Tsirelson's stochastic differential equation explained

Tsirelson's stochastic differential equation (also Tsirelson's drift or Tsirelson's equation) is a stochastic differential equation which has a weak solution but no strong solution. It is therefore a counter-example and named after its discoverer Boris Tsirelson.^[1] Tsirelson's equation is of the form

dX_t=a[t,(X_s,s\leqt)]dt+dW_t, X_0=0,

where

W_t

is the one-dimensional Brownian motion. Tsirelson chose the drift

to be a bounded measurable function that depends on the past times of

but is independent of the natural filtration

\mathcal^W

of the Brownian motion. This gives a weak solution, but since the process

is not

	W
l{F}
	infty

-measurable, not a strong solution.

Tsirelson's Drift

Let

	W
l{F}
	t

=\sigma(W_s:0\leqs\leqt)

and

	W
\{l{F}
	t


	t\in\R₊

be the natural Brownian filtration that satisfies the usual conditions,

t₀₌₁

and

(t_n)_n\in-\N

be a descending sequence

t_0>t_-1>t_-2>...,

such that

\lim_n\tot_n=0

\Delta

X
	t_n

=X
	t_n

-X
	t_n-1

and

\Deltat_n=t_n-t_n-1

\{x\}=x-\lfloorx\rfloor

be the decimal part.

Tsirelson now defined the following drift

a[t,(X_s,s\leqt)]=\sum\limits_n\in\{

\Delta

X
	t_n

\Deltat_n

\}1
	(t_n,t_n+1]

(t).

Let the expression

η_n=\xi_n+\{η_n-1\}

be the abbreviation for

\Delta

X
	t_n+1

\Deltat_n+1

\Delta

W
	t_n+1

+\{

\Deltat

\Delta

X
	t_n

\Deltat_n

\}.

Theorem

According to a theorem by Tsirelson and Yor:

1) The natural filtration of

has the following decomposition

	X
l{F}
	t

	W
=l{F}
	t

\vee\sigma(\{η_n-1\}), \forallt\geq0, \forallt_n\leqt

2) For each

n\in-\N

the

\{η_n\}

are uniformly distributed on

[0,1)

and independent of

(W_t)_t\geq

resp.

	W
l{F}
	infty

	X
l{F}
	0+

is the

-trivial σ-algebra, i.e. all events have probability

.^[2] ^[3]

Literature

Book: L. C. G.. Rogers. David. Williams . Cambridge University Press . Diffusions, Markov Processes and Martingales: Volume 2, Itô Calculus . United Kingdom . 2000 . 155–156.

References

Boris S.. Tsirel'son . An Example of a Stochastic Differential Equation Having No Strong Solution. Theory of Probability & Its Applications. 20 . 2 . 1975 . 427–430 . 10.1137/1120049.
Book: L. C. G.. Rogers. David. Williams . Cambridge University Press . Diffusions, Markov Processes and Martingales: Volume 2, Itô Calculus . United Kingdom . 2000 . 156.
Kouji. Yano. Marc. Yor . Around Tsirelson's equation, or: The evolution process may not explain everything . Probability Surveys. 12 . 2010 . 1–12 . 10.1214/15-PS256. 0906.3442 .