Journal
2020 AMERICAN CONTROL CONFERENCE (ACC)
Volume -, Issue -, Pages 2382-2387Publisher
IEEE
DOI: 10.23919/acc45564.2020.9147594
Keywords
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Funding
- NSF [CNS1739295, OAC-1934675, ECCS-1839616, ECCS-1611301, CCF-1934904]
- PTX-Sandia National Lab grant [PO 2079716]
- Sclumberger Foundation Faculty for the Future fellowship
- Army Research Office [ARL W911NF-17-1-0072]
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We consider the problem of guaranteeing transient stability of a network of interconnected angle droop controlled microgrids, where voltage phase angle measurements from phasor measurement units (PMUs) may be lost, leading to poor performance and instability. In this paper, we propose a novel mixed voltage angle and frequency droop control (MAFD) framework to improve the reliability of such angle droop controlled microgrid interconnections. In this framework, when the phase angle measurement is lost at a microgrid, conventional frequency droop control is temporarily used for primary control in place of angle droop control. We model the network of interconnected microgrids with the MAFD architecture as a nonlinear switched system. We then propose a dissipativity-based distributed secondary control design to guarantee transient stability of this network under arbitrary switching between angle droop and frequency droop controllers. We demonstrate the performance of this control framework by simulation on a test 123-feeder distribution network.
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