5,151 research outputs found
Performance evaluation of multiplexed model predictive control for a large airliner in nominal and contingency scenarios
Model predictive control allows systematic han- dling of physical and operational constraints through the use of constrained optimisation. It has also been shown to successfully exploit plant redundancy to maintain a level of control in scenarios when faults are present. Unfortunately, the computa- tional complexity of each individual iteration of the algorithm to solve the optimisation problem scales cubically with the number of plant inputs, so the computational demands are high for large MIMO plants. Multiplexed MPC only calculates changes in a subset of the plant inputs at each sampling instant, thus reducing the complexity of the optimisation. This paper demonstrates the application of multiplexed model predictive control to a large transport airliner in a nominal and a contingency scenario. The performance is compared to that obtained with a conventional synchronous model predictive controller, designed using an equivalent cost function.This work was supported by Engineering and Physical Sciences Research Council grant number EP/G030308/1.The 2012 American Control Conference, June 27-29, Montreal, Canada
Embedded ADMM-based QP solver for MPC with polytopic constraints
We propose an algorithm for solving quadratic programming (QP) problems with inequality and equality constraints arising from linear MPC. The proposed algorithm is based on the ‘alternating direction method of multipliers’ (ADMM), with the introduction of slack variables. In comparison with algorithms available in the literature, our proposed algorithm can handle the so-called sparse MPC formulation with general inequality constraints. Moreover, our proposed algorithm is suitable for implementation on embedded platforms where computational resources are limited. In some cases, our algorithm is division-free when certain fixed matrices are computed offline. This enables our algorithm to be implemented in fixed-point arithmetic on a FPGA. In this paper, we also propose heuristic rules to select the step size of ADMM for a good convergence rate.This is the author accepted manuscript. The final version is available from IEEE via http://dx.doi.org/10.1109/ECC.2015.733106
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Optimal nonlinear model predictive control based on Bernstein polynomial approach
© 2017 IEEE. In this paper, we compare the performance of Bernstein global optimization algorithm based nonlinear model predictive control (NMPC) with a power system stabilizer and linear model predictive control (MPC) for the excitation control of a single machine infinite bus power system. The control simulation studies with Bernstein algorithm based NMPC show improvement in the system damping and settling time when compared with respect to a power system stabilizer and linear MPC scheme. Further, the efficacy of the Bernstein algorithm is also compared with global optimization solver BMIBNB from YALMIP toolbox in terms of NMPC scheme and results are found to be satisfactory.National Research Foundation, Singapore
Application of quadratically-constrained model predictive control in power systems
Simulations for the quadratically-constrained model
predictive control (qc-MPC) with power system linear models are
studied in this work. In qc-MPC, the optimization is imposed
with two additional constraints to achieve the closed-loop system
stability and the recursive-feasibility simultaneously. Instead of
engaging the traditional terminal constraint for MPC, both
constraints in qc-MPC are imposed on the first control vector
of the MPC control sequence. As a result, qc-MPC has the
potential for further extension to the control of network centric
power systems. The algorithm of qc-MPC has been developed
in a previous paper. Here, simulation studies with small-signal
linear models of three typical power systems are presented
to demonstrate its efficacy. We also develop a computational
strategy for the decentralized static state-feedback control using
the same quadratic dissipativity constraint as of the qc-MPC.
Only state constraints are considered in the state feedback design.
A comparison is then provided in the simulation study of qc-MPC
relatively to the constrained-state feedback control.This publication is made possible by the Singapore National Research
Foundation under its Campus for Research Excellence And Technological
Enterprise (CREATE) programmeThis is the author accepted manuscript. The final version is available from IEEE via http://dx.doi.org/10.1109/ICARCV.2014.706430
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Multiplexed model predictive control of interconnected systems
A Multiplexed Model Predictive Control (MMPC) scheme with Quadratic Dissipativity Constraint (QDC) for interconnected systems is presented in this paper. A centralized MMPC is designed for the global system, wherein the controls of subsystems are updated sequentially to reduce the computational time. In MMPC, the global state vector of the interconnected system is required by the optimization. The QDC is converted into an enforced stability constraint for the MMPC as an alternative to the terminal constraint and terminal cost in this approach. The nominal recursive feasibility for the global system and the iterative feasibility for the local subsystems are obtained via set operations on the invariant sets. The admissible sets for the control inputs are obtained and employed in this approach for the QDC-based stability constraint. The set operations are speed up by multiple magnitudes thanks to the implementation of multiplexed inputs in MMPC. Numerical simulations with Automatic Generation Control (AGC) in power systems having tie-lines demonstrate the theoretical development.The authors acknowledge the support by the Singapore National Research Foundation (NRF) under its Campus for Research Excellence And Technological Enterprise (CREATE) programme and the Cambridge Centre for Advanced Research in Energy Efficiency in Singapore (Cambridge CARES), C4T project.This is the author accepted manuscript. The final version is available from IEEE via http://dx.doi.org/10.1109/CDC.2015.740256
Electron emission from deep level defects EL2 and EL6 in semi-insulating GaAs observed by positron drift velocity transient measurements
A ±100 V square wave applied to a Au/semi-insulating SI-GaAs interface was used to bring about electron emission from and capture into deep level defects in the region adjacent to the interface. The electric field transient resulting from deep level emission was studied by monitoring the positron drift velocity in the region. A deep level transient spectrum was obtained by computing the trap emission rate as a function of temperature and two peaks corresponding to EL2 (E a=0.81±0.15 eV) and EL6 (E a=0.30±0.12 eV) have been identified. © 2002 American Institute of Physics.published_or_final_versio
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Covariance Analysis of LAV Robust Dynamic State Estimation in Power Systems
In power system state estimation, the robust
Least Absolute Value robust dynamic estimator is well-known.
However, the covariance of the state estimation error cannot
be obtained easily. In this paper, an analytical equation is
derived using Influence Function approximation to analyze the
covariance of the robust Least Absolute Value dynamic state
estimator. The equation gives insights into the precision of the
estimation and can be used to express the variances of the
state estimates as functions of measurement noise variances,
enabling the selection of sensors for specified estimator precision.
Simulations on the IEEE 14-bus, 30-bus and 118-bus
systems are given to illustrate the usefulness of the equation.
Monte-Carlo experiments can also be used to determine the
covariance, but many data points are needed and hence many
runs are required to achieve convergence. Our result shows
that to obtain the covariance of the state estimation error, the
analytical equation proposed in this paper is four orders of
magnitude faster than a 10,000-run Monte-Carlo experiment
on both the IEEE 14-bus and 30-bus systems.National Research Foundation Singapor
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A trust-region based sequential linear programming approach for AC optimal power flow problems
© 2018 Elsevier B.V. This study proposes a new trust-region based sequential linear programming algorithm to solve the AC optimal power flow (OPF) problem. The OPF problem is solved by linearizing the cost function, power balance and engineering constraints of the system, followed by a trust-region to control the validity of the linear model. To alleviate the problems associated with the infeasibilities of a linear approximation, a feasibility restoration phase is introduced. This phase uses the original nonlinear constraints to quickly locate a feasible point when the linear approximation is infeasible. The algorithm follows convergence criteria to satisfy the first order optimality conditions for the original OPF problem. Studies on standard IEEE systems and large-scale Polish systems show an acceptable quality of convergence to a set of best-known solutions and a substantial improvement in computational time, with linear scaling proportional to the network size.National Research Foundation, Singapore
Distributed model predictive control of linear systems with persistent disturbances
This article presents a new form of robust distributed model predictive control (MPC) for multiple dynamically decoupled subsystems, in which distributed control agents exchange plans to achieve satisfaction of coupling constraints. The new method offers greater flexibility in communications than existing robust methods, and relaxes restrictions on the order in which distributed computations are performed. The local controllers use the concept of tube MPC – in which an optimisation designs a tube for the system to follow rather than a trajectory – to achieve robust feasibility and stability despite the presence of persistent, bounded disturbances. A methodical exploration of the trades between performance and communication is provided by numerical simulations of an example scenario. It is shown that at low levels of inter-agent communication, distributed MPC can obtain a lower closed-loop cost than that obtained by a centralised implementation. A further example shows that the flexibility in communications means the new algorithm has a relatively low susceptibility to the adverse effects of delays in computation and communication
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Experiments with hybrid Bernstein global optimization algorithm for the OPF problem in power systems
This paper presents an algorithm based on the Bernstein form of polynomials for solving the optimal power flow (OPF) problem in electrical power networks. The proposed algorithm combines local and global optimization methods and is therefore referred to as a `hybrid'
Bernstein algorithm in the context of this work. The proposed algorithm is a branch-and-bound (B&B) procedure wherein a local search method is used to obtain a good upper bound on the global minimum at each branching node. Subsequently, the Bernstein form of polynomials is used to obtain a lower bound on the global minimum. The performance of the proposed algorithm is compared with the previously reported Bernstein algorithm
to demonstrate its effi cacy in terms of the chosen performance metrics. Furthermore, the proposed algorithm is tested by solving the OPF problem for several benchmark IEEE power system examples and its performance is compared with generic global optimization solvers such as BARON and COUENNE. The test results demonstrate that the algorithm HBBB
delivers satisfactory performance in terms of solution optimality.This research is supported by the National Research Foundation, Prime Ministers Office, Singapore, under its CREATE programme
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