changes.mady.by.user Arthur Aslanyan (Nafta College)
Saved on Nov 22, 2021
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\phi_n(p) = \frac{B_o - R_s \, B_g}{1- R_s \, R_v} \cdot G_O +\frac{ B_g - R_v \, B_o}{1- R_s \, R_v} \cdot G_G +B_w \, G_W - \phi_n = 0
(B_o - R_s \, B_g) \, G_O +(B_g - R_v \, B_o) \, G_G + (B_w \, G_W - \phi_n )\, (1- R_s \, R_v) = 0
G_O = V_e^{-1} \, \delta \, Q_O + \left[ \frac{s_{oi}}{B_{oi}} + \frac{R_{vi}\, s_{gi}}{B_{gi}}\right]
\delta \, Q_O = - Q^{\uparrow}_O
G_G = V_e^{-1} \, \delta \, Q_G + \left[ \frac{R_{si}\, s_{oi}}{B_{oi}} + \frac{ s_{gi}}{B_{gi}}\right]
\delta \, Q_G = Q^{\downarrow}_G - Q^{\uparrow}_G + Q^{\downarrow}_{GCAP}
G_W = V_e^{-1} \, \delta \, Q_W + \frac{ s_{wi}}{B_{wi}}
\delta \, Q_W = Q^{\downarrow}_W - Q^{\uparrow}_W + Q^{\downarrow}_{WAQ}
\phi_n = \exp \left[ c_\phi \, (p-p_i) \right] \approx 1 + c_\phi \, (p-p_i) + 0.5 \, c^2_\phi \, (p-p_i)^2