Necessary and sufficient condition for the smoothness of intersection local time of subfractional Brownian motions

Abstract

Let S^H and ${\tilde{S}}^H$ be two independent d-dimensional sub-fractional Brownian motions with indices H ∈ (0, 1). Assume d ≥ 2, we investigate the intersection local time of subfractional Brownian motions

$${\ell }_T=\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\delta \left(S_t^H-{\tilde{S}}_s^H\right)\mathsf{\text{d}}s\mathsf{\text{d}}t,T>0,$$

where δ denotes the Dirac delta function at zero. By elementary inequalities, we show that ℓ _T exists in L² if and only if Hd < 2 and it is smooth in the sense of the Meyer-Watanabe if and only if $H<\frac{2}{d+2}$. As a related problem, we give also the regularity of the intersection local time process.

2010 Mathematics Subject Classification: 60G15; 60F25; 60G18; 60J55.

1. Introduction

The intersection properties of Brownian motion paths have been investigated since the forties (see [1]), and since then, a large number of results on intersection local times of Brownian motion have been accumulated (see Wolpert [2], Geman et al. [3], Imkeller et al. [4], de Faria et al. [5], Albeverio et al. [6] and the references therein). The intersection local time of independent fractional Brownian motions has been studied by Chen and Yan [7], Nualart et al. [8], Rosen [9], Wu and Xiao [10] and the references therein. As for applications in physics, the Edwards' model of long polymer molecules by Brownian motion paths uses the intersection local time to model the 'excluded volume' effect: different parts of the molecule should not be located at the same point in space, while Symanzik [11], Wolpert [12] introduced the intersection local time as a tool in constructive quantum field theory.

Intersection functionals of independent Brownian motions are used in models handling different types of polymers (see, e.g., Stoll [13]). They also occur in models of quantum fields (see, e.g., Albeverio [14]).

As an extension of Brownian motion, recently, Bojdecki et al. [15] introduced and studied a rather special class of self-similar Gaussian processes, which preserves many properties of the fractional Brownian motion. This process arises from occupation time fluctuations of branching particle systems with Poisson initial condition. This process is called the subfractional Brownian motion. The so-called subfractional Brownian motion (sub-fBm in short) with index H ∈ (0, 1) is a mean zero Gaussian process $S^H=\left\{S_t^H,t\ge 0\right\}$ with $S_0^H=0$ and

$$C_H\left(s,t\right):=E\left[S_t^H{S}_s^H\right]=s^{2H}+t^{2H}-\frac{1}{2}\left[{\left(s+t\right)}^{2H}+{\left(t-s\right)}^{2H}\right]$$

(1.1)

for all s, t ≥ 0. For $H=\frac{1}{2}$, S^H coincides with the Brownian motion B. S^H is neither a semimartingale nor a Markov process unless H = 1/ 2, so many of the powerful techniques from stochastic analysis are not available when dealing with S^H . The sub-fBm has self-similarity and long-range dependence and satisfies the following estimates:

$$\left[\left(2-2^{2H-1}\right)\wedge 1\right]{\left(t-s\right)}^{2H}\le E\left[{\left(S_t^H-S_s^H\right)}^2\right]\le \left[\left(2-2^{2H-1}\right)\vee 1\right]{\left(t-s\right)}^{2H}.$$

(1.2)

Thus, Kolmogorov's continuity criterion implies that sub-fBm is Hölder continuous of order γ for any γ < H. But its increments are not stationary. More works for sub-fBm can be found in Bardina and Bascompte [16], Bojdecki et al. [17–19], Shen et al. [20–22], Tudor [23] and Yan et al. [24, 25].

In the present paper, we consider the intersection local time of two independent sub-fBms on ℝ^d, d ≥ 2, with the same indices H ∈ (0, 1). This means that we have two d-dimensional independent centered Gaussian processes $S^H=\left\{S_t^H,t\ge 0\right\}$ and ${\tilde{S}}^H=\left\{{\tilde{S}}_t^H,t\ge 0\right\}$ with covariance structure given by

$$E\left(S_t^{H,i}{S}_s^{H,j}\right)=E\left({\tilde{S}}_t^{H,i}{\tilde{S}}_s^{H,j}\right)={\delta }_{i,j}{C}_H\left(s,t\right),$$

where i, j = 1,..., d, s, t ≥ 0. The intersection local time can be formally defined as follows, for every T > 0,

$${\ell }_T=\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\delta \left(S_t^H-{\tilde{S}}_s^H\right)\mathsf{\text{d}}s\mathsf{\text{d}}t,$$

(1.3)

where δ(·) denotes the Dirac delta function. It is a measure of the amount of time that the trajectories of the two processes, S^H and ${\tilde{S}}^H$, intersect on the time interval [0, T]. As we pointed out, this definition is only formal. In order to give a rigorous meaning to ℓ _T , we approximate the Dirac delta function by the heat kernel

$$p_{\epsilon }\left(x\right)={\left(2\pi \epsilon \right)}^{-\frac{d}{2}}{e}^{-\frac{|x{|}^2}{2\epsilon }},x\in {ℝ}^d.$$

Then, we can consider the following family of random variables indexed by ε > 0

$${\ell }_{\epsilon ,T}=\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{p}_{\epsilon }\left(S_t^H-{\tilde{S}}_s^H\right)\mathsf{\text{d}}s\mathsf{\text{d}}t,$$

(1.4)

that we will call the approximated intersection local time of S^H and ${\tilde{S}}^H$. An interesting question is to study the behavior of ℓ _ε,T as ε tends to zero.

For $H=\frac{1}{2}$, the process S^H and ${\tilde{S}}^H$ are Brownian motions. The intersection local time of independent Brownian motions has been studied by several authors (see Wolpert [2], Geman et al. [3] and the references therein). In the general case, that is $H\ne \frac{1}{2}$, only the collision local time has been studied by Yan and Shen [24]. Because of interesting properties of sub-fBm, such as short-/long-range dependence and self-similarity, it can be widely used in a variety of areas such as signal processing and telecommunications( see Doukhan et al. [26]). Therefore, it seems interesting to study the so-called intersection local time for sub-fBms, a rather special class of self-similar Gaussian processes.

The aim of this paper is to prove the existence, smoothness, regularity of the intersection local time of S^H and ${\tilde{S}}^H$, for $H\ne \frac{1}{2}$ and d ≥ 2 . It is organized as follows. In Section 2, we recall some facts for the chaos expansion. In Section 3, we study the existence of the intersection local time. In Section 4, we show that the intersection local time is smooth in the sense of the Meyer-Watanabe if and only if $H<\frac{2}{d+2}$. In Section 5, the regularity of the intersection local time is also considered.

2. Preliminaries

In this section, firstly, we recall the chaos expansion, which is an orthogonal decomposition of L²(Ω, P). We refer to Meyer [27] and Nualart [28] and Hu [29] and the references therein for more details. Let X = {X _t , t ∈ [0, T]} be a d- dimensional Gaussian process defined on the probability space $\left(\mathrm{\Omega },\mathcal{F},P\right)$ with mean zero. If p _n (x₁, . ., x _k ) is a polynomial of degree n of k variables x₁,..., x _k , then we call $p_n\left(X_{t_1}^{i_1},...,X_{t_k}^{i_k}\right)$ a polynomial functional of X with t₁,..., t _k ∈ [0, T] and 1 ≤ i₁,..., i _k ≤ d. Let ${\mathcal{P}}_n$ be the completion with respect to the L²(Ω, P) norm of the set $\left\{p_m\left(X_{t_1}^{i_1},...,X_{t_k}^{i_k}\right):0\le m\le n\right\}$. Clearly, ${\mathcal{P}}_n$ is a subspace of L²(Ω, P). If ${\mathcal{C}}_n$ denotes the orthogonal complement of ${\mathcal{P}}_{n-1}$ in ${\mathcal{P}}_n$, then L²(Ω, P) is actually the direct sum of ${\mathcal{C}}_n$, i.e.,

$$L^2\left(\mathrm{\Omega },P\right)=\underset{n=0}{\overset{\infty }{\oplus }}{\mathcal{C}}_n.$$

(2.1)

For F ∈ L² (Ω, P), we then see that there exists $F_n\in {\mathcal{C}}_n$, n = 0, 1, 2,..., such that

$$F=\sum _{n=0}^{\infty }{F}_n,$$

(2.2)

This decomposition is called the chaos expansion of F. F _n is called the n-th chaos of F. Clearly, we have

$$E\left(|F{|}^2\right)=\sum _{n=0}^{\infty }E\left(|F_n{|}^2\right).$$

(2.3)

As in the Malliavin calculus, we introduce the space of "smooth" functionals in the sense of Meyer and Watanabe (see Watanabe [30]):

$$\mathcal{U}:=\left\{F\in L^2\left(\mathrm{\Omega },P\right):F=\sum _{n=0}^{\infty }{F}_n\mathsf{\text{and}}\sum _{n=0}^{\infty }nE\left(|F_n{|}^2\right)<\infty \right\},$$

and F ∈ L²(Ω, P) is said to be smooth if $F\in \mathcal{U}$.

Now, for F ∈ L²(Ω, P), we define an operator ϒ _u with u ∈ [0,1] by

$${\Upsilon }_{u}F:=\sum _{n=0}^{\infty }{u}^n{F}_n.$$

(2.4)

Set $\mathrm{\Theta }\left(u\right):={\Upsilon }_{\sqrt{u}}F$. Then, Θ(1) = F. Define ${\mathrm{\Phi }}_{\ominus }\left(u\right):=\frac{\mathsf{\text{d}}}{\mathsf{\text{d}}u}\left(\left|\right|\mathrm{\Theta }\left(u\right)|{|}^2\right)$, where ||F||² := E(|F|²) for F∈ L²(Ω, P). We have

$${\mathrm{\Phi }}_{\mathrm{\Theta }}\left(u\right)=\sum _{n=1}^{\infty }n{u}^{n-1}E\left(|F_n{|}^2\right).$$

(2.5)

Note that $\left|\right|\mathrm{\Theta }\left(u\right)|{|}^2=E\left(|\mathrm{\Theta }\left(u\right){|}^2\right)={\sum }_{n=1}^{\infty }E\left(u^n|F_n{|}^2\right)$.

Proposition 1. Let F ∈ L²(Ω, P). Then $F\in \mathcal{U}$, if and only if Φ_Θ(1) < ∞.

Now consider two d-dimensional independent sub-fBms S^H and ${\tilde{S}}^H$ with indices H ∈ (0, 1). Let H _n (x), x ∈ ℝ be the Hermite polynomials of degree n. That is,

$$H_n\left(x\right)={\left(-1\right)}^n\frac{1}{n!}{e}^{\frac{x^2}{2}}\frac{{\partial }^n}{\partial x^n}{e}^{-\frac{x^2}{2}}.$$

(2.6)

Then,

$$e^{tx-\frac{t^2}{2}}=\sum _{n=0}^{\infty }{t}^n{H}_n\left(x\right)$$

(2.7)

for all t ∈ ℂ and x ∈ ℝ, which deduces

$$\begin{array}{l}\exp (iu〈\xi ,S_t^H–{\tilde{S}}_s^H〉+\frac{1}{2}{u}^2|\xi {|}^2\text{Var(}{S}_t^{H,1}–{\tilde{S}}_s^{H,1}))\\ ={\displaystyle \sum _{n=0}^{\infty }{(iu)}^n}{\sigma }^n(t,s,\xi )H_n\left(\frac{〈\xi ,S_t^H-{\tilde{S}}_s^H〉}{\sigma (t,s,\xi )}\right),\end{array}$$

where $\sigma \left(t,s,\xi \right)=\sqrt{\mathsf{\text{Var}}\left(S_t^{H,1}-{\tilde{S}}_s^{H,1}\right)|}\xi {|}^2$ for ξ ∈ ℝ^d. Because of the orthogonality of ${\left\{H_n\left(x\right),x\in ℝ\right\}}_{n\in {\mathbb{N}}_{+}}$, we will get from (2.2) that

$${\left(iu\right)}^n{\sigma }^n\left(t,s,\xi \right)H_n\left(\frac{⟨\xi ,S_t^H-{\tilde{S}}_s^H⟩}{\sigma \left(t,s,\xi \right)}\right)$$

is the n-th chaos of

$$exp\left(iu⟨\xi ,S_t^H-{\tilde{S}}_s^H⟩+\frac{1}{2}{u}^2|\xi {|}^2\mathsf{\text{Var}}\left(S_t^{H,1}\mathsf{\text{-}}{\tilde{S}}_s^{H,1}\right)\right)$$

for all t, s ≥ 0.

3. Existence of the intersection local time

The aim of this section is to prove the existence of the intersection local time of S^H and ${\tilde{S}}^H$, for an $H\ne \frac{1}{2}$ and d ≥ 2. We have obtained the following result.

Theorem 2. (i) If Hd < 2, then the ℓ _ε,T converges in L²(Ω). The limit is denoted by ℓ _T

1. (ii)

   If Hd ≥ 2, then

   $$\underset{\epsilon \to 0}{lim}E\left({\ell }_{\epsilon ,T}\right)=+\infty ,$$

and

$$\underset{\epsilon \to 0}{lim}\mathsf{\text{Var}}\left({\ell }_{\epsilon ,T}\right)=+\infty .$$

Note that if ${\left\{S_t^{\frac{1}{2}}\right\}}_{t\ge 0}$ is a planar Brownian motion, then

$${\ell }_{\epsilon }=\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{p}_{\epsilon }\left(S_t^{1∕2}-S_s^{1∕2}\right)\mathsf{\text{d}}s\mathsf{\text{d}}t,$$

diverges almost sure, when ε tends to zero. Varadhan, in [31], proved that the renormalized self-intersection local time defined as lim _{ε →0}(ℓ _ε -E ℓ _ε ) exists in L²(Ω). Condition (ii) implies that Varadhan renormalization does not converge in this case.

For Hd ≥ 2, according to Theorem 2, ℓ _ε,T does not converge in L²(Ω), and therefore, ℓ _T , the intersection local time of S^H and ${\tilde{S}}^H$, does not exist.

Using the following classical equality

$$p_{\epsilon }\left(x\right)=\frac{1}{{\left(2\pi \epsilon \right)}^{\frac{d}{2}}}{e}^{-\frac{|x{|}^2}{2e}}=\frac{1}{{\left(2\pi \right)}^d}\underset{{ℝ}^d}{\int }{e}^{i⟨\xi ,x⟩}{e}^{-\epsilon \frac{|\xi {|}^2}{2}}\mathsf{\text{d}}\xi \mathsf{\text{,}}$$

we have

$$\begin{array}{ll}\hfill {\ell }_{\epsilon ,T}& =\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{p}_{\epsilon }\left(S_t^H-{\tilde{S}}_s^H\right)\mathsf{\text{d}}s\mathsf{\text{d}}t\\ =\frac{1}{{\left(2\pi \right)}^d}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{\underset{{ℝ}^d}{\int }e}^{i⟨\xi ,S_t^H-{\tilde{S}}_s^H⟩}\cdot e^{-\epsilon \frac{|\epsilon {|}^2}{2}}\mathsf{\text{d}}\xi \mathsf{\text{d}}s\mathsf{\text{d}}t.\end{array}$$

(3.1)

Since $⟨\xi ,S_t^H-{\tilde{S}}_s^H⟩~N\left(0,|\xi {|}^2\left(2-2^{2H-1}\right)\left(t^{2H}+s^{2H}\right)\right)$, so

$$E|e^{i⟨\xi ,S_t^H-{\tilde{S}}_s^H⟩}=e^{-\left[\left(2-2^{2H-1}\right)\left(t^{2H}+s^{2H}\right)\right]\frac{|\xi {|}^2}{2}}.$$

Therefore,

$$\begin{array}{c}E({\ell }_{\epsilon ,T})=\frac{1}{{(2\pi )}^d}{\displaystyle \underset{0}{\overset{T}{\int }}{\displaystyle \underset{0}{\overset{T}{\int }}{\displaystyle \underset{{ℝ}^d}{\int }E\left[e^{i〈\xi ,}{S_t^H-{\tilde{S}}_s^H〉}^{}\right]\cdot e^{-\epsilon \frac{|\xi {|}^2}{2}}\text{d}\xi \text{d}s\text{d}t}}}\\ =\frac{1}{{(2\pi )}^d}{\displaystyle \underset{0}{\overset{T}{\int }}{\displaystyle \underset{0}{\overset{T}{\int }}{\displaystyle \underset{{ℝ}^d}{\int }{e}^{–[\epsilon +(2-2^{2H-1})(t^{2H}+s^{2H})]\frac{|\xi {|}^2}{2}}\text{d}\xi \text{d}s\text{d}t}}}\\ =\frac{1}{{(2\pi )}^{\frac{d}{2}}}{\displaystyle \underset{0}{\overset{T}{\int }}{\displaystyle \underset{0}{\overset{T}{\int }}{[\epsilon +(2-2^{2H-1})(t^{2H}+s^{2H})]}^{–\frac{d}{2}}\text{d}s\text{d}t,}}\end{array}$$

(3.2)

where we have used the fact

$$\underset{{ℝ}^d}{\int }{e}^{-\left[\epsilon +\left(2-2^{2H-1}\right)\left(t^{2H}+s^{2H}\right)\right]\frac{|\xi {|}^2}{2}}\mathsf{\text{d}}\xi ={\left(\frac{2\pi }{\epsilon +\left(2-2^{2H-1}\right)\left(t^{2H}+s^{2H}\right)}\right)}^{\frac{d}{2}}.$$

We also have

$$\begin{array}{c}E\left({\ell }_{\epsilon ,\mathsf{\text{T}}}^2\right)=\frac{1}{{\left(2\pi \right)}^{2d}}\underset{{\left[0,T\right]}^4}{\int }\underset{{ℝ}^{2d}}{\int }E\left[e^{i⟨\xi ,S_t^H-{\tilde{S}}_s^H⟩+i⟨\eta ,S_u^H-{\tilde{S}}_v^H⟩}\right]\\ \times e^{-\frac{\epsilon \left(|\xi {|}^2+|\eta {|}^2\right)}{2}}\mathsf{\text{d}}\xi d\eta \mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v.\end{array}$$

(3.3)

Let we introduce some notations that will be used throughout this paper,

$$\begin{array}{l}{\lambda }_{s,t}=\text{Var(}{S}_t^{H,1}-S_s^{H,2})=(2–2^{2H–1})(t^{2H}+s^{2H}),\\ {\rho }_{u,v}=\text{Var(}{S}_v^{H,1}-S_u^{H,2})=(2–2^{2H–1})(u^{2H}+v^{2H}),\end{array}$$

and

$$\begin{array}{ll}\hfill {\mu }_{s,t,u,v}& =Cov\left(S_t^{H,1}-S_s^{H,2},S_v^{H,1}-S_u^{H,2}\right)\\ =s^{2H}+t^{2H}+u^{2H}+v^{2H}-\frac{1}{2}\left[{\left(t+v\right)}^{2H}+|t-v{|}^{2H}+{\left(s+u\right)}^{2H}+|s-u{|}^{2H}\right],\end{array}$$

where S^H,1 and S^H,2 are independent one dimensional sub-fBms with indices H. Using the above notations, we can write for any ε > 0

$$\begin{array}{ll}\hfill E\left({\ell }_{\epsilon }{,}_{\mathsf{\text{T}}}^2\right)& =\frac{1}{{\left(2\pi \right)}^{2d}}\underset{{\left[0,T\right]}^4}{\int }\underset{{ℝ}^{2d}}{\int }exp\left\{-\frac{1}{2}\left(\left({\lambda }_{s,t}+\epsilon \right)|\xi {|}^2+\left({\rho }_{u,v}+\epsilon \right)|\eta {|}^2+2{\mu }_{s,t,u,v}⟨\xi ,\eta ⟩\right)\right\}\times \mathsf{\text{d}}\xi \mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v\\ =\frac{1}{{\left(2\pi \right)}^d}\underset{{\left[0,T\right]}^4}{\int }{\left[\left({\lambda }_{s,t}+\epsilon \right)\left({\rho }_{u,v}+\epsilon \right)-{\mu }_{s,t,u,v}^2\right]}^{-\frac{d}{2}}\mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v.\end{array}$$

(3.4)

In order to prove the Theorem 2, we need some auxiliary lemmas. Without loss of generality, we may assume v ≤ t, u ≤ s and v = xt, u = ys with x, y ∈ [0,1]. Then, we can rewrite ρ _u,v and µ _s,t,u,v as following.

$$\begin{array}{c}{\rho }_{u,v}=\left(2-2^{2H-1}\right)\left(x^{2H}{t}^{2H}+y^{2H}{s}^{2H}\right),\\ {\mu }_{s,t,u,v}=t^{2H}\left\{1+x^{2H}-\frac{1}{2}\left[{\left(1+x\right)}^{2H}+{\left(1-x\right)}^{2H}\right]\right\}\\ +s^{2H}\left\{1+y^{2H}-\frac{1}{2}\left[{\left(1+y\right)}^{2H}+{\left(1-y\right)}^{2H}\right]\right\}.\end{array}$$

(3.5)

It follows that

$${\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2=t^{4H}f\left(x\right)+s^{4H}f\left(y\right)+t^{2H}{s}^{2H}g\left(x,y\right),$$

(3.6)

where

$$f\left(x\right):={\left(2-2^{2H-1}\right)}^2{x}^{2H}-{\left(1+x^{2H}-\frac{1}{2}{\left(1+x\right)}^{2H}-\frac{1}{2}{\left(1-x\right)}^{2H}\right)}^2,$$

and

$$\begin{array}{ll}\hfill g\left(x,y\right)& ={\left(2-2^{2H-1}\right)}^2\left(x^{2H}+y^{2H}\right)\\ -2\left(1+x^{2H}-\frac{1}{2}{\left(1+x\right)}^{2H}-\frac{1}{2}{\left(1-x\right)}^{2H}\right)\\ \times \left(1+y^{2H}-\frac{1}{2}{\left(1+y\right)}^{2H}-\frac{1}{2}{\left(1-y\right)}^{2H}\right).\end{array}$$

(3.7)

For simplicity throughout this paper, we assume that the notation F ≍ G means that there are positive constants c₁ and c₂ so that

$$c_{1}G\left(x\right)\le F\left(x\right)\le c_{2}G\left(x\right)$$

in the common domain of definition for F and G. For a, b ∈ ℝ, a ∧ b := min{a, b} and a ∨ b := max{a, b}. By Lemma 4.2 of Yan and Shen [24], we get

Lemma 3. Let f(x) and g(x, y) be defined as above and let 0 < H < 1. Then, we have

$$f\left(x\right)\asymp x^{2H}{\left(1-x\right)}^{2H},$$

(3.8)

and

$$g\left(x,y\right)\asymp x^{2H}{\left(1-y\right)}^{2H}+y^{2H}{\left(1-x\right)}^{2H}$$

(3.9)

for all x, y ∈ [0,1].

Lemma 4. Let

$$A_T:=\underset{{\left[0,T\right]}^4}{\int }{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}\mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v.$$

Then, A _T is finite if and only if Hd < 2 .

Proof. It is easily to prove the necessary condition. In fact, we can find ε > 0 such that D _ε ⊂ [0, T]⁴, where

$$D_{\epsilon }\equiv \left\{\left(s,t,u,v\right)\in {ℝ}_{+}^4:s^2+t^2+u^2+v^2\le {\epsilon }^2\right\}.$$

We make a change to spherical coordinates as following

$$\left\{\begin{array}{c}\hfill s=rcos{\phi }_1,\hfill \\ \hfill t=rsin{\phi }_{1}cos{\phi }_2,\hfill \\ \hfill u=rsin{\phi }_{1}sin{\phi }_{2}cos{\phi }_3,\hfill \\ \hfill v=rsin{\phi }_{1}sin{\phi }_{2}sin{\phi }_3.\hfill \end{array}\right.$$

(3.10)

where 0 ≤ r ≤ ε, 0 ≤ φ₁, φ₂ ≤ π, 0 ≤ φ₃ ≤ 2π,

$$J=\frac{\partial \left(s,t,u,v\right)}{\partial \left(r,{\phi }_1,{\phi }_2,{\phi }_3\right)}=r^3{sin}^2{\phi }_{1}sin{\phi }_2.$$

As ${\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2$ is always positive, and ${\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2=r^{4H}\varphi \left(\theta \right)$, we have

$$A_T\ge \underset{D_{\epsilon }}{\int }{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}\mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v=\underset{0}{\overset{\epsilon }{\int }}{r}^{3-2Hd}\underset{\mathrm{\Theta }}{\int }\varphi \left(\theta \right)\mathsf{\text{d}}\theta ,$$

(3.11)

where the integral in r is convergent if and only if 3 - 2Hd > -1 i.e., Hd < 2 and the angular integral is different from zero thanks to the positivity of the integrand. Therefore, Hd ≥ 2 implies that A _T = +∞.

Now, we turn to the proof of sufficient condition. Suppose that Hd < 2. By symmetry, we have

$$A_T=4\underset{\Upsilon }{\int }{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}\mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v,$$

where ϒ = f(u, v, s, t):0 < u < s ≤ T, 0 < v < t ≤ T}.

By Lemma 3, we get

$$\begin{array}{ll}\hfill {\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2& =t^{4H}f\left(x\right)+s^{4H}f\left(y\right)+t^{2H}{s}^{2H}g\left(x,y\right)\\ \asymp t^{4H}{x}^{2H}{\left(1-x\right)}^{2H}+s^{4H}{y}^{2H}{\left(1-y\right)}^{2H}\\ +t^{2H}{s}^{2H}\left(x^{2H}{\left(1-y\right)}^{2H}+y^{2H}{\left(1-x\right)}^{2H}\right)\\ =\left[x^{2H}{t}^{2H}+y^{2H}{s}^{2H}\right]\left[{\left(1-x\right)}^{2H}{t}^{2H}+{\left(1-y\right)}^{2H}{s}^{2H}\right]\\ =\left(v^{2H}+u^{2H}\right)\left[{\left(t-v\right)}^{2H}+{\left(s-u\right)}^{2H}\right].\end{array}$$

(3.12)

These deduce for all H ∈ (0, 1) and T > 0,

$$\begin{array}{c}{\Lambda }_T\le C_H\underset{0}{\overset{T}{\int }}\mathsf{\text{d}}t\underset{0}{\overset{t}{\int }}{\left(v^H{\left(t-v\right)}^H\right)}^{-d∕2}\mathsf{\text{d}}v\underset{0}{\overset{T}{\int }}\mathsf{\text{d}}s\underset{0}{\overset{s}{\int }}{\left(u^H{\left(s-u\right)}^H\right)}^{-d∕2}\mathsf{\text{d}}u\\ =C_H{\left(\underset{0}{\overset{T}{\int }}{t}^{1-Hd}\mathsf{\text{d}}t\underset{0}{\overset{1}{\int }}{x}^{-\frac{Hd}{2}}{\left(1-x\right)}^{-\frac{Hd}{2}}\mathsf{\text{d}}x\right)}^2<\infty .\end{array}$$

   □

Proof of Theorem 2. Suppose Hd < 2, we have

$$E\left({\ell }_{\epsilon ,T}\cdot {\ell }_{\eta ,T}\right)=\frac{1}{{\left(2\pi \right)}^d}\underset{{\left[0,T\right]}^4}{\int }{\left(\left({\lambda }_{s,t}+\epsilon \right)\left({\rho }_{u,v}+\eta \right)-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}\mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v.$$

Consequently, a necessary and sufficient condition for the convergence in L²(Ω) of ℓ _ε,T is that

$$\underset{{\left[0,T\right]}^4}{\int }{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}\mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v<\infty .$$

This is true due to Lemma 4.

If Hd ≥ 2, then from (3.2) and using monotone convergence theorem

$$\underset{\epsilon \to 0}{lim}E\left({\ell }_{\epsilon ,T}\right)=\frac{1}{{\left(2\pi \left(2-2^{2H-1}\right)\right)}^{d∕2}}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{\left(s^{2H}+t^{2H}\right)}^{-\frac{d}{2}}\mathsf{\text{d}}s\mathsf{\text{d}}t.$$

Making a polar change of coordinates

$$\left\{\begin{array}{c}\hfill x=rcos\theta ,\hfill \\ \hfill y=rsin\theta ,\hfill \end{array}\right.$$

where 0 ≥ r ≥ T, $0\le \theta \le \frac{\pi }{2}$,

$$\begin{array}{c}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{\left(s^{2H}+t^{2H}\right)}^{-\frac{d}{2}}\mathsf{\text{d}}s\mathsf{\text{d}}t\\ =\underset{0}{\overset{T}{\int }}\underset{0}{\overset{\frac{\pi }{2}}{\int }}{r}^{1-Hd}{\left({cos}^{2H}\theta +{sin}^{2H}\theta \right)}^{-\frac{d}{2}}\mathsf{\text{d}}r\mathsf{\text{d}}\theta ,\end{array}$$

and this integral is divergent if Hd ≥ 2. By the expression (3.2) and (3.4), we have

$$\begin{array}{ll}\hfill \underset{\epsilon \to 0}{lim}\mathsf{\text{Var}}\left({\ell }_{\epsilon ,T}\right)& =\underset{\epsilon \to 0}{lim}\left[E\left({\ell }_{\epsilon ,T}^2\right)-{\left(E{\ell }_{\epsilon ,T}\right)}^2\right]\\ =\frac{1}{{\left(2\pi \right)}^d}\underset{{\left[0,T\right]}^4}{\int }\left\{{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}-{\left({\lambda }_{s,t}{\rho }_{u,v}\right)}^{-\frac{d}{2}}\right\}\mathsf{\text{d}}v\mathsf{\text{d}}u\mathsf{\text{d}}s\mathsf{\text{d}}t.& \hfill \text{(2) }\end{array}$$

Making a change of variables to spherical coordinates as (3.10), if Hd ≥ 2, we have

$$\underset{\epsilon \to 0}{lim}Var\left({\ell }_{\epsilon ,T}\right)=+\infty .$$

In fact, as the integrand is always positive, we obtain

$$\begin{array}{c}\underset{{\left[0,T\right]}^4}{\int }\left\{{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}-{\left({\lambda }_{s,t}{\rho }_{u,v}\right)}^{-\frac{d}{2}}\right\}\mathsf{\text{d}}v\mathsf{\text{d}}u\mathsf{\text{d}}s\mathsf{\text{d}}t\\ \ge \underset{D_{\epsilon }}{\int }\left\{{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}-{\left({\lambda }_{s,t}{\rho }_{u,v}\right)}^{-\frac{d}{2}}\right\}\mathsf{\text{d}}v\mathsf{\text{d}}u\mathsf{\text{d}}s\mathsf{\text{d}}t\\ =\underset{0}{\overset{\epsilon }{\int }}{r}^{3-2Hd}\mathsf{\text{d}}r\underset{\mathrm{\Theta }}{\int }\psi \left(\theta \right)\mathsf{\text{d}}\theta ,\end{array}$$

where the integral in r is convergent if and only if Hd < 2, and the angular integral is different from zero thanks to the positivity of the integrand. Therefore, Hd ≥ 2 implies that

$$\underset{\epsilon \to 0}{lim}Var\left({\ell }_{\epsilon ,T}\right)=+\infty .$$

This completes the proof of Theorem 2.    □

4. Smoothness of the intersection local time

In this section, we consider the smoothness of the intersection local time. Our main object is to explain and prove the following theorem. The idea is due to An and Yan [32] and Chen and Yan [7].

Theorem 5. Let ℓ _T be the intersection local time of two independent d-dimensional sub-fBms S^H and ${\tilde{S}}^H$ with indices H ∈ (0, 1) . Then , ℓ _T ∈ $\mathcal{U}$ if and only if

$$H<\frac{2}{d+2}.$$

Recall that

$$\begin{array}{ll}\hfill {\lambda }_{s,t}& =\left(2-2^{2H-1}\right)\left(t^{2H}+s^{2H}\right),\\ \hfill {\rho }_{u,v}& =\left(2-2^{2H-1}\right)\left(u^{2H}+v^{2H}\right),\end{array}$$

and

$${\mu }_{s,t,u,v}=s^{2H}+t^{2H}+u^{2H}+v^{2H}-\frac{1}{2}\left[{\left(t+v\right)}^{2H}+|t-v{|}^{2H}+{\left(s+u\right)}^{2H}+|s-u{|}^{2H}\right],$$

for all s, t, u, v ≥ 0.

In order to prove Theorem 5, we need the following propositions.

Proposition 6. Under the assumptions above, the following statements are equivalent:

1. (i)

   $H<\frac{2}{d+2}$ ;

2. (ii)

   $\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}-1}{\mu }_{s,t,u,v}^2\mathsf{\text{d}}v\mathsf{\text{d}}u\mathsf{\text{d}}s\mathsf{\text{d}}t<\infty$.

Proof. By (3.12), we have

$$\begin{array}{ll}\hfill {\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2& =t^{4H}f\left(x\right)+s^{4H}f\left(y\right)+t^{2H}{s}^{2H}g\left(x,y\right)\\ \asymp t^{4H}{x}^{2H}{\left(1-x\right)}^{2H}+s^{4H}{y}^{2H}{\left(1-y\right)}^{2H}\\ +t^{2H}{s}^{2H}\left(x^{2H}{\left(1-y\right)}^{2H}+y^{2H}{\left(1-x\right)}^{2H}\right)\\ =\left[x^{2H}{t}^{2H}+y^{2H}{s}^{2H}\right]\left[{\left(1-x\right)}^{2H}{t}^{2H}+{\left(1-y\right)}^{2H}{s}^{2H}\right].\end{array}$$

(4.1)

On the other hand, an elementary calculus can show that

$$x^{2H}\le 1+x^{2H}-\frac{1}{2}{\left(1+x\right)}^{2H}-\frac{1}{2}{\left(1-x\right)}^{2H}\le \left(2-2^{2H-1}\right)x^{2H}$$

for all x, H ∈ (0, 1). By (3.5), we obtain

$${\left(t^{2H}{x}^{2H}+s^{2H}{y}^{2H}\right)}^2\le {\mu }_{s,t,u,v}^2\le {\left(2-2^{2H-1}\right)}^2{\left(t^{2H}{x}^{2H}+s^{2H}{y}^{2H}\right)}^2.$$

(4.2)

It follows that

$$\begin{array}{c}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}-1}{\mu }_{s,t,u,v}^2\mathsf{\text{d}}s\mathsf{\text{d}}t\mathsf{\text{d}}u\mathsf{\text{d}}v\\ \ge C_{H,T}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{1}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{1}{\int }}\frac{\left(t^{2H}{x}^{2H}+s^{2H}{y}^{2H}\right)st}{{\left({\left(1-x\right)}^{2H}{t}^{2H}+{\left(1-y\right)}^{2H}{s}^{2H}\right)}^{1+\frac{d}{2}}}\mathsf{\text{d}}y\mathsf{\text{d}}s\mathsf{\text{d}}x\mathsf{\text{d}}t\\ \ge C_{H,T}\underset{0}{\overset{1}{\int }}\underset{0}{\overset{1}{\int }}\underset{0}{\overset{1}{\int }}\underset{0}{\overset{1}{\int }}\frac{\left(t^{2H}{x}^{2H}+s^{2H}{y}^{2H}\right)st}{{\left({\left(1-x\right)}^{2H}{t}^{2H}+{\left(1-y\right)}^{2H}{s}^{2H}\right)}^{1+\frac{d}{2}}}\mathsf{\text{d}}y\mathsf{\text{d}}s\mathsf{\text{d}}x\mathsf{\text{d}}t\\ \ge C_{H,T}\underset{0}{\overset{1}{\int }}\mathsf{\text{d}}y\underset{0}{\overset{y}{\int }}\mathsf{\text{d}}x\underset{0}{\overset{x}{\int }}\mathsf{\text{d}}t\underset{0}{\overset{t}{\int }}\mathsf{\text{d}}s\frac{s^{2H+1}{x}^{2H}}{t^{2H\left(1+d∕2\right)-1}{\left(1-x\right)}^{2H\left(1+d∕2\right)}}\\ \ge C_{H,T}\underset{0}{\overset{1}{\int }}\mathsf{\text{d}}y\underset{0}{\overset{y}{\int }}\frac{x^{4-H\left(d-2\right)}}{{\left(1-x\right)}^{2H\left(1+d∕2\right)}}\mathsf{\text{d}}x=C_{H,T}\underset{0}{\overset{1}{\int }}{x}^{4-H\left(d-2\right)}{\left(1-x\right)}^{1-2H\left(1+d∕2\right)}\mathsf{\text{d}}x,\end{array}$$

where C _H,T > 0 is a constant depending only on H and T and its value may differ from line to line, which implies that $H<\frac{2}{d+2}$ if the convergence (ii) holds.

On the other hand,

$$\begin{array}{c}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}-1}{\mu }_{s,t,u,v}^2\mathsf{\text{d}}u\mathsf{\text{d}}s\mathsf{\text{d}}v\mathsf{\text{d}}t\\ \le C_H\underset{0}{\overset{T}{\int }}\underset{0}{\overset{1}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{1}{\int }}\frac{{\left(t^{2H}{x}^{2H}+s^{2H}{y}^{2H}\right)}^{2}st}{{\left[\left(x^{2H}{t}^{2H}+y^{2H}{s}^{2H}\right)\left({\left(1-x\right)}^{2H}{t}^{2H}+{\left(1-y\right)}^{2H}{s}^{2H}\right)\right]}^{d∕2+1}}\mathsf{\text{d}}y\mathsf{\text{d}}s\mathsf{\text{d}}x\mathsf{\text{d}}t\\ \le C_H\underset{0}{\overset{T}{\int }}\underset{0}{\overset{1}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{1}{\int }}\frac{{\left(t^{2H}{x}^{2H}+s^{2H}{y}^{2H}\right)}^{2}st}{{\left[\left(x^H{t}^H{y}^H{s}^H\right)\left({\left(1-x\right)}^H{t}^H{\left(1-y\right)}^H{s}^H\right)\right]}^{d∕2+1}}\mathsf{\text{d}}y\mathsf{\text{d}}s\mathsf{\text{d}}x\mathsf{\text{d}}t\\ \le C_H\underset{0}{\overset{T}{\int }}\underset{0}{\overset{1}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{1}{\int }}\frac{T^{4H}}{x^{\frac{d+2}{2}H}{y}^{\frac{d+2}{2}H}{\left(1-x\right)}^{\frac{d+2}{2}H}{\left(1-y\right)}^{\frac{d+2}{2}H}{t}^{\left(d+2\right)H-1_S\left(d+2\right)H-1}}\mathsf{\text{d}}y\mathsf{\text{d}}s\mathsf{\text{d}}x\mathsf{\text{d}}t\\ <\infty \end{array}$$

if $H<\frac{2}{d+2}$. Where C _H > 0 is a constant depending only on H and its value may differ from line to line. Thus, the proof is completed.    □

Hence, Theorem 5 follows from the next proposition.

Proposition 7. Under the assumptions above, the following statements are equivalent: ℓ _T ∈ $\mathcal{U}$ if and only if

$$\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}-1}{\mu }_{s,t,u,v}^2\mathsf{\text{d}}u\mathsf{\text{d}}v\mathsf{\text{d}}s\mathsf{\text{d}}t<\infty .$$

(4.3)

In order to prove Proposition 7, we need some preliminaries(see Nualart [28]). Let X, Y be two random variables with joint Gaussian distribution such that E(X) = E(Y) = 0 and E(X²) = E(Y²) = 1. Then, for all n, m ≥ 0, we have

$$E\left(H_n\left(X\right)H_m\left(Y\right)\right)=\left\{\begin{array}{cc}\hfill 0,\hfill & \hfill m\ne n,\hfill \\ \hfill \frac{1}{n!}{\left[E\left(XY\right)\right]}^n,\hfill & \hfill m=n.\hfill \end{array}\right.$$

(4.4)

Moreover, elementary calculus can show that the following lemma holds.

Lemma 8 ([7]). Suppose d ≥ 1. For any x ∈ [-1, 1) we have

$$\sum _{n=1}^{\infty }\sum _{\begin{array}{c}{k}_1,\dots ,k_d=0\\ k_1+\cdots +k_d=n\end{array}}^n\frac{2n\left(2k_1-1\right)!!\cdot \cdot \cdot \cdot \cdot \left(2k_d-1\right)!!}{\left(2k_1\right)!!\cdot \cdot \cdot \cdot \cdot \left(2k_d\right)!!}{x}^n\asymp x{\left(1-x\right)}^{-\left(\frac{d}{2}+1\right)}.$$

Particularly, this is an equality if and only if d = 1 (see An and Yan [32]).

It follows from ${\mu }_{s,t,u,v}^2\le {\lambda }_{s,t}{\rho }_{u,v}$ that

$$\begin{array}{ll}\hfill \frac{{\mu }_{s,t,u,v}^2}{{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{\frac{d}{2}+1}}& =\frac{{\mu }_{s,t,u,v}^2}{{\lambda }_{s,t}{\rho }_{u,v}}{\left(1-\frac{{\mu }_{s,t,u,v}^2}{{\lambda }_{s,t}{\rho }_{u,v}}\right)}^{-\left(\frac{d}{2}+1\right)}{\left(\frac{1}{{\lambda }_{s,t}{\rho }_{u,v}}\right)}^{\frac{d}{2}}\\ \asymp \sum _{n=1}^{\infty }\sum _{\begin{array}{c}{k}_1,\dots ,k_d=0\\ k_1+\cdots +k_d=n\end{array}}^n\frac{2n\left(2k_1-1\right)!!\cdot \cdot \cdot \cdot \cdot \left(2k_d-1\right)!!}{\left(2k_1\right)!!\cdot \cdot \cdot \cdot \cdot \left(2k_d\right)!!}\frac{{\mu }_{s,t,u,v}^{2n}}{{\left({\lambda }_{s,t}{\rho }_{u,v}\right)}^{n+\frac{d}{2}}}.\end{array}$$

Proof of Proposition 7. For ε > 0, T ≥ 0, we denote

$${\mathrm{\Phi }}_{{\mathrm{\Theta }}_{\epsilon }}\left(\kappa \right):=E\left(|{\Upsilon }_{\sqrt{\kappa }}{\ell }_{\epsilon ,T}{|}^2\right)$$

and ${\mathrm{\Phi }}_{\mathrm{\Theta }}\left(\kappa \right):=E\left(|{\Upsilon }_{\sqrt{\kappa }}{\ell }_T{|}^2\right)$. Thus, by Proposition 2.1, it suffices to prove (4.3) if and only if Φ_Θ(1) < ∞. Noticing that

$$\begin{array}{ll}\hfill {\ell }_{\epsilon ,T}& =\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}{p}_{\epsilon }\left(S_t^H-{\tilde{S}}_s^H\right)\mathsf{\text{d}}s\mathsf{\text{d}}t\\ =\frac{1}{{\left(2\pi \right)}^d}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{{ℝ}^d}{\int }{e}^i⟨\xi ,S_t^H-{\tilde{S}}_s^H⟩e^{-\epsilon \frac{|\xi {|}^2}{2}}\mathsf{\text{d}}\xi \mathsf{\text{d}}s\mathsf{\text{d}}t\\ =\frac{1}{{\left(2\pi \right)}^d}\underset{0}{\overset{T}{\int }}\underset{0}{\overset{T}{\int }}\underset{{ℝ}^d}{\int }{e}^{-\frac{1}{2}\left({\lambda }_{s,t}+\epsilon \right)|\xi {|}^2}\sum _{n=0}^{\infty }{i}^n{\sigma }^n\left(t,s,\xi \right)H_n\left(\frac{⟨\xi ,S_t^H-{\tilde{S}}_s^H⟩}{\sigma \left(t,s,\xi \right)}\right)\mathsf{\text{d}}\xi \mathsf{\text{d}}s\mathsf{\text{dt}}\\ \equiv \sum _{n=0}^{\infty }{F}_n.\end{array}$$

Thus, by (4.4) and Lemma 8, we have

$$\begin{array}{l}{\mathrm{\Phi }}_{{\mathrm{\Theta }}_{\epsilon }}(1)={\displaystyle \sum _{n=0}^{\infty }n}E(|F_n{|}^2)\\ ={\displaystyle \sum _{n=0}^{\infty }\frac{n}{{(2\pi )}^{2d}}}E[{\displaystyle \underset{{[0,T]}^4}{\int }{\displaystyle \underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}(({\lambda }_{s,t}+\epsilon )|\xi {|}^2+({\rho }_{u,v}+\epsilon )|\eta {|}^2)}{\sigma }^n(t,s,\xi ){\sigma }^n(u,v,\eta )}}\\ H_n\left(\frac{〈\xi ,S_t^H-{\tilde{S}}_s^H〉}{\sigma (t,s,\xi )}\right)H_n\left(\frac{〈\eta ,S_u^H-{\tilde{S}}_v^H〉}{\sigma (u,v,\eta )}\right)\text{d}\xi \text{d}\eta \text{d}u\text{d}v\text{d}s\text{d}t]\\ ={\displaystyle \sum _{n=1}^{\infty }\frac{1}{{(2\pi )}^{2d}(n-1)!}}{\displaystyle \underset{{[0,T]}^4}{\int }{\mu }_{s,t,u,v}^n}\text{d}u\text{d}v\text{d}s\text{d}t{\displaystyle \underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}(({\lambda }_{s,t}+\epsilon )|\xi {|}^2+({\rho }_{u,v}+\epsilon )|\eta {|}^2)}}{〈\xi ,\eta 〉}^n\text{d}\xi \text{d}\eta \\ ={\displaystyle \sum _{n=1}^{\infty }\frac{1}{{(2\pi )}^{2d}(2n-1)!}}{\displaystyle \underset{{[0,T]}^4}{\int }{\mu }_{s,t,u,v}^{2n}}\text{d}u\text{d}v\text{d}s\text{d}t{\displaystyle \underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}\left(({\lambda }_{s,t}+\epsilon )|\xi {|}^2+({\rho }_{u.v}+\epsilon )|\eta {|}^2\right)}}{〈\xi ,\eta 〉}^{2n}\text{d}\xi \text{d}\eta \\ ={\displaystyle \sum _{n=1}^{\infty }\frac{1}{{(2\pi )}^{2d}(2n-1)!}}{\displaystyle \underset{{[0,T]}^4}{\int }{\mu }_{s,t,u,v}^{2n}}\text{d}u\text{d}v\text{d}s\text{d}t\\ \times {\displaystyle \underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}(({\lambda }_{s,t}+\epsilon )({\xi }_1^2+\cdots +{\xi }_d^2)+({\rho }_{u,v}+\epsilon )({\eta }_1^2+\cdots +{\eta }_d^2)}{({\xi }_1{\eta }_1+\cdots +{\xi }_{\text{d}}{\eta }_d)}^{2n}\text{d}{\xi }_1\cdots \text{d}{\xi }_d\text{d}{\eta }_1\dots \text{d}{\eta }_d}\\ ={\displaystyle \sum _{n=1}^{\infty }\frac{1}{{(2\pi )}^{2d}(2n-1)!}}{\displaystyle \underset{{[0,T]}^4}{\int }{\mu }_{s,t,u,v}^{2n}}\text{d}u\text{d}v\text{d}s\text{d}t\times {\displaystyle \underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}\left(({\lambda }_{s,t}+\epsilon )({\xi }_1^2+\cdots +{\xi }_d^2)+({\rho }_{u,v}+\epsilon )({\eta }_1^2+\cdots +{\eta }_d^2)\right)}}\\ {\displaystyle \sum _{\begin{array}{l}{k}_1,\dots ,k_d=0\\ k_1+\cdots +k_d=n\end{array}}^n{({\xi }_1{\eta }_1)}^{2k_1}{({\xi }_2{\eta }_2)}^{2k_2}\dots {({\xi }_{\text{d}}{\eta }_d)}^{2k_d}\text{d}{\xi }_1\dots \text{d}{\xi }_d\text{d}{\eta }_1\dots \text{d}{\eta }_d}\\ =\frac{1}{{(2\pi )}^d}{\displaystyle \sum _{n=1}^{\infty }{\displaystyle \sum _{\begin{array}{l}{k}_1,\dots ,k_d=0\\ k_1+\cdots +k_d=n\end{array}}^n\frac{2n(2k_1-1)!!\cdot \cdot \cdot \cdot \cdot (2k_d-1)!!}{(2k_1)!!\cdot \cdot \cdot \cdot \cdot (2k_d)!!}{\displaystyle \underset{{[0,T]}^4}{\int }\frac{{\mu }_{s,t,u,v}^{2n}}{{(({\lambda }_{s,t}+\epsilon )({\rho }_{u,v}+\epsilon ))}^{n+\frac{d}{2}}}\text{d}u\text{d}v\text{d}s\text{d}t}}}\\ \asymp {\displaystyle \underset{{[0,T]}^4}{\int }{\mu }_{s,t,u,v}^2}{(({\lambda }_{s,t}+\epsilon )({\rho }_{u,v}+\epsilon )-{\mu }_{s,t,u,v}^2)}^{-\frac{d}{2}-1}\text{d}u\text{d}v\text{d}s\text{d}t,\end{array}$$

where we have used the following fact:

$$\begin{array}{c}\underset{ℝ}{\int }{\xi }^{2k}{e}^{-\frac{1}{2}\left({\lambda }_{s,t}+\epsilon \right){\xi }^2}\mathsf{\text{d}}\xi =2\underset{0}{\overset{\infty }{\int }}{\xi }^{2k}{e}^{-\frac{1}{2}\left({\lambda }_{s,t}+\epsilon \right){\xi }^2}\mathsf{\text{d}}\xi \\ =2^{k+\frac{1}{2}}\Gamma \left(k+\frac{1}{2}\right){\left({\lambda }_{s,t}+\epsilon \right)}^{-\left(k+\frac{1}{2}\right)}=\sqrt{2\pi }\left(2k-1\right)!!{\left({\lambda }_{s,t}+\epsilon \right)}^{-\left(k+\frac{1}{2}\right)}.\end{array}$$

It follows that

$$\underset{\epsilon \to 0}{lim}{\mathrm{\Phi }}_{{\mathrm{\Theta }}_{\epsilon }}\left(1\right)\asymp \underset{{\left[0,T\right]}^4}{\int }{\mu }_{s,t,u,v}^2{\left({\lambda }_{s,t}{\rho }_{u,v}-{\mu }_{s,t,u,v}^2\right)}^{-\frac{d}{2}}\mathsf{\text{d}}u\mathsf{\text{d}}v\mathsf{\text{d}}s\mathsf{\text{d}}t$$

for all T ≥ 0. This completes the proof.    □

5. Regularity of the intersection local time

The main object of this section is to prove the next theorem.

Theorem 9. Let Hd < 2. Then, the intersection local time ℓ _t admits the following estimate:

$$E\left(|{\ell }_t-{\ell }_s{|}^2\right)\le C{t}^{2-Hd}|t-s{|}^{2-Hd},$$

for a constant C > 0 depending only on H and d.

Proof. Let C > 0 be a constant depending only on H and d and its value may differ from line to line. For any 0 ≤ r, l, u, v ≤ T, denote

$${\sigma }^2=\mathsf{\text{Var}}\left[\xi \left(S_r^H-{\tilde{S}}_l^H\right)+\eta \left(S_u^H-{\tilde{S}}_v^H\right)\right].$$

Then, the property of strong local nondeterminism (see Yan et al. [24]):there exists a constant κ₀ > 0 such that (see Berman [33]) the inequality

$$\mathsf{\text{Var}}\left(\sum _{j=2}^n{u}_j\left(S_{t_j}^H-{\tilde{S}}_{t_{j-1}}^H\right)\right)\ge {\kappa }_0\sum _{j=2}^n{u}_j^2\mathsf{\text{Var}}\left(S_{t_j}^H-{\tilde{S}}_{t_{j-1}}^H\right).$$

(5.1)

holds for 0 ≤ t₁ < t₂ < · · · < t _n ≤ T and u _j ∈ ℝ, j = 2, 3,..., n. and (1.2) yield

$$\begin{array}{ll}\hfill {\sigma }^2& =\mathsf{\text{Var}}\left(\xi \left(S_r^H-S_u^H\right)-\xi \left({\tilde{S}}_l^H-{\tilde{S}}_v^H\right)+\left(\xi +\eta \right)\left(S_u^H-{\tilde{S}}_v^H\right)\right)\\ \ge C\left[{\xi }^2\left(|r-u{|}^{2H}+|l-v{|}^{2H}\right)+{\left(\xi +\eta \right)}^2\left(u^{2H}+v^{2H}\right)\right].\end{array}$$

It follows from (3.1) that for 0 ≤ s ≤ t ≤ T

$$\begin{array}{ll}\hfill E{\left|P_{\epsilon ,t}-{\ell }_{\epsilon ,s}\right|}^2& =\frac{1}{{\left(2\pi \right)}^{2d}}\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}r\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v\underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}\left({\sigma }^2+\epsilon |\xi {|}^2+\epsilon |\eta {|}^2\right)}\mathsf{\text{d}}\xi \mathsf{\text{d}}\eta \\ +\frac{4}{{\left(2\pi \right)}^{2d}}\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}r\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v\underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}\left({\sigma }^2+\epsilon |\xi {|}^2+\epsilon |\eta {|}^2\right)}\mathsf{\text{d}}\xi \mathsf{\text{d}}\eta \\ +\frac{4}{{\left(2\pi \right)}^{2d}}\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}r\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v\underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}\left({\sigma }^2+\epsilon |\xi {|}^2+\epsilon |\eta {|}^2\right)}\mathsf{\text{d}}\xi \mathsf{\text{d}}\eta \\ \equiv \frac{1}{{\left(2\pi \right)}^{2d}}\left[A_1\left(s,t\right)+4A_2\left(s,t\right)+4A_3\left(s,t\right)\right].\end{array}$$

We have

$$\begin{array}{ll}\hfill A_1\left(s,t\right)& =\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}r\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v\underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}\left({\sigma }^2+\epsilon |\xi {|}^2+\epsilon |\eta {|}^2\right)}\mathsf{\text{d}}\xi \mathsf{\text{d}}\eta \\ \le C\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}r\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v{\left[\left(|r-u{|}^{2H}+|l-v{|}^{2H}\right)\left(u^{2H}+v^{2H}\right)\right]}^{-\frac{d}{2}}\\ \le C\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}|r-u{|}^{-\frac{Hd}{2}}|l-v{|}^{-\frac{Hd}{2}}{u}^{-\frac{Hd}{2}}{v}^{-\frac{Hd}{2}}\mathsf{\text{d}}r\mathsf{\text{d}}l\mathsf{\text{d}}u\mathsf{\text{d}}v\\ =C{\left(\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}|r-u{|}^{-\frac{Hd}{2}}{u}^{-\frac{Hd}{2}}\mathsf{\text{d}}rdu\right)}^2\le 4C{\left(\underset{s}{\overset{t}{\int }}\underset{s}{\overset{r}{\int }}{\left(r-u\right)}^{-\frac{Hd}{2}}{u}^{-\frac{Hd}{2}}du\mathsf{\text{d}}r\right)}^2,\end{array}$$

for 0 ≤ s ≤ t ≤ T. Noting that

$$\underset{\alpha }{\overset{1}{\int }}{\left(1-m\right)}^{x-1}{m}^{x-1}dm\le {\beta }_x{\left(1-\alpha \right)}^x,$$

for all α ∈ [0,1] and x > 0, where β _x is a constant depending only on x, we get

$$\begin{array}{ll}\hfill \underset{s}{\overset{t}{\int }}\underset{s}{\overset{r}{\int }}{\left(r-u\right)}^{-\frac{Hd}{2}}{u}^{-\frac{Hd}{2}}du\mathsf{\text{d}}r& =\underset{s}{\overset{t}{\int }}{r}^{1-Hd}\mathsf{\text{d}}r\underset{s/r}{\overset{1}{\int }}{\left(1-m\right)}^{-\frac{Hd}{2}}{m}^{-\frac{Hd}{2}}\mathsf{\text{d}}m\\ \le C{\left(t-s\right)}^{2-dH},\end{array}$$

which yields

$$A_1\left(s,t\right)\le C{\left(t-s\right)}^{4-2dH},$$

for 0 ≤ s ≤ t ≤ T. Similarly, for A₂(s, t) and A₃(s, t) we have also

$$\begin{array}{ll}\hfill A_2\left(s,t\right)& =\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}r\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v\underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}\left({\sigma }^2+\epsilon |\xi {|}^2+\epsilon |\eta {|}^2\right)}\mathsf{\text{d}}\xi \mathsf{\text{d}}\eta \\ \le C\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}r\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v{\left[\left(|r-u{|}^{2H}+|l-v{|}^{2H}\right)\left(u^{2H}+v^{2H}\right)\right]}^{-\frac{d}{2}}\\ =C\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}|r-u{|}^{-\frac{Hd}{2}}{u}^{-\frac{Hd}{2}}\mathsf{\text{d}}rdu\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}l\underset{0}{\overset{s}{\int }}|l-v{|}^{-\frac{Hd}{2}}{v}^{-\frac{Hd}{2}}dv\\ \le C{t}^{2-Hd}{\left(t-s\right)}^{2-Hd},\end{array}$$

$$\begin{array}{ll}\hfill A_3\left(s,t\right)& =\underset{s}{\overset{t}{\int }}\mathsf{\text{d}}r\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v\underset{{ℝ}^{2d}}{\int }{e}^{-\frac{1}{2}\left({\sigma }^2+\epsilon |\xi {|}^2+\epsilon |\eta {|}^2\right)}\mathsf{\text{d}}\xi \mathsf{\text{d}}\eta \\ \le C\underset{s}{\overset{t}{\int }}\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}r\mathsf{\text{d}}l\underset{s}{\overset{t}{\int }}\underset{0}{\overset{s}{\int }}\mathsf{\text{d}}u\mathsf{\text{d}}v{\left[\left(|r-u{|}^{2H}+|l-v{|}^{2H}\right)\left(u^{2H}+v^{2H}\right)\right]}^{-\frac{d}{2}}\\ =C\underset{s}{\overset{t}{\int }}\underset{s}{\overset{t}{\int }}|r-u{|}^{-\frac{Hd}{2}}{u}^{-\frac{Hd}{2}}\mathsf{\text{d}}rdu\underset{0}{\overset{s}{\int }}\underset{0}{\overset{s}{\int }}|l-v{|}^{-\frac{Hd}{2}}{v}^{-\frac{Hd}{2}}\mathsf{\text{d}}ldv\\ \le C{t}^{2-Hd}{\left(t-s\right)}^{2-Hd},\end{array}$$

for 0 ≤ s ≤ t ≤ T. Thus, Theorem 2 and Fatou's lemma yield

$$E\left(|{\ell }_t-{\ell }_s{|}^2\right)=E\left(\underset{\epsilon \to 0}{lim}|{\ell }_{\epsilon ,t}-{\ell }_{\epsilon ,s}{|}^2\right)\le \underset{\epsilon \to 0}{liminf}E\left(|{\ell }_{\epsilon ,t}-{\ell }_{\epsilon ,s}{|}^2\right)\le C{t}^{2-Hd}{\left(t-s\right)}^{2-Hd}.$$

This completes the proof.    □