Yamada–Watanabe theorem

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The Yamada–Watanabe theorem is a result from probability theory saying that for a large class of stochastic differential equations a weak solution with pathwise uniqueness implies a strong solution and uniqueness in distribution. In its original form, the theorem was stated for ${\displaystyle n}$-dimensional Itô equations and was proven by Toshio Yamada and Shinzō Watanabe in 1971.^[1] Since then, many generalizations appeared particularly one for general semimartingales by Jean Jacod from 1980.^[2]

Jean Jacod generalized the result to SDEs of the form

${\displaystyle d{X}_t=u(X,Z)d{Z}_t,}$

where ${\displaystyle (Z_t{)}_{t\ge 0}}$ is a semimartingale and the coefficient ${\displaystyle u}$ can depend on the path of ${\displaystyle Z}$.^[2]

Further generalisations were done by Hans-Jürgen Engelbert (1991^[3]) and Thomas G. Kurtz (2007^[4]). For SDEs in Banach spaces there is a result from Martin Ondrejat (2004^[5]), one by Michael Röckner, Byron Schmuland and Xicheng Zhang (2008^[6]) and one by Stefan Tappe (2013^[7]).

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^[3]) and a more general version by Alexander Cherny (2002^[8]).

Let ${\displaystyle n,r\in \mathbb{N}}$ and ${\displaystyle C({ℝ}_{+},{ℝ}^n)}$ be the space of continuous functions. Consider the ${\displaystyle n}$-dimensional Itô equation

${\displaystyle d{X}_t=b(t,X)dt+\sigma (t,X)d{W}_t,X_0=x_0}$

where

• ${\displaystyle b:{ℝ}_{+}\times C({ℝ}_{+},{ℝ}^n)\to {ℝ}^n}$ and ${\displaystyle \sigma :{ℝ}_{+}\times C({ℝ}_{+},{ℝ}^n)\to {ℝ}^{n\times r}}$ are predictable processes,
• ${\displaystyle (W_t{)}_{t\ge 0}={((W_t^{(1)},\dots ,W_t^{(r)}))}_{t\ge 0}}$ is an ${\displaystyle r}$-dimensional Brownian Motion,
• ${\displaystyle x_0\in {ℝ}^n}$ is deterministic.

We say uniqueness in distribution (or weak uniqueness), if for two arbitrary solutions ${\displaystyle (X^{(1)},W^{(1)})}$ and ${\displaystyle (X^{(2)},W^{(2)})}$ defined on (possibly different) filtered probability spaces ${\displaystyle ({\mathrm{\Omega }}_1,{ℱ}_1,{𝐅}_1,P_1)}$ and ${\displaystyle ({\mathrm{\Omega }}_2,{ℱ}_2,{𝐅}_2,P_2)}$, we have for their distributions ${\displaystyle P_{X^{(1)}}=P_{X^{(2)}}}$, where ${\displaystyle P_{X^{(1)}}:=\mathrm{Law}(X_t^1,t\ge 0)}$.

We say pathwise uniqueness (or strong uniqueness) if any two solutions ${\displaystyle (X^{(1)},W)}$ and ${\displaystyle (X^{(2)},W)}$, defined on the same filtered probability spaces ${\displaystyle (\mathrm{\Omega },ℱ,𝐅,P)}$ with the same ${\displaystyle 𝐅}$-Brownian motion, are indistinguishable processes, i.e. we have ${\displaystyle P}$-almost surely that ${\displaystyle \{X_t^{(1)}=X_t^{(2)},t\ge 0\}}$

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.^[3][8]

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.^[2]