A Novel LQI Control Technique for Interleaved-Boost Converters
Abstract
:1. Introduction
2. Interleaved Boost Converter
2.1. Circuit Configuration
2.2. Switching Modes
3. Control Methods
3.1. Derivation of State Averaging Equations
3.2. Derivation of Small-Signal Model
3.3. Derivation of Small-Signal-Model for Servo System
3.4. PI Controller
4. Verification
4.1. Steady-State Characteristics
4.2. Tracking Performance and Load Response
5. Conclusions
- The small-signal model for the servo system of the interleaved-boost converter was derived. The LQI control was proposed using the small-signal model.
- In the proposed method, an output voltage and a current signal error between two-phase input currents are selected as output variables to control the output voltage and balance between two-phase input currents. The proposed method has a simple system and can control both output variables without additional controllers.
- Steady-state characteristics in terms of the output voltage and the input current were demonstrated by experiments and simulations using an experimental apparatus with a rated power of 700 W.
- The validity of tracking performance and load response of the proposed method was demonstrated by comparing it with that of the conventional PI control. The tracking performance of the LQI control for the 40 V step response has a ten times faster response than that of the PI control. Also, the experimental results demonstrated that the proposed method can keep the output voltage constant for a load step of 300 W while that of the PI control varies by 10 V during 70 ms and has an excellent disturbance rejection.
- Therefore, the proposed LQI control improves the tracking performance and the load response and miniaturizes the motor-drive systems in HEVs and FCEVs.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Input voltage Vi | 100 V |
Carrier frequency fc1 and fc2 | 20 kHz |
IGBT | FGH40T120SMD |
rated voltage | 1200 V |
rated current | 40 A |
Diode | FEP16DT |
rated voltage | 600 V |
rated current | 16 A |
Load (Resistance) R | 100 Ω |
DC reactor | - |
inductance L1 and L2 | 1.8 mH |
rated current | 9 A |
core | silicon steel plate |
resistance r1 and r2 | 68.6 mΩ |
Capacitance C | 750 µF |
Converter | - |
Power rating | 700 W |
Output voltage Vdc | 250 V |
Duty cycle | 0.6 |
Input current | 7 A |
Output current | 2.8 A |
Feedback Gain | |||
---|---|---|---|
K1 | 2.2138 | K6 | 1.9795 |
K2 | 1.1652 | G1 | −497.60 |
K3 | 2.0918 | G2 | −97.733 |
K4 | 1.1604 | G3 | −478.74 |
K5 | 2.1158 | G4 | 106.94 |
Parameter | Value |
---|---|
Kpv | 0.15 |
Tiv | 0.02 |
Kpi | 4.0 |
Tii | 0.002 |
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© 2024 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
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Sakasegawa, E.; Watanabe, S.; Shiraishi, T.; Haga, H.; Kennel, R.M. A Novel LQI Control Technique for Interleaved-Boost Converters. World Electr. Veh. J. 2024, 15, 343. https://doi.org/10.3390/wevj15080343
Sakasegawa E, Watanabe S, Shiraishi T, Haga H, Kennel RM. A Novel LQI Control Technique for Interleaved-Boost Converters. World Electric Vehicle Journal. 2024; 15(8):343. https://doi.org/10.3390/wevj15080343
Chicago/Turabian StyleSakasegawa, Eiichi, So Watanabe, Takayuki Shiraishi, Hitoshi Haga, and Ralph M. Kennel. 2024. "A Novel LQI Control Technique for Interleaved-Boost Converters" World Electric Vehicle Journal 15, no. 8: 343. https://doi.org/10.3390/wevj15080343
APA StyleSakasegawa, E., Watanabe, S., Shiraishi, T., Haga, H., & Kennel, R. M. (2024). A Novel LQI Control Technique for Interleaved-Boost Converters. World Electric Vehicle Journal, 15(8), 343. https://doi.org/10.3390/wevj15080343