Single VDCC-based electronically tunable voltage-mode second order universal filter

• Autorzy: Uttaphut P.

Identyfikatory

DOI

10.15199/48.2018.04.06

Warianty tytułu

PL

Uniwersalny strojony filtr drugiego rzędu wykorzystujący technologię VDC

• Języki publikacji: EN

Abstrakty

EN

A design of second-order multiple-input single-output voltage-mode universal filter is presented in this paper. The proposed filter consists of single voltage differencing current conveyor (VDCC), single resistor and two capacitors. The new circuit provides five filter responses namely, lowpass, high-pass, band-pas, band-reject and all-pass functions. Each output filter response can be selected without the requirement of the matching condition and double gain amplifier for selecting all-pass function. The tuning of natural frequency and quality factor can be electronically done. The proposed circuit only uses single active element, which can be easily implemented as an integrated circuit. The MOS modeling of VDCC and Pspice simulation of proposed filter were carried out on TSMC 0.18 micrometer CMOS technology

PL

Opisano uniwersalny filtr drugiego rzędu wykorzystujący układ VDCC (voltage differencing current conveyor). Częstotliwość graniczną filtru i jego dobroćmoga być dobierane elektronicznie. Zaproponowany filtr opracowano w technologii CMOS 0.18 mikrometra.

Słowa kluczowe

EN

VDCC; universal biquad; analog circuit; electronic control; active filter; commercially available IC

PL

układ VDCC; filtr; strojenie filtru

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2018
• Tom: R. 94, nr 4
• Strony: 22--25
• Opis fizyczny: Bibliogr. 27 poz., rys., wykr.

Twórcy

autor

Uttaphut P.

• Department of Electrical Technology, Faculty of Industrial Technology, Suan Sunandha Rajabhat University, Dusit, Bangkok, 10300, Thailan

Bibliografia

• [1] Sedra, A. S., Smith, K. C., Microelectronic circuits. 3rd ed., Florida: Holt, Rinehart and Winston, 1991
• [2] Jaikla, W., Khateb, F., Siripongdee, S., Supavarasuwat, P., Suwanjan, P., Electronically tunable current-mode biquad filter employing CCCDTAs and grounded capacitors with low input and high output impedance, AEU - International Journal of Electronics and Communications, 67 (2013); n 12, 1005-1009
• [3] Ninsraku, W., Biolek, D., Jaikla, W., Siripongdee, S., Suwanjan, P., Electronically controlled high input and low output impedance voltage mode multifunction filter with grounded capacitors, AEU - International Journal of Electronics and Communications, 68 (2014), n 12, 1239-1246
• [4] Kinnaree, P., Sa-Ngiamvibool, W., Current-mode multi-input single-output filter based on CCCDTAs, Przegląd Elektrotechniczny, 93 (2017), n 3, 201-206
• [5] Biolek, D., Senani, R., Biolkova, V., Kolka, Z., Active elements for analog signal processing, classification, review and new proposals, Radioengineering, 17 (2008), n. 4, 15-32
• [6] Siripongdee, S., Jaikla, W., Electronically controllable grounded inductance simulators using single commercially available IC: LT1228, AEU - International Journal of Electronics and Communications, 76 (2017); 1-10
• [7] Khateb, F., Jaikla, W., Kumngern, M., Prommee, P., Comparative study of sub-volt differential difference current conveyors, Microelectronics Journal, 44 (2014), n 12, 12781284
• [8] Sotner, R., Jerabek, J., Herencsar, N., Zak, T., Jaikla, w., Vrba, K., Modified current differencing unit and its application for electronically reconfigurable simple first-order transfer function, Advances in Electrical and Computer Engineering, 15 (2015), n 1, 3-10
• [9] Jantakun, A., The configuration of Current-Mode Single-Input Multi-Output, Multi-Input Single-Output biquad filter and quadrature oscillator Based-On BiCMOS CCCTAs, Przegląd Elektrotechniczny, 93 (2017), n 7, 102-107
• [10] Kacar, F., Yesil, A., Minaei, S., Kuntman, H., Positive/negative lossy/lossless grounded inductance simulators employing single VDCC and only two passive elements, AEU-International Journal of Electronics and Communications, 68 (2014), n 1, 7378
• [11] Prasad, D., Ahmad, J., New electronically-controllable lossless synthetic floating inductance circuit using single VDCC, Circuits and Systems, 5 (2014), 13-17
• [12] Kartci, A., Ayten, U. E., Sotner, R., Arslanalp, R., Electronically tunable VDCC-based floating capacitance multiplier, 23rd Signal Processing and Communications Applications Conference, (2015), 2474-2477
• [13] Kartci, A., Ayten, U. E., Herencsar, R., Sotner, R., Jerabek, J., Vrba, K., Floating capacitance multiplier simulator for grounded RC colpitts oscillator design, International Conference on Applied Electronics, (2015), 93-96
• [14] Srivastava, M. Bhanja, Mir, S. F., A new configuration for simulating passive elements in floating state employing VDCCs and grounded passive elements, IEEE-International Conference on Power Electronics, Intelligent Control and Energy Systems, (2016), 13-18
• [15] Kartci, A., Ayten, U. E., Herencsar, N., Sotner, R., Jerabek, J., Vrba, K., Application possibilities of VDCC in general floating element simulator circuit, European Conference on Circuit Theory and Design, 2015.
• [16] Sotner, R., Jerabek, J., Herencsar, N., Dostal, T., Vrba, K., Design of Z-copy controlled-gain voltage differencing current conveyor based adjustable functional generator. Microelectronics Journal, 46 (2015), n 2, 143-152.
• [17] Prasad, D., Bhaskar, D. R., Srivastava, M., New single VDCCbased explicit current-mode SRCO employing all grounded passive components, Electronics, 18 (2014), n 2, 81-88
• [18] Sotner, R., Jerabek, J., Prokop, R., Kledrowetz V., Simple CMOS voltage differencing current conveyor-based electronically tunable quadrature oscillator, Electronics Letters, 52 (2016), n 12, 1016-1018
• [19] Sotner, R., Jerabek, J., Petrzela, J., Dostal, T., Voltage differencing current conveyor based linearly controllable quadrature oscillators, 21st International Conference on Applied Electronics, (2016), 237-240
• [20] Satipar, D., Intani, P., Jaikla, W., Electronically tunable quadrature sinusoidal oscillator with equal output amplitudes during frequency tuning process, Journal of Electrical and Computer Engineering, (2017), Article ID 8575743
• [21] Sotner, R., Herencsar, N., Jerabek, J., Vrba, K., Dostal, T., Jaikla, W., Metin, B., Novel first-order all-pass filter applications of z-copy voltage differencing current conveyor, Indian Journal of Pure and Applied Physics, 53 (2015), n 8, 537-545
• [22] Prasad, D., Ahmad, A., Shukla, A., Mukhopadhyay, A., Sharma, B. B., Srivastava, M., Novel VDCC based low-pass and high-pass ladder filters, 12th IEEE International Conference Electronics, Energy, Environment, Communication, Computer, Control, (2016)
• [23] Lamun, P., Phatsornsiri, P., Torteanchai U., Single VDCCbased current-mode universal biquadratic filter, 7th International Conference on Information Technology and Electrical Engineering, (2015), 122-125
• [24] Jerabek, J., Sotner, R., Polak, J., Vrba, K., Dostal, T., Reconnection-less electronically reconfigurable filter with adjustable gain using voltage differencing current conveyor, Elektronika ir Elektrotechnika, 22 (2016), n 6, 39-45
• [25] Sagbras, M., Ayten, U. E., Koksal, M., Herencsar, N., Electronically tunable universal biquad using a single active component, 38th International Conference on Telecommunications and Signal Processing, (2015), 698-702
• [26] Kacar, F., Yesil, A., Gurkan, K., Design and experiment of VDCC-based voltage mode universal filter, Indian Journal of Pure and Applied Physics, 53 (2015), n 5, 341-349
• [27] Minaei, S., Yuce, E., Novel voltage-mode all-pass filter based on using DVCCs, Circuits, Systems, and Signal Processing, 29 (2010), 391–40

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).