Multi-curve framework
In mathematical finance the multi-curve framework refers to [1] the use of multiple curves to price different types of fixed income securities and derivatives, based on their characteristics, particularly tenor, but also currency.
Context
[edit ]Historically interest rate swaps, IRSs, were valued using discount factors derived from the same curve used to forecast the LIBOR (-IBOR) rates for payment (the erstwhile reference rates; see below re MRRs). This has been called "self-discounted". Following the 2008 financial crisis, however, it became apparent that the approach was not appropriate, and alignment towards discount factors associated with physical collateral of the IRSs was needed. [2] [3] [4]
Thus, the now-standard pricing approach is the "multi-curve framework" where separate discount curves and forecast curves are built; here, respectively:
- Overnight index swap (OIS) rates are typically used to derive discount factors, since that index is the standard inclusion on Credit Support Annexes (CSAs) to determine the rate of interest payable on collateral for IRS contracts.
- As regards the payment / rates forecast, since the basis spread between LIBOR rates of different maturities widened during the crisis, forecast curves are generally constructed for each LIBOR tenor used in floating rate derivative legs.[5]
Note that, context dependent, the reference to "multi-curves" may also include the various curves relating to credit quality as required for, e.g., XVA-modelling, also a post-crisis practice. (Where the underlying-instrument exhibits optionality — caps and floors, swaptions, embedded derivatives — so a volatility "cube" will be further required.) Investment banks will similarly value their bonds using CSA-linked discount curves, while adjusting the expected cashflows - coupons and "face" - for default risk via the use of an issuer credit curve.
Curve construction
[edit ]Although the Multi-curve framework modifies the overall approach, there is no change to the economic pricing principle: swap leg values are still identical at initiation (see Rational pricing § Swaps). What differs is that, as above, separate curves are constructed for payments and for discounting.
Thus, regarding the curve build, the following emerges. [6] [7] [8] Under the old framework a single self-discounted curve was "bootstrapped" for each tenor; i.e.: solved such that it exactly returned the observed prices of selected instruments—IRSs, with FRAs in the short end—with the build proceeding sequentially, date-wise, through these instruments. Under the new framework, the various curves are best fitted to observed market prices as a "curve set": one curve for discounting, and one for each IBOR-tenor "forecast curve"; the build is then based on quotes for IRSs and OISs, with FRAs included as before. Here, since the observed average overnight rate plus a spread is swapped for [9] the -IBOR rate over the same period (the most liquid tenor in that market), and the -IBOR IRSs are in turn discounted on the OIS curve, the problem entails a nonlinear system, where all curve points are solved at once, and specialized iterative methods are usually employed (see further following). The forecast-curves for other tenors can be solved in a "second stage", bootstrap-style, with discounting on the now-solved OIS curve.
A CSA could allow for collateral, and hence interest payments on that collateral, in any currency.[10] To accommodate this, banks include in their curve-set a USD discount-curve to be used for discounting local-IBOR trades which have USD collateral; this curve is sometimes called the (Dollar) "basis-curve". It is built by solving for observed (mark-to-market) cross-currency swap rates, where the local -IBOR is swapped for USD LIBOR with USD collateral as underpin. The latest, pre-solved USD-LIBOR-curve is therefore an (external) element of the curve-set, and the basis-curve is then solved in the "third stage". Each currency's curve-set will thus include a local-currency discount-curve and its USD discounting basis-curve. As required, a third-currency discount curve — i.e. for local trades collateralized in a currency other than local or USD (or any other combination) — can then be constructed from the local-currency basis-curve and third-currency basis-curve, combined via an arbitrage relationship known here as "FX Forward Invariance".[11]
Various approaches to solving curves are possible. Modern methods tend to employ global optimizers with complete flexibility in the parameters that are solved relative to the calibrating instruments used to tune them. These optimizers will seek to minimize some objective function - here matching the observed instrument values - and this assumes that some interpolation mode [12] [13] [14] has been configured for the curves; the approach ultimately employed may be a modification of Newton's method. Maturities corresponding to input instruments are referred to as "pillar points"; often, these are solved directly, while other spot rates are interpolated. (Then, once solved, all that need be stored are the pillar point rates and the interpolation rule.)
Transition
[edit ]Starting in 2021, LIBOR is being phased out, with replacements including other "market reference rates" (MRRs) such as SOFR and TONAR. (These MRRs are based on secured overnight funding transactions). With the coexistence of "old" and "new" rates in the market, multi-curve and OIS curve "management" is necessary, with changes required to incorporate new discounting and compounding conventions, while the underlying logic is unaffected; see.[15] [16] [17]
See also
[edit ]- Yield curve § Construction of the full yield curve from market data
- Fixed-income attribution § Modeling the yield curve
References
[edit ]- ^ Staff (2023). "Multi-curve Framework", rebellionresearch.com
- ^ Henrard M. (2007). The Irony in the Derivatives Discounting, Wilmott Magazine, pp. 92–98, July 2007. SSRN preprint.
- ^ Henrard M. (2010). The Irony in the Derivatives Discounting Part II: The Crisis, Wilmott Journal, Vol. 2, pp. 301–316, 2010. SSRN preprint.
- ^ Bianchetti M. (2010). Two Curves, One Price: Pricing & Hedging Interest Rate Derivatives Decoupling Forwarding and Discounting Yield Curves, Risk Magazine, August 2010. SSRN preprint.
- ^ Multi-Curve Valuation Approaches and their Application to Hedge Accounting according to IAS 39, Dr. Dirk Schubert, KPMG
- ^ M. Henrard (2014). Interest Rate Modelling in the Multi-Curve Framework: Foundations, Evolution and Implementation. Palgrave Macmillan ISBN 978-1137374653
- ^ See section 3 of Marco Bianchetti and Mattia Carlicchi (2012). Interest Rates after The Credit Crunch: Multiple-Curve Vanilla Derivatives and SABR
- ^ Pricing and Trading Interest Rate Derivatives: A Practical Guide to Swaps, J H M Darbyshire, 2017, ISBN 978-0995455528
- ^ CQF Institute. "Multi-curve and collateral framework"
- ^ Fujii, Masaaki Fujii; Yasufumi Shimada; Akihiko Takahashi (26 January 2010). "A Note on Construction of Multiple Swap Curves with and without Collateral". CARF Working Paper Series No. CARF-F-154. SSRN 1440633.
- ^ Burgess, Nicholas (2017). FX Forward Invariance & Discounting with CSA Collateral
- ^ P. Hagan and G. West (2006). Interpolation methods for curve construction. Applied Mathematical Finance , 13 (2):89—129, 2006.
- ^ P. Hagan and G. West (2008). Methods for Constructing a Yield Curve. Wilmott Magazine , May, 70-81.
- ^ P du Preez and E Maré (2013). Interpolating Yield Curve Data in a Manner That Ensures Positive and Continuous Forward Curves. SAJEMS 16 (2013) No 4:395-406
- ^ Fabio Mercurio (2018). SOFR So Far: Modeling the LIBOR Replacement
- ^ FINCAD (2020). Future-Proof Curve-Building for the End of Libor
- ^ Finastra (2020). Transitioning from LIBOR to alternative reference rates
Further reading
[edit ]- Henrard M. (2014) Interest Rate Modelling in the Multi-curve Framework: Foundations, Evolution, and Implementation. Palgrave Macmillan. Applied Quantitative Finance series. June 2014. ISBN 978-1-137-37465-3.