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A novel dual-BJT avalanche pulse generator with mixer effect

Published online by Cambridge University Press:  19 January 2023

Emrah Telli Open the ORCID record for Emrah Telli [Opens in a new window]  and
Bahad׀r S. Y׀ld׀r׀m Open the ORCID record for Bahad׀r S. Y׀ld׀r׀m [Opens in a new window]
Emrah Telli
Affiliation:
Electrical and Electronics Engineering Department, Muğla S׀tk׀ Koçman University, 48000 Kötekli-Muğla, Türkiye
Bahad׀r S. Y׀ld׀r׀m*
Affiliation:
Electrical and Electronics Engineering Department, Muğla S׀tk׀ Koçman University, 48000 Kötekli-Muğla, Türkiye
*
Author for correspondence: Bahad׀r S. Y׀ld׀r׀m, E-mail: bahadir.yildirim@mu.edu.tr
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Abstract

This paper presents a novel, simple, and efficient pulse generation technique using BJTs in avalanche mode with mixer effect. The presented design is an improved version of the basic single transistor avalanche pulse generator, and it composes of two identical pulse generators that drive a common 50-Ω load resistor at the output. The output signal exhibits wider bandwidth and narrower pulsewidth, compared to the basic single transistor circuit. The presented pulse generator also provides increased power output without using any power amplifier, and can be used in ground-penetrating radar and ultra-wideband communication systems.

Keywords

Avalanche effect transistorspulse generatorsmixers
Type
Frequency Mixers
Information
International Journal of Microwave and Wireless Technologies , Volume 15 , Special Issue 8: EuCAP 2022 Special Issue , October 2023 , pp. 1319 - 1326
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Copyright
© The Author(s), 2023. Published by Cambridge University Press in association with the European Microwave Association

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References

Omurzakov, A, Keskin, AK and Turk, AS (2016) Avalanche transistor short pulse generator trials for GPR. 2016 8th Int. Conf. Ultrawideband Ultrashort Impuls. Signals, IEEE, Odessa, Ukraine, pp. 201–204.10.1109/UWBUSIS.2016.7724188CrossRefGoogle Scholar
Wang, L, Zhang, A and Shi, Z (2020) A high voltage pulse generator used in ground penetrating radar. 2020 IEEE MTT-S Int. Wirel. Symp., IEEE, Shanghai, China, pp. 1–3.10.1109/IWS49314.2020.9360129CrossRefGoogle Scholar
Wang, Q, Tian, X, Liu, Y, Li, B and Gao, B (2008) Design of an ultra-wideband pulse generator based on avalanche transistor. 2008 4th Int. Conf. Wirel. Commun. Netw. Mob. Comput., IEEE, Dalian, China, pp. 1–4.10.1109/WiCom.2008.263CrossRefGoogle Scholar
Wu, Q and Tian, W (2010) Design of electronic circuits of nanosecond impulser based on avalanche transistor. Proc – 2010 11th Int Conf Electron PackagTechnol High Density Packag ICEPT-HDP (2010), IEEE, Xi'an, China pp. 774–777. https://doi.org/10.1109/ICEPT.2010.5582702.CrossRefGoogle Scholar
Wong Choi, G, Joo Choi, J and Hoon Han, S (2011) Note: Picosecond impulse generator driven by cascaded step recovery diode pulse shaping circuit. Review of Scientific Instruments 82, 16106.10.1063/1.3523342CrossRefGoogle Scholar
Protiva, P, Mrkvica, J and Macháč, J (2010) A compact step recovery diode subnanosecond pulse generator. Microwave and Optical Technology Letters 52, 438440.10.1002/mop.24945CrossRefGoogle Scholar
Valizade, A, Rezaei, P and Orouji, AA (2017) A compact reconfigurable sub-nanosecond pulse generator with pulse-shape modulation. International Journal of Microwave and Wireless Technologies 9, 741745.10.1017/S1759078716000921CrossRefGoogle Scholar
Yin, Q, Pan, Z and Zhang, Z (2018) Design of a high-performance ultra-wideband monocycle pulse generator. 2018 Int. Conf. Mech. Electron. Control Autom. Eng. (MECAE 2018), Atlantis Press, Qingdao, China.10.2991/mecae-18.2018.34CrossRefGoogle Scholar
Guo, Y and Zu, G (2014) Novel design and implementation of ultra-wideband pulse generator based on avalanche transistor. Sess 1P0 2014, PIERS Proceedings, Guangzhou, China.Google Scholar
Razavi, B, Aytur, T, Lam, C, Yang, F-R, Li, K-Y, Yan, R-H, Kang, H-C, Hsu, C-C and Lee, C-C (2005) A uwb cmos transceiver. IEEE Journal of Solid-State Circuits 40, 25552562.10.1109/JSSC.2005.857430CrossRefGoogle Scholar
Arafat, MA and Harun-ur-Rashid, ABM (2012) A novel 7 Gbps low-power CMOS ultra-wideband pulse generator. IET Circuits, Devices & Systems 6, 406412.10.1049/iet-cds.2012.0057CrossRefGoogle Scholar
Xia, X, Liu, L, Guan, H and Fang, G (2013) Balanced pulse generator for ultra-wideband radar application. Electronics Letters 49, 293295.10.1049/el.2012.4186CrossRefGoogle Scholar
Ameri, AAH, Kompa, G and Bangert, A (2011) Balanced pulse generator for UWB radar application. 2011 8th Eur. Radar Conf., IEEE, Manchester, United Kingdom, pp. 198–201.Google Scholar
Sim, S, Kim, D-W and Hong, S (2009) A CMOS UWB pulse generator for 6–10 GHz applications. IEEE Microwave and Wireless Components Letters 19, 8385.Google Scholar
Ahajjam, Y, Aghzout, O, Catala-Civera, JM, Peñaranda-Foix, F and Driouach, A (2020) Two-stage design of high power UWB monocycle generator for radar sensor applied in the fourth industry revolution. Procedia Manufacturing 46, 730737.10.1016/j.promfg.2020.03.103CrossRefGoogle Scholar
Chadderton, N (1996) The ZTX415 avalanche mode transistor. Zetex Application Note 8, 19.Google Scholar
Dias, JAS (2005) On the avalanche multiplication mechanism in SPICE simulations of high-frequency bipolar transistors with thin basewidths and low breakdown voltages. AEU – International Journal of Electronics and Communications 59, 483485.10.1016/j.aeue.2005.01.010CrossRefGoogle Scholar