400 research outputs found
Optimal PMU Placement for Power System Dynamic State Estimation by Using Empirical Observability Gramian
In this paper the empirical observability Gramian calculated around the
operating region of a power system is used to quantify the degree of
observability of the system states under specific phasor measurement unit (PMU)
placement. An optimal PMU placement method for power system dynamic state
estimation is further formulated as an optimization problem which maximizes the
determinant of the empirical observability Gramian and is efficiently solved by
the NOMAD solver, which implements the Mesh Adaptive Direct Search (MADS)
algorithm. The implementation, validation, and also the robustness to load
fluctuations and contingencies of the proposed method are carefully discussed.
The proposed method is tested on WSCC 3-machine 9-bus system and NPCC
48-machine 140-bus system by performing dynamic state estimation with
square-root unscented Kalman filter. The simulation results show that the
determined optimal PMU placements by the proposed method can guarantee good
observability of the system states, which further leads to smaller estimation
errors and larger number of convergent states for dynamic state estimation
compared with random PMU placements. Under optimal PMU placements an obvious
observability transition can be observed. The proposed method is also validated
to be very robust to both load fluctuations and contingencies.Comment: Accepted by IEEE Transactions on Power System
Model Order Reduction for Gas and Energy Networks
To counter the volatile nature of renewable energy sources, gas networks take
a vital role. But, to ensure fulfillment of contracts under these
circumstances, a vast number of possible scenarios, incorporating uncertain
supply and demand, has to be simulated ahead of time. This many-query gas
network simulation task can be accelerated by model reduction, yet,
large-scale, nonlinear, parametric, hyperbolic partial differential(-algebraic)
equation systems, modeling natural gas transport, are a challenging application
for model order reduction algorithms.
For this industrial application, we bring together the scientific computing
topics of: mathematical modeling of gas transport networks, numerical
simulation of hyperbolic partial differential equation, and parametric model
reduction for nonlinear systems. This research resulted in the "morgen" (Model
Order Reduction for Gas and Energy Networks) software platform, which enables
modular testing of various combinations of models, solvers, and model reduction
methods. In this work we present the theoretical background on systemic
modeling and structured, data-driven, system-theoretic model reduction for gas
networks, as well as the implementation of "morgen" and associated numerical
experiments testing model reduction adapted to gas network models
A Surrogate Data Assimilation Model for the Estimation of Dynamical System in a Limited Area
We propose a novel learning-based surrogate data assimilation (DA) model for
efficient state estimation in a limited area. Our model employs a feedforward
neural network for online computation, eliminating the need for integrating
high-dimensional limited-area models. This approach offers significant
computational advantages over traditional DA algorithms. Furthermore, our
method avoids the requirement of lateral boundary conditions for the
limited-area model in both online and offline computations. The design of our
surrogate DA model is built upon a robust theoretical framework that leverages
two fundamental concepts: observability and effective region. The concept of
observability enables us to quantitatively determine the optimal amount of
observation data necessary for accurate DA. Meanwhile, the concept of effective
region substantially reduces the computational burden associated with computing
observability and generating training data
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