Consider integers $a$ and $b$ satisfying the equation $$14a + 9b = 147. \tag{1}$$
(1) We are to find the positive integers $a$ and $b$ satisfying equation (1).
Since $$14a = \mathbf{A}(\mathbf{BC} - \mathbf{D}b) \text{ and } 9b = \mathbf{E}(\mathbf{FG} - \mathbf{H}a),$$ $a$ is a multiple of $\mathbf{A}$, and $b$ is a multiple of $\mathbf{E}$.
So, when we set $a = \mathbf{A}m$ and $b = \mathbf{E}n$, where $m$ and $n$ are integers, from (1) we have $$\mathbf{I}m + \mathbf{J}n = \mathbf{K}.$$
Since the positive integers $m$ and $n$ satisfying this are $$m = \mathbf{L} \text{ and } n = \mathbf{M},$$ we obtain $$a = \mathbf{N} \text{ and } b = \mathbf{O}.$$
(2) We are to find the solutions $a$ and $b$ of equation (1) satisfying $0 < a + b < 5$.
Since $14 \times \mathbf{N} + 9 \times \mathbf{O} = 147$, from this equality and (1) we have $$14(a - \mathbf{N}) = 9(\mathbf{O} - b).$$
Since 14 and 9 are relatively prime, $a$ and $b$ can be expressed in terms of an integer $k$ as $$a = \mathbf{P} + \mathbf{Q}k, \quad b = -\mathbf{RS}k + \mathbf{T}.$$
Since $0 < a + b < 5$, we have $k = \mathbf{U}$, and we obtain $$a = \mathbf{VW}, \quad b = -\mathbf{XY}.$$