Power balancing approach for modeling and stabilization of DC networks
Power balancing approach for modeling and stabilization of DC networks
We propose a set of theoretical and practical tools for the stabilization of dc networks. In order to do so, we propose a new framework to study the dynamics of dc grids - one that permits the combination of power converter models with those impedances - directly in higher-order terms. This mathematical setting includes a convenient modeling specification that allows one to analyze complex high-gain converter topologies and to develop an energy-based stability analysis for dc grids with potential destabilizers such as loads with negative impedance characteristics (e.g., constant power loads). We show that instability problems arise due to a power imbalance between passive and non-passive loads, hence power balancing is a suitable stabilizing mechanism. Moreover, a low-cost hardware solution that ensures stability is provided in the form of a lossless (H-bridge) stabilizing filter. The new theoretical results, combined with the proposed implementation, offer a low-cost alternative with respect to other (battery/super-capacitor) energy-storage-based existing strategies. Experimental results based on a high voltage gain quadratic converter feeding multiple non-passive loads are included.
DC-DC converters, high-gain converters, linear matrix inequalities, modeling, stability
4188-4200
Mayo-Maldonado, Jonathan C.
c7321b60-3130-43f4-89f4-f12ac5b2f822
Valdez-Resendiz, Jesus E.
b3ae7403-50bb-4b32-a7bf-d2d4646a5293
Rosas-Caro, Julio C.
8814ed10-b07c-438b-8cda-ed4eddb2b45e
29 June 2018
Mayo-Maldonado, Jonathan C.
c7321b60-3130-43f4-89f4-f12ac5b2f822
Valdez-Resendiz, Jesus E.
b3ae7403-50bb-4b32-a7bf-d2d4646a5293
Rosas-Caro, Julio C.
8814ed10-b07c-438b-8cda-ed4eddb2b45e
Mayo-Maldonado, Jonathan C., Valdez-Resendiz, Jesus E. and Rosas-Caro, Julio C.
(2018)
Power balancing approach for modeling and stabilization of DC networks.
IEEE Transactions on Smart Grid, 10 (4), , [8400393].
(doi:10.1109/TSG.2018.2851589).
Abstract
We propose a set of theoretical and practical tools for the stabilization of dc networks. In order to do so, we propose a new framework to study the dynamics of dc grids - one that permits the combination of power converter models with those impedances - directly in higher-order terms. This mathematical setting includes a convenient modeling specification that allows one to analyze complex high-gain converter topologies and to develop an energy-based stability analysis for dc grids with potential destabilizers such as loads with negative impedance characteristics (e.g., constant power loads). We show that instability problems arise due to a power imbalance between passive and non-passive loads, hence power balancing is a suitable stabilizing mechanism. Moreover, a low-cost hardware solution that ensures stability is provided in the form of a lossless (H-bridge) stabilizing filter. The new theoretical results, combined with the proposed implementation, offer a low-cost alternative with respect to other (battery/super-capacitor) energy-storage-based existing strategies. Experimental results based on a high voltage gain quadratic converter feeding multiple non-passive loads are included.
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Published date: 29 June 2018
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© 2010-2012 IEEE.
Keywords:
DC-DC converters, high-gain converters, linear matrix inequalities, modeling, stability
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Local EPrints ID: 503436
URI: http://eprints.soton.ac.uk/id/eprint/503436
ISSN: 1949-3053
PURE UUID: 9156db7d-e3ed-49a6-96fb-5e0a2e06b9ec
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Date deposited: 31 Jul 2025 16:56
Last modified: 01 Aug 2025 02:18
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Contributors
Author:
Jonathan C. Mayo-Maldonado
Author:
Jesus E. Valdez-Resendiz
Author:
Julio C. Rosas-Caro
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