TY - JOUR
T1 - All adapted topologies are equal
AU - Backhoff-Veraguas, Julio
AU - Bartl, Daniel
AU - Beiglböck, Mathias
AU - Eder, Manuel
N1 - Publisher Copyright:
© 2020, The Author(s).
PY - 2020
Y1 - 2020
N2 - A number of researchers have introduced topological structures on the set of laws of stochastic processes. A unifying goal of these authors is to strengthen the usual weak topology in order to adequately capture the temporal structure of stochastic processes. Aldous defines an extended weak topology based on the weak convergence of prediction processes. In the economic literature, Hellwig introduced the information topology to study the stability of equilibrium problems. Bion–Nadal and Talay introduce a version of the Wasserstein distance between the laws of diffusion processes. Pflug and Pichler consider the nested distance (and the weak nested topology) to obtain continuity of stochastic multistage programming problems. These distances can be seen as a symmetrization of Lassalle’s causal transport problem, but there are also further natural ways to derive a topology from causal transport. Our main result is that all of these seemingly independent approaches define the same topology in finite discrete time. Moreover we show that this ‘weak adapted topology’ is characterized as the coarsest topology that guarantees continuity of optimal stopping problems for continuous bounded reward functions.
AB - A number of researchers have introduced topological structures on the set of laws of stochastic processes. A unifying goal of these authors is to strengthen the usual weak topology in order to adequately capture the temporal structure of stochastic processes. Aldous defines an extended weak topology based on the weak convergence of prediction processes. In the economic literature, Hellwig introduced the information topology to study the stability of equilibrium problems. Bion–Nadal and Talay introduce a version of the Wasserstein distance between the laws of diffusion processes. Pflug and Pichler consider the nested distance (and the weak nested topology) to obtain continuity of stochastic multistage programming problems. These distances can be seen as a symmetrization of Lassalle’s causal transport problem, but there are also further natural ways to derive a topology from causal transport. Our main result is that all of these seemingly independent approaches define the same topology in finite discrete time. Moreover we show that this ‘weak adapted topology’ is characterized as the coarsest topology that guarantees continuity of optimal stopping problems for continuous bounded reward functions.
KW - APPROXIMATION
KW - ARBITRAGE
KW - Aldous' extended weak topology
KW - BOUNDS
KW - CAUSAL TRANSPORT
KW - CONVERGENCE
KW - Causal optimal transport
KW - DISCRETE-TIME
KW - DISTANCE
KW - Hellwig's information topology
KW - Nested distance
KW - OPTIMAL TRANSPORT
KW - STANDARDNESS
KW - Stability of optimal stopping
KW - Vershik's iterated Kantorovich distance
KW - Hellwig’s information topology
KW - Aldous’ extended weak topology
KW - Vershik’s iterated Kantorovich distance
UR - http://www.scopus.com/inward/record.url?scp=85090986958&partnerID=8YFLogxK
U2 - 10.1007/s00440-020-00993-8
DO - 10.1007/s00440-020-00993-8
M3 - Article
SN - 0178-8051
VL - 178
SP - 1125
EP - 1172
JO - Probability Theory and Related Fields
JF - Probability Theory and Related Fields
ER -