[1] Jiang-Ling Dou, Jin-Ping Xu, Meng-Yuan Xu. W-band full band tripler based on 3D EM model in installation circuit environment for Schottky diodes. Journal of Southeast University ( Natural Science Edition).

[2] X Wen, H Yang, Z Wu et al. A 100–180-GHz coaxial frequency tripler based on copper additive manufacturing. IEEE Transactions on Microwave Theory and Techniques, 71, 4337-4345(2023).

[3] C Guo, X Shang, M J Lancaster et al. A 135–150-GHz frequency tripler with waveguide filter matching. IEEE Transactions on Microwave Theory and Techniques, 66, 4608-4616(2018).

[4] C Guo, Y Dhayalan, X Shang et al. A 135–150-GHz frequency tripler using SU-8 micromachined WR-5 waveguides. IEEE Transactions on Microwave Theory and Techniques, 68, 1035-1044(2020).

[5] J V Siles, C Lee, R Lin et al. A high-power 105–120 GHz broadband on-chip power-combined frequency tripler. IEEE Microwave and Wireless Components Letters, 25, 157-159(2015).

[6] J A Qayyum, J D Albrecht, J Papapolymerou et al. A compact W-band frequency tripler using single-balanced topology. IEEE Microwave and Wireless Components Letters, 30, 806-809(2020).

[7] Y Campos-Roca, M Fernandez-Barciela, E Sanchez et al. An optimized 25.5-76.5 GHz PHEMT-based coplanar frequency tripler. IEEE Microwave and Guided Wave Letters, 10, 242-244(2000).

[8] K Han, T Liu, H He et al. A W band balanced tripler MMIC with excellent harmonic suppression and low conversion loss, 2015, 1-4.

[9] M Abbasi, M Gavell, M Ferndahl et al. An E-band(71–76, 81–86 GHz) balanced frequency tripler for high-speed communications, 1184-1187(2009).

[10] C S Yoo, S Song, K Seo. A W-band tripler with a novel band pass filter on thin-film substrate, 1-4(2008).