دانشگاه سمنان

 آمار

تعداد نشریات21
تعداد شماره‌ها610
تعداد مقالات9,028
تعداد مشاهده مقاله67,082,918
تعداد دریافت فایل اصل مقاله7,656,373
Rahimzadeh, Nima, Rezaei, Pejman. (1401). Wideband Balun-LNA Employing gm-Boosting Feedback Technique and CBLD Circuit for Digital Televisions Tuner Application. نشریه هنرهای کاربردی, 2(2), 9-15. doi: 10.22075/mseee.2022.26789.1095
Nima Rahimzadeh; Pejman Rezaei. "Wideband Balun-LNA Employing gm-Boosting Feedback Technique and CBLD Circuit for Digital Televisions Tuner Application". نشریه هنرهای کاربردی, 2, 2, 1401, 9-15. doi: 10.22075/mseee.2022.26789.1095
Rahimzadeh, Nima, Rezaei, Pejman. (1401). 'Wideband Balun-LNA Employing gm-Boosting Feedback Technique and CBLD Circuit for Digital Televisions Tuner Application', نشریه هنرهای کاربردی, 2(2), pp. 9-15. doi: 10.22075/mseee.2022.26789.1095
Rahimzadeh, Nima, Rezaei, Pejman. Wideband Balun-LNA Employing gm-Boosting Feedback Technique and CBLD Circuit for Digital Televisions Tuner Application. نشریه هنرهای کاربردی, 1401; 2(2): 9-15. doi: 10.22075/mseee.2022.26789.1095

Wideband Balun-LNA Employing gm-Boosting Feedback Technique and CBLD Circuit for Digital Televisions Tuner Application

Modeling and Simulation in Electrical and Electronics Engineering
دوره 2، شماره 2 - شماره پیاپی 8، آبان 2022، صفحه 9-15    اصل مقاله (554.51 K)
نوع مقاله: Research Paper
شناسه دیجیتال (DOI): 10.22075/mseee.2022.26789.1095
نویسندگان
Nima Rahimzadeh؛ Pejman Rezaei*
Department of Communications, Faculty of Electrical and Computer Engineering, Semnan University, Semnan, Iran.
تاریخ دریافت: 17 فروردین 1401،  تاریخ بازنگری: 22 خرداد 1401،  تاریخ پذیرش: 21 شهریور 1401 
چکیده
A balun Low Noise Amplifier (Balun-LNA) with technique of gm-boosting feedback and a modified current bleeding (CBLD) circuit is proposed for application in the tuner of digital television (DTV) and other wideband radio and microwave receivers. Using the technique of gm-boosting feedback causes input impedance matching to not just depend on the CG transistor, and input impedance matching is satisfied by the transconductance of CG and CS transistors. Therefore, the transconductance of the CG transistor increases to boost the differential voltage gain of Balun-LNA and decrease its NF. Also, a modified current bleeding circuit is used in the CS stage in order to make the CS transistor have higher transconductance and its output current be identical to the output current of the CG stage. To compensate for having identical output currents, symmetrical loads are used in differential output so that they cause the gain and phase balance at the differential output. This Balun-LNA is built on 90-nm CMOS technology and operates in the digital television frequency band of 48 to 864 MHz. This Balun-LNA achieves a maximum differential voltage gain of 24 dB, an input return loss of less than -10 dB, and a minimum NF of 5 dB. This Balun-LNA works at 2.8 v nominal supply voltage and consumes the power of 2.5 mW.
کلیدواژه‌ها
Balanced output؛ Balun-LNA؛ Low power consumption؛ Noise Cancelling؛ Symmetrical loads؛ Digital television tuner
مراجع
  1. Im, I. Nam and K. Lee. A CMOS active feedback balun-LNA with high IIP2 for wideband digital TV receivers. IEEE Trans. Microw. Theory Techn. 58(12), pp. 3566-3578, 2010.
  2. Wang, L. Zhang and Zh. Yu. A wideband inductorless LNA with local feedback and noise cancelling for low-power low-voltage applications. IEEE Trans. Circ. Syst. -I: Regular Papers. 57(8), 2010.
  3. Im, O. Lee and I. Nam. A TV Receiver Front-End with Linearized LNA and Current-Summing Harmonic Rejection Mixer. IEEE Trans. Circuits Syst. II. 64(3), pp. 269-273, 2017.
  4. Guo, D. Prevedelli, R. Castello, and D. Manstretta, A 0.008 mm2 1-6.2 GHz Receiver Front-End with Inverter–Base Shunt-Feedback Balun-LNA. IEEE Radio Frequency Integrated Circuits Symposium, 2020.
  5. Bevilacqua, A. and Niknejad, A. M. An Ultra-Wideband CMOS Low-Noise Amplifier for 3.1 - 10.6-GHz Wireless Receivers,” IEEE J. Solid-State Circuits, vol. 39, no. 12, pp. 2259-2267, 2004.
  6. Bagheri, et al. An 800-MHz–6-GHz software-defined wireless receiver in 90-nm CMOS. IEEE J. Solid-State Circ. 41(12), pp. 2260-2262, 2006.
  7. Hotti, et al. An IIP2 Calibration Techniques for Direct Conversion Reveivers. IEEE Int. Symp. Circuits and Syst, pp. 257-258, 2004.
  8. Svensson. The Blocker Challenge When Implementing Software Defined Radio Receiver RF Frontends. Analog Integr. Circuits Signal Processing, pp. 81-82, 2010.
  9. Ryynanen, et al. A Dual-Band RF Front-End for WCDMA and GSM Applications. IEEE J. Solid-State Circuits. 36(8), pp. 1198-1199, 2001.
  10. I. Mak and R. P. Martins. A 0.46-mm2 4-Db NF unified receiver front-end for full-band mobile TV in 65-nm CMOS. IEEE J. Solid-State Circ. 46(9), 2011.
  11. Jang, S. Park and D. Im, A PVT Insensitive Noise Canceling Balun-LNA for TV Receiver Application. Progress in Electromagnetics Research Symposium-Fall (PIERS-FALL). pp.1726-1728, 2017.
  12. Mastantuono, and D. Manstretta, A Low-Noise Active Balun with IM2 Cancellation for Multiband Portable DVB-H Receivers. IEEE Int. Solid-State Circuits Conf. pp. 215-217, 2009.
  13. Im, I. Nam and S.S. Song. A CMOS resistive feedback single to differential low noise amplifier with multiple-tuner-outputs for a digital TV tuner. IEEE Radio Freq. Integr. Circuits symp. pp. 555-558, 2009.
  14. Jin, T.Y. Oh, K.T. Hong, H.T. Kim and B. Kim. Wide-Band CMOS Loop-Through Amplifier for Cable TV Tuner. IEEE Radio Freq. Integr. Circuits Symp. pp. 215-218, 2008.
  15. Kwon, H.T. Kim and K. Lee, A 50-300-MHz highly linear and low-noise CMOS Gm-C filter adopting multiple gated transistors for digital TV tuner ICs., Trans. Microw. Theory Techn. 57(2), pp. 306-312, 2009.
  16. Vitee, H. Ramiah, P. I. Mak, and R. P. Martins. A 3.15-mW +16.0-dBm IIP3 22-dB CG inductively source degenerated balun-LNA mixer with integrated transformer-based gate inductor and IM2 injection technique. IEEE Trans. Very Large Scale Integration Syst. 28(3), pp. 700-710, 2020.
  17. H. Chen, et al. A highly linear broadband CMOS LNA employing noise and distortion cancellation. IEEE J. Solid-State Circ. 43(5), pp. 1164-1173, 2008.
  18. El-Nozahi, et al. A CMOS low-noise amplifier with reconfigurable input matching network. IEEE Trans. Microw. Theory Techn. 57(5), pp. 1054-1059, 2009.
  19. Koizumi, et al. A GaAs single balanced mixer MMIC with built-in active balun for personal communication systems. IEEE Microw. Millimeter-Wav. Monolithic Circ. Symp. pp. 77-79, 1995.
  20. -K. Chen, et al. 5.8-GHz merged LNA-mixer with on-chip balun. Microw. Opt. Technol. Lett. 48(3). pp. 508-511, 2006.
  21. Ch. Kuo, Ch. N. Kuo and T. Ch. Chueh. Wideband LNA compatible for differential and single-ended inputs. IEEE Microw. Wirel. Compon. Lett. 19(7), pp. 482-484, 2009.
  22. A. Martins, et al. A single-to-differential LNA topology with robust output gain-phase balancing against balun imbalance. IEEE Int. Sym. Circ. Syst. (ISCAS). pp. 289-291, 2011.
  23. Joo, et al. A 3-to-5 GHz UWB LNA with a low-power balanced active balun. IEEE Radio Freq. Integr. Circ. Symp. pp. 303-306, 2009.
  24. Liu, et al. A 0.061-mm2 1-11GHz noise-cancelling low-noise amplifier employing active feedforward with simultaneous current and noise reduction. IEEE Trans. Microw. Theory Techn. 69(6), pp. 3093-3104, 2021.
  25. Masihi, P. Rezaei and M. Panahi. Compact chip-resistor loaded active integrated patch antenna for ISM band applications. Wirel. Pers. Commun. 97(4), pp. 5738-5746, 2017.
  26. Valizadeh, P. Rezaei and A.A. Orouji, Design of reconfigurable active integrated microstrip antenna with switchable low-noise amplifier/power amplifier performance for wireless local area network and WiMAX applications. IET Microw. Antennas Propag. 9(9), pp. 874-881, 2015.
  27. Valizadeh, P. Rezaei, and A.A. Orouji, A new design of dual-port active integrated antenna for 2.4/5.2 GHz WLAN applications. Prog. Electromag. Res. B. 58, pp. 86-94, 2014.
  28. Rahimzadeh and P. Rezaei. A balun-LNA employing positive feedback and modifies current-bleeding technique and symmetrical loads for tuner of digital televisions. 3rd Iranian Conf. Microelectron. Tarbiat Modares University, Dec. 2021 (in Persian).
  29. Rahimzadeh and P. Rezaei. Decreasing power consumption of BLNA with balanced output with gm boosting feedback for application of tuner of digital televisions. 6th Conf. Elec. and Comput. Eng. Tech., Tafresh University, March 2022. (in Persian).
  30. Bozorg and R.B. Staszewski. A 20 MHz-2 GHz inductorless two-fold noise-canceling low-noise amplifier in 28-nm CMOS. IEEE Trans. Circ. Syst. I: Regular Papers, vol. 69(1), pp. 42-50, 2022.
  31. Tiwari, and J. Mukherjee, An inductorless noise cancelling wideband balun LNA with dual shunt feedback and current reuse. IEEE 62nd Int. Midwest Symp. Circ. Syst. pp. 432-435, 2019.
  32. Chang, et al. ESD-protected wideband CMOS LNAs using modified resistive feedback techniques with chip-on-board packaging,” IEEE Trans. Microw. Theory Techn., vol. 56, no. 8, pp. 1817-1819, 2008.
  33. Ma, et al. Novel active differential phase splitters in RFIC for wireless applications. IEEE Radio Freq. Integr. Circ. Symp., pp. 51-52, June 1998.
  34. Bruccoleri, EA and M. Klumperink. Wide-Band CMOS Low-Noise Amplifier Exploiting Thermal Noise Canceling. IEEE J. Solid-State Circ. 39(2), pp. 275-277, 2004.
  35. C. Blaakmeer, et al. Wideband balun-LNA with simultaneous output balancing, noise-canceling and distoryion-canceling. IEEE J. Solid-State Circ. 43(6), pp. 1341-1347, 2008.
  36. Kim and J. Silva-Martinez, Wideband Inductorless Balun-LNA Employing Feedback for Low-Power Low-Voltage Applications. Trans. Microw. Theory Techn. 60(9), 2012.
  37. Kim and K. Kwon. (2019, Feb.). A 50-MHz–1-ghz 2.3-dB NF Noise-cancelling Balun-LNA Employing a Modified Current-Bleeding Technique and Balanced loads,” IEEE Trans. Circuits Syst. I: Regular Papers. 66(2), pp. 546–554.
  38. Kim and K. Kwon. Broadband balun-LNA employing local feedback gm-boosting technique and balanced loads for low-power low-voltage applications. Trans. Circ. Syst. I. 67(12), pp. 4631-4640, 2020.
  39. Yi, Ch. Liu and J. Sh. Chen. A wideband inductorless single-to-differential LNA in 0.18µm CMOS technology for digital TV receivers. IEEE Microw. Wirel. Compon. Lett. 24(7), 2014.
  40. Blaakmeer, E. Klumperink, D. Leenaerts and B. Nautra, A Wideband Balun LNA I/Q-Mixer Combination in 65nm CMOS. IEEE Int. Solid-State Circ. Conf. pp. 326-328, 2008.
  41. ShirMohammadi and M. Yavari. A low power wideband balun-LNA employing local feedback, modified current-bleeding technique, and balanced loads. 28th Iranian Conf. Elec. Eng. (ICEE), Aug. 2020.
  42. Manstretta. A broadband low-power low-noise active balun with second-order distortion cancellation,” IEEE J. Solid-State Circ. 47(2), 2012.
  43. Kim, et al. A broadband PVT-insensitive all-nMOS noise-cancelling balun-LNA for subgigahertz wireless communication applications. IEEE Microw. Wirel. Compon. Lett. 31(2), pp. 165-167, 2021.
  44. Tiwari and J. Mukherjee. An inductorless wideband gm-boosted balun LNA with nMOS-pMOS configuration and capability coupled loads for sub-GHz IOT applications. IEEE Trans. Circ. Syst. II: Express Briefs. 68(10), pp. 3204-3207, 2021.
  45. Liu, Zh. Lu, K. Zhang, Zh. Ren, A. Hu and X. Zou. Wideband balun-LNA exploiting noise cancellation and gm compensation technique. Electron. Lett. 52(8), pp. 673-674, 2016.
  46. Borremans, et al. Low-area active-feedback low-noise amplifier design in scaled digital CMOS. IEEE J. Solid-State. 43(11), pp. 2422-30, 2008.
  47. Kim, S. Hoyos and J. Silva-Martinez. Wideband common-gate CMOS LNA employing dual negative feedback with simultaneous noise, gain, and bandwidth optimization. Trans. Microw. Theory Techn. 58(9), 2010.
  48. Afshar, and A.M. Niknejad, X/Ku band CMOS LNA design techniques. IEEE Custom Integr. Circ. Conf. pp. 389-390, 2006.
  49. Woo, et al. A 3.6 mW differential common-gate CMOS LNA with positive-negative feedback. IEEE Int. Solid-State Circ. Conf., pp. 217-219, Feb. 2009.
آمار
تعداد مشاهده مقاله: 358
تعداد دریافت فایل اصل مقاله: 221


سامانه مدیریت نشریات علمی. قدرت گرفته از سیناوب