quantitative finance Mathematical finance, also known as quantitative finance and financial mathematics, is a field of applied mathematics, concerned with mathematical modeling in the financial field. In general, there exist two separate branches of finance that requ ...

, a lattice model is a numerical approach to the valuation of derivatives in situations requiring a discrete time model. For dividend paying equity options, a typical application would correspond to the pricing of an American-style option, where a decision to

exercise Exercise or workout is physical activity that enhances or maintains fitness and overall health. It is performed for various reasons, including weight loss or maintenance, to aid growth and improve strength, develop muscles and the cardio ...

is allowed at the closing of any calendar day up to the maturity. A continuous model, on the other hand, such as the standard Black–Scholes one, would only allow for the valuation of

European option In finance, the style or family of an option is the class into which the option falls, usually defined by the dates on which the option may be exercised. The vast majority of options are either European or American (style) options. These options ...

s, where exercise is limited to the option's maturity date. For interest rate derivatives lattices are additionally useful in that they address many of the issues encountered with continuous models, such as pull to par. The method is also used for valuing certain

exotic option In finance, an exotic option is an option which has features making it more complex than commonly traded vanilla options. Like the more general exotic derivatives they may have several triggers relating to determination of payoff. An exotic op ...

s, because of

path dependence Path dependence is a concept in the Social science, social sciences, referring to processes where past events or decisions constrain later events or decisions. It can be used to refer to outcomes at a single point in time or to long-run equilibria ...

in the payoff. Traditional Monte Carlo methods for option pricing fail to account for optimal decisions to terminate the derivative by early exercise, but some methods now exist for solving this problem.

Equity and commodity derivatives

In general the approach is to divide time between now and the option's expiration into ''N'' discrete periods. At the specific time ''n'', the model has a finite number of outcomes at time ''n'' + 1 such that every possible change in the state of the world between ''n'' and ''n'' + 1 is captured in a branch. This process is iterated until every possible path between ''n'' = 0 and ''n'' = ''N'' is mapped. Probabilities are then estimated for every ''n'' to ''n'' + 1 path. The outcomes and probabilities flow backwards through the tree until a fair value of the option today is calculated.

Variants

For European equity- and commodity options the application is as follows. The first step is to trace the evolution of the option's key underlying variable(s), starting with today's

spot price In finance, a spot contract, spot transaction, or simply spot, is a contract of buying or selling a commodity, security or currency for immediate settlement (payment and delivery) on the spot date, which is normally two business days after t ...

, such that this

process A process is a series or set of activities that interact to produce a result; it may occur once-only or be recurrent or periodic. Things called a process include: Business and management * Business process, activities that produce a specific s ...

is consistent with its volatility; log-normal

Brownian motion Brownian motion is the random motion of particles suspended in a medium (a liquid or a gas). The traditional mathematical formulation of Brownian motion is that of the Wiener process, which is often called Brownian motion, even in mathematical ...

with constant volatility is usually assumed.Chance, Don M. (March 2008)
"A Synthesis of Binomial Option Pricing Models for Lognormally Distributed Assets"
. ''Journal of Applied Finance'', Vol. 18. The next step is to value the option recursively: stepping backwards from the final time-step, where we have exercise value at each node; and applying risk neutral valuation at each earlier node, where option value is the probability-weighted

present value In economics and finance, present value (PV), also known as present discounted value (PDV), is the value of an expected income stream determined as of the date of valuation. The present value is usually less than the future value because money ha ...

of the up- and down-nodes in the later time-step. See for more detail, as well as for logic and formulae derivation. As stated above, the lattice approach is particularly useful in valuing American options, where the choice whether to exercise the option early, or to hold the option, may be modeled at each discrete time/price combination; this is also true for Bermudan options. For similar reasons,

real options Real options valuation, also often termed real options analysis,Adam Borison (Stanford University)''Real Options Analysis: Where are the Emperor's Clothes?'' (ROV or ROA) applies option (finance), option Valuation of options, valuation technique ...

and employee stock options are often modeled using a lattice framework, though with modified assumptions. In each of these cases, a third step is to determine whether the option is to be exercised or held, and to then apply this value at the node in question. Some exotic options, such as barrier options, are also easily modeled here; for other Path-Dependent Options,

simulation A simulation is an imitative representation of a process or system that could exist in the real world. In this broad sense, simulation can often be used interchangeably with model. Sometimes a clear distinction between the two terms is made, in ...

would be preferred. (Although, tree-based methods have been developed. ) The simplest lattice model is the binomial options pricing model; the standard ("canonical") method is that proposed by Cox, Ross and Rubinstein (CRR) in 1979; see diagram for formulae. Over 20 other methods have been developed,Mark S. Joshi (2008)
"The Convergence of Binomial Trees for Pricing the American Put"
with each "derived under a variety of assumptions" as regards the development of the underlying's price. In the limit, as the number of time-steps increases, these converge to the Log-normal distribution, and hence produce the "same" option price as Black-Scholes: to achieve this, these will variously seek to agree with the underlying's central moments, raw moments and / or log-moments at each time-step, as measured discretely. Further enhancements are designed to achieve stability relative to Black-Scholes as the number of time-steps changes. More recent models, in fact, are designed around direct convergence to Black-Scholes. A variant on the Binomial, is the

Trinomial tree The trinomial tree is a Lattice model (finance), lattice-based computational model used in financial mathematics to price option (finance), options. It was developed by Phelim Boyle in 1986. It is an extension of the binomial options pricing model, ...

, developed by Phelim Boyle in 1986. Here, the share price may remain ''unchanged'' over the time-step, and option valuation is then based on the value of the share at the up-, down- and middle-nodes in the later time-step. As for the binomial, a similar (although smaller) range of methods exist. The trinomial model is considered to produce more accurate results than the binomial model when fewer time steps are modelled, and is therefore used when computational speed or resources may be an issue. For vanilla options, as the number of steps increases, the results rapidly converge, and the binomial model is then preferred due to its simpler implementation. For

s the trinomial model (or adaptations) is sometimes more stable and accurate, regardless of step-size. For multiple underlyers – e.g. Rainbow- and Basket options – "multinomial lattices" can be built. Each underlyer will have its own tree, and the per node option-value will be a function of the corresponding nodes on all underlying trees. In the case of two assets, the tree will then be referred to as a "binomial

pyramid A pyramid () is a structure whose visible surfaces are triangular in broad outline and converge toward the top, making the appearance roughly a pyramid in the geometric sense. The base of a pyramid can be of any polygon shape, such as trian ...

". Two additional complications exist here. First, the number of nodes increases exponentially with the number of underlyers. Second, in these products, correlations between assets play a significant role, and these must also inhere in the modelling.

Risk measurement and management

Various of the

Greeks Greeks or Hellenes (; , ) are an ethnic group and nation native to Greece, Greek Cypriots, Cyprus, Greeks in Albania, southern Albania, Greeks in Turkey#History, Anatolia, parts of Greeks in Italy, Italy and Egyptian Greeks, Egypt, and to a l ...

can be estimated directly on the lattice, where the sensitivities are calculated using finite differences.

Delta Delta commonly refers to: * Delta (letter) (Δ or δ), the fourth letter of the Greek alphabet * D (NATO phonetic alphabet: "Delta"), the fourth letter in the Latin alphabet * River delta, at a river mouth * Delta Air Lines, a major US carrier ...

and

gamma Gamma (; uppercase , lowercase ; ) is the third letter of the Greek alphabet. In the system of Greek numerals it has a value of 3. In Ancient Greek, the letter gamma represented a voiced velar stop . In Modern Greek, this letter normally repr ...

, being sensitivities of option value w.r.t. price, are approximated given differences between option prices – with their related spot – in the same time step.

Theta Theta (, ) uppercase Θ or ; lowercase θ or ; ''thē̂ta'' ; Modern: ''thī́ta'' ) is the eighth letter of the Greek alphabet, derived from the Phoenician letter Teth 𐤈. In the system of Greek numerals, it has a value of 9. Gree ...

, sensitivity to time, is likewise estimated given the option price at the first node in the tree and the option price for the same spot in a later time step. (Second time step for trinomial, third for binomial. Depending on method, if the "down factor" is not the inverse of the "up factor", this method will not be precise.) For

rho Rho (; uppercase Ρ, lowercase ρ or ; or ) is the seventeenth letter of the Greek alphabet. In the system of Greek numerals it has a value of 100. It is derived from Phoenician alphabet, Phoenician letter resh . Its uppercase form uses the same ...

, sensitivity to interest rates, and vega, sensitivity to input volatility, the measurement is indirect, as the value must be calculated a second time on a new lattice built with these inputs slightly altered – and the sensitivity here is likewise returned via finite difference. See also Fugit, the estimated time to exercise for a non-European option, which is typically calculated using a lattice. Beginning with the 1987 crash, and especially since the

2008 financial crisis The 2008 financial crisis, also known as the global financial crisis (GFC), was a major worldwide financial crisis centered in the United States. The causes of the 2008 crisis included excessive speculation on housing values by both homeowners ...

, it has become important to incorporate the volatility smile / surface into pricing models. This recognizes the fact that the underlying price-change distribution displays a term structure and is non-normal, unlike that assumed by Black-Scholes; see and . To do so, banks typically apply stochastic- or

local volatility A local volatility model, in mathematical finance and financial engineering, is an option pricing model that treats Volatility (finance), volatility as a function of both the current asset level S_t and of time t . As such, it is a generalisati ...

models. In the Lattice framework, implied trees can be constructed; these essentially discretize the latter. Here, the tree is solved such that it successfully reproduces selected (all) market prices, across various strikes and expirations. These trees thus "ensure that all European standard options (with strikes and maturities coinciding with the tree nodes) will have theoretical values which match their market prices".Emanuel Derman, Iraj Kani, and Neil Chriss (1996)
Implied Trinomial Trees of the Volatility Smile
Goldman Sachs, Quantitative Strategies Research Notes Using the calibrated lattice one can then price options with strike / maturity combinations not quoted in the market, such that these prices are consistent with observed volatility patterns. For

risk management Risk management is the identification, evaluation, and prioritization of risks, followed by the minimization, monitoring, and control of the impact or probability of those risks occurring. Risks can come from various sources (i.e, Threat (sec ...

, the Greeks returned will reflect sensitivities more appropriately. There exist both implied binomial trees, often Rubinstein IBTs (R-IBT), and

implied trinomial tree In quantitative finance, a lattice model is a numerical methods, numerical approach to the Valuation of options, valuation of derivatives in situations requiring a discrete time model. For dividend paying stock option, equity options, a typical ...

s, often Derman-Kani- Chriss (DKC; superseding the DK-IBT). The former is easier built, but is consistent with one maturity only; the latter will be consistent with, but at the same time requires, known (or interpolated) prices at all time-steps and nodes. As regards the construction, for an R-IBT the first step is to recover the "Implied Ending Risk-Neutral Probabilities" of spot prices. Then by the assumption that all paths which lead to the same ending node have the same risk-neutral probability, a "path probability" is attached to each ending node. Thereafter "it's as simple as One-Two-Three", and a three step backwards recursion allows for the node probabilities to be recovered for each time step. Option valuation then proceeds as standard, with these probabilities replacing

p

above. For DKC, the first step is to recover the

state price In financial economics, a state-price security, also called an Arrow–Debreu security (from its origins in the Arrow–Debreu model), a pure security, or a primitive security is a contract that agrees to pay one unit of a numeraire (a currency or ...

s corresponding to each node in the tree, such that these are consistent with observed option prices (i.e. with the volatility surface). Thereafter the up-, down- and middle-probabilities are found for each node such that: these sum to 1; spot prices adjacent time-step-wise evolve risk neutrally, incorporating

dividend yield The dividend yield or dividend–price ratio of a share is the dividend per share divided by the price per share. It is also a company's total annual dividend payments divided by its market capitalization, assuming the number of shares is constan ...

; state prices similarly "grow" at the risk free rate. (The solution here is iterative per time step as opposed to simultaneous.) As for R-IBTs, option valuation is then by standard backward recursion. As an alternative, Edgeworth binomial trees may be employed, as these allow for an analyst-specified skew and kurtosis in spot-price returns (see Edgeworth series). Here, options with differing strikes will return differing implied volatilities, and the tree may then be calibrated to the volatility smile, by a "judicious choice" of parameter values. For pricing American options, the valuation will be on an R-IBT as combined with the calibrated maturity distribution. The Edgeworth approach is limited as to the set of skewness and kurtosis pairs for which valid distributions are available: the more recent Johnson binomial trees, then, use the Johnson "family" of distributions, as this is capable of accommodating all possible pairs. Edgeworth (or Johnson) trees are also useful for other applications where the underlying's behavior departs (markedly) from normal. As an example, these trees can be applied to multinomial options: Basket options, for instance, can be priced using an "approximating distribution" which provides the end-nodes, and skew and kurtosis, on which the tree is then built. Re the modelling of CVA /

XVA X-Value Adjustment (XVA, xVA) is an hyponymy and hypernymy, umbrella term referring to a number of different "valuation adjustments" that banks must make when assessing the value of derivative (finance), derivative contracts that they have entered ...

via lattice, see below.

Interest rate derivatives

Lattices are commonly used in valuing bond options, swaptions, and other interest rate derivatives In these cases the valuation is largely as above, but requires an additional, zeroeth, step of constructing an interest rate tree, on which the price of the underlying is then based. The next step also differs: the underlying price here is built via "backward induction" i.e. flows backwards from maturity, accumulating the present value of scheduled cash flows at each node, as opposed to flowing forwards from valuation date as above. The final step, option valuation, then proceeds as standard. See top for graphic, and aside for description.

Approaches

The initial lattice is built by discretizing either a

short-rate model 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 r_t \,. The short rate Under a sh ...

, such as Hull–White or Black Derman Toy, or a

forward rate The forward rate is the future yield on a bond. It is calculated using the yield curve. For example, the yield on a three-month Treasury bill six months from now is a ''forward rate''.. Forward rate calculation To extract the forward rate, we ...

-based model, such as the LIBOR market model or HJM. As for equity, trinomial trees may also be employed for these models; this is usually the case for Hull-White trees. Under HJM,Pricing Interest Rate-dependent Financial Claims with Option Features
Ch 11. in Rendleman (2002), per Bibliography. the condition of no arbitrage implies that there exists a martingale probability measure, as well as a corresponding restriction on the "drift coefficients" of the forward rates. These, in turn, are functions of the volatility(s) of the forward rates. A "simple" discretized expression for the drift then allows for forward rates to be expressed in a binomial lattice. For these forward rate-based models, dependent on volatility assumptions, the lattice might not recombine. (This means that an "up-move" followed by a "down-move" will not give the same result as a "down-move" followed by an "up-move".) In this case, the Lattice is sometimes referred to as a "bush", and the number of nodes grows exponentially as a function of number of time-steps. A recombining binomial tree methodology is also available for the Libor Market Model. As regards the short-rate models, these are, in turn, further categorized: these will be either equilibrium-based ( Vasicek and CIR) or arbitrage-free ( Ho–Lee and subsequent). This distinction: for equilibrium-based models the

yield curve In finance, the yield curve is a graph which depicts how the Yield to maturity, yields on debt instruments – such as bonds – vary as a function of their years remaining to Maturity (finance), maturity. Typically, the graph's horizontal ...

is an ''output'' from the model, while for arbitrage-free models the yield curve is an ''input'' to the model. In the former case, the approach is to "calibrate" the model parameters, such that bond prices produced by the model, in its continuous form, best fit observed market prices. The tree is then built as a function of these parameters. In the latter case, the calibration is directly on the lattice: the fit is to both the current term structure of interest rates (i.e. the

), and the corresponding volatility structure. Here, calibration means that the interest-rate-tree reproduces the prices of the

zero-coupon bond A zero-coupon bond (also discount bond or deep discount bond) is a bond in which the face value is repaid at the time of maturity. Unlike regular bonds, it does not make periodic interest payments or have so-called coupons, hence the term zer ...

s—and any other interest-rate sensitive securities—used in constructing the yield curve; note the parallel to the implied trees for equity above, and compare

Bootstrapping (finance) In finance, bootstrapping is a method for constructing a ( zero-coupon) fixed-income yield curve from the prices of a set of coupon-bearing products, e.g. bonds and swaps. A ''bootstrapped curve'', correspondingly, is one where the prices of the ...

. For models assuming a

normal distribution In probability theory and statistics, a normal distribution or Gaussian distribution is a type of continuous probability distribution for a real-valued random variable. The general form of its probability density function is f(x) = \frac ...

(such as Ho-Lee), calibration may be performed analytically, while for log-normal models the calibration is via a root-finding algorithm; see for example, the boxed-description under Black–Derman–Toy model. The volatility structure—i.e. vertical node-spacing—here reflects the volatility of rates during the quarter, or other period, corresponding to the lattice time-step. (Some analysts use "Volatility (finance)#Volatility terminology, realized volatility", i.e. of the rates applicable ''historically'' for the time-step; to be market-consistent, analysts generally prefer to use ''current'' interest rate cap prices, and the implied volatility for the Black-76-prices of each component Interest rate cap and floor#Interest rate cap, caplet; see .) Given this functional link to volatility, note now the resultant ''difference'' in the construction relative to equity implied trees: for interest rates, the volatility is known for each time-step, and the node-values (i.e. interest rates) must be solved for specified risk neutral probabilities; for equity, on the other hand, a single volatility cannot be specified per time-step, i.e. we have a "smile", and the tree is built by solving for the probabilities corresponding to specified values of the underlying at each node. Once calibrated, the interest rate lattice is then used in the valuation of various of the fixed income instruments and derivatives. The approach for bond options is described aside—note that this approach addresses the problem of pull to par experienced under closed form approaches; see . For swaptions the logic is almost identical, substituting swap (finance), swaps for bonds in step 1, and swaptions for bond options in step 2. For caps (and floors) step 1 and 2 are combined: at each node the value is based on the relevant nodes at the later step, plus, for any caplet (Interest rate cap and floor#Interest rate floor, floorlet) maturing in the time-step, the difference between its reference-rate and the short-rate at the node (and reflecting the corresponding day count fraction and notional-value exchanged). For callable bond, callable- and putable bonds a third step would be required: at each node in the time-step incorporate the effect of the embedded option on the bond price and / or the option price there before stepping-backwards one time-step. (And noting that these options are not mutually exclusive, and so a bond may have several options embedded; hybrid securities are treated below.) For other, Interest rate derivative#Exotic derivatives, more exotic interest rate derivatives, similar adjustments are made to steps 1 and onward. For the "Greeks", largely as for equity, see under next section. An alternative approach to modeling (American) bond options, particularly those strike price, struck on yield to maturity (YTM), employs modified equity-lattice methods. Here the analyst builds a CRR tree of YTM, applying a constant volatility assumption, and then Bond valuation#Present value approach, calculates the bond price as a function of this yield at each node; prices here are thus pulling-to-par. The second step is to then incorporate any Forward volatility, term structure of volatility by building a corresponding DKC tree (based on every second time-step in the CRR tree: as DKC is trinomial whereas CRR is binomial) and then using this for option valuation.

Post-crisis

Since the

, Swap (finance)#Valuation, swap pricing is (generally) under a "multi-curve framework", whereas previously it was off a single, "self discounting", curve; see . Here, payoffs are set as a function of the Reference rate or forecast rate (LIBOR) specific to the Tenor (finance), tenor in question, while discounting is at the Overnight indexed swap, OIS rate. To accommodate this in the lattice framework, the OIS rate and the relevant reference rate are jointly modeled in a three-dimensional tree, constructed so as to return the input OIS- and Libor-swap prices, while also inhering any correlation between the two rate sets. With the zeroeth step thus accomplished, the valuation will proceed largely as previously, using steps 1 and onwards, but here – similar to the above "pyramid" – with cashflows based on the LIBOR tree, and discounting using the corresponding nodes from the OIS tree. A Valuation of options#Post crisis, related development is that banks will make a credit valuation adjustment, CVA – as well as various of the other

– when assessing the value of derivative contracts that they have entered into. The purpose of these is twofold: primarily to hedge for possible losses due to counterparty credit risk, the other parties' failures to pay amounts due on the derivative contracts; but also to determine (and hedge) the amount of capital required under Basel III, the bank capital adequacy rules. Although Credit valuation adjustment#Calculation, usually calculated under a simulation framework, tree-based methods can be applied here also. Donald Smith (2016)
"Understanding CVA, DVA, and FVA: Examples of Interest Rate Swap Valuation"
''Journal of Accounting and Finance'' Vol. 16(8) 2016 In the case of a swap, for example, the potential future exposure, PFE, facing the bank on each date is the probability-weighted average of the positive Settlement (finance), settlement payments and Swap (finance)#Valuation and Pricing, swap values over the lattice-nodes at the date; each node's probability is in turn a function of the tree's cumulative up- and down-probabilities. This PFE is combined with the counterparty's (tree-exogenous) probability of default and recovery rate to derive the loss given default, expected loss for the date. Finally, the aggregated present value of these is the CVA for the counterparty on that position.

Hybrid securities

Hybrid security, Hybrid securities, incorporating both equity- and bond-like features are also valued using trees. For convertible bonds (CBs) the approach of Tsiveriotis and Fernandes (1998) is to divide the value of the bond at each node into an "equity" component, arising from situations where the CB will be converted, and a "debt" component, arising from situations where CB is redeemed. Correspondingly, twin trees are constructed where discounting is at the risk free and credit risk adjusted rate respectively, with the sum being the value of the CB. There are other methods, which similarly combine an equity-type tree with a short-rate tree. An alternate approach, originally published by Goldman Sachs (1994), does not decouple the components, rather, discounting is at a conversion-probability-weighted risk-free and risky interest rate within a single tree. See , Contingent convertible bond. More generally, Equity (finance), equity can be viewed as a call option on the firm: where the value of the firm is less than the value of the outstanding debt shareholders would choose not to repay the firm's debt; they would choose to repay—and not to liquidate (i.e. Exercise (options), exercise their option)—otherwise. Lattice models have been developed for equity analysis here, particularly as relates to Distressed securities, distressed firms. Relatedly, as regards corporate debt pricing, the relationship between equity holders' limited liability and potential Chapter 11 proceedings has also been modelled via lattice. The calculation of "Greeks" for interest rate derivatives proceeds as for equity. There is however an additional requirement, particularly for hybrid securities: that is, to estimate sensitivities related to ''overall changes'' in interest rates. For a bond with an embedded option, the standard yield to maturity based calculations of Bond duration, duration and Bond convexity, convexity do not consider how changes in interest rates will alter the cash flows due to option exercise. To address this, effective duration and effective convexity, -convexity are introduced. Here, similar to rho and vega above, the interest rate tree is rebuilt for an upward and then downward Yield curve#Significance of slope and shape, parallel shift in the yield curve and these measures are Finite difference, calculated numerically given the corresponding changes in bond value.See Fabozzi under Bibliography.

References

Bibliography

* * * * * * * * * * * * {{DEFAULTSORT:Lattice Model (Finance) Options (finance) Short-rate models Mathematical finance Models of computation Trees (data structures) Financial models Heath–Jarrow–Morton framework