2.1. Mittag–Leffler function

The three-parameter Mittag–Leffler function is defined as (see [Reference Kilbas, Srivastava and Trujillo20, p. 45])

\begin{equation*}E_{\alpha,\beta}^{\gamma}(x)\;:\!=\;\sum_{j=0}^{\infty} \dfrac{\gamma(\gamma+1)\cdots(\gamma+j-1)x^{j}}{j!\Gamma(j\alpha+\beta)},\quad x\in\mathbb{R},\end{equation*}

where $\alpha>0$ , $\beta>0$ , and $\gamma>0$ .

It reduces to the two-parameter Mittag–Leffler function for $\gamma=1$ . It further reduces to the Mittag–Leffler function for $\gamma=\beta=1$ .

For $n\ge0$ , we have (see [Reference Kilbas, Srivastava and Trujillo20, eq. (1.9.5)])

(2.1) \begin{equation}\bigl(E_{\alpha, \beta}^{\gamma}(x)\bigr)^{(n)}=\gamma(\gamma+1)\cdots(\gamma+n-1)E_{\alpha, n\alpha+\beta}^{\gamma+n}(x),\end{equation}

where $\bigl(E_{\alpha, \beta}^{\gamma}(x)\bigr)^{(n)}$ denotes the nth derivative of three-parameter Mittag–Leffler function, that is,

\[\bigl(E_{\alpha, \beta}^{\gamma}(x)\bigr)^{(n)}= \dfrac{{\mathrm{d}}^{n}}{{\mathrm{d}} x^{n}}E_{\alpha, \beta}^{\gamma}(x).\]

The following asymptotic result follows from equation (2.44) of [Reference Beghin3]:

(2.2) \begin{equation}E_{\alpha, \beta}^{\gamma}(\!-\!\lambda t^{\alpha})\sim\dfrac{\lambda^{-\gamma}t^{-\alpha \gamma}}{\Gamma(\beta-\alpha\gamma)},\quad t\to\infty,\end{equation}

where $\lambda>0$ and $\beta\neq\alpha\gamma$ .

The following result holds (see [Reference Haubold, Mathai and Saxena14, eq. (17.6)]):

(2.3) \begin{equation}\mathcal{L}^{-1}\biggl(\dfrac{s^{\rho-1}}{s^{\alpha}+as^{\beta}+b};\;t\biggr)=t^{\alpha-\rho}\sum_{m=0}^{\infty}(\!-\!a)^{m}t^{(\alpha-\beta)m}E_{\alpha,\alpha+(\alpha-\beta)m-\rho+1}^{m+1}(\!-\!bt^{\alpha}),\end{equation}

along with the conditions $\alpha>\beta>0$ , $\alpha-\rho+1>0$ , and $|as^{\beta}/(s^{\alpha}+b)|<1$ .

2.2. Z transform

The unilateral Z transform of a function f(k), $k\in\mathbb{N}_{0}$ , is defined by (see [Reference Debnath and Bhatta9, eq. (12.3.3)])

(2.4) \begin{equation}F(z)=Zf(k)=\sum_{k=0}^{\infty}f(k)z^{-k}, \quad z\in \mathbb{R}.\end{equation}

The following translation property holds (see [Reference Debnath and Bhatta9, eq. (12.4.1)]):

(2.5) \begin{equation}Zf(k-m)=z^{-m}\Biggl(F(z)+\sum_{r=-m}^{-1}f(r)z^{-r}\Biggr),\quad m\ge0.\end{equation}

Note that the coefficient of $z^{-k}$ in (2.4) is the inverse Z transform, i.e. $f(k)=Z^{-1}(F(z))$ . Let f(k) be a probability mass function (PMF) whose support is $\mathbb{N}_{0}$ . Then its PGF is given by

\begin{equation*}G(u)=\sum_{k=0}^{\infty}u^{k}f(k),\quad |u|\le 1.\end{equation*}

It is related to the unilateral Z transform as follows:

(2.6) \begin{equation}G(z^{-1})=F(z).\end{equation}

2.3. Inverse mixed stable subordinator

Let $f_{\alpha_{1},\alpha_{2}}(t,x)$ be the density function of the IMSS. Its Laplace transform is given by (see [Reference Aletti, Leonenko and Merzbach1])

(2.7) \begin{equation}\mathcal{L}(f_{\alpha_{1},\alpha_{2}}(t,x);s)=\dfrac{\phi(s)}{s}{\mathrm{e}}^{-x\phi(s)},\end{equation}

where $\phi(s)$ is given in (1.4).

The mean $U_{{\alpha_{1},\alpha_{2}}}(t)=\mathbb{E}(Y_{\alpha_{1},\alpha_{2}}(t))$ of the IMSS is given by (see [Reference Leonenko, Meerschaert, Schilling and Sikorskii22])

(2.8) \begin{equation}U_{{\alpha_{1},\alpha_{2}}}(t)=\dfrac{t^{\alpha_{1}}}{C_{1}} E_{\alpha_{1}-\alpha_{2}, \alpha_{1}+1}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1}),\end{equation}

where $E_{\alpha_{1}-\alpha_{2}, \alpha_{1}+1}(\!\cdot\!)$ is the two-parameter Mittag–Leffler function.

The following asymptotic result holds (see [Reference Veillette and Taqqu28, eq. (48)]):

(2.9) \begin{equation}U_{{\alpha_{1},\alpha_{2}}}(t) \sim \begin{cases}\dfrac{t^{\alpha_{1}}}{C_{1} \Gamma(\alpha_{1}+1)}, & t \rightarrow 0,\\[9pt] \dfrac{t^{\alpha_{2}}}{C_{2} \Gamma(\alpha_{2}+1)}, & t \rightarrow \infty.\end{cases}\end{equation}

For fixed $s>0$ and large t, the variance and covariance of the IMSS have the following limiting behaviour (see [Reference Kataria and Khandakar17, eqs (22) and (29)]):

\begin{equation*} \operatorname{Var}\!(Y_{\alpha_{1},\alpha_{2}}(t))\sim\dfrac{t^{2\alpha_{2}}}{C_{2}^{2}}\biggl(\dfrac{2}{\Gamma(2\alpha_{2}+1)}-\dfrac{1}{(\Gamma(\alpha_{2}+1))^{2}}\biggr)\end{equation*}

and

(2.10) \begin{equation}\operatorname{Cov}\!(Y_{\alpha_{1},\alpha_{2}}(s), Y_{\alpha_{1},\alpha_{2}}(t))\sim C_{1}^{-2}s^{2\alpha_{1}} E_{\alpha_{1}-\alpha_{2}, 2\alpha_{1}+1}^{2}(\!-\!C_{2}s^{\alpha_{1}-\alpha_{2}}/C_{1})-t^{\alpha_2-1}K(s),\end{equation}

where

(2.11) \begin{equation}K(s)=\dfrac{s^{\alpha_1+1}}{C_{1}C_{2}\Gamma(\alpha_{2})}\sum_{m=0}^{\infty}\dfrac{(m(\alpha_{1}-\alpha_{2})+\alpha_{1})(\!-\!C_{2}s^{\alpha_{1}-\alpha_{2}}/C_{1})^{m}}{\Gamma(m(\alpha_{1}-\alpha_{2})+\alpha_{1}+2)}.\end{equation}

2.4. The LRD and SRD properties

We will use the following definition (see [Reference D’Ovidio and Nane13], [Reference Maheshwari and Vellaisamy23]).

Definition 2.1. Let $s>0$ be fixed and let $\{X(t)\}_{t\ge0}$ be a stochastic process such that its correlation function has the following asymptotic behaviour:

\begin{equation*}\operatorname{Corr}(X(s),X(t))\sim c(s)t^{-\gamma},\quad \text{as $ t\to\infty$,}\end{equation*}

where the value of c(s) depends on s. The process $\{X(t)\}_{t\ge0}$ is said to exhibit the LRD property if $\gamma\in(0,1)$ and it has the SRD property if $\gamma\in (1,2)$ .

3.1. Some properties of the MFCP

Here we discuss some distributional properties of the MFCP. Let $0<s\le t<\infty$ and

\begin{equation*}q_{1}=\sum_{j=1}^{k}j\lambda_{j},\quad q_{2}=\sum_{j=1}^{k}j^{2}\lambda_{j}.\end{equation*}

The mean and variance of the GCP are given by (see [Reference Di Crescenzo, Martinucci and Meoli10])

(3.2) \begin{equation}\mathbb{E}(M(t))=tq_{1} \quad \text{and}\quad \operatorname{Var}\!(M(t))=tq_{2}.\end{equation}

The mean, variance, and covariance of the MFCP can be obtained using (3.2) and Theorem 2.1 of [Reference Leonenko, Meerschaert, Schilling and Sikorskii22] in the following form:

(3.3) \begin{align}\mathbb{E}(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))&=q_{1} U_{{\alpha_{1},\alpha_{2}}}(t),\end{align}

(3.4) \begin{align}\operatorname{Var}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))&=q_{2} U_{\alpha_{1},\alpha_{2}}(t)+q_{1}^{2}\operatorname {Var} (Y_{\alpha_{1}, \alpha_{2}}(t)),\end{align}

(3.5) \begin{align}\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s), \mathcal{M}_{\alpha_{1},\alpha_{2}}(t))&=q_{2} U_{\alpha_{1},\alpha_{2}}(s)+q_{1}^{2}\operatorname{Cov}\!(Y_{\alpha_{1},\alpha_{2}}(s), Y_{\alpha_{1},\alpha_{2}}(t)),\end{align}

where $U_{\alpha_{1},\alpha_{2}}(\!\cdot\!)$ is given in (2.8).

Remark 3.1. A stochastic process $\{X(t)\}_{t\ge0}$ is said to exhibit overdispersion if

\[ \operatorname{Var}\!(X(t))-\mathbb{E}(X(t))>0,\quad t>0. \]

Observe that

\begin{equation*}\operatorname{Var}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))- \mathbb{E}(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))=(q_{2}-q_{1}) U_{\alpha_{1},\alpha_{2}}(t)+q_{1}^{2}\operatorname {Var} (Y_{\alpha_{1}, \alpha_{2}}(t))>0,\quad t>0.\end{equation*}

Thus the MFCP exhibits overdispersion.

Proof. Let $s>0$ be fixed. From (3.4) and (3.5), we get

\begin{equation*}\operatorname{Corr}(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s), \mathcal{M}_{\alpha_{1},\alpha_{2}}(t))=\dfrac{q_{2} U_{\alpha_{1},\alpha_{2}}(s)+q_{1}^{2}\operatorname{Cov}\!(Y_{\alpha_{1},\alpha_{2}}(s), Y_{\alpha_{1},\alpha_{2}}(t))}{\sqrt{\operatorname{Var}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s))}\sqrt{q_{2} U_{\alpha_{1},\alpha_{2}}(t)+q_{1}^{2}\operatorname {Var} (Y_{\alpha_{1}, \alpha_{2}}(t))}},\end{equation*}

which on using (2.9)–(2.10) reduces to the following as $t\to\infty$ :

\begin{align*}&\operatorname{Corr}(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s), \mathcal{M}_{\alpha_{1},\alpha_{2}}(t))\\[5pt] &\quad \sim \dfrac{q_{2}U_{\alpha_{1},\alpha_{2}}(s)+q_{1}^{2}\bigl(C_{1}^{-2}s^{2\alpha_{1}}E_{\alpha_{1}-\alpha_{2}, 2\alpha_{1}+1}^{2}(\!-\!C_{2}s^{\alpha_{1}-\alpha_{2}}/C_{1})-t^{\alpha_2-1}K(s)\bigr)}{\sqrt{\operatorname{Var}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s))}\sqrt{\frac{q_{2}t^{\alpha_{2}}}{C_{2}\Gamma(\alpha_{2}+1)}+q_{1}^{2}\frac{t^{2\alpha_{2}}}{C_{2}^{2}}\bigl(\frac{2}{\Gamma(2\alpha_{2}+1)}-\frac{1}{(\Gamma(\alpha_{2}+1))^{2}}\bigr)}}\\[5pt] &\quad \sim c(s)t^{-\alpha_{2}},\end{align*}

where

\begin{equation*}c(s)=\dfrac{q_{2}U_{\alpha_{1},\alpha_{2}}(s)+q_{1}^{2}C_{1}^{-2}s^{2\alpha_{1}}E_{\alpha_{1}-\alpha_{2}, 2\alpha_{1}+1}^{2}(\!-\!C_{2}s^{\alpha_{1}-\alpha_{2}}/C_{1})}{\sqrt{\operatorname{Var}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s))}\sqrt{\frac{q_{1}^{2}}{C_{2}^{2}}\bigl(\frac{2}{\Gamma(2\alpha_{2}+1)}-\frac{1}{(\Gamma(\alpha_{2}+1))^{2}}\bigr)}}.\end{equation*}

As $0<\alpha_{2}<1$ , the MFCP exhibits the LRD property.

Let $\stackrel{d}{=}$ denote the equality in distribution. Di Crescenzo et al. [Reference Di Crescenzo, Martinucci and Meoli10] showed that the GCP is equal in distribution to a compound Poisson process, that is,

(3.6) \begin{equation}M(t)\overset{d}{=}\sum_{i=1}^{N(t)}X_{i},\quad t\ge0.\end{equation}

Here $\{N(t)\}_{t\ge0}$ is the Poisson process with intensity parameter $\Lambda$ which is independent of the sequence of i.i.d. random variables $\{X_{i}\}_{i\ge1}$ such that

\begin{equation*}\mathbb{P}\{X_{1}=j\}=\dfrac{\lambda_{j}}{\Lambda},\quad j=1,2,\ldots,k.\end{equation*}

From (3.1) and (3.6), we get

(3.7) \begin{equation}\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)\stackrel{d}{=}\sum_{i=1}^{N_{\alpha_{1},\alpha_{2}}(t)}X_{i},\end{equation}

where $\{N_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ is the MFPP. Thus the MFCP is equal in distribution to a compound MFPP studied in [Reference Kataria and Khandakar18].

In the next result, we obtain the PGF $G^{\alpha_{1},\alpha_{2}}(u,t)=\mathbb{E}(u^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)})$ of the MFCP.

Proposition 3.1. The PGF of the MFCP is given by

(3.8) \begin{align}G^{\alpha_{1},\alpha_{2}}(u,t)&=\sum_{m=0}^{\infty}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1})^{m}E^{m+1}_{\alpha_{1},(\alpha_{1}-\alpha_{2})m+1}\Biggl(\!-\!\dfrac{t^{\alpha_{1}}}{C_{1}}\sum_{j=1}^{k}(1-u^{j})\lambda_{j}\Biggr)\notag\\[5pt] &\quad -\sum_{m=0}^{\infty}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1})^{m+1}E^{m+1}_{\alpha_{1},(\alpha_{1}-\alpha_{2})(m+1)+1}\Biggl(\!-\!\dfrac{t^{\alpha_{1}}}{C_{1}}\sum_{j=1}^{k}(1-u^{j})\lambda_{j}\Biggr).\end{align}

Proof. We have

(3.9) \begin{equation}G_{X_{1}}(u)=E(u^{X_{1}})=\dfrac{1}{\Lambda}\sum_{j=1}^{k}\lambda_{j}u^{j}.\end{equation}

Using (3.7) and (3.9), the proof follows from the PGF of the MFPP (see [Reference Beghin3, eq. (2.28)]).

Let $p^{\alpha_{1},\alpha_{2}}(n,t)=\mathbb{P}\{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)=n\}$ , $n\ge 0$ be the PMF of the MFCP. On substituting $u=0$ in (3.8), we get

\begin{align*}p^{\alpha_{1},\alpha_{2}}(0,t)&=\sum_{m=0}^{\infty}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1})^{m}E^{m+1}_{\alpha_{1},(\alpha_{1}-\alpha_{2})m+1}(\!-\!\Lambda t^{\alpha_{1}}/C_{1})\\[5pt] &\quad -\sum_{m=0}^{\infty}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1})^{m+1}E^{m+1}_{\alpha_{1},(\alpha_{1}-\alpha_{2})(m+1)+1}(\!-\!\Lambda t^{\alpha_{1}}/C_{1}),\end{align*}

which reduces to the zero state probability of the MFPP for $k=1$ , i.e. $\Lambda=\lambda_{1}$ (see [Reference Beghin3, eq. (2.13)]).

Remark 3.3. On substituting $u=1$ in (3.8), we get

\begin{align*}G^{\alpha_{1},\alpha_{2}}(u,t)\big|_{u=1}&=\sum_{n=0}^{\infty}p^{\alpha_{1},\alpha_{2}}(n,t)\\[5pt] &=\sum_{m=0}^{\infty}\dfrac{(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1})^{m}}{\Gamma((\alpha_{1}-\alpha_{2})m+1)}-\sum_{m=0}^{\infty}\dfrac{(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1})^{m+1}}{\Gamma((\alpha_{1}-\alpha_{2})(m+1)+1)}\\[5pt] &=1.\end{align*}

Thus $p^{\alpha_{1},\alpha_{2}}(n,t)$ is indeed a PMF.

Next we use the Z transform technique to obtain the system of fractional differential equations that governs the state probabilities of the MFCP.

Proposition 3.2. For $n\ge0$ , the state probabilities of the MFCP satisfy

(3.10) \begin{equation}C_{1}\dfrac{{\mathrm{d}}^{\alpha_{1}}}{{\mathrm{d}} t^{\alpha_{1}}}p^{\alpha_{1},\alpha_{2}}(n,t)+C_{2}\dfrac{{\mathrm{d}}^{\alpha_{2}}}{{\mathrm{d}} t^{\alpha_{2}}}p^{\alpha_{1},\alpha_{2}}(n,t)=-\Lambda p^{\alpha_{1},\alpha_{2}}(n,t)+\sum_{j=1}^{\min\{n,k\}}\lambda_{j}p^{\alpha_{1},\alpha_{2}}(n-j,t),\end{equation}

with the initial conditions $p^{\alpha_{1},\alpha_{2}}(0,0)=1$ and $p^{\alpha_{1},\alpha_{2}}(n,0)=0$ , $n\ge1$ .

Using (3.10), it can be shown that the PGF of the MFCP solves the following fractional differential equation:

\begin{equation*}C_{1}\dfrac{{\mathrm{d}}^{\alpha_{1}}}{{\mathrm{d}} t^{\alpha_{1}}}G^{\alpha_{1},\alpha_{2}}(u,t)+C_{2}\dfrac{{\mathrm{d}}^{\alpha_{2}}}{{\mathrm{d}} t^{\alpha_{2}}}G^{\alpha_{1},\alpha_{2}}(u,t)=-\sum_{j=1}^{k}(1-u^{j})\lambda_{j}G^{\alpha_{1},\alpha_{2}}(u,t),\end{equation*}

with initial condition $G^{\alpha_{1},\alpha_{2}}(u,0)=1$ .

Theorem 3.2. Let

\begin{align*} \Omega(k,n)&=\{(x_{1},x_{2},\ldots,x_{k})\colon x_{1}+2x_{2}+\cdots+kx_{k}=n,\ {x_{j}}\in\mathbb{N}_0\},\\[5pt] z_{k}&=x_{1}+x_{2}+\cdots+x_{k}. \end{align*}

The state probabilities of the MFCP are given by

(3.11) \begin{equation}p^{\alpha_{1},\alpha_{2}}(n,t)=\sum_{\Omega(k,n)}\prod_{j=1}^{k}\dfrac{\lambda_{j}^{x_{j}}}{x_{j}!}\dfrac{z_{k}!}{C_{1}^{z_{k}+1}}\bigl(C_1f^{*(z_{k}+1)}(t)+C_2g^{*(z_{k}+1)}(t)\bigr),\quad n\ge0,\end{equation}

where $f^{*(z_{k}+1)}$ and $g^{*(z_{k}+1)}$ are $(z_{k}+1)$ -fold convolutions of

\begin{equation*}f(t)=t^{\frac{z_{k}(\alpha_{1}-1)}{z_{k}+1}}\sum_{m=0}^{\infty}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1} )^{m}E_{\alpha_{1},(\alpha_{1}-\alpha_{2})m+\frac{z_{k}\alpha_{1}+1}{z_{k}+1}}^{m+1}(\!-\!\Lambda t^{\alpha_{1}}/C_{1})\end{equation*}

and

\begin{equation*}g(t)=t^{\frac{z_{k}(\alpha_{1}-1)+\alpha_{1}-\alpha_{2}}{z_{k}+1}}\sum_{m=0}^{\infty}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1} )^{m}E_{\alpha_{1},(\alpha_{1}-\alpha_{2})m+\frac{z_{k}\alpha_{1}+\alpha_{1}-\alpha_{2}+1}{z_{k}+1}}^{m+1}(\!-\!\Lambda t^{\alpha_{1}}/C_{1}),\end{equation*}

respectively.

Remark 3.6. In view of (3.7), the PMF of the MFCP can be obtained as follows:

\begin{align*}p^{\alpha_{1},\alpha_{2}}(n,t)&=\sum_{r=0}^{n}\mathbb{P}\{X_{1}+X_{2}+\cdots+X_{r}=n\}\mathbb{P}\{N_{\alpha_{1},\alpha_{2}}(t)=r\}\\[5pt] &=\sum_{r=0}^{n}\sum_{\substack{x_{1}+x_{2}+\cdots+x_{k}=r\\ x_{1}+2x_{2}+\cdots+kx_{k}=n}}\dfrac{r!}{\Lambda^{r}}\prod_{j=1}^{k}\dfrac{\lambda_{j}^{x_{j}}}{x_{j}!}\mathbb{P}\{N_{\alpha_{1},\alpha_{2}}(t)=r\}\\[5pt] &=\sum_{\Omega(k,n)}\dfrac{z_{k}!}{\Lambda^{z_{k}}}\prod_{j=1}^{k}\dfrac{\lambda_{j}^{x_{j}}}{x_{j}!}\mathbb{P}\{N_{\alpha_{1},\alpha_{2}}(t)=z_{k}\},\end{align*}

where in the penultimate step we used the explicit expression for the PMF of $X_{1}+X_{2}+\cdots+X_{r}$ (see [Reference Di Crescenzo, Martinucci and Meoli10, p. 297]). The result follows on using the PMF of the MFPP (see [Reference Kataria and Khandakar18, eq. (3.1)]).

The rth factorial moment

\[\psi^{\alpha_{1},\alpha_{2}}(r,t)=\mathbb{E}(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)-1)\cdots (\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)-r+1)),\quad r\ge1,\]

of the MFCP can be obtained using its PGF as follows.

Proposition 3.3. For $r\ge1$ , the rth factorial moment of the MFCP is given by

\begin{align*} &\psi^{\alpha_{1},\alpha_{2}}(r,t)\\[5pt] &\quad =\sum_{m=0}^{\infty}\sum_{n=1}^{r}\dfrac{f_{m,n}(r,t)}{\Gamma(n\alpha_{1}+(\alpha_{1}-\alpha_{2})m+1)} +\dfrac{C_{2}}{C_{1}}t^{\alpha_{1}-\alpha_{2}}\sum_{m=0}^{\infty}\sum_{n=1}^{r}\dfrac{f_{m,n}(r,t)}{\Gamma(n\alpha_{1}+(\alpha_{1}-\alpha_{2})(m+1)+1)},\end{align*}

where

(3.12) \begin{equation} f_{m,n}(r,t)=\dfrac{(\!-\!1)^{m}r!C_{2}^{m}}{C_{1}^{m+n}}\binom{m+n}{n}t^{n\alpha_{1}+(\alpha_{1}-\alpha_{2})m}\sum_{\substack{\sum_{i=1}^nm_i=r \\ m_i\in\mathbb{N}}} \prod_{\ell=1}^{n}\biggl(\dfrac{1}{m_\ell!}\sum_{j=1}^{k}(j)_{m_\ell}\lambda_{j}\biggr)\end{equation}

and $(j)_{m_\ell}=j(j-1)\cdots(j-m_{\ell}+1)$ .

The convergence of the series involved in Proposition 3.3 follows from Theorem 1.5 of [Reference Kilbas, Srivastava and Trujillo20].

3.2. The increments of the MFCP

For a fixed $\delta>0$ , the increment process $\{Z^{\delta}_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ of the MFCP is defined as

\begin{equation*}Z^{\delta}_{\alpha_{1},\alpha_{2}}(t)\;:\!=\;\mathcal{M}_{\alpha_{1},\alpha_{2}}(t+\delta)-\mathcal{M}_{\alpha_{1},\alpha_{2}}(t).\end{equation*}

Next we show that $\{Z^{\delta}_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ exhibits the SRD property. First we give an asymptotic result for the covariance of the MFCP.

Proposition 3.4. For fixed $s>0$ , we have

(3.13) \begin{align}&\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s), \mathcal{M}_{\alpha_{1},\alpha_{2}}(t))\sim L(s)-q_{1}^{2}t^{\alpha_2-1}K(s),\quad {as}\ t\rightarrow\infty,\end{align}

where L(s) and K(s) are some constants that depend on s.

Proof. For fixed $s>0$ and large t, we get the following on substituting (2.10) in (3.5):

\begin{align*}\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s), \mathcal{M}_{\alpha_{1},\alpha_{2}}(t))&\sim q_{2} U_{{\alpha_{1},\alpha_{2}}}(s)+q_{1}^{2}C_{1}^{-2}s^{2\alpha_{1}} E_{\alpha_{1}-\alpha_{2}, 2\alpha_{1}+1}^{2}(\!-\!C_{2}s^{\alpha_{1}-\alpha_{2}}/C_{1})\\[5pt] &\quad -q_{1}^{2}t^{\alpha_2-1}K(s),\end{align*}

where K(s) is given in (2.11). On taking

\begin{equation*}L(s)=q_{2}U_{{\alpha_{1},\alpha_{2}}}(s)+q_{1}^{2}C_{1}^{-2} s^{2\alpha_{1}} E_{\alpha_{1}-\alpha_{2}, 2\alpha_{1}+1}^{2}(\!-\!C_{2}s^{\alpha_{1}-\alpha_{2}}/C_{1}),\end{equation*}

the result follows.

Proof. The proof follows similar lines to that of Theorem 2 of [Reference Kataria and Khandakar17]. Here we give a brief outline.

Let $s>0$ be fixed such that $0< s+\delta\le t$ . From (3.5) and (3.13) we have

(3.14) \begin{align}&\operatorname{Cov} \bigl(Z^{\delta}_{\alpha_{1},\alpha_{2}}(s),Z^{\delta}_{\alpha_{1},\alpha_{2}}(t)\bigr)\notag\\[5pt] &\quad =\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s+\delta),\mathcal{M}_{\alpha_{1},\alpha_{2}}(t+\delta))+\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s),\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))\notag\\[5pt] &\quad \quad -\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s+\delta),\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))-\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(s),\mathcal{M}_{\alpha_{1},\alpha_{2}}(t+\delta))\notag\\[5pt] &\quad \sim(1-\alpha_2)\delta q_{1}^{2}(K(s+\delta)-K(s))t^{\alpha_2-2}.\end{align}

From (3.5) we have

(3.15) \begin{align}&\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t),\mathcal{M}_{\alpha_{1},\alpha_{2}}(t+\delta))\notag\\[5pt] &\quad=q_{2} U_{\alpha_{1},\alpha_{2}}(t)+q_{1}^{2}\operatorname{Cov}\!(Y_{\alpha_{1},\alpha_{2}}(t), Y_{\alpha_{1},\alpha_{2}}(t+\delta))\notag\\[5pt] &\quad \sim q_{2} U_{\alpha_{1},\alpha_{2}}(t)-q_{1}^{2}U_{\alpha_{1},\alpha_{2}}(t)U_{\alpha_{1},\alpha_{2}}(t+\delta)\notag\\[5pt] &\quad \quad +q_{1}^{2}\biggl( \dfrac{(t+\delta)^{\alpha_{1}+\alpha_{2}}}{C_{1}C_{2}}E_{\alpha_{1}-\alpha_{2}, \alpha_{1}+\alpha_{2}+1}(\!-\!C_{2}(t+\delta)^{\alpha_{1}-\alpha_{2}}/C_{1})\notag\\[5pt] &\quad \quad +\dfrac{t^{2\alpha_{1}}}{C_{1}^{2}} E_{\alpha_{1}-\alpha_{2}, 2\alpha_{1}+1}^{2}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1}) \biggr),\end{align}

where in the last step we used an asymptotic result for the covariance of the IMSS (see [Reference Kataria and Khandakar17, eqs (31) and (32)]).

Substituting $\delta=0$ in (3.15), we get an asymptotic behaviour of the variance of the MFCP. Thus

(3.16) \begin{align}&\operatorname{Var}\bigl(Z^{\delta}_{\alpha_{1},\alpha_{2}}(t)\bigr)\notag\\[5pt] &\quad =\operatorname{Var}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t+\delta))+\operatorname{Var}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))-2\operatorname{Cov}\!(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t),\mathcal{M}_{\alpha_{1},\alpha_{2}}(t+\delta))\notag\\[5pt] &\quad \sim q_{2}(U_{\alpha_{1},\alpha_{2}}(t+\delta)-U_{\alpha_{1},\alpha_{2}}(t))+q_{1}^{2}\bigl(2U_{\alpha_{1},\alpha_{2}}(t)U_{\alpha_{1},\alpha_{2}}(t+\delta)-U^2_{\alpha_{1},\alpha_{2}}(t)\notag\\[5pt] &\quad\quad -U^2_{\alpha_{1},\alpha_{2}}(t+\delta)\bigr)+q_{1}^{2}\biggl(\dfrac{(t+\delta)^{2\alpha_{1}}}{C_{1}^{2}} E_{\alpha_{1}-\alpha_{2}, 2\alpha_{1}+1}^{2}(\!-\!C_{2}(t+\delta)^{\alpha_{1}-\alpha_{2}}/C_{1}) \notag\\[5pt] &\quad\quad -\dfrac{t^{2\alpha_{1}}}{C_{1}^2}E^{2}_{\alpha_{1}-\alpha_{2}, 2\alpha_{1}+1}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1}) +\dfrac{t^{\alpha_{1}+\alpha_{2}}}{C_{1}C_{2}}E_{\alpha_{1}-\alpha_{2}, \alpha_{1}+\alpha_{2}+1}(\!-\!C_{2}t^{\alpha_{1}-\alpha_{2}}/C_{1})\notag\\[5pt] &\quad\quad -\dfrac{(t+\delta)^{\alpha_{1}+\alpha_{2}}}{C_{1}C_{2}}E_{\alpha_{1}-\alpha_{2},\alpha_{1}+\alpha_{2}+1}(\!-\!C_{2}(t+\delta)^{\alpha_{1}-\alpha_{2}}/C_{1})\biggr)\notag\\[5pt] &\quad \sim\dfrac{q_{2} \alpha_{2}\delta}{C_{2}\Gamma(\alpha_{2}+1)}t^{\alpha_{2}-1} \quad (\text{using (2.2) and (2.9)}).\end{align}

From (3.14) and (3.16) we get

\begin{equation*}\operatorname{Corr}\bigl(Z^{\delta}_{\alpha_{1},\alpha_{2}}(s),Z^{\delta}_{\alpha_{1},\alpha_{2}}(t)\bigr)\sim d(s)t^{-(3-\alpha_{2})/2}, \quad \text{as $ t\to \infty$,}\end{equation*}

where

\begin{equation*}d(s)=\dfrac{(1-\alpha_2)\delta q_{1}^2(K(s+\delta)-K(s))}{\sqrt{\operatorname{Var}\!(Z^{\delta}_{\alpha_{1},\alpha_{2}}(s))}\sqrt{\frac{q_{2} \alpha_{2}\delta}{C_{2}\Gamma(\alpha_{2}+1)}}}.\end{equation*}

As $1<(3-\alpha_{2})/2<1.5$ , the result follows.

3.3 An application of the MFCP to risk theory

Beghin and Macci [Reference Beghin and Macci4] introduced the following risk process:

\begin{equation*}R_{\alpha}(t)=u+ct-\sum_{i=1}^{N_{\alpha}^{h}(t)}X_{i}, \quad t\ge0,\end{equation*}

where $u>0$ is the initial capital, and $c>0$ is the constant premium rate. The claim numbers

\[N_{\alpha}^{h}(t)\;:\!=\; \sum_{n\ge 1}1_{\{T_{1}+T_{2}+\cdots+T_{n}\le t\}},\quad 0<\alpha\le 1,\ h>0\]

form a renewal process whose interarrival times $\{T_{n}\}_{n\ge1}$ has the density

\begin{equation*}f_{\alpha}^{h}(t)=\lambda^{h}t^{\alpha h-1}E^{h}_{\alpha,\alpha h}(\!-\!\lambda t^{\alpha}),\quad \lambda>0, \ t>0,\end{equation*}

and the $X_{i}$ are i.i.d. positive random variables that represent the claim sizes and are independent of $\{N_{\alpha}^{h}(t)\}_{t\ge0}$ . For $h=1$ , the process $\{N_{\alpha}^{h}(t)\}_{t\ge0}$ reduces to the TFPP. Beghin and Macci [Reference Beghin and Macci4] have obtained some asymptotic results for the ruin probabilities of $\{R_{\alpha}(t)\}_{t\ge0}$ . For more applications of the TFPP to risk theory, we refer the reader to Biard and Saussereau [Reference Biard and Saussereau7], Constantinescu et al. [Reference Constantinescu, Ramirez and Zhu8], and Kumar et al. [Reference Kumar, Leonenko and Pichler21].

Here we consider a risk process in which the number of claims received by an insurance company is modelled using the MFCP. We define it as follows:

(3.17) \begin{equation}R_{\alpha_{1},\alpha_{2}}(t)\;:\!=\; u+ct-\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)}X_{i}, \quad t\ge0,\end{equation}

where $u>0$ is the initial capital and $c>0$ is the constant premium rate. Here, the i.i.d. positive random variables $X_{i}$ are the claim sizes with mean $\mu>0$ and these are independent of the MFCP $\{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ .

The mean of $\{R_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ is

\begin{equation*}\mathbb{E}(R_{\alpha_{1},\alpha_{2}}(t))=u+ct-\mu q_{1} U_{{\alpha_{1},\alpha_{2}}}(t),\end{equation*}

where $U_{{\alpha_{1},\alpha_{2}}}(t)$ is given in (2.8).

It is important to note that initially the expected number of claims is higher under the MFCP regime than that of the GFCP or GCP. From (2.9) and (3.3), since $0<C\le 1$ , $0<\alpha<1$ , and t is small, we have

\begin{equation*}\dfrac{t^{\alpha}}{C\Gamma(\alpha+1)}\ge \dfrac{t^{\alpha}}{\Gamma(\alpha+1)}>t.\end{equation*}

The covariance of $\{R_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ can be obtained along similar lines to that of Proposition 10 of [Reference Kumar, Leonenko and Pichler21], and it is given by

\begin{align*}\operatorname{Cov}\!(R_{\alpha_{1},\alpha_{2}}(s), R_{\alpha_{1},\alpha_{2}}(t))&=\operatorname{Cov}\Biggl(\sum_{j=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(s)}X_{j}, \sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)}X_{i}\Biggr), \quad 0<s\le t\\[5pt] &=(\mu^{2}q_{2}+\operatorname{Var}\!(X_{1})q_{1}) U_{\alpha_{1},\alpha_{2}}(s)+\mu^{2}q_{1}^{2}\operatorname{Cov}\!(Y_{\alpha_{1},\alpha_{2}}(s), Y_{\alpha_{1},\alpha_{2}}(t)).\end{align*}

Its variance is given by

\begin{equation*}\operatorname{Var}\!(R_{\alpha_{1},\alpha_{2}}(t))=(\mu^{2}q_{2}+\operatorname{Var}\!(X_{1})q_{1}) U_{\alpha_{1},\alpha_{2}}(t)+\mu^{2}q_{1}^{2}\operatorname{Var}\!(Y_{\alpha_{1},\alpha_{2}}(t)).\end{equation*}

It is important to observe that if the mean and variance of claim sizes are finite then the risk process $\{R_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ exhibits the LRD property.

The finite-time ruin probability for the risk process $\{R_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ is defined as follows:

\begin{equation*}\psi_{u}(t)=\mathbb{P}\{R_{\alpha_{1},\alpha_{2}}(s)<0 \ \text{for some $ s\le t<\infty$}\}.\end{equation*}

Now we give an asymptotic behaviour of the finite-time ruin probability when the claim sizes are subexponentially distributed and the initial capital is arbitrarily large, i.e. $u\to\infty$ .

Let the distribution function $F_{X_{1}}(t)=\mathbb{P}\{X_1\leq t\}$ of the claim sizes in (3.17) be subexponential, that is,

\[\lim_{t\to \infty}\bigl(1-F_{X_{1}}^{*2}(t)\bigr)/(1-F_{X_{1}}(t))=2,\]

where $F_{X_{1}}^{*2}(t)$ denotes the 2-fold convolution of $F_{X_{1}}(t)$ .

The following result related to subexponential distribution will be used (see [Reference Asmussen and Albrecher2]).

Lemma 3.1. Let $\{X_{i}\}_{i\ge1}$ be a sequence of i.i.d. random variables having subexponential distribution $\bar{F}_{X_{1}}(t)=\mathbb{P}\{X_{1}>t\}$ and let N be an integer-valued random variable with $\mathbb{E}(z^{N})<\infty$ for some $z>1$ . Then

\begin{equation*}\mathbb{P}\Biggl\{\sum_{i=1}^{N}X_{i}>t\Biggr\}\sim \mathbb{E}(N)\bar{F}_{X_{1}}(t), \quad as\ \text{$ t\to \infty$,}\end{equation*}

where N is independent of $\{X_{i}\}_{i\ge1}$ .

The following inequalities hold for the finite-time ruin probability of $\{R_{\alpha_{1},\alpha_{2}}(t)\}_{t\ge0}$ :

(3.18) \begin{align}\mathbb{P}\Biggl\{\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)}X_{i}>u+ct\Biggr\}&\le\mathbb{P}\Biggl\{\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t^*)}X_{i}>u+ct^*\ \mathrm{for\ some}\ t^* \leq t<\infty\Biggr\}\notag\\[5pt] &\le\mathbb{P}\Biggl\{\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)}X_{i}>u\Biggr\}.\end{align}

The PGF of the MFCP is given in (3.8), which is finite for some $z>1$ . On dividing (3.18) by

\[\mathbb{P}\Biggl\{\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)}X_{i}>u\Biggr\}\]

and taking the limit $u\rightarrow\infty$ , we get

\begin{equation*}\mathbb{P}\Biggl\{\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t^*)}X_{i}>u+ct^*\ \mathrm{for\ some}\ t^* \leq t<\infty\Biggr\}\sim\mathbb{P}\Biggl\{\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)}X_{i}>u\Biggr\},\end{equation*}

where we have used $\lim_{u\to \infty}\bar{F}_{X_{1}}(u+ct)/\bar{F}_{X_{1}}(u)=1$ . On using Lemma 3.1, we get

(3.19) \begin{equation}\psi_{u}(t)\sim\mathbb{E}(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))\bar{F}_{X_{1}}(u),\quad {as}\ u\rightarrow \infty.\end{equation}

Thus the finite-time ruin probability has the following asymptotic behaviour as the initial capital $u\rightarrow \infty$ :

\begin{equation*}\psi_{u}(t)\sim q_{1} U_{{\alpha_{1},\alpha_{2}}}(t)\bar{F}_{X_{1}}(u),\end{equation*}

where we used (3.3) in (3.19).

Next we extend the above result to the case of m-dimensional risk processes, which is motivated by Proposition 5 of [Reference Biard and Saussereau7].

Let us consider the following independent risk processes:

\begin{equation*}R_{\alpha_{1},\alpha_{2}}^{(j)}(t)\;:\!=\; u^{(j)}+c^{(j)}t-\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)}X_{i}^{(j)},\quad j=1,2,\ldots,m.\end{equation*}

The above collection of independent risk processes can be rewritten as follows:

(3.20) \begin{equation}\bar{R}_{\alpha_{1},\alpha_{2}}(t)\;:\!=\; \bar{u}+\bar{c}t-\sum_{i=1}^{\mathcal{M}_{\alpha_{1},\alpha_{2}}(t)}\bar{X}_{i}, \quad t\ge0,\end{equation}

where

\[\bar{R}_{\alpha_{1},\alpha_{2}}(t)=\bigl(R_{\alpha_{1},\alpha_{2}}^{(1)}(t),R_{\alpha_{1},\alpha_{2}}^{(2)}(t),\ldots,R_{\alpha_{1},\alpha_{2}}^{(m)}(t)\bigr)\]

is an m-dimensional risk process, $\bar{u}=\bigl(u^{(1)}, u^{(2)}, \ldots, u^{(m)}\bigr)$ is the initial capital vector, $\bar{c}=\bigl(c^{(1)}, c^{(2)}, \ldots, c^{(m)}\bigr)$ is the premium intensity vector, and $\bar{X}_{i}=\bigl(X_{i}^{(1)}, X_{i}^{(2)},\ldots, X_{i}^{(m)}\bigr)$ is the ith claim size vector. Also, $\{\bar{X}_{i}\}_{i\ge 1}$ is a sequence of i.i.d. random vectors with the following joint distribution:

\begin{align*}F(x_{1},x_{2},\ldots, x_{m})&=\mathbb{P}\bigl\{X^{(1)}\le x_{1}, X^{(2)}\le x_{2},\ldots, X^{(m)}\le x_{m}\bigr\}\\[5pt] &=\prod_{j=1}^{m}\mathbb{P}\bigl\{X^{(j)}\le x_{j}\bigr\}\\[5pt] &=\prod_{j=1}^{m}F^{(j)}(x_{j}).\end{align*}

Next we give an extension of the result given in (3.19) for the risk process defined in (3.20). Its proof follows similar lines to that of the result given in (3.19).

Proposition 3.5. For $j=1,2,\ldots,m$ , let the distribution of the claim sizes $F^{(j)}$ be subexponentially distributed. For an initial capital vector $\bar{u}$ , let

\begin{equation*}\tau_{\max}(\bar{u})=\inf\bigl\{s>0\colon \max \bigl\{R_{\alpha_{1},\alpha_{2}}^{(1)}(s),R_{\alpha_{1},\alpha_{2}}^{(2)}(s),\ldots,R_{\alpha_{1},\alpha_{2}}^{(m)}(s)\bigr\}<0\bigr\}\end{equation*}

be the first time all the components of $\bar{R}_{\alpha_{1},\alpha_{2}}(t)$ are negative. Then, for any $t>0$ , we have

\begin{equation*}\mathbb{P}\{\tau_{\max}(\bar{u})\le t\}\sim \mathbb{E}(\mathcal{M}_{\alpha_{1},\alpha_{2}}(t))^{m}\prod_{j=1}^{m}\bigl(1-F^{(j)}(u_{j})\bigr),\end{equation*}

as $u_{j}\to \infty$ for all $j=1,2,\ldots,m$ .