Contingency-Constrained PMU Placement in Power Networks
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Transcript of Contingency-Constrained PMU Placement in Power Networks
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Contingency-Constrained PMUPlacement in Power Networks
Farrokh Aminifar, Amin Khodaei, Mahmud Fotuhi-Firuzabad, and Mohammad Shahidehpour
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Outline
• Introduction• Problem Formulation• Integer Linear Programming• Experimental Results• Conclusion
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Definition • PMU is a device for synchronizing ac voltage and current measurements
with a common time reference.
http://criepi.denken.or.jp/en/system/common/img/unit/unit1_ind_pic2.gif http://www.phasor-rtdms.com/phaserconcepts/images/pmu.jpg
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Problem Formulation• The objective of PMU placement problem is to find the minimum # of
PMUs as well as their placement to make the power network topologically observable.
bus 1bus 2
bus 3bus 4
bus 5 bus 8bus 7
bus 9bus 11bus 6
bus 14bus 13bus 12
bus 10
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ILP Notation
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Traditional ILP Formulation
bus 1bus 2
bus 3bus 4
bus 5bus 8bus 7
bus 9bus 11bus 6
bus 14
bus 13bus 12
bus 10
a12 =1
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New Constraints in This Work
• Effect of Zero-Injection Buses• Loss of Measurement Contingency• Line Outage Contingency• Measurement Limitations
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Parameter “z” is a binary parameter that is equal to 1 if bus is a zero-injection bus and 0 otherwise
Zero-Injection Buses
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Zero-Injection Buses (Cont.)
bus 1bus 2
bus 3bus 4
bus 5bus 8bus 7
bus 9bus 11bus 6
bus 14
bus 13bus 12
bus 10
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Loss of Measurement Contingency
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Loss of Measurement Contingency (Cont.)
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Line Outage Contingency
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Line Outage Contingency (Cont.)
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Measurement Limitations
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Experimental Setup
• The standard IEEE 14, IEEE 30, IEEE 39, IEEE 57 and IEEE 118 are investigated.
• CPLEX solver is used to solve the ILP.
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Experimental ResultsTest System Base case
systemNo PMU at Zero-Injection
Line Outage Loss of Measurement
Line Outage or Loss of Measurement
IEEE 14-Bus 3 3 7 7 8
IEEE 30-Bus 7 7 13 15 17
IEEE 39-Bus 8 8 15 18 22
IEEE 57-Bus 11 11 19 26 26
IEEE 118-Bus 28 28 53 63 65
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Comparing to other works (Cont.)
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Conclusions• A fast and practical model based on integer linear programming is
proposed for solving the optimal PMU placement problem. • Different contingency conditions associated with power systems, i.e., line
outages and loss of measurements were considered. • Communication constraints of power networks were considered as
measurement limitations and included in the model.
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Thanks
• Questions?