A Non-Skorohod Topology on the Skorohod Space

Abstract: A new topology (called S) is defined on the space ID of functions x : [0, 1] → IR 1 which are right-continuous and admit limits from the left at each t > 0. Although S cannot be metricized, it is quite natural and shares many useful properties with the traditional Skorohod's topologies J 1 and M 1 . In particular, on the space P(ID) of laws of stochastic processes with trajectories in ID the topology S induces a sequential topology for which both the direct and the converse Prohorov's theorems are valid, the a… Show more

“…, R 2 , where we equip the first factor with the sup-norm topology, and the second factor with the S-topology of Jakubowski (see [1]). Considering the SDE and the BSDE satisfying respectively by X and Y :…”

Homogenization of a Degenerate Pde With Non Linear Wentzell Boundary Condition

“…, R 2 , where we equip the first factor with the sup-norm topology, and the second factor with the S-topology of Jakubowski (see [1]). Considering the SDE and the BSDE satisfying respectively by X and Y :…”

Homogenization of a Degenerate Pde With Non Linear Wentzell Boundary Condition

“…are generated by the projection mappings π t : x → x(t) for t ∈ [0, T ]; we shall see later that these sets are the Borel sets of the topology S of A. Jakubowski [21]. )…”

“…Pseudopaths were invented by Dellacherie and Meyer [14], actually they are Young measures on the state space (see Subsection 3.4 for the definition of Young measures). The success of Meyer-Zheng topology comes from a tightness criterion which is easily satisfied and ensures that all limits have their trajectories in the Skorokhod space D. We use here the fact that Meyer-Zheng's criterion also yields tightness for Jakubowski's stronger topology S on D [21]. Note that the result of Buckdahn, Engelbert and Rȃşcanu [11,Theorem 4.6] is more general than ours in the sense that f in [11] depends functionally on Y , more precisely, their generator f (t, x, y) is defined on [0, T ] × D × D. Furthermore, in [11], W is only supposed to be a càdlàg martingale.…”

Weak solutions of backward stochastic differential equations with continuous generator

“…We can then solve the Poisson equation 9) and carry on with the usual line of proof (see e.g. the introduction in [2]), provided we have sufficient regularity.…”

“…Recall that in the linear case we first establish a tightness result for the family of processes X , > 0, in the space C( [0, T ] , R d ) endowed with the sup-norm and proceed to identify the limit via an ergodic theorem and a martingale problem formulation. In the non-linear case however, it seems difficult to work out tightness results for the process Y (and the related martingale M , see (2.17)) in C( [0, T ] , R d ) endowed with the sup-norm and it turns out that the weaker topology of Jakubowski [9] on D( [0, T ] , R d+1 ) is convenient, see also [11] where a tightness criterion is established (actually relaxed by Kurtz [10]). Moreover, it is important to note that given our formal assumptions on the coefficients, a natural stability argument, first devised in [5] and used below with a slight modification, seems to be necessary since the family of processes Z , > 0, does not seem to converge.…”

Homogenization of a semilinear parabolic PDE with locally periodic coefficients: a probabilistic approach