Your search keyword '"Suying Liao"' showing total 3 results

1. Design and simulation of a sub-terahertz folded-waveguide extended interaction oscillator.

Author

Wenxin Liu, Zhaochuan Zhang, Chao Zhao, Xin Guo, and Suying Liao

Subjects

SUBMILLIMETER waves, PLASMA waveguides, ELECTRON optics, ELECTRON beams, SIMULATION methods & models, PARAMETERS (Statistics)

Abstract

In this paper, an interesting type of a two-section folded wave-guide (TSFW) slow wave structure (SWS) for the development of sub-Terahertz (sub-THz) extended interaction oscillator (EIO) is proposed. In this sub-THz device, the prebunching electron beam is produced by the TSFW SWS, which results in the enhancement of the output power. To verify this concept, the TSFW for sub- THz EIO is developed, which includes the design, simulation, and some fabrications. A small size of electron optics system (EOS), the TSFW SWS for beam-wave interactions, and the output structure are studied with simulations. Through the codes Egun and Superfish, the EOS is designed and optimized. With a help of CST studio and 3D particle-in-cell (PIC) simulation CHIPIC, the characteristics of beam-wave interaction generated by the TSFW are studied. The results of PIC simulation show that the output power is remarkably enhanced by a factor of 3, which exceeds 200W at the frequency of 108 GHz. Based on the optimum parameters, the TSFW is manufactured with a high speed numerical mill, and the test transmission characteristic ∣S21∣ is 13 dB. At last, the output structure with a pill-box window is optimized, fabricated, integrated, and tested, and the result shows that the voltage standing-wave ratio of the window is about 2.2 at an operating frequency of 108 GHz. This design and simulation can provide an effective method to develop high power THz sources. [ABSTRACT FROM AUTHOR]

Published

2017

2. Enhancement of the output power of terahertz folded waveguide oscillator by two parallel electron beams.

Author

Ke Li, Wenxin Liu, Yong Wang, Miaomiao Cao, and Suying Liao

Subjects

ELECTRIC power, PLASMA waveguides, ELECTRIC circuits, COMPUTER simulation, ELECTRIC potential

Abstract

A novel two-beam folded waveguide (FW) oscillator is presented for the purpose of gaining higher power with a small-size circuit compared with the normal FW oscillator. The high-frequency characteristics of the two-beam FW, including dispersion and interaction impedance, were investigated by the numerical simulation and compared with the one-beam FW. The radio-frequency loss of the two-beam FW was also analyzed. A 3-D particle-in-cell code CHIPIC was applied to analyze and optimize the performance of a G-band two-beam FW oscillator. The influences of the distance between the two beam tunnels, beam voltage, the number of periods, magnetic field, radius of beam tunnel, and the packing ratio on the circuit performance are investigated in detail. Compared with a one-beam circuit, a larger output power of the two-beam circuit with the same beam power was observed by the simulation. Moreover, the start-oscillation current of two-beam circuit is much lower than the one-beam circuit with better performance. It will favor the miniaturized design of the high-power terahertz oscillator. [ABSTRACT FROM AUTHOR]

Published

2015

3. High-order modes suppression in large-mode-area fiber amplifiers and lasers by controlling the mode power allocations.

Author

Mali Gong, Suying Liao, Yanyang Yuan, and Haitao Zhang

Subjects

*OPTICAL amplifiers, *FIBERS, *LASERS, *SUPERPOSITION principle (Physics), *OPTOELECTRONIC devices, *NONLINEAR optics

Abstract

The modal weight factors and their changing properties in large-mode-area fibers are investigated when the optical beam propagates from one fiber into another one with a different cross-sectional structure. Based on a weighted mode power superposition theory, a novel scheme of inserting a filter fiber to change the power allocation among the co-existing modes in active fibers is proposed. In order to verify the effectiveness of this method in practical implementations, the mode power propagation of a fiber laser and a fiber amplifier with an inserted filter fiber are calculated, respectively. Compared with the cases without a filter fiber, the numerical results show an obvious suppression effect of high-order modes. [ABSTRACT FROM AUTHOR]

Published

2009