Stochastic finance

Stochastic finance is a field of mathematical finance that models prices, interest rates and risk with stochastic processes, and applies probability, stochastic calculus and martingale techniques to valuation, hedging and risk measurement. Specialist journals frame the area as finance “based on stochastic methods,” spanning both theory and applications at the interface of probability and finance.

History

’s 1900 thesis in the Annales scientifiques de l’École Normale Supérieure modelled price changes with Brownian motion and anticipated later diffusion-based approaches. A modern synthesis emerged with the Black–Scholes article in 1973, which connected dynamic hedging to a pricing partial differential equation and a closed-form solution. From the late 1980s, martingale and semimartingale methods supplied a measure-theoretic foundation, notably the fundamental theorem of asset pricing that links absence of arbitrage to the existence of an equivalent martingale measure.

Mathematical foundations

Core tools come from continuous-time probability and stochastic analysis. Graduate texts present Brownian motion as a canonical model and develop Itô integration and stochastic differential equations; pricing is set on martingale grounds with changes of measure and links to parabolic PDEs via Feynman–Kac.

Representative models

A small set of models has shaped practice and pedagogy.

Model/framework	Purpose in the literature	Canonical source
Black–Scholes diffusion	Baseline diffusion for dynamic hedging and valuation, yielding a pricing PDE and closed-form solutions for European options.
Stochastic volatility	Variance follows its own diffusion, producing volatility smiles/skews while retaining analytic tractability through characteristic functions.
Jump and Lévy models	Discontinuities and heavy tails are modelled with jump-diffusions or pure-jump processes, improving fit to returns and option smiles.
Heath–Jarrow–Morton rates	Forward-rate dynamics are specified under no-arbitrage for the entire curve, unifying interest-rate derivative valuation.

Themes and results

Work in the field returns to a handful of ideas. The fundamental theorem of asset pricing states that absence of arbitrage corresponds to a probability measure under which discounted price processes are martingales; in complete markets this gives exact replication, while incompleteness leads to super-replication and risk-measure approaches. Continuous-time portfolio choice and stochastic control supply consumption–investment results and verification through Hamilton–Jacobi–Bellman equations, while optimal stopping handles American-style exercise and related free-boundary problems.

Journals and texts

Research commonly appears in Finance and Stochastics and Mathematical Finance; widely used books include Karatzas & Shreve’s graduate text on Brownian motion and stochastic calculus, Shreve’s two-volume sequence on continuous-time models, Baxter & Rennie’s introduction to derivative pricing, and Cont & Tankov’s monograph on jump processes.