Your search keyword '"Antonio Fanelli"' showing total 3 results

1. A PWM Nie-Tan Type-Reducer Circuit for a Low-Power Interval Type-2 Fuzzy Controller

Author

Lester A. Faria, Gabriel Antonio Fanelli de Souza, and Rodrigo Bispo dos Santos

Subjects

low-power, General Computer Science, Reducer, General Engineering, Interval (mathematics), Type (model theory), Fuzzy logic, Power (physics), TK1-9971, fuzzy hardware, Control theory, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, Analog integrated circuits, interval type-2 fuzzy logic, Pulse-width modulation, Mathematics

Abstract

A novel Type-Reduction/Defuzzification circuit architecture for an analog interval type-2 fuzzy inference system is proposed. Based on the Nie-Tan type-reduction method, the circuit operates with current-mode inputs, representing the firing intervals of the rules created by the inference engine, and generating a PWM output. It is demonstrated that by selecting an appropriate number of consequents it is possible to create the PWM output directly, without the need for analog multiplier/divider circuits. This feature makes the circuit very simple, aiding in the design process, while the PWM output makes it suitable for controlling DC-DC converters, maximum power point trackers (MPPT) for energy generators, or other switching applications. It is designed to achieve very low power consumption, allowing its use in power restrained environments, such as energy harvesting systems. The circuit was designed using TSMC $0.18~\mu \text{m}$ technology, in CADENCE Virtuoso software, and simulated for different combinations of input values, demonstrating its capabilities. It was also simulated as part of a type-2 fuzzy inference system with two inputs, nine rules, and firing intervals represented by currents within 0 and $10~\mu \text{A}$ . The circuit was prototyped, and the experimental average power consumption was only $53.8~\mu \text{W}$ , validating its low power consumption characteristic.

Published

2021

2. Low-Power Current-Mode Interval Type-2 Fuzzy Inference Engine Circuit.

Author

de Souza, Gabriel Antonio Fanelli, dos Santos, Rodrigo Bispo, and de Abreu Faria, Lester

Subjects

*DIFFERENTIAL amplifiers, *FUZZY sets, *EQUALIZERS (Electronics), *POWER resources, *WIRELESS power transmission

Abstract

A novel strategy for implementation of an analog current-mode interval type-2 fuzzy inference engine circuit with low-power consumption is presented. Previous current-mode architectures rely on minimum/maximum circuits, using current mirrors to perform bounded-difference operations or winner-take-all circuits to mirror the appropriate current among the inputs. It means that currents representing the membership degrees of input fuzzy sets may need to be copied several times to obtain the firing levels of each rule. To avoid this drawback, the proposed method uses high-gain differential amplifiers, operating with low bias currents, as comparators, creating digital signals that indicate the largest/smallest current. It allows digital gates to determine directly which of the currents from the membership degree generator circuits represent the correct solution to the overall inference process. The methodology for developing the system and obtaining the logical expressions is presented. Simulations show that a traditional implementation using min/max circuits presented in the literature consumes 4.4 times more power than the proposed architecture. The circuit was prototyped in TSMC 0.18- $\mu \text{m}$ technology and its functionality demonstrated by the correct generation of the consequents firing levels. The measured power consumption was 413.42 $\mu \text{W}$ , including the power from the fuzzifier circuits, with a power supply of 1.2 V. [ABSTRACT FROM AUTHOR]

Published

2019

3. A PWM Nie-Tan Type-Reducer Circuit for a Low-Power Interval Type-2 Fuzzy Controller

Author

Gabriel Antonio Fanelli de Souza, Rodrigo Bispo Dos Santos, and Lester de Abreu Faria

Subjects

Analog integrated circuits, fuzzy hardware, interval type-2 fuzzy logic, low-power, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

A novel Type-Reduction/Defuzzification circuit architecture for an analog interval type-2 fuzzy inference system is proposed. Based on the Nie-Tan type-reduction method, the circuit operates with current-mode inputs, representing the firing intervals of the rules created by the inference engine, and generating a PWM output. It is demonstrated that by selecting an appropriate number of consequents it is possible to create the PWM output directly, without the need for analog multiplier/divider circuits. This feature makes the circuit very simple, aiding in the design process, while the PWM output makes it suitable for controlling DC-DC converters, maximum power point trackers (MPPT) for energy generators, or other switching applications. It is designed to achieve very low power consumption, allowing its use in power restrained environments, such as energy harvesting systems. The circuit was designed using TSMC $0.18~\mu \text{m}$ technology, in CADENCE Virtuoso software, and simulated for different combinations of input values, demonstrating its capabilities. It was also simulated as part of a type-2 fuzzy inference system with two inputs, nine rules, and firing intervals represented by currents within 0 and $10~\mu \text{A}$ . The circuit was prototyped, and the experimental average power consumption was only $53.8~\mu \text{W}$ , validating its low power consumption characteristic.

Published

2021