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High Power Laser and Particle Beams, Volume. 34, Issue 7, 075005(2022)

Voltage droop compensation based on resonant circuit for solid-state Marx generators

Junfeng Rao, Xiuzhi Wang, Yonggang Wang, Zi Li, and Song Jiang
Author Affiliations
  • School of Mechanical Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China
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    AbstractGet PDF(in Chinese)
    Figures&Tables (15)
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    References (16)
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    Figures & Tables(15)
    Unipolar SSMG with multi-stage voltage droop compensation

    Fig. 1. Unipolar SSMG with multi-stage voltage droop compensation

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    Principle of resonant compensation

    Fig. 2. Principle of resonant compensation

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    Charging operating mode of the circuit

    Fig. 3. Charging operating mode of the circuit

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    Resonance process of the circuit

    Fig. 4. Resonance process of the circuit

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    Discharge operating mode of the circuit

    Fig. 5. Discharge operating mode of the circuit

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    Discharge operating mode without compensation

    Fig. 6. Discharge operating mode without compensation

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    Recharging operating mode and progress of truncating the wave tail

    Fig. 7. Recharging operating mode and progress of truncating the wave tail

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    Drive signals of switches of the circuit

    Fig. 8. Drive signals of switches of the circuit

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    A 16-stage Marx generator with 4 resonant voltage droop compensation stages

    Fig. 9. A 16-stage Marx generator with 4 resonant voltage droop compensation stages

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    Voltage waveforms with different voltage droop over (a) 400-Ω and (b) 5-kΩ resistive loads

    Fig. 10. Voltage waveforms with different voltage droop over (a) 400-Ω and (b) 5-kΩ resistive loads

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    Voltage waveforms with voltage droop compensation over (a) 400-Ω and (b) 5-kΩ resistive loads

    Fig. 11. Voltage waveforms with voltage droop compensation over (a) 400-Ω and (b) 5-kΩ resistive loads

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    Waveforms with different number of stages of resonant voltage droop compensation

    Fig. 12. Waveforms with different number of stages of resonant voltage droop compensation

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    Waveform of the 2.5-kV output voltage after compensation and voltage of its capacitor Cres1

    Fig. 13. Waveform of the 2.5-kV output voltage after compensation and voltage of its capacitor Cres1

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    Waveform of the 2.5-kV output voltage after compensation with different pulse widths

    Fig. 14. Waveform of the 2.5-kV output voltage after compensation with different pulse widths

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    Waveform of the 13.3-kV output voltage increased by 4 compensation stages

    Fig. 15. Waveform of the 13.3-kV output voltage increased by 4 compensation stages

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    Junfeng Rao, Xiuzhi Wang, Yonggang Wang, Zi Li, Song Jiang. Voltage droop compensation based on resonant circuit for solid-state Marx generators[J]. High Power Laser and Particle Beams, 2022, 34(7): 075005

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    Paper Information

    Category: Pulsed Power Technology

    Received: Oct. 14, 2021

    Accepted: Jan. 5, 2022

    Published Online: Jul. 5, 2022

    The Author Email:

    DOI:10.11884/HPLPB202234.210435

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology