All-Pass Filter IC Design and Its Cascaded Second-Order and Third-Order All-Pass Filters and Quadrature Sinusoidal Oscillator Applications

This study presents the design and application of a cascaded voltage-mode (VM) first-order all-pass filter (APF) integrated circuit (IC) based on a positive differential current conveyor (DDCC+). The proposed single- and differential-input VM-APF uses two DDCC+ active components and two passive comp...

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Bibliographic Details
Published inIEEE access Vol. 12; pp. 78040 - 78057
Main Authors Chen, Hua-Pin, Wang, San-Fu, Ku, Yitsen, Chen, Liang-Yen, Liu, Tzu-Yi
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Analog circuits
analogue signal processing
circuit design
Circuit synthesis
CMOS chip
CMOS technology
Current conveyors
Electric potential
filters
Impedance
Integrated circuits
Noise measurement
Oscillators
Passive components
Power consumption
Power demand
Quadratures
Semiconductor device measurement
Signal processing
Sine waves
System-on-chip
Transfer functions
Voltage
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Summary:This study presents the design and application of a cascaded voltage-mode (VM) first-order all-pass filter (APF) integrated circuit (IC) based on a positive differential current conveyor (DDCC+). The proposed single- and differential-input VM-APF uses two DDCC+ active components and two passive components consisting of a grounded capacitor and a resistor. Both non-inverting APF (NAPF) and inverting APF (IAPF) transfer functions of VM-APF can be implemented without any critical passive component matching condition. The proposed first-order VM-APF can realize both NAPF and IAPF transfer functions with high-input and low-output (HILO) impedance, which makes it suitable for cascading without any voltage buffer. Owing to the VM-APF with HILO impedance configuration, the proposed circuit can quickly cascade nth-order VM-APF without adding additional circuit architectures. The circuit is implemented on-chip based on TSMC 1P6M 180 nm process technology with a supply voltage of ±0.9 V. The first-order VM-APF power consumption is 1.8 mW. Integrating a first-order VM-APF into a single chip can improve system integration efficiency, reduce voltage and power consumption, and shrink circuit size. On-chip measurements verify the cascading feasibility of the proposed first-order VM-APF and demonstrate that the implemented chip can be easily cascaded for second- and third-order VM-APFs and VM APF-based quadrature sinusoidal oscillator applications.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2024.3404925