Abstract
Power hardware-in-the-loop (PHIL) simulation leverages the advanced real-time emulation based technique to carry out in-depth investigations on novel real-world power components. Power amplifiers, sensors, and signal conversion units based power interfaces (PI) incorporate physical hardware systems and real-time simulation platforms into PHIL setups. However, the employment of any interfacing technique inevitably introduces disturbances such as sensor noise, switching harmonics, or quantization noise to PHIL systems. To facilitate quantitatively analyzing and assessing the impact of external disturbances on PHIL simulation systems, a framework for sensitivity analysis of PHIL setups has been developed in this paper. Detailed modelling principles related to the sensitivity analysis of PHIL systems and the inherent relationship between sensitivity transfer functions and stability criteria are elaborated along with theoretical and experimental validation. Based on this concept, accuracy assessment methods are employed in this framework to quantify generic sensitivity criteria. Moreover, physical passive load and converter-based PHIL setups are applied and experimental results are presented to characterize and demonstrate the applicability of the proposed framework.
| Original language | English |
|---|---|
| Pages (from-to) | 101305-101318 |
| Number of pages | 14 |
| Journal | IEEE Access |
| Volume | 10 |
| Early online date | 15 Sept 2022 |
| DOIs | |
| Publication status | Published - 2022 |
Keywords
- power hardware-in-the-loop (PHIL)
- simulation systems
- sensitivity analysis
- power interface
- system modelling
- system theory
- control systems
- real-time simulation
Fingerprint
Dive into the research topics of 'A framework for sensitivity analysis of real-time power hardware-in-the-loop (PHIL) systems'. Together they form a unique fingerprint.Projects
- 1 Finished
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ERIGRID ll_ European Research Infrastructure supporting Smart Grid and Smart Energy Systems Research, Technology Development (H2020 INFRA IA)
Burt, G. (Principal Investigator), Abdulhadi, I. F. (Co-investigator), Coffele, F. (Co-investigator) & Syed, M. H. (Co-investigator)
European Commission - Horizon Europe + H2020
1/04/20 → 30/09/24
Project: Research
Equipment
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Dynamic Power Systems Laboratory
Burt, G. (Manager)
Electronic And Electrical EngineeringFacility/equipment: Facility
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Improved Hardware-in-the-Loop-Based Testing
Feng, Z., Syed, M. H., Paspatis, A., Kontou, A., Lauss, G., De Paola, A., Kotsampopoulos, P., Hatziargyriou, N. & Burt, G., 28 Dec 2025, European Guide to Smart Energy System Testing. Strasser, T. I., Calin, M. & Ramos Perez, L. E. (eds.). Springer, p. 47-63 17 p.Research output: Chapter in Book/Report/Conference proceeding › Chapter
Open AccessFile6 Downloads (Pure) -
Adaptive Smith predictor for enhanced stability of power hardware-in-the-loop setups
Feng, Z., Peña-Alzola, R., Syed, M. H., Norman, P. J. & Burt, G. M., Oct 2023, In: IEEE Transactions on Industrial Electronics. 70, 10, p. 10204-10214 11 p.Research output: Contribution to journal › Article › peer-review
Open AccessFile27 Link opens in a new tab Citations (Scopus)220 Downloads (Pure) -
Current-type power hardware-in-the-loop interface for black-start testing of grid-forming converter
Feng, Z., Alassi, A., Syed, M. H., Pena Alzola, R., Ahmed, K. & Burt, G., 9 Dec 2022. 7 p.Research output: Contribution to conference › Paper › peer-review
Open AccessFile11 Link opens in a new tab Citations (Scopus)210 Downloads (Pure)
Student theses
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Stability and accuracy enhancement of power hardware-in-the-loop simulation
Feng, Z. (Author), Pena Alzola, R. (Supervisor) & Burt, G. (Supervisor), 18 May 2023Student thesis: Doctoral Thesis
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