DocumentCode
3587910
Title
Energy price matrix factorization
Author
Kekatos, Vassilis
Author_Institution
Dept. of ECE & DTC, Univ. of Minnesota, Minneapolis, MN, USA
fYear
2014
Firstpage
1346
Lastpage
1350
Abstract
Statistical learning tools are utilized here to study the potential risks of revealing the topology of the underlying power grid using publicly available market data. It is first recognized that the vector of real-time locational marginal prices admits an interesting decomposition: It can be expressed as the product of a sparse, positive definite matrix with non-positive off-diagonal entries times a sparse vector. A convex optimization problem involving sparse regularizers is formulated to recover the constituent factors under relevant noisy and noiseless scenarios. To tackle the high dimensionality and the streaming nature of real-time energy market data, an online algorithm with efficient closed-form iterates is developed. The grid topology matrix is updated every time a new set of locational marginal prices becomes available. Numerical tests with real demand data used on the IEEE 30-bus grid benchmark justify that the solver can partially track the underlying grid topology.
Keywords
convex programming; learning (artificial intelligence); marketing data processing; matrix decomposition; power grids; power markets; pricing; topology; IEEE 30-bus grid benchmark; closed-form iterates; convex optimization problem; demand data; energy price matrix factorization; grid topology matrix; noiseless scenarios; noisy scenarios; nonpositive off-diagonal; numerical test; online algorithm; power grid; publicly available market data; real-time energy market data; real-time locational marginal prices; sparse positive definite matrix; sparse regularizers; sparse vector; statistical learning tool; Benchmark testing; Network topology; Real-time systems; Smart grids; Topology; Transmission line matrix methods;
fLanguage
English
Publisher
ieee
Conference_Titel
Signals, Systems and Computers, 2014 48th Asilomar Conference on
Print_ISBN
978-1-4799-8295-0
Type
conf
DOI
10.1109/ACSSC.2014.7094680
Filename
7094680
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