------------------------------ AC Optimal Power Flow (Jabr relaxation) ------------------------------ This formulation employs rectangular coordinates to represent voltages, where the voltage at node :math:`n` is expressed as: .. math:: \mathcal{V}_n = e_n + j f_n Here, :math:`e_n` and :math:`f_n` denote the real and imaginary components of the voltage, respectively. The formulation relaxes the rectangular definitions and incorporates a rotated cone valid inequality, resulting in a convex quadratically constrained quadratic program (QCQP). Objective Function ------------------ The objective is to minimize the total generation cost: .. math:: \text{Minimize: } \sum_{g} \left( a_{g} \cdot p_g^2 + b_{g} \cdot p_g + c_{g} \right) Constraints ----------- 1. **Power Balance Equations**: .. math:: \sum_{g\in\mathcal{G}_n} p_g - p^d_n = G^{sh}_n v_n^{(2)} + \sum_{l} \left( F_{ln} \cdot p^f_l + T_{ln} \cdot p^t_l \right), \quad \forall n .. math:: \sum_{g\in\mathcal{G}_n} q_g - q^d_n = -B^{sh}_n v_n^{(2)} + \sum_{l} \left( F_{ln} \cdot q^f_l + T_{ln} \cdot q^t_l \right), \quad \forall n 2. **Line Flow Equations**: .. math:: p^f_l = G^{ff}_l v_n^{(2)} + G^{ft}_l c^{ft}_l + B^{ft}_l s^{ft}_l, \quad \forall (l, n, m): F_{ln} = 1, T_{lm} = 1 .. math:: q^f_l = -B^{ff}_l v_n^{(2)} + G^{ft}_l s^{ft}_l - B^{ft}_l c^{ft}_l, \quad \forall (l, n, m): F_{ln} = 1, T_{lm} = 1 .. math:: p^t_l = G^{tt}_l v_m^{(2)} + G^{tf}_l c^{ft}_l + B^{tf}_l s^{ft}_l, \quad \forall (l, n, m): F_{ln} = 1, T_{lm} = 1 .. math:: q^t_l = -B^{tt}_l v_m^{(2)} + G^{tf}_l s^{ft}_l - B^{tf}_l c^{ft}_l, \quad \forall (l, n, m): F_{ln} = 1, T_{lm} = 1 3. **Jabr Relaxation**: .. math:: (c^{ft}_l)^2 + (s^{ft}_l)^2 \leq v_{n}^{(2)} v_{m}^{(2)}, \quad \forall (l,n,m): F_{ln} = 1, T_{lm} = 1 4. **Generator Limits**: .. math:: \underline{p}_g \leq p_g \leq \overline{p}_g, \quad \forall g .. math:: \underline{q}_g \leq q_g \leq \overline{q}_g, \quad \forall g 5. **Line Flow Limits**: .. math:: (p^f_l)^2 + (q^f_l)^2 \leq (\overline{s}_l)^2, \quad \forall l .. math:: (p^t_l)^2 + (q^t_l)^2 \leq (\overline{s}_l)^2, \quad \forall l 6. **Voltage Magnitude Limits**: .. math:: (\underline{v}_n)^2 \leq v_n^{(2)} \leq (\overline{v}_n)^2, \quad \forall n