A novel electronically tunable high input impedance voltage-mode multifunction filter with single inputs and three outputs employing two single-output-operational transconductance amplifiers, one differential difference current conveyor and two capacitors is proposed. The presented filter can be realized the highpass, bandpass and lowpass functions, simultaneously. The input of the filter exhibits high input impedance so that the synthesized filter can be cascaded without additional buffers. The circuit needs no any external resistors and employs two grounded capacitors, which is suitable for integrated circuit implementation.

Despite the extensive literature on current conveyor-based universal (namely, low-pass, band-pass, high-pass, notch, and all-pass) biquads with three inputs and one output, no filter circuits have been reported to date which simultaneously achieve the following seven important features: (i) employment of only two current conveyors, (ii) employment of only grounded capacitors, (iii) employment of only grounded resistors, (iv) high-input and low-output impedance, (v) no need to employ inverting type input signals, (vi) no need to impose component choice conditions to realize specific filtering functions, and (vii) low active and passive sensitivity performances. This letter describes a new voltage-mode biquad circuit that satisfies all the above features simultaneously, and without trade-offs.

Despite the extensive literature on current conveyor-based voltage-mode universal biquads with single input and multiple outputs, no filter circuits have been reported to date which simultaneously achieve all of the advantageous features: (i) employment of only one differential difference current conveyor (DDCC), (ii) employment of only two grounded capacitors, (iii) employment of only three resistors, (iv) simultaneous realization of voltage-mode low-pass, band-pass, and high-pass filter signals from the three output terminals, respectively, (v) no need to employ inverting type input signals, and (vi) no need to impose component choice.

Despite the extensive literature on current conveyor-based voltage-mode first-order all-pass filters, no filter circuits have been reported to date that simultaneously achieve all of the advantageous features: (i) the employment of only one current conveyor, (ii) the employment of only one grounded capacitor, (iii) the employment of only one resistor, (iv) no need to impose component choice conditions, and (v) low active and passive sensitivities. In this letter, we describe such a filter structure with all of the above features simultaneously present, without trade-offs. H-Spice simulation results using the TSMC025 process and 1.25 V supply voltages validate the theoretical predictions.

In this paper, a novel CMOS defuzzification circuit using dual-output current conveyors (DO-CCII) is introduced. The behaviour of the proposed circuit has been verified with PSPICE using the models for 1.2 µm MIETEC CMOS process. The proposed circuit offers high-speed operation and high accuracy because of using second generation current conveyors (CCII). The designed circuit is suitable for fuzzy logic controllers using center of gravity (COG) defuzzification method.

A new current-mode (CM) multifunction filter with single input and three outputs (SITO) employing only three dual output current conveyors (DO-CCII) and four passive elements is presented. The proposed filter realizes three basic filter functions simultaneously all at high impedance outputs. No component matching is required and all the passive and active sensitivities are low.

This letter describes new active building blocks defined as the generalized voltage conveyor (GVC) and the generalized current conveyor (GCC). A very simple practical realization of the GVC using the second generation current conveyors (CCII) is given. The special cases of the first generation voltage conveyor (VCI) and the second generation voltage conveyor (VCII) are also considered. A practical realization of the GCC using the CCII is also given. Applications of the voltage and current conveyors in oscillators are considered.

This letter presents a realization of active current-mode resonator with complex coefficients using CCIIs. The resonator can be used for cascade or leapfrog configuration of high-order bandpass filters with complex coefficients. For realizing the resonators, only the grounded capacitors and the grounded resistors as passive elements are required, therfore the resonator is suitable for the integrated circuit realization. The letter shows that the response error of the proposed circuit caused by nonideality of active components is more easily compensated than that of voltage-mode counterpart. Experimental result is used for verifying the feasibility of the proposed resonator.

This paper treats the synthesis of immittance floatator using nullors. Eight sets of circuit equations for realizing immittance floatators and their nullor (nullator-norator) representations are given. By replacing nullors with active elements such as biporlar junction transistors (BJTs), current conveyors (CCIIs), operational amplifiers (OAs) and operational transconductance amplifiers (OTAs), the immittance floatators can be derived. The development is important because it enables one to convert the present wealth of knowledge concerning grounded immittance simulation networks into floating immittance simulation networks. Using immittance floatators, we can obtain not only the floating form of 1-port but also that of 2-port networks. Novel circuits use solely minus-type norators. Using one-type (minus- or plus-type) norators greatly simplifies the simulation circuit. In the case of an immittance floatator using CCIIs as the active elements, the effects of nonideal CCIIs and sensitivities are given. Many circuits can be systematically derived using nullor technique.