Mathematical finance, also known as quantitative finance and financial mathematics, is a field of applied mathematics, concerned with mathematical modeling of financial markets. Generally, mathematical finance will derive and extend the mathematical or numerical models without necessarily establishing a link to financial theory, taking observed market prices as input. Mathematical consistency is required, not compatibility with economic theory. Thus, for example, while a financial economist might study the structural reasons why a company may have a certain share price, a financial mathematician may take the share price as a given, and attempt to use stochastic calculus to obtain the corresponding value of derivatives of the stock (see: Valuation of options; Financial modeling; Asset pricing). The fundamental theorem of arbitragefree pricing is one of the key theorems in mathematical finance, while the Black–Scholes equation and formula are amongst the key results.^{[1]}
Mathematical finance also overlaps heavily with the fields of computational finance and financial engineering. The latter focuses on applications and modeling, often by help of stochastic asset models (see: Quantitative analyst), while the former focuses, in addition to analysis, on building tools of implementation for the models. In general, there exist two separate branches of finance that require advanced quantitative techniques: derivatives pricing on the one hand, and risk and portfolio management on the other.^{[2]}
French mathematician Louis Bachelier is considered the author of the first scholarly work on mathematical finance, published in 1900. But mathematical finance emerged as a discipline in the 1970s, following the work of Fischer Black, Myron Scholes and Robert Merton on option pricing theory.
Today many universities offer degree and research programs in mathematical finance.
History: Q versus PEdit
There are two separate branches of finance that require advanced quantitative techniques: derivatives pricing, and risk and portfolio management. One of the main differences is that they use different probabilities such as the riskneutral probability (or arbitragepricing probability), denoted by "Q", and the actual (or actuarial) probability, denoted by "P".
Derivatives pricing: the Q worldEdit
Goal  "extrapolate the present" 
Environment  riskneutral probability 
Processes  continuoustime martingales 
Dimension  low 
Tools  Itō calculus, PDEs 
Challenges  calibration 
Business  sellside 
The goal of derivatives pricing is to determine the fair price of a given security in terms of more liquid securities whose price is determined by the law of supply and demand. The meaning of "fair" depends, of course, on whether one considers buying or selling the security. Examples of securities being priced are plain vanilla and exotic options, convertible bonds, etc.
Once a fair price has been determined, the sellside trader can make a market on the security. Therefore, derivatives pricing is a complex "extrapolation" exercise to define the current market value of a security, which is then used by the sellside community. Quantitative derivatives pricing was initiated by Louis Bachelier in The Theory of Speculation ("Theorie de la speculation", published 1900), with the introduction of the most basic and most influential of processes, the Brownian motion, and its applications to the pricing of options.^{[3]}^{[4]} The Brownian motion is derived using the Langevin equation and the discrete random walk.^{[5]} Bachelier modeled the time series of changes in the logarithm of stock prices as a random walk in which the shortterm changes had a finite variance. This causes longerterm changes to follow a Gaussian distribution.^{[6]}
The theory remained dormant until Fischer Black and Myron Scholes, along with fundamental contributions by Robert C. Merton, applied the second most influential process, the geometric Brownian motion, to option pricing. For this M. Scholes and R. Merton were awarded the 1997 Nobel Memorial Prize in Economic Sciences. Black was ineligible for the prize because of his death in 1995.^{[7]}
The next important step was the fundamental theorem of asset pricing by Harrison and Pliska (1981), according to which the suitably normalized current price P_{0} of a security is arbitragefree, and thus truly fair only if there exists a stochastic process P_{t} with constant expected value which describes its future evolution:^{[8]}

(1)
A process satisfying (1) is called a "martingale". A martingale does not reward risk. Thus the probability of the normalized security price process is called "riskneutral" and is typically denoted by the blackboard font letter " ".
The relationship (1) must hold for all times t: therefore the processes used for derivatives pricing are naturally set in continuous time.
The quants who operate in the Q world of derivatives pricing are specialists with deep knowledge of the specific products they model.
Securities are priced individually, and thus the problems in the Q world are lowdimensional in nature. Calibration is one of the main challenges of the Q world: once a continuoustime parametric process has been calibrated to a set of traded securities through a relationship such as (1), a similar relationship is used to define the price of new derivatives.
The main quantitative tools necessary to handle continuoustime Qprocesses are Itō's stochastic calculus, simulation and partial differential equations (PDE's).
Risk and portfolio management: the P worldEdit
Goal  "model the future" 
Environment  realworld probability 
Processes  discretetime series 
Dimension  large 
Tools  multivariate statistics 
Challenges  estimation 
Business  buyside 
Risk and portfolio management aims at modeling the statistically derived probability distribution of the market prices of all the securities at a given future investment horizon.
This "real" probability distribution of the market prices is typically denoted by the blackboard font letter " ", as opposed to the "riskneutral" probability " " used in derivatives pricing. Based on the P distribution, the buyside community takes decisions on which securities to purchase in order to improve the prospective profitandloss profile of their positions considered as a portfolio.
For their pioneering work, Markowitz and Sharpe, along with Merton Miller, shared the 1990 Nobel Memorial Prize in Economic Sciences, for the first time ever awarded for a work in finance.
The portfolioselection work of Markowitz and Sharpe introduced mathematics to investment management. With time, the mathematics has become more sophisticated. Thanks to Robert Merton and Paul Samuelson, oneperiod models were replaced by continuous time, Brownianmotion models, and the quadratic utility function implicit in mean–variance optimization was replaced by more general increasing, concave utility functions.^{[9]} Furthermore, in recent years the focus shifted toward estimation risk, i.e., the dangers of incorrectly assuming that advanced time series analysis alone can provide completely accurate estimates of the market parameters.^{[10]}
Much effort has gone into the study of financial markets and how prices vary with time. Charles Dow, one of the founders of Dow Jones & Company and The Wall Street Journal, enunciated a set of ideas on the subject which are now called Dow Theory. This is the basis of the socalled technical analysis method of attempting to predict future changes. One of the tenets of "technical analysis" is that market trends give an indication of the future, at least in the short term. The claims of the technical analysts are disputed by many academics.
CriticismEdit
Over the years, increasingly sophisticated mathematical models and derivative pricing strategies have been developed, but their credibility was damaged by the financial crisis of 2007–2010. Contemporary practice of mathematical finance has been subjected to criticism from figures within the field notably by Paul Wilmott, and by Nassim Nicholas Taleb, in his book The Black Swan.^{[11]} Taleb claims that the prices of financial assets cannot be characterized by the simple models currently in use, rendering much of current practice at best irrelevant, and, at worst, dangerously misleading. Wilmott and Emanuel Derman published the Financial Modelers' Manifesto in January 2009^{[12]} which addresses some of the most serious concerns. Bodies such as the Institute for New Economic Thinking are now attempting to develop new theories and methods.^{[13]}
In general, modeling the changes by distributions with finite variance is, increasingly, said to be inappropriate.^{[14]} In the 1960s it was discovered by Benoit Mandelbrot that changes in prices do not follow a Gaussian distribution, but are rather modeled better by Levy alphastable distributions.^{[15]} The scale of change, or volatility, depends on the length of the time interval to a power a bit more than 1/2. Large changes up or down are more likely than what one would calculate using a Gaussian distribution with an estimated standard deviation. But the problem is that it does not solve the problem as it makes parametrization much harder and risk control less reliable.^{[11]} See also Variance gamma process#Option pricing.
Mathematical finance articlesEdit
Mathematical toolsEdit
 Asymptotic analysis
 Calculus
 Copulas, including Gaussian
 Differential equations
 Expected value
 Ergodic theory
 Feynman–Kac formula
 Fourier transform
 Girsanov theorem
 Itô's lemma
 Martingale representation theorem
 Mathematical models
 Mathematical optimization
 Monte Carlo method
 Numerical analysis
 Real analysis
 Partial differential equations
 Probability
 Probability distributions
 Quantile functions
 Radon–Nikodym derivative
 Riskneutral measure
 Scenario optimization
 Stochastic calculus
 Stochastic differential equation
 Stochastic optimization
 Stochastic volatility
 Survival analysis
 Value at risk
 Volatility
 This list was truncated from 46 items.
Derivatives pricingEdit
 The Brownian model of financial markets
 Rational pricing assumptions
 Risk neutral valuation
 Arbitragefree pricing
 Valuation adjustments
 Forward Price Formula
 Futures contract pricing
 Swap valuation
 Options
 Put–call parity (Arbitrage relationships for options)
 Intrinsic value, Time value
 Moneyness
 Pricing models
 Black–Scholes model
 Black model
 Binomial options model
 Monte Carlo option model
 Implied volatility, Volatility smile
 Local volatility
 Stochastic volatility
 Markov switching multifractal
 The Greeks
 Finite difference methods for option pricing
 Vanna–Volga pricing
 Trinomial tree
 GarmanKohlhagen model
 Lattice model (finance)
 Margrabe's formula
 This list was truncated from 22 items.
 Pricing of American options
 BaroneAdesi and Whaley
 Bjerksund and Stensland
 Black's approximation
 Least Square Monte Carlo
 Optimal stopping
 RollGeskeWhaley
 This list was truncated from 6 items.
 This list was truncated from 33 items.
 Interest rate derivatives
 Black model
 Shortrate models
 Forward ratebased models
 LIBOR market model (Brace–Gatarek–Musiela Model, BGM)
 Heath–Jarrow–Morton Model (HJM)
 This list was truncated from 18 items.
 This list was truncated from 69 items.
Portfolio modellingEdit
See alsoEdit
 Brownian model of financial markets
 Computational finance
 Derivative (finance), list of derivatives topics
 Economic model
 Financial economics
 Financial engineering
 Financial modeling § Quantitative finance
 International Swaps and Derivatives Association
 Index of accounting articles
 List of economists
 Master of Quantitative Finance
 Outline of economics
 Outline of finance
 Quantitative behavioral finance
 Statistical finance
 Technical analysis
 XVA
 This list was truncated from 17 items.
NotesEdit
 ^ Johnson, Tim (September 2009). "What is financial mathematics?". +Plus Magazine. Retrieved 28 March 2014.
 ^ "Quantitative Finance". About.com. Retrieved 28 March 2014.
 ^ E., Shreve, Steven (2004). Stochastic calculus for finance. New York: Springer. ISBN 9780387401003. OCLC 53289874.
 ^ Stephen., Blyth (2013). Introduction to Quantitative Finance. Oxford University Press, USA. p. 157. ISBN 9780199666591. OCLC 868286679.
 ^ B., Schmidt, Anatoly (2005). Quantitative finance for physicists : an introduction. San Diego, Calif.: Elsevier Academic Press. ISBN 9780080492209. OCLC 57743436.
 ^ Bachelir, Louis. "The Theory of Speculation". Retrieved 28 March 2014.
 ^ Lindbeck, Assar. "The Sveriges Riksbank Prize in Economic Sciences in Memory of Alfred Nobel 19692007 inches. Nobel Prize. Retrieved 28 March 2014.
 ^ Brown, Angus (1 Dec 2008). "A risky business: How to price derivatives". Price+ Magazine. Retrieved 28 March 2014.
 ^ Karatzas, Ioannis; Shreve, Steve (1998). Methods of Mathematical Finance. Secaucus, NJ, USA: SpringerVerlag New York, Incorporated. ISBN 9780387948393.
 ^ Meucci, Attilio (2005). Risk and Asset Allocation. Springer. ISBN 9783642009648.
 ^ ^{a} ^{b} Taleb, Nassim Nicholas (2007). The Black Swan: The Impact of the Highly Improbable. Random House Trade. ISBN 9781400063512.
 ^ "Financial Modelers' Manifesto". Paul Wilmott's Blog. January 8, 2009. Archived from the original on September 8, 2014. Retrieved June 1, 2012.
 ^ Gillian Tett (April 15, 2010). "Mathematicians must get out of their ivory towers". Financial Times.
 ^ Svetlozar T. Rachev; Frank J. Fabozzi; Christian Menn (2005). FatTailed and Skewed Asset Return Distributions: Implications for Risk Management, Portfolio Selection, and Option Pricing. John Wiley and Sons. ISBN 9780471718864.
 ^ B. Mandelbrot, "The variation of certain Speculative Prices", The Journal of Business 1963
ReferencesEdit
 Harold Markowitz, "Portfolio Selection", The Journal of Finance, 7, 1952, pp. 77–91
 William F. Sharpe, Investments, PrenticeHall, 1985
 Attilio Meucci, P versus Q: Differences and Commonalities between the Two Areas of Quantitative Finance, GARP Risk Professional, February 2011, pp. 41–44
 Nicole El Karoui, The Future of Financial Mathematics, ParisTech Review, September 2013