Demodulation of Three-Phase AC Power Transients in the Presence of Harmonic Distortion
Abstract
:1. Introduction
2. AC Power Flow and Demodulation
2.1. Reference Circuit
2.2. Power Demodulation
3. Demodulation via Costas Loop
- Costas loop exhibits transient effects itself, and these transient effects interfere with the desired demodulation of power flow transient effects.
- Costas loop demodulates the amplitude with an ambiguous sign: the phase of the demodulated signal may be misread by radians, causing a sign mismatch in the demodulated signal.
- The magnitude of the feedback signal is dependent on that of the input; the VCO sensitivity may be optimal for one transient while completely ineffectual for another.
4. The GOLD Method
4.1. Rationale
4.2. Algorithm
5. Robustness
5.1. Unbalanced Loading
5.2. Harmonic Distortion
6. Testing and Experimental Results
6.1. Hardware Implementation
6.2. Demonstration on Reference Circuit
6.3. Improvement in Signal Quality
7. Conclusions and Future Work
Author Contributions
Funding
Conflicts of Interest
Nomenclature
Grid frequency | |
N | Number of samples per cycle |
Angular frequency of voltage input, | |
Reference circuit natural frequency | |
Time of reference circuit switch-closure | |
Discreet time variable with time step | |
Discreet time variable with time step | |
Voltage on phase ‘p’ where , or c | |
Superscript ‘−90’ indicates radian phase shift on the signal | |
Line voltage, , or c and , or a, respectively | |
V | Input voltage amplitude |
‘Candidate’ signal ‘m’: normalized voltage, may be delayed | |
Voltage phase at time of switch closure. | |
Current on phase ‘p’ | |
Steady-state current amplitude | |
Transient current amplitude | |
Reference circuit damping attenuation | |
Phase difference between steady-state current and voltage | |
Phase of three-phase power fluctuation | |
P | Three-phase instantaneous active power |
Steady-state component of active power | |
Transient component of active power | |
Filtered three-phase instantaneous active power | |
Reconstruction of steady-state component of active power | |
Estimated transient component of active power | |
Transient component of active power demodulated by | |
Decoded active power signal | |
Q | Three-phase instantaneous reactive power |
Estimated transient component of reactive power | |
Band-pass filter input ‘m’ | |
Band-pass filter output ‘m’ | |
F | Filter transfer function. Subscript denotes type: ‘LP’-low-pass; ‘MA’-moving average; ‘BP’-band-pass |
B | Function representing error due to filtering |
H | Harmonic order. |
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Power | Power | |
---|---|---|
(Percent of Nominal) | (Watts) | (%) |
0.00% | 0 W | 99.4% |
0.31% | 113 W | 100.5% |
0.63% | 225 W | 143.9% |
0.94% | 338 W | 160.6% |
1.25% | 450 W | 146.5% |
1.56% | 563 W | 118.7% |
1.88% | 625 W | 100.9% |
2.19% | 788 W | 84.5% |
2.50% | 900 W | 71.5% |
2.85% | 1013 W | 63.6% |
3.13% | 1125 W | 57.2% |
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Gwynn, B.T.; de Callafon, R. Demodulation of Three-Phase AC Power Transients in the Presence of Harmonic Distortion. Energies 2020, 13, 2341. https://doi.org/10.3390/en13092341
Gwynn BT, de Callafon R. Demodulation of Three-Phase AC Power Transients in the Presence of Harmonic Distortion. Energies. 2020; 13(9):2341. https://doi.org/10.3390/en13092341
Chicago/Turabian StyleGwynn, Benjamin T., and Raymond de Callafon. 2020. "Demodulation of Three-Phase AC Power Transients in the Presence of Harmonic Distortion" Energies 13, no. 9: 2341. https://doi.org/10.3390/en13092341
APA StyleGwynn, B. T., & de Callafon, R. (2020). Demodulation of Three-Phase AC Power Transients in the Presence of Harmonic Distortion. Energies, 13(9), 2341. https://doi.org/10.3390/en13092341