Fig 4 - uploaded by Salman Zaferanlouei
Content may be subject to copyright.
Download
View publication
Scaling factor multiplied by vector of consumption of active load P d in order to simulate one period of 24 hours

Scaling factor multiplied by vector of consumption of active load P d in order to simulate one period of 24 hours

Source publication
Fig. 1. Structure of Jacobian of the Newton-Raphson's algorithm before...
Fig. 2. Overall structure of the main Schur-Complement: σ σ σ c . The...
Fig. 3. Overal structure of the main Schur-Complement: σ σ σ c , for a...
Fig. 4. Scaling factor multiplied by vector of consumption of active...
+7 Fig. 5. IEEE Case9, ny = 3, T = 24 and ng = 3. Total loads and...
BATTPOWER Toolbox: Memory-Efficient and High-Performance Multi-Period AC Optimal Power Flow Solver
Preprint
Full-text available
  • Dec 2020
With the introduction of massive renewable energy sources and storage devices, the traditional process of grid operation must be improved in order to be safe, reliable, fast responsive and cost efficient, and in this regard power flow solvers are indispensable. In this paper, we introduce an Interior Point-based (IP) Multi-Period AC Optimal Power F...
Cite
Download full-text

Contexts in source publication

Context 1
... is taken for all results presented in this paper. Vector of bus active load is obtained through P d = c p (t).P, and c p (t) is illustrated in Fig. 4, which fluctuates similar to a base load of households. Vector of bus reactive load is simulated as Q d = c q (t).Q with a constant scaling factor shown in Fig. 4 by a red line. Note that the objective function of the optimisation problem in this paper includes only active power minimisation. P and Q are taken from the original values ...
Context 2
... is taken for all results presented in this paper. Vector of bus active load is obtained through P d = c p (t).P, and c p (t) is illustrated in Fig. 4, which fluctuates similar to a base load of households. Vector of bus reactive load is simulated as Q d = c q (t).Q with a constant scaling factor shown in Fig. 4 by a red line. Note that the objective function of the optimisation problem in this paper includes only active power minimisation. P and Q are taken from the original values in BUS matrix. All simulations codes are developed in MATLAB environment. They are performed on a computer with Intel(R) Xeon(R) CPU E5-2690 v4 @ 2.60 GHz and 384 ...
Context 3
... is taken for all results presented in this paper. Vector of bus active load is obtained through P d = c p (t).P, and c p (t) is illustrated in Fig. 4, which fluctuates similar to a base load of households. Vector of bus reactive load is simulated as Q d = c q (t).Q with a constant scaling factor shown in Fig. 4 by a red line. Note that the objective function of the optimisation problem in this paper includes only active power minimisation. P and Q are taken from the original values ...
Context 4
... is taken for all results presented in this paper. Vector of bus active load is obtained through P d = c p (t).P, and c p (t) is illustrated in Fig. 4, which fluctuates similar to a base load of households. Vector of bus reactive load is simulated as Q d = c q (t).Q with a constant scaling factor shown in Fig. 4 by a red line. Note that the objective function of the optimisation problem in this paper includes only active power minimisation. P and Q are taken from the original values in BUS matrix. All simulations codes are developed in MATLAB environment. They are performed on a computer with Intel(R) Xeon(R) CPU E5-2690 v4 @ 2.60 GHz and 384 ...