Volume LII, Number 4, September 1997.
Duffie, Darrell and Kenneth J. Singleton, “Modeling Term Structures of Defaultable Bonds,” The Review of Financial Studies, Volume 12, Number 4, 1999.
Heath, David, Robert A. Jarrow and Andrew Morton, “Bond Pricing and the Term Structure of Interest Rates: A New Methodology for Contingent Claims Valuation,” Econometrica, 60(1), January 1992.
van Deventer, Donald R. and Kenji Imai, Financial Risk Analytics: A Term Structure Model Approach for Banking, Insurance, and Investment Management, Irwin Professional Publishing, Chicago, 1997.
van Deventer, Donald R., Kenji Imai, and Mark Mesler, Advanced Financial Risk Management, John Wiley & Sons, 2004. Translated into modern Chinese and published by China Renmin University Press, Beijing, 2007.
Donald R. van Deventer and Daniel T. Dickler
October 6, 2011
© Copyright 2011 by Donald R. van Deventer, All Rights Reserved.
1 For computational convenience, it was assumed that each month is the same length, 1/12 of one year, rather than using exact day count of 28, 29, 30 or 31 days for the length of the month.
2 One can approximate a mapping from a monthly data interval to semi-annual data interval if one is willing to assume that the monthly change in rates will be on average 1/6th of the semi-annual change in rates.