ABSTRACT

This paper investigates the numerical solution of two-dimensional nonlinear stochastic Itô-Volterra integral equations based on block pulse functions. The nonlinear stochastic integral equation is transformed into a set of algebraic equations by operational matrix of block pulse functions. Then, we give error analysis and prove that the rate of convergence of this method is efficient. Lastly, a numerical example is given to confirm the method.

Keywords:

Block Pulse Functions, Integration Operational Matrix, Stochastic Itô-Volterra Integral Equations

1. Introduction

Two-dimensional stochastic Itô-Volterra integral equations arise from many phenomena in physics and engineering fields [1] . Some different orthogonal basis functions, polynomials and wavelets are used to approximate the solution of two-dimensional Volterra integral equations. For example, block pulse functions, triangular functions, modification of hat functions, Legender polynomials and Haar wavelet and the like (see [2] [3] [4] [5] [6] ).

Especially, Fallahpour et al. [3] introduced the following two-dimensional linear stochastic Volterra integral equation by Haar wavelet

$\begin{array}{c}x\left(t_1,t_2\right)=f\left(t_1,t_2\right)+{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}\tilde{k}\left(t_1,t_2,s_1,s_2\right)x\left(s_1,s_2\right)\text{d}{s}_1\text{d}{s}_2\\ +{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}\hat{k}\left(t_1,t_2,s_1,s_2\right)x\left(s_1,s_2\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right),\end{array}$ (1)

where $x\left(t_1\mathrm{,}{t}_2\right)$ is unknown and called the solution of the Equation (1), $\tilde{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)$ , $\hat{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)$ and $f\left(t_1\mathrm{,}{t}_2\right)$ are known functions $\left(t_1\mathrm{,}{t}_2\right)\in \left[\mathrm{0,}{T}_1\right)\times \left[\mathrm{0,}{T}_2\right)$ , $s_1\le t_1\mathrm{,}{s}_2\le t_2$ . $B\left(s_1\right)$ and $B\left(s_2\right)$ are two independent Brownian motions and ${\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}\hat{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)x\left(s_1\mathrm{,}{s}_2\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right)$ is the double Itô integral. The authors transformed stochastic Volterra integral equations to algebra equations by Haar wavelet and gave the numerical solutions to the equations. Similarly, Fallahpour et al. [7] obtained a numerical method for two-dimensional linear stochastic Volterra integral equations by block pulse functions.

For nonlinear determinate Volterra integral equations, Maleknejad et al. [8] and Nemati et al. [6] used two-dimensional block pulse functions and Legendre polynomials to solve those respectively. Both Babolian et al. [2] and Maleknejad et al. [9] employed triangular functions to get the numerical solutions. Mirzaee et al. [5] [10] applied modified two-dimensional block pulse functions to approximate the following determinate equation

$f\left(t_1,t_2\right)={\displaystyle {\int }_0^{t_1}}{\displaystyle {\int }_0^{t_2}}\tilde{k}\left(t_1,t_2,s_1,s_2\right){\left[x\left(s_1,s_2\right)\right]}^n\text{d}{s}_2\text{d}{s}_1,\left(t_1,t_2\right)\in \left[0,T_1\right)\times \left[0,T_2\right),$ (2)

where nonlinear term ${\left[x\left(s_1\mathrm{,}{s}_2\right)\right]}^n$ is power function and $x\left(s_1\mathrm{,}{s}_2\right)$ is unknown, n is a positive integer. $\tilde{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)$ is determinate kernel function $0\le s_1\le t_1\le T_1\mathrm{,0}\le s_2\le t_2\le T_2$ . The authors revealed the accuracy and efficiency of the proposed method by some examples and gave the rate of convergence to the numerical solution.

However, as far as we known, there are hardly any papers about the numerical solution of two-dimensional nonlinear stochastic Itô-Volterra integral equations. Inspired by the above literatures, we introduce an efficient numerical method for the following nonlinear stochastic integral equation based on block pulse functions.

$\begin{array}{c}x\left(t_1,t_2\right)=x_0\left(t_1,t_2\right)+{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}\tilde{k}\left(t_1,t_2,s_1,s_2\right)\sigma \left(x\left(s_1,s_2\right)\right)\text{d}{s}_1\text{d}{s}_2\\ +{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}\hat{k}\left(t_1,t_2,s_1,s_2\right)g\left(x\left(s_1,s_2\right)\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right),\end{array}$ (3)

where $x\left(t_1\mathrm{,}{t}_2\right)$ is unknown function and is called the solution of the Equation (3) defined on district $D=\left[0,1\right)\times \left[0,1\right)$ . $x_0\left(t_1\mathrm{,}{t}_2\right)$ is known determinate function. $\tilde{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)$ and $\hat{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)$ are determinate kernel functions. ${\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}\hat{k}\left(t_1,t_2,s_1,s_2\right)g\left(x\left(s_1,s_2\right)\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right)$ is the double Itô integral. $B\left(s_1\right)$ and $B\left(s_2\right)$ are two independent Brownian motions. $\sigma$ and g are analytical functions.

In Section 2, we recall the definition and properties of block pulse function. In Section 3 and 4, we show the integration operational matrix about two-dimensional block pulse functions. In Section 5, an efficient numerical method to nonlinear stochastic Itô-Volterra integral equation is obtained. In Section 6, the error and the rate of convergence of this method are given. It’s important to emphasize that the error is analyzed by Gronwall’s inequality and the interchangeability of integral and expectation. However, the norm was used in the literature [11] , it is a pity that the interchangeability of norm and integral wasn’t proved. In Section 7, we give a numerical example to illustrate the validity of the method. In the final Section 8, we make some conclusions and look ahead to further work.

2. Two-Dimensional Block Pulse Functions

One dimensional block pulse functions (BPFs) have been widely studied and applied to solve different problems. For example, the article [12] and their relative references give a detailed description. A $m_1{m}_2$ -set of two-dimensional block pulse functions (2D-BPFs) ${\varphi }_{a_1\mathrm{,}{a}_2}\left(t_1\mathrm{,}{t}_2\right)$ in the region of $D=\left[0,1\right)\times \left[0,1\right)$ are defined as:

${\varphi }_{a_1\mathrm{,}{a}_2}\left(t_1\mathrm{,}{t}_2\right)=\{\begin{array}{l}1\left(a_1-1\right)h_1\le t_1<a_1{h}_1,\left(a_2-1\right)h_2\le t_2<a_2{h}_2\\ 0\text{otherwise}\mathrm{,}\end{array}$

where $a_i=1,2,\cdots ,m_i$ , $h_i=\frac{1}{m_i}$ , $m_i=2^n$ , $m_i$ and n are arbitrary positive integers and $i=1,2$ .

Similar to the one-dimensional case [12] . There are some elementary properties for 2D-BPFs as follows:

1) Disjointness:

${\varphi }_{a_1,a_2}\left(t_1,t_2\right){\varphi }_{b_1,b_2}\left(t_1,t_2\right)=\{\begin{array}{l}{\varphi }_{a_1,a_2}\left(t_1,t_2\right)\text{if}{a}_1=b_1,a_2=b_2\\ 0\text{otherwise},\end{array}$ (4)

where $a_i,b_i=1,2,\cdots ,m_i$ , $i=1,2$ .

2) Orthogonality:

${\displaystyle {\int }_0^1}{\displaystyle {\int }_0^1}{\varphi }_{a_1,a_2}\left(t_1,t_2\right){\varphi }_{b_1,b_2}\left(t_1,t_2\right)\text{d}{t}_1\text{d}{t}_2=\{\begin{array}{l}{h}_1{h}_2\text{if}{a}_1=b_1,a_2=b_2\\ 0\text{otherwise}.\end{array}$ (5)

3) Completeness: for every $f\in \left(L^2\left(D\right)\right)$ , when $m_1$ and $m_2$ approach to the infinity, Parseval’s identity holds:

${\displaystyle {\int }_0^1}{\displaystyle {\int }_0^1}{f}^2\left(t_1,t_2\right)\text{d}{t}_1\text{d}{t}_2={\displaystyle \underset{a_1=1}{\overset{\infty }{\sum }}}{\displaystyle \underset{a_2=1}{\overset{\infty }{\sum }}}{f}_{a_1,a_2}^2{\Vert {\varphi }_{a_1,a_2}\left(t_1,t_2\right)\Vert }^2,$ (6)

where

$f_{a_1,a_2}=\frac{1}{h_1{h}_2}{\displaystyle {\int }_0^1}{\displaystyle {\int }_0^1}f\left(t_1,t_2\right){\varphi }_{a_1,a_2}\left(t_1,t_2\right)\text{d}{t}_1\text{d}{t}_2.$

The set of 2D-BPFs may be written as a vector $\Phi \left(t_1\mathrm{,}{t}_2\right)$ of dimension $\left(m_1{m}_2\right)$ :

${\Phi }_{m_1{m}_2}\left(t_1,t_2\right)={\left({\varphi }_{1,1}\left(t_1,t_2\right),\cdots ,{\varphi }_{1,m_2}\left(t_1,t_2\right),\cdots ,{\varphi }_{m_1,1}\left(t_1,t_2\right),\cdots ,{\varphi }_{m_1,m_2}\left(t_1,t_2\right)\right)}^{\text{T}},$ (7)

where $\left(t_1\mathrm{,}{t}_2\right)\in D$ .

From the above representation and disjointness property, it follows that:

${\Phi }_{m_1{m}_2}\left(t_1,t_2\right){\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1,t_2\right)={\left(\begin{array}{cccc}\text{}\text{}\text{}{\varphi }_{1,1}\left(t_1,t_2\right)\text{}\text{}\text{}& \text{}\text{}\text{}0\text{}\text{}\text{}& \text{}\text{}\text{}\cdots \text{}\text{}\text{}& \text{}\text{}\text{}0\text{}\text{}\text{}\\ \text{}\text{}\text{}0\text{}\text{}\text{}& \text{}\text{}\text{}{\varphi }_{1,2}\left(t_1,t_2\right)\text{}\text{}\text{}& \text{}\text{}\text{}\cdots \text{}\text{}\text{}& \text{}\text{}\text{}0\text{}\text{}\text{}\\ \text{}\text{}\text{}⋮\text{}\text{}\text{}& \text{}\text{}\text{}⋮\text{}\text{}\text{}& \text{}\text{}\text{}\ddots \text{}\text{}\text{}& \text{}\text{}\text{}⋮\text{}\text{}\text{}\\ \text{}\text{}\text{}0\text{}\text{}\text{}& \text{}\text{}\text{}0\text{}\text{}\text{}& \text{}\text{}\text{}\cdots \text{}\text{}\text{}& \text{}\text{}\text{}{\varphi }_{m_1,m_2}\left(t_1,t_2\right)\text{}\text{}\text{}\end{array}\right)}_{m_1{m}_2\times m_1{m}_2},$ (8)

${\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1,t_2\right){\Phi }_{m_1{m}_2}\left(t_1,t_2\right)=1,$

${\Phi }_{m_1{m}_2}\left(t_1,t_2\right){\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1,t_2\right)G=\tilde{G}{\Phi }_{m_1{m}_2}\left(t_1,t_2\right),$ (9)

where G is a $\left(m_1{m}_2\right)$ -vector and the matrix $\tilde{G}=diag\left(G\right)$ . Moreover, it is easy to conclude that for every $\left(m_1{m}_2\right)\times \left(m_1{m}_2\right)$ matrix $A$

${\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)A{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)={\hat{A}}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\mathrm{,}$ (10)

where $\hat{A}$ is a $\left(m_1{m}_2\right)$ -vector with elements equal to the diagonal entries of matrix $A$ .

Any function $x\left(t_1\mathrm{,}{t}_2\right)$ which is square integrable in the interval D can be expanded in terms of BPFs as

$x\left(t_1\mathrm{,}{t}_2\right)\simeq x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)={\displaystyle \underset{a_1=1}{\overset{m_1}{\sum }}}{\displaystyle \underset{a_2=1}{\overset{m_2}{\sum }}}{x}_{a_1\mathrm{,}{a}_2}{\varphi }_{a_1\mathrm{,}{a}_2}\left(t_1\mathrm{,}{t}_2\right)=X_{m_1{m}_2}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t\right)\mathrm{,}$ (11)

where $x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)$ is $m_1{m}_2$ approximations of 2D-BPFs of $x\left(t_1\mathrm{,}{t}_2\right)$ , $x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)$ is a coefficient $\left(m_1{m}_2\right)$ -vector, i.e.

$X_{m_1{m}_2}={\left(x_{1,1},\cdots ,x_{1,m_2},\cdots ,x_{m_1,1},\cdots ,x_{m_1,m_2}\right)}^{\text{T}},$ (12)

where the block pulse coefficients $x_{a_1\mathrm{,}{a}_2}$ are obtained as

$x_{a_1,a_2}=\frac{1}{h_1{h}_2}{\displaystyle {\int }_{\left(a_2-1\right)h_2}^{a_2{h}_2}}{\displaystyle {\int }_{\left(a_1-1\right)h_1}^{a_1{h}_1}}x\left(t_1,t_2\right)\text{d}{t}_1\text{d}{t}_2.$

Similarly, a function of four variables $k\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)$ on $L^2\left(D\times D\right)$ may be approximated with respect to 2D-BPFs such as

$k\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)\simeq {\Phi }_{m_1{m}_2}{\left(t_1\mathrm{,}{t}_2\right)}^{\text{T}}K{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\mathrm{,}$

where ${\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)$ is a 2D-BPFs vector of dimension $\left(m_1{m}_2\right)$ , $K$ is the $\left(m_1{m}_2\right)\times \left(m_1{m}_2\right)$ two-dimensional block pulse coefficient matrix in the following form

$K={\left(K_{a_1{b}_1}\right)}_{m_1\times m_1}\mathrm{,}{K}_{a_1{b}_1}={\left(k_{a_1{a}_2{b}_1{b}_2}\right)}_{m_2\times m_2}\mathrm{,}$

$a_i,b_i=1,\cdots ,m_i,i=1,2$ and two-dimensional block pulse coefficients $k_{a_1{a}_2{b}_1{b}_2}$ are given by

$k_{a_1{a}_2{b}_1{b}_2}=\frac{1}{h_1^2{h}_2^2}\left[{\displaystyle {\int }_0^1}{\displaystyle {\int }_0^1}{\displaystyle {\int }_0^1}{\displaystyle {\int }_0^1}k\left(t_1,t_2,s_1,s_2\right){\varphi }_{b_1,b_2}\left(t_1,t_2\right){\varphi }_{a_1,a_2}\left(s_1,s_2\right)\text{d}{t}_1\text{d}{t}_2\text{d}{s}_1\text{d}{s}_2\right].$ (13)

The more details can also reference to [7] .

3. Operational Matrix of Integration

Let $M={\left({\xi }_{ij}\right)}_{M_1\times M_2}$ and $N={\left({\eta }_{ij}\right)}_{N_1\times N_2}$ be matrices. $M_l\mathrm{,}{N}_l$ are positive

integers, $l=1,2$ . We have

$M\otimes N=\left({\xi }_{ij}N\right)={\left(\begin{array}{cccc}{\xi }_{11}N& {\xi }_{12}N& \cdots & {\xi }_{1M_2}N\\ {\xi }_{21}N& {\xi }_{22}N& \cdots & {\xi }_{2M_2}N\\ ⋮& ⋮& \ddots & ⋮\\ {\xi }_{M_{1}1}N& {\xi }_{M_{1}2}N& \cdots & {\xi }_{M_1{M}_2}N\end{array}\right)}_{M_1{N}_1\times M_2{N}_2}\mathrm{,}$

where $\otimes$ denotes the Kronecker product defined as [13] . Each ${\xi }_{ij}N$ is a block of size $N_1\times N_2$ , $M\otimes N$ is of size $M_1{N}_1\times M_2{N}_2$ .

Then the vector ${\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)$ can be showed as following

$\begin{array}{l}{\Phi }_{m_1{m}_2}\left(t_1,t_2\right)\\ ={\Phi }_{m_1}\left(t_1\right)\otimes {\Phi }_{m_2}\left(t_2\right)\\ ={\left({\varphi }_1\left(t_1\right),{\varphi }_2\left(t_1\right),\cdots ,{\varphi }_{m_1}\left(t_1\right)\right)}^{\text{T}}\otimes {\left({\varphi }_1\left(t_2\right),{\varphi }_2\left(t_2\right),\cdots ,{\varphi }_{m_2}\left(t_2\right)\right)}^{\text{T}}\\ ={\left({\varphi }_1\left(t_1\right){\varphi }_1\left(t_2\right),\cdots ,{\varphi }_1\left(t_1\right){\varphi }_{m_2}\left(t_2\right),\cdots ,{\varphi }_{m_1}\left(t_1\right){\varphi }_1\left(t_2\right),\cdots ,{\varphi }_{m_1}\left(t_1\right){\varphi }_{m_2}\left(t_2\right)\right)}^{\text{T}}\end{array}$

where ${\varphi }_{a_i}\left(t_i\right)$ are one dimensional BPFs, ${\Phi }_{m_i}\left(t_i\right)$ are vectors of one dimensional BPFs, $a_i=1,2,\cdots ,m_i,i=1,2$ .

The integration of the vector ${\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)$ defined in (7) can be approximately obtained as following

$\begin{array}{c}{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\text{d}{s}_1\text{d}{s}_2={\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1}\left(s_1\right)\otimes {\Phi }_{m_2}\left(s_2\right)\text{d}{s}_1\text{d}{s}_2\\ ={\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1}\left(s_1\right)\text{d}{s}_1\otimes {\displaystyle {\int }_0^{t_2}}{\Phi }_{m_2}\left(s_2\right)\text{d}{s}_2\\ \simeq P_1{\Phi }_{m_1}\left(t_1\right)\otimes P_2{\Phi }_{m_2}\left(t_2\right)\\ ={\left(P_1\otimes P\right)}_2{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\\ =P{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\mathrm{,}\end{array}$ (14)

where $t_1\in \left[\mathrm{0,1}\right)\mathrm{,}{t}_2\in \left[\mathrm{0,1}\right)$ , $P$ is the $\left(m_1{m}_2\right)\times \left(m_1{m}_2\right)$ operational matrix of integration for 2D-BPFs and $P_i$ , $\left(i=1,2\right)$ are the operational matrix of one-dimensional BPFs [12] defined over $\left[\mathrm{0,1}\right)$ as following.

$P_i=\frac{h}{2}{\left(\begin{array}{ccccc}1& 2& 2& \cdots & 2\\ 0& 1& 2& \cdots & 2\\ 0& 0& 1& \cdots & 2\\ ⋮& ⋮& ⋮& \ddots & ⋮\\ 0& 0& 0& \cdots & 1\end{array}\right)}_{\left(m_i\times m_i\right)}\mathrm{.}$

For details, see [7] , so

$\begin{array}{c}{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}x\left(s_1\mathrm{,}{s}_2\right)\text{d}{s}_1\text{d}{s}_2\simeq {\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{X}_{m_1{m}_2}^T{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\text{d}{s}_1\text{d}{s}_2\\ =X_{m_1{m}_2}^{T}P{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\mathrm{.}\end{array}$ (15)

4. Stochastic Integration Operational Matrix

Similarly, we obtain the stochastic integration of the vector ${\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)$ defined in (7) as following

$\begin{array}{l}{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right)\\ ={\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1}\left(s_1\right)\otimes {\Phi }_{m_2}\left(s_2\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right)\\ ={\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1}\left(s_1\right)\text{d}B\left(s_1\right)\otimes {\displaystyle {\int }_0^{t_2}}{\Phi }_{m_2}\left(s_2\right)\text{d}B\left(s_2\right)\\ \simeq P_{s_1}{\Phi }_{m_1}\left(t_1\right)\otimes P_{s_2}{\Phi }_{m_2}\left(t_2\right)\\ =\left(P_{s_1}\otimes P_{s_2}\right){\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)=P_s{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\mathrm{,}\end{array}$ (16)

where $t_1\in \left[\mathrm{0,1}\right)\mathrm{,}{t}_2\in \left[\mathrm{0,1}\right)$ , $P_s$ is the $\left(m_1{m}_2\right)\times \left(m_1{m}_2\right)$ stochastic operational matrix of integration for 2D-BPFs and $P_{s_i}$ , $\left(i=1,2\right)$ are the stochastic operational matrix of one-dimensional BPFs [12] defined over $\left[\mathrm{0,1}\right)$ as following.

$P_{s_i}={\left(\begin{array}{ccccc}B\left(\frac{h_i}{2}\right)\text{}\text{}\text{}& B\left(h_i\right)\text{}\text{}& B\left(h_i\right)\text{}\text{}& \cdots & B\left(h_i\right)\text{}\text{}\\ 0& B\left(\frac{3h_i}{2}\right)-B\left(h_i\right)\text{}\text{}& B\left(2h_i\right)-B\left(h_i\right)\text{}\text{}& \cdots & B\left(2h_i\right)-B\left(h_i\right)\text{}\text{}\\ 0& 0& B\left(\frac{5h_i}{2}\right)-B\left(5h_i\right)\text{}\text{}& \cdots & B\left(3h_i\right)-B\left(2h_i\right)\text{}\text{}\\ ⋮& ⋮& ⋮& \ddots & ⋮\\ 0& 0& 0& \cdots & B\left(\frac{\left(2m_i-1\right)h_i}{2}\right)-B\left(\left(m_i-1\right)h_i\right)\end{array}\right)}_{m_i\times m_i}\mathrm{.}$ (17)

For details, see [7] . Therefore,

$\begin{array}{c}{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}x\left(s_1\mathrm{,}{s}_2\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right)\simeq {\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{X}_{m_1{m}_2}^{\text{T}}{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right)\\ =X_{m_1{m}_2}^{\text{T}}{P}_s{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\mathrm{.}\end{array}$ (18)

5. Numerical Method

In this section, we first provide a useful result for solving two-dimensional nonlinear stochastic Itô-Volterra integral Equation (3).

Lemma 1. Let $\sigma \left(t\right)={\displaystyle \sum }{a}_j{t}^j$ , $g\left(t\right)={\displaystyle \sum }{b}_j{t}^j$ be the analytic functions for positive integer $j\in \left(\mathrm{0,}\infty \right)$ , then

$\sigma \left(x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\right)={\sigma }^{\text{T}}\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right),$

$g\left(x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\right)=g^{\text{T}}\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right),$

where ${\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)$ and $X_{m_1{m}_2}$ are derived in (7) and (12),

${\sigma }^{\text{T}}\left(X_{m_1{m}_2}\right)=\left(\sigma \left(x_{1,1}\right),\cdots ,\sigma \left(x_{1,m_2}\right),\cdots ,\sigma \left(x_{m_1,1}\right),\cdots ,\sigma \left(x_{m_1,m_2}\right)\right),$

$g^{\text{T}}\left(X_{m_1{m}_2}\right)=\left(g\left(x_{1,1}\right),\cdots ,g\left(x_{1,m_2}\right),\cdots ,g\left(x_{m_1,1}\right),\cdots ,g\left(x_{m_1,m_2}\right)\right).$

Proof. By virtue of the known conditions and the disjointness properties of 2D-BPFs defined in (4), we can get

$\begin{array}{l}\sigma \left(x_{m_1{m}_2}\left(t_1,t_2\right)\right)={\displaystyle \sum }{a}_j{\left(x_{m_1{m}_2}\left(t_1,t_2\right)\right)}^j={\displaystyle \sum }{a}_j{\left[{\displaystyle \underset{a_1=1}{\overset{m_1}{\sum }}}{\displaystyle \underset{a_2=1}{\overset{m_2}{\sum }}}{x}_{a_1,a_2}{\varphi }_{a_1,a_2}\left(t_1,t_2\right)\right]}^j\\ ={\displaystyle \sum }{a}_j[x_{1,1}{\varphi }_{1,1}\left(t_1,t_2\right)+\cdots +x_{1,m_2}{\varphi }_{1,m_2}\left(t_1,t_2\right)+\cdots +x_{m_1,1}{\varphi }_{m_1,1}\left(t_1,t_2\right)\\ +{\cdots +x_{m_1,m_2}{\varphi }_{m_1,m_2}\left(t_1,t_2\right)]}^j\\ ={\displaystyle \sum }{a}_j\left(x_{1,1}^j,\cdots ,x_{1,m_2}^j,\cdots ,x_{m_1,1}^j,\cdots ,x_{m_1,m_2}^j\right){\Phi }_{m_1{m}_2}\left(t_1,t_2\right)\\ ={\sigma }^{\text{T}}\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(t_1,t_2\right),\end{array}$

thus,

$\sigma \left(x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\right)={\sigma }^{\text{T}}\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)={\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)\sigma \left(X_{m_1{m}_2}\right)\mathrm{,}$ (19)

$g\left(x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\right)=g^{\text{T}}\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)={\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)g\left(X_{m_1{m}_2}\right)\mathrm{.}$ (20)

The proof is completed. □

Now we suppose $x\left(t_1\mathrm{,}{t}_2\right)$ , $x_0\left(t_1\mathrm{,}{t}_2\right)$ , $\sigma \left(x\left(t_1\mathrm{,}{t}_2\right)\right)$ , $g\left(x\left(t_1\mathrm{,}{t}_2\right)\right)$ , $\tilde{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)$ and $\hat{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)$ can be approximated in terms of 2D-BPFs.

$x\left(t_1\mathrm{,}{t}_2\right)\simeq x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)=X_{m_1{m}_2}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)={\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)X_{m_1{m}_2}\mathrm{,}$ (21)

$x_0\left(t_1\mathrm{,}{t}_2\right)\simeq x_{0_{m_1{m}_2}}\left(t_1\mathrm{,}{t}_2\right)=X_{0_{m_1{m}_2}}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)={\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)X_{0_{m_1{m}_2}}\mathrm{,}$ (22)

$\sigma \left(x\left(t_1\mathrm{,}{t}_2\right)\right)\simeq \sigma \left(x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\right)={\sigma }^{\text{T}}\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)={\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)\sigma \left(X_{m_1{m}_2}\right)\mathrm{,}$ (23)

$g\left(x\left(t_1\mathrm{,}{t}_2\right)\right)\simeq g\left(x_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\right)=g^{\text{T}}\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)={\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)g\left(X_{m_1{m}_2}\right)\mathrm{,}$ (24)

$\tilde{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)\simeq {\tilde{k}}_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)={\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_1{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\mathrm{,}$ (25)

$\hat{k}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)\simeq {\hat{k}}_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\mathrm{,}{s}_1\mathrm{,}{s}_2\right)={\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_2{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\mathrm{,}$ (26)

where $X_{m_1{m}_2}$ , $X_{0_{m_1{m}_2}}$ , $\sigma \left(X_{m_1{m}_2}\right)$ and $g\left(X_{m_1{m}_2}\right)$ are two-dimensional block

pulse coefficient vectors. $K_1$ and $K_2$ are two-dimensional block pulse coefficient matrices.

Now, by (21)-(26), we approximate the Equation (3)

$\begin{array}{l}{X}_{m_1{m}_2}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\\ =X_{0_{m_1{m}_2}}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\\ +{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_1{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right){\Phi }_{m_1{m}_2}^{\text{T}}\left(s_1\mathrm{,}{s}_2\right)\sigma \left(X_{m_1{m}_2}\right)\text{d}{s}_1\text{d}{s}_2\\ +{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_2{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right){\Phi }_{m_1{m}_2}^{\text{T}}\left(s_1\mathrm{,}{s}_2\right)g\left(X_{m_1{m}_2}\right)\text{d}B\left(s_1\right)\text{d}B(s2)\end{array}$

$\begin{array}{l}=X_{0_{m_1{m}_2}}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\\ +{\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_1{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right){\Phi }_{m_1{m}_2}^{\text{T}}\left(s_1\mathrm{,}{s}_2\right)\sigma \left(X_{m_1{m}_2}\right)\text{d}{s}_1\text{d}{s}_2\\ +{\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_2{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right){\Phi }_{m_1{m}_2}^{\text{T}}\left(s_1\mathrm{,}{s}_2\right)g\left(X_{m_1{m}_2}\right)\text{d}B\left(s_1\right)\text{d}B(s2)\end{array}$

$\begin{array}{l}=X_{0_{m_1{m}_2}}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\\ +{\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_1{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}\tilde{\sigma }\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\text{d}{s}_1\text{d}{s}_2\\ +{\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_2{\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}\tilde{g}\left(X_{m_1{m}_2}\right){\Phi }_{m_1{m}_2}\left(s_1\mathrm{,}{s}_2\right)\text{d}B\left(s_1\right)\text{d}B(s2)\end{array}$

$\begin{array}{l}=X_{0_{m_1{m}_2}}^{\text{T}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\\ +{\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_1\tilde{\sigma }\left(X_{m_1{m}_2}\right){\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\text{d}{s}_1\text{d}{s}_2\\ +{\Phi }_{m_1{m}_2}^{\text{T}}\left(t_1\mathrm{,}{t}_2\right)K_2\tilde{g}\left(X_{m_1{m}_2}\right){\displaystyle {\int }_0^{t_2}}{\displaystyle {\int }_0^{t_1}}{\Phi }_{m_1{m}_2}\left(t_1\mathrm{,}{t}_2\right)\text{d}B\left(s_1\right)\text{d}B\left(s_2\right)\mathrm{,}\end{array}$