4.6 Article

Overlapping-Mode Extended Interaction Klystrons for Broadband Terahertz Power Amplifiers

Journal

IEEE TRANSACTIONS ON ELECTRON DEVICES
Volume 69, Issue 3, Pages 1486-1491

Publisher

IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TED.2022.3147438

Keywords

Voltage; Electron beams; Couplings; Bandwidth; Broadband communication; Power generation; Impedance; Amplifier; broadband; extended interaction klystron (EIK); multimode operation; particle-in-cell (PIC) simulation; terahertz (THz)

Funding

  1. National Key Basic Research Program of China [2019YFA0210201]
  2. National Nation Natural Science Foundation ofChina [12075247]

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This paper presents the design approaches of overlapping-mode extended interaction klystrons (EIKs) to meet the requirements for broadband terahertz power amplifiers. By operating the cavities in multiple-cavity modes, the overlapping-mode EIKs can provide high output power over a wider frequency band. The circuit characteristics of the overlapping-mode EIKs are studied, and a six-cavity EIK operating at 0.34 THz is designed to demonstrate its broadband output capability.
The design approaches of the overlapping-mode extended interaction klystrons (EIKs) are presented to satisfy the requirement for broadband terahertz power amplifiers. Since all the cavities are designed and tuned to operate in multiple-cavity modes, the overlapping-mode EIKs can provide high output power over a wider frequency band. The circuit characteristics of the overlapping-mode EIKs are studied, including the dispersion curve, the coupling coefficient, and the frequency interval between cavity modes. Moreover, a six-cavity EIK operating at 0.34 THz is designed to demonstrate the broadband output capability of the overlapping-mode EIKs. The 2 pi -mode and its adjacent axial mode, the pi /13-mode, are chosen as the operating modes of the designed EIK. The 3-D particle-in-cell (PIC) simulation predicts a 3-dB bandwidth of 2.9 GHz for the designed power amplifier at a small-signal level or in saturation. Driven by an input power of 10 mW, the amplifier can provide the output power of 3.9 W, and the corresponding gain is 25.9 dB. When the input power is 150 mW, the amplifier is partially saturated and can provide the output power of 33 W with a corresponding electronic efficiency of 1.23%.

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