The Yamada–Watanabe theorem is a result from

probability theory Probability theory or probability calculus is the branch of mathematics concerned with probability. Although there are several different probability interpretations, probability theory treats the concept in a rigorous mathematical manner by expre ...

saying that for a large class of

stochastic differential equation A stochastic differential equation (SDE) is a differential equation in which one or more of the terms is a stochastic process, resulting in a solution which is also a stochastic process. SDEs have many applications throughout pure mathematics an ...

s a ''weak solution'' with ''pathwise uniqueness'' implies a ''strong solution'' and ''uniqueness in distribution''. In its original form, the theorem was stated for

n

-dimensional ''Itô equations'' and was proven by Toshio Yamada and Shinzo Watanabe in 1971. Since then, many generalizations appeared particularly one for general

semimartingale In probability theory, a real-valued stochastic process ''X'' is called a semimartingale if it can be decomposed as the sum of a local martingale and a càdlàg adapted finite-variation process. Semimartingales are "good integrators", forming the ...

s by Jean Jacod from 1980.

Yamada–Watanabe theorem

History, generalizations and related results

Jean Jacod generalized the result to SDEs of the form :

dX_t=u(X,Z)dZ_t,

where

(Z_t)_

is a

and the coefficient

u

can depend on the path of

Z

. Further generalisations were done by Hans-Jürgen Engelbert (1991) and Thomas G. Kurtz (2007). For SDEs in

Banach space In mathematics, more specifically in functional analysis, a Banach space (, ) is a complete normed vector space. Thus, a Banach space is a vector space with a metric that allows the computation of vector length and distance between vectors and ...

s there is a result from Martin Ondrejat (2004), one by Michael Röckner, Byron Schmuland and Xicheng Zhang (2008) and one by Stefan Tappe (2013). The converse of the theorem is also true and called the ''dual Yamada–Watanabe theorem''. The first version of this theorem was proven by Engelbert (1991) and a more general version by Alexander Cherny (2002).

Setting

Let

n,r\in\mathbb

and

C(\R_+,\R^n)

be the space of continuous functions. Consider the

n

-dimensional Itô equation :

dX_t=b(t,X)dt+\sigma(t,X)dW_t,\quad X_0=x_0

where *

b\colon \R_+\times C(\R_+,\R^n)\to\R^n

and

\sigma \colon \R_+\times C(\R_+,\R^n)\to\R^

are

predictable process In stochastic analysis, a part of the mathematical theory of probability, a predictable process is a stochastic process whose value is knowable at a prior time. The predictable processes form the smallest class that is closed under taking limits o ...

es, *

(W_t)_=\left((W^_t,\dots,W^_t)\right)_

is an

r

-dimensional

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 ...

, *

x_0\in \R^n

is deterministic.

Basic terminology

We say ''uniqueness in distribution'' (or ''weak uniqueness''), if for two arbitrary solutions

(X^,W^)

and

(X^,W^)

defined on (possibly different) filtered probability spaces

(\Omega_1,\mathcal_1,\mathbf_1,P_1)

and

(\Omega_2,\mathcal_2,\mathbf_2,P_2)

, we have for their distributions

P_=P_

, where

P_:=\operatorname(X_t^,t\geq 0)

. We say ''pathwise uniqueness'' (or ''strong uniqueness'') if any two solutions

(X^,W)

and

(X^,W)

, defined on the same filtered probability spaces

(\Omega,\mathcal,\mathbf,P)

with the same

\mathbf

-Brownian motion, are indistinguishable processes, i.e. we have

P

-almost surely that

\{X_t^{(1)}=X_t^{(2)},t\geq 0\}

Theorem

Assume the described setting above is valid, then the theorem is: : If there is ''pathwise uniqueness'', then there is also ''uniqueness in distribution''. And if for every initial distribution, there exists a weak solution, then for every initial distribution, also a pathwise unique strong solution exists. Jacod's result improved the statement with the additional statement that : If a weak solutions exists and pathwise uniqueness holds, then this solution is also a strong solution.

References

Theorems in probability theory Stochastic differential equations