changes.mady.by.user Arthur Aslanyan (Nafta College)
Saved on May 22, 2023
p_{e,n} \ (t) = p_{i,n} \ (0) + \gamma_n^{-1} \cdot \sum_m \left( Q^{\uparrow}_{nm} + Q^{\downarrow}_{nm} \ \right)
p_{{\rm wf}, n} \ \ \ (t) = p_e \ (t) + 0.5 \, \left[ q_O(t)/J_{On} + f_{nn} \cdot q_W(t)/ J_{Wn} \right]
Q^{\uparrow}_{nm} \ = \ - \ f^{\uparrow}_{O,nm} \ \cdot B_{ob} \cdot \, Q^{\uparrow}_O \ - \ f^{\uparrow}_{G,nm} \ \cdot B_{go} \cdot Q^{\uparrow}_G \ - \ f^{\uparrow}_{W,nm} \ \cdot B_w \cdot Q^{\uparrow}_W
Q^{\downarrow}_{nm} \ = f^{\downarrow}_{G,nm} \ \cdot B_{go} \cdot Q^{\downarrow}_G \ + \ f^{\downarrow}_{W,nm} \ \cdot B_w \cdot Q^{\downarrow}_W \ + \ B_{go} \cdot Q^{\downarrow}_{GCAP} \ \ + \ B_w \cdot Q^{\downarrow}_{WAQ}
Q_m(t) = \int_0^t q_m(t) \, dt
B_{og} = \frac{B_o - R_s \, B_g}{1- R_s \, R_v}
B_{go} = \frac{ B_g - R_v \, B_o}{1- R_s \, R_v}
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