Pressure spatial superposition principle @ model

Implication that a total pressure $\begin{array}{l}p(t, {\bf r})\end{array}$ in any point $\begin{array}{l}{\bf r}\end{array}$ of a porous reservoir is a sum of pressure responses $\begin{array}{l}\delta p_k(t, {\bf r})\end{array}$ to individual rate variations $\begin{array}{l}q_k(t)\end{array}$ in all wells $\begin{array}{l}k\end{array}$ connected to this reservoir:

(1)	$\begin{array}{l}\displaystyle p(t, {\bf r}) = p_i + \sum_k \delta p_k(t, {\bf r}) = p_i + \sum_k \int_0^t p_{uk}(t-\tau, {\bf r}) \, dq(\tau)\end{array}$

In case reservoir point $\begin{array}{l}{\bf r}\end{array}$ defines location of $\begin{array}{l}m\end{array}$ -well the superposition principle can be rewritten as:

(2)	$\begin{array}{l}\displaystyle p_m(t) = p_i + \sum_k \delta p_{mk}(t) = p_i + \sum_k \int_0^t p_{umk}(t-\tau) \, dq_k(\tau) = p_i + \int_0^t p_{umm}(t-\tau) \, dq_k(\tau) + \sum_{k \neq m} \int_0^t p_{umk}(t-\tau) \, dq_k(\tau)\end{array}$

where

$\begin{array}{l}\delta p_{mk}(t)\end{array}$	specific component of $\begin{array}{l}m\end{array}$ -well pressure variation caused by $\begin{array}{l}k\end{array}$ -well flowrate history $\begin{array}{l}q_k(t)\end{array}$
$\begin{array}{l}p_{umm}(\tau)\end{array}$	bottomhole pressure response in $\begin{array}{l}m\end{array}$ -well to unit-rate production in the same well (DTR)
$\begin{array}{l}p_{ukm}(\tau)\end{array}$	bottomhole pressure in $\begin{array}{l}m\end{array}$ -well to unit-rate production in $\begin{array}{l}k\end{array}$ -well (CTR), $\begin{array}{l}k \neq m\end{array}$

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Pressure spatial superposition principle @ model