Wang Shaoqing, Lin Weigan, Zhang Mei. OPTIMUM DESIGN OF SHORT-SLOT HYBRID POWER COMBINER[J]. Journal of Electronics & Information Technology, 1994, 16(2): 198-202.
Citation:
Wang Shaoqing, Lin Weigan, Zhang Mei. OPTIMUM DESIGN OF SHORT-SLOT HYBRID POWER COMBINER[J]. Journal of Electronics & Information Technology, 1994, 16(2): 198-202.
Wang Shaoqing, Lin Weigan, Zhang Mei. OPTIMUM DESIGN OF SHORT-SLOT HYBRID POWER COMBINER[J]. Journal of Electronics & Information Technology, 1994, 16(2): 198-202.
Citation:
Wang Shaoqing, Lin Weigan, Zhang Mei. OPTIMUM DESIGN OF SHORT-SLOT HYBRID POWER COMBINER[J]. Journal of Electronics & Information Technology, 1994, 16(2): 198-202.
A new idea of representing the mutual injection locking phenomena in the short-slot hybrid power combiner by a model of negative nonlinear network is proposed. This model thoroughly represents the nonlinear characteristic of the combiner. After the nonlinear equations of the combining system are derived, a method of optimizing the parameters of the combined oscillators to achieve a maximum power combining efficiency is given. The optimum results agree with experimental ones quite well.
Russell K J. IEEE Trans. on MTT, 1979, MTT-27(5): 472-478.[2]Chang K, Sun C. IEEE Trans. on MTT, 1983. MTT-31(2): 91-107.[3]Mizushina S. Proc[J].IEEE.1967, 55(12):2166-2167[4]Mizushina S, Kondon H, Ashiki M. IEEE Trans. on MTT, 1980, MTT-28(12): 1428-1432.[5]Ohta I Kaneko T. IEEE Trans. on MTT, 1989, MTT-37(11): 1699-1707.[6]Nakajima M, Ikenoue J. Int. J. Electron. 1978, 44(4): 465-472.[7]Fukumoto K, Nakajima M, Ikenoue J. IEEE Trans. on MTT, 1983, MTT-31: 954-959.[8]Fukumoto K, Nakajima M, Ikenoue J. IEEE Trans. on MTT, 1985, MTT-33: 319-323.
DownLoad: