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An Example of Easy Synthesis of Active Filter and Oscillator using Signal Flowgraph Modification and Controllable Current Conveyors Cover

An Example of Easy Synthesis of Active Filter and Oscillator using Signal Flowgraph Modification and Controllable Current Conveyors

Journal of Electrical Engineering
Volume 62 (2011): Issue 5 (September 2011)
By: Roman Šotner,  Zdeněk Hruboš,  Břetislav Ševčík,  Josef Slezák,  Jiří Petržela and  Tomáš Dostál  
Open Access
|Oct 2011

References

  1. BIOLEK, D.—SENANI, R.—BIOLKOVA, V.—KOLKA, Z.: Active Elements for Analog Signal Processing: Classification, Review, and New Proposal, Radioengineering 17 No. 4 (2008), 15-32.
    Search in Google Scholar
  2. BIOLEK, D.—BIOLKOVA, V.—KOLKA, Z.: Universal Current-Mode OTA-C KHN Biquad, International Journal of Electronics, Circuits and Systems 1 No. 4 (2007), 214-217.
    Search in Google Scholar
  3. CHUNGUA, W.—LING, Z.—TAO, L.: A New OTA-C Current-Mode Biquad Filter with Single Input and Multiple Outputs, International Journal of Electronics and Communications AEU 62 (2008), 232-234.10.1016/j.aeue.2007.03.017
    Search in Google Scholar
  4. SOTNER, R.—PETRZELA, J.—SLEZAK, J.: Current-Controlled Current-Mode Universal Biquad Employing Multi-Output Transconductors, Radioengin. 18 No. 3 (2009), 285-294.
    Search in Google Scholar
  5. WANG, C.—ZHAO, Y.—ZHANG, Q.—DU, S.: A New Current Mode SIMO-Type Universal Biquad Employing Multi-Output Current Conveyors (MOCCIIs), Radioengineering 18 No. 1 (2008), 83-88.
    Search in Google Scholar
  6. SOTNER, R.—SLEZAK, J.—DOSTAL, T.—PETRZELA, J: Universal Tunable Current-Mode Biquad Employing Distributed Feedback Structure with MO-CCCII, Journal of Electrical Engineering 61 No. 1 (2010), 52-56.10.2478/v10187-010-0007-6
    Search in Google Scholar
  7. MINAEI, S.—SAYIN, O. K.—KUNTMAN, H.: A New CMOS Electronically Tunable Current Conveyor and its Application to Current-Mode Filters, IEEE Transaction on Circuits and Systems I - Regular papers 53 No. 7 (2006), 1448-1457.10.1109/TCSI.2006.875184
    Search in Google Scholar
  8. KOTON, J.—HERENCSAR, N.—CICEKOGLU, O.—VRBA, K.: Current-Mode KHN Equivalent Frequency Filter using ECCIIs, Proceedings of the 33th International Conference on Telecommunications and Signal Processing - TSP 2010, Baden - Austria, 2010, pp. 27-30.
    Search in Google Scholar
  9. MARCELLIS, A.—FERRI, G.—GUERRINI, N. C.—SCOTTI, G.—STORNELLI, V.—TRIFILETTI, A: The VGC-CCII: a Novel Building Block and its Application to Capacitance Multiplication, Analog Integrated Circuits and Signal Processing 58 No. 1 (2009), 55-59.10.1007/s10470-008-9213-6
    Search in Google Scholar
  10. KESKIN, A.—BIOLEK, D: Current Mode Quadrature Oscillator using Current Differencing Transconductance Amplifiers (CDTA), IEE Proceedings - Circuits, Devices and Systems 153 No. 3 (2006), 214-217.10.1049/ip-cds:20050304
    Search in Google Scholar
  11. BIOLEK, D.—KESKIN, A.—BIOLKOVÁ, V.: Quadrature Oscillator using CDTA-Based Integrators, WSEAS Transactions on Electronics 3 No. 9 (2006), 463-469.
    Search in Google Scholar
  12. PROKOP, R.—MUSIL, V.: Modular Approach to Design of Modern Circuit Blocks for Current Signal Processing and New Device CCTA, Proceedings of the Seventh IASTED International Conference on Signal and Image Processing, 2005, pp. 494-499.
    Search in Google Scholar
  13. PROKOP, R.—MUSIL, V.: New Modular Current Devices for True Current Mode Signal Processing, Electronics 16 No. 4 (2007), 36-42.
    Search in Google Scholar
  14. SIRIPRUCHYANUN, M.—JAIKLA, W.: Current Controlled Current Conveyor Transconductance Amplifier (CCCCTA): a Building Block for Analog Signal Processing, Electrical Engineering 90 No. 6 (2008), 443-453, Springer.
    Search in Google Scholar
  15. HERENCSAR, N.—VRBA, K.—KOTON, J.—LATTENBERG, I.: The Conception of Differential-Input Buffered and Transconductance Amplifier (DBTA) and its Application, IEICE Electronics Express 6 No. 6 (2009), 329-334.10.1587/elex.6.329
    Search in Google Scholar
  16. HERENCSAR, N.—KOTON, J.—VRBA, K.: Realization of current-Mode KHN-Equivalent Biquad using Current Follower Transconductance Amplifiers (CFTAs), IEICE Trans. Fundamentals E93-A No. 10 (2010), 1816-1819.10.1587/transfun.E93.A.1816
    Search in Google Scholar
  17. JERABEK, J.—VRBA, K.: SIMO Type Low-Input and High-Output Impedance Current-Mode Universal Filter Employing Three Universal Current Conveyors, International Journal of Electronics and Communications (AEU) 64 No. 6 (2010), 588-593.10.1016/j.aeue.2009.03.002
    Search in Google Scholar
  18. JERABEK, J.—SOTNER, R.—VRBA, K.: Fully-Differential Current Amplifier and its Application to Universal and Adjustable filter, International Conference on Applied Electronics. Plzeň: University of West Bohemia, 2010, pp. 141-144.
    Search in Google Scholar
  19. JERABEK, J.—VRBA, K.: Multiple-Input Multiple-Output Universal Filter using Current Followers, Proceedings of the 31th International Conference on Telecommunications and Signal Processing - TSP' 2008. Budapest, Hungary: Asszisztencia Szervezo Kft., 2008, pp. 29-32.
    Search in Google Scholar
  20. CHANG, C. M.: Current Mode Allpass/Notch and Bandpass Filter using Single CCII, Electronics Letters 27 No. 20 (1991, 1812-1813.10.1049/el:19911126
    Search in Google Scholar
  21. LIU, S.—KUO, J.—TSAY, J.: New CCII-Based Current-Mode Biquadratic Filters, International Journal of Electronics 72 No. 2 (1992), 243-252.
    Search in Google Scholar
  22. SHARMA, S.—RAJPUT, S. S.—PAL, K.—MANGOTRA, L. K.—JAMUR, S. S.: Low-Voltage CCII Based All-Pass/Notch Filter, Indian Journal of Pure and Applied Physics 44 No. 11 (2006), 871-874.
    Search in Google Scholar
  23. KUMAR, M.—SRISTAVA, M. C.—KUMAR, U.: Tunable Multifunctional Filter using Current Conveyor, International Journal of Computer Science and Information Security 8 No. 1 (2010), 95-98.
    Search in Google Scholar
  24. KUMAR, P.—PAL, K.: Variable Q All-Pass, Notch and Band-Pass Filters using Single CCII, Frequenz 59 No. 9-10 (2005), 235-239.10.1515/FREQ.2005.59.9-10.235
    Search in Google Scholar
  25. SOLIMAN, A. M.: New All-Pass and Notch Filters using Current Conveyors, Frequenz 53 No. 3-4 (1999), 84-86.10.1515/FREQ.1999.53.3-4.84
    Search in Google Scholar
  26. HIGASHIMURA, M.—FUKUI, Y.: Realization of All-Pass and Notch Filters using a Single Current Conveyor, International Journal of Electronics 65 No. 4 (1988, 823-828.10.1080/00207218808945282
    Search in Google Scholar
  27. MINAEI, S.—YUCE, E.—CICEKOGLU, O.: Electronically Tunable Multi-Input Single-Output Voltage-Mode Filter, Proceedings of the 2005 European Conference on Circuit Theory and Design, vol. 3, 2005, pp. III/401-III/404.
    Search in Google Scholar
  28. TANGSRIRAT, W.: Current-Tunable Current-Mode Multifunctional Filter Based on Dual-Output Current-Controlled Conveyors, International Journal of Electronics and Communications (AEU) 61 No. 8 (2007), 528-533.10.1016/j.aeue.2006.09.005
    Search in Google Scholar
  29. SOLIMAN, A. M.: Current-Mode Universal Filters Using Current Conveyors: Classification and Review, Circuits Systems and Signal Processing 27 No. 3 (2008), 405-427.10.1007/s00034-008-9034-y
    Search in Google Scholar
  30. PANDEY, N.—PAUL, S. K.—JAIN, S. B.: Voltage Mode Universal Filter using Two Plus Type CCIIs, Int. J. of Active and Passive Electronic Devices 3 No. 2 (2008), 165-173.
    Search in Google Scholar
  31. CHEN, H. P.: Single CCII-Based Voltage-Mode Universal Filter, Analog Integrated Circuits Signal Processing 62 No. 2 (2010), 259-262.10.1007/s10470-009-9345-3
    Search in Google Scholar
  32. LIU, S.—LEE, L.: Voltage-Mode Universal Filters using Two Current Conveyors, International Journal of Electronics 82 No. 2 (1997), 145-149.10.1080/002072197136147
    Search in Google Scholar
  33. ABUELMAATTI, M. T.—SHABRA, M. A.: A Novel Current-Conveyor-Based Universal Current-Mode Filter, Microelectronics Journal 27 No. 6 (1996), 471-475.10.1016/0026-2692(95)00108-5
    Search in Google Scholar
  34. HORNG, J. W.: Current Conveyors based Allpass Filters and Quadrature Oscillators Employing Grounded Capacitors and Resistors, Computers and Electrical Engineering 31 No. 1 (2005), 81-92.10.1016/j.compeleceng.2004.11.006
    Search in Google Scholar
  35. CHANG, C. M.: Novel Current-Conveyor-Based Single-Resistance-Controlled/Voltage-Controlled Oscillator Employing Grounded Resistors and Capacitors, Electronic Letters 30 No. 3 (1994), 181-183.10.1049/el:19940133
    Search in Google Scholar
  36. KUMAR, V.—PAL, K.: Single Element Controlled Sinusoidal Oscillators using Current Conveyors, Journal of Active and Passive Electronic Devices 4 No. 3 (2009), 197-202.
    Search in Google Scholar
  37. KUMAR, A.—VYAS, A. L.: A Single Resistance Controlled Eight Possible Oscillator Circuits for analog Signal Processing Applications, Academic Open Internet Journal 21 (2007), 1-7.
    Search in Google Scholar
  38. TOKER, A.—KUNTMAN, H.—CICEKOGLU, O.—DISCIGIL, M.: New Oscillator Topologies using Inverting Second-Generation Current Conveyors, Turk. J. Elec. Engin. 10 No. 1 (2002), 119-129.
    Search in Google Scholar
  39. SHEN-IUAN, LIU: Single-Resistance-Controlled/Voltage Controlled Oscillator using Current Conveyors and Grounded Capacitors, Electronic Letters 31 No. 5 (1995), 337-338.
    Search in Google Scholar
  40. AGGARWAL, V.: Novel Canonic Current Mode DDCC Based SRCO Synthesized using a Genetic Algorithm, Analog Integrated Circuits and Signal Processing 40 No. 1 (2004), 83-85.10.1023/B:ALOG.0000031437.64488.f7
    Search in Google Scholar
  41. SOLIMAN, A. M.: Current-Mode Oscillators using Single Output Current Conveyors, Microelectronics Journal 29 No. 11 (1998), 907-912.10.1016/S0026-2692(98)00053-6
    Search in Google Scholar
  42. SOLIMAN, A. M.: Synthesis of Grounded Capacitor and Grounded Resistor Oscillators, Journal of the Franklin Institute 336 No. 4 (1999), 735-746.10.1016/S0016-0032(98)00050-7
    Search in Google Scholar
  43. LAHIRI, A.: Additional Realization of Single-Element-Controlled Oscillators using Single ICCII-, International Journal of Computer and Electrical Engineering 1 No. 3 (2009), 303-306.10.7763/IJCEE.2009.V1.47
    Search in Google Scholar
  44. PANDEY, N.—PAUL, K.: A Novel Electronically Tunable Sinusoidal Oscillator based on CCCII (-IR), Journal of Active and Passive Electronic Devices 3 No. 2 (2008), 135-141.
    Search in Google Scholar
  45. HORNG, J. W.: A Sinusoidal Oscillator using Current-Controlled Current Conveyors, Int. Journal of Electronics 88 No. 6 (2001), 659-664.10.1080/00207210110044369
    Search in Google Scholar
  46. HORNG, J. W.—LIN, S.—YANG, CH.: Sinusoidal Oscillators using Current Conveyors and Grounded Capacitors, Journal of Active and Passive Electronic Devices 2 No. 2 (2007), 127-136.
    Search in Google Scholar
  47. ABUELMAATTI, M. T.: New Sinusoidal Oscillators with Fully Uncoupled Control of Oscillation Frequency and Condition using Three CCII+s, Analog Integrated Circuits and Signal Processing 24 No. 3 (2000), 253-261.10.1023/A:1008321911123
    Search in Google Scholar
  48. KHAN, A. A.—BIMAL, S.—DEY, K. K.—ROY, S. S.: Novel RC Sinusoidal Oscillator using Second-Generation Current Conveyor, IEEE Transaction on Instrumentation and Measurement 54 No. 6 (2005), 2402-2406.10.1109/TIM.2005.859141
    Search in Google Scholar
  49. MARTINEZ, P. A.—SABADELL, J.—ALDEA, C—CELMA, S.: Variable Frequency Sinusoidal Oscillators based on CCII+, IEEE Transaction on Circuits and Systems-I: Fundamental Theory and Applications 46 No. 11 (1999), 1386-1390.10.1109/81.802841
    Search in Google Scholar
  50. KILINC, S.—JAIN, V.—AGGARWAL, V.—CAM, U.: Catalogue of Variable Frequency and Single-Resistance-Controlled Oscillators Employing a Single Differential Difference Complementary Current Conveyor, Frequenz 60 No. 7-8 (2006), 142-146.10.1515/FREQ.2006.60.7-8.142
    Search in Google Scholar
  51. SOTNER, R.—HRUBOS, Z.—SLEZAK, J.—DOSTAL, T.: Simply Adjustable Sinusoidal Oscillator Based on Negative Three-Port Current Conveyors, Radioengineering 19 No. 3 (2010), 446-453.
    Search in Google Scholar
  52. Analog Devices. Monolithic Op Amp AD 844, 2003, 16 p. Available at: http://www.analog.com
    Search in Google Scholar
  53. MASON, S. J.: Feedback Theory: Further properties of Signal Flow Graphs, Proc. IRE 44 No. 7 (1956), 920-926.10.1109/JRPROC.1956.275147
    Search in Google Scholar
  54. SOTNER, R.—SLEZAK, J.—DOSTAL, T.: Electronically-Controlled Multifunctional Current Mode Filter based on Commercially Available Current Conveyors and Buffers, Proceedings of 19th International Conference Radioelektronika 2009, 2009, pp. 309-312.10.1109/RADIOELEK.2009.5158778
    Search in Google Scholar
  55. SOTNER, R.—SLEZAK, J.—DOSTAL, T.: Multifunctional Electronically Tunable Current Mode Biquad using Commercially Available Current Conveyors, Proceedings of the 16th International Conference Mixed Design Of Integrated Circuits And Systems MIXDES 2009, 2009, pp. 652-655.
    Search in Google Scholar
  56. Texas Instruments Inc. OPA 860 Wide Bandwidth Operational Transconductance Amplifier and Buffer, 2006, 32 p. Available at http://www.ti.com
    Search in Google Scholar
  57. Intersil (Elantec). EL 2082CN Current-Mode Multiplier, 1996, 16 p. Available at: http://www.intersil.com
    Search in Google Scholar
DOI: https://doi.org/10.2478/v10187-011-0041-z | Journal eISSN: 1339-309X | Journal ISSN: 1335-3632
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Language: English
Page range: 258 - 266
Published on: Oct 24, 2011
Published by: Slovak University of Technology in Bratislava
In partnership with: Paradigm Publishing Services
Publication frequency: 6 issues per year
Keywords:
frequency filters,
oscillators
Related subjects:
Engineering,
Introductions and overviews,
Engineering, other

© 2011 Roman Šotner, Zdeněk Hruboš, Břetislav Ševčík, Josef Slezák, Jiří Petržela, Tomáš Dostál, published by Slovak University of Technology in Bratislava
This work is licensed under the Creative Commons License.

Volume 62 (2011): Issue 5 (September 2011)