Convexity of Energy-Like Functions: Theoretical Results and Applications to Power System Operations

Power systems are undergoing unprecedented transformations with increased adoption of renewables and distributed generation, as well as the adoption of demand response programs. All of these changes, while making the grid more responsive and potentially more efficient, pose significant challenges for power systems operators. Conventional operational paradigms are no longer sufficient as the power system may no longer have big dispatchable generators with sufficient positive and negative reserves. This increases the need for tools and algorithms that can efficiently predict safe regions of operation of the power system. In this paper, we study energy functions as a tool to design algorithms for various operational problems in power systems. These have a long history in power systems and have been primarily applied to transient stability problems. In this paper, we take a new look at power systems, focusing on an aspect that has previously received little attention: Convexity. We characterize the domain of voltage magnitudes and phases within which the energy function is convex in these variables. We show that this corresponds naturally with standard operational constraints imposed in power systems. We show that power of equations can be solved using this approach, as long as the solution lies within themore » convexity domain. We outline various desirable properties of solutions in the convexity domain and present simple numerical illustrations supporting our results.« less

[1]  Pravin Varaiya,et al.  A structure preserving energy function for power system transient stability analysis , 1985 .

[2]  Javad Lavaei,et al.  Geometry of Power Flows and Optimization in Distribution Networks , 2012, IEEE Transactions on Power Systems.

[3]  K. R. Padiyar,et al.  ENERGY FUNCTION ANALYSIS FOR POWER SYSTEM STABILITY , 1990 .

[4]  R D Zimmerman,et al.  MATPOWER: Steady-State Operations, Planning, and Analysis Tools for Power Systems Research and Education , 2011, IEEE Transactions on Power Systems.

[5]  Jean‐Claude Sabonnadière,et al.  Stability Analysis of Power Systems , 2013 .

[6]  Carlos J. Tavora,et al.  Equilibrium Analysis of Power Systems , 1972 .

[7]  Steven H. Low,et al.  Convex Relaxation of Optimal Power Flow—Part I: Formulations and Equivalence , 2014, IEEE Transactions on Control of Network Systems.

[8]  Stephen P. Boyd,et al.  Convex Optimization , 2004, Algorithms and Theory of Computation Handbook.

[9]  Steven H. Low,et al.  Convex Relaxation of Optimal Power Flow—Part II: Exactness , 2014, IEEE Transactions on Control of Network Systems.

[10]  M. Ribbens-Pavella,et al.  Structure preserving direct methods for transient stability analysis of power systems , 1985, 1985 24th IEEE Conference on Decision and Control.

[11]  Russell Bent,et al.  Synchronization-aware and algorithm-efficient chance constrained optimal power flow , 2013, 2013 IREP Symposium Bulk Power System Dynamics and Control - IX Optimization, Security and Control of the Emerging Power Grid.

[12]  C. Singh,et al.  Direct Assessment of Protection Operation and Nonviable Transients , 2001, IEEE Power Engineering Review.

[13]  Peter W. Sauer,et al.  Existence of solutions for the network/load equations in power systems , 1999 .

[14]  David Tse,et al.  Geometry of injection regions of power networks , 2011, IEEE Transactions on Power Systems.

[15]  F.F. Wu,et al.  Direct methods for transient stability analysis of power systems: Recent results , 1985, Proceedings of the IEEE.

[16]  Javad Lavaei,et al.  Promises of Conic Relaxation for Contingency-Constrained Optimal Power Flow Problem , 2014, IEEE Transactions on Power Systems.

[17]  Carlos J. Tavora,et al.  Characterization of Equilibrium and Stability in Power Systems , 1972 .

[18]  B. Lesieutre,et al.  A Sufficient Condition for Power Flow Insolvability With Applications to Voltage Stability Margins , 2012, IEEE Transactions on Power Systems.

[19]  S. Zampieri,et al.  On the Existence and Linear Approximation of the Power Flow Solution in Power Distribution Networks , 2014, IEEE Transactions on Power Systems.

[20]  H. Chiang Direct Methods for Stability Analysis of Electric Power Systems: Theoretical Foundation, BCU Methodologies, and Applications , 2010 .

[21]  F. Bullo,et al.  Synchronization in complex oscillator networks and smart grids , 2012, Proceedings of the National Academy of Sciences.

[22]  Eilyan Bitar,et al.  Nondegeneracy and Inexactness of Semidefinite Relaxations of Optimal Power Flow , 2014, 1411.4663.

[23]  Florian Dörfler,et al.  Synchronization and transient stability in power networks and non-uniform Kuramoto oscillators , 2009, Proceedings of the 2010 American Control Conference.

[24]  P. Aylett The energy-integral criterion of transient stability limits of power systems , 1958 .

[25]  M. Ilić Network theoretic conditions for existence and uniqueness of steady state solutions to electric power circuits , 1992, [Proceedings] 1992 IEEE International Symposium on Circuits and Systems.

[26]  Florian Dörfler,et al.  Synchronization in complex networks of phase oscillators: A survey , 2014, Autom..

[27]  S. Kumagai,et al.  Steady-State Security Regions of Power Systems , 1982 .

[28]  A.R. Bergen,et al.  A Structure Preserving Model for Power System Stability Analysis , 1981, IEEE Transactions on Power Apparatus and Systems.

[29]  N. Narasimhamurthi,et al.  A generalized energy function for transient stability analysis of power systems , 1984 .

[30]  S. Sastry,et al.  Analysis of power-flow equation , 1981 .