In this article, a fully programmable membership function generator (MFG) is proposed. This MFG is capable of generating triangular, trapezoidal as well as both S-shaped and Z-shaped membership functions simultaneously. Utilizing a differential pair as an analog switch leads to relax the design of fuzzy systems control part. This MFG has the ability of adapting itself with various fuzzy controllers which produce different control voltage ranges. Unlike the available reported literatures, this MFG uses a new analog programmable current mirror (APCM) instead of digitally programmable current mirrors to adjust the slopes of membership functions. Extensive time domain simulations have been carried out using Hspice by level 49 parameters (BSIM3v3) in standard CMOS technology to validate the effective performance of the proposed MFG.
A wide-angle, dual-polarized frequency selective rasorber (FSR) with two absorption bands located at both sides of a passband is proposed. The structure comprises a lossy frequency selective surface (FSS), a bandpass FSS, and an air spacer located in between. A modified electric field coupled (ELC) resonator is used as a parallel resonance at the lossy layer to achieve a passband within the absorption band. The characteristic mode theory is utilized to investigate the absorption behavior of the lossy layer. Extensive simulations were carried out to assess the performance of the presented structure. Under the normal incidence, the proposed structure provides an operating bandwidth (|S11| < −10 dB) from 1.94 to 7.16 GHz, corresponding to a fractional bandwidth (FBW) of 114.7%. The achieved passband is around 4.3 GHz with a minimum insertion loss of 0.81 dB. The absorption bands with an absorption rate higher than 80% are 1.81–3.69 GHz (FBW of 68.4%) in the lower band and 4.95–7.43 GHz (FBW of 40%) in the upper band, respectively. It exhibits quite stable characteristics up to 50° angle of incidence. Furthermore, a prototype was fabricated and measured, which confirms that a good agreement exists between the experimental and simulation results. The proposed FSR is a suitable candidate for lowering the radar cross section (RCS) of the communication equipment or making them stealthy.
As threshold voltage of CMOS transistors is the main parameter that takes effect from process variations, in this paper a novel method for corner detection is presented which senses the variations of fabrication process through threshold voltage of the devices. A new general purpose 2-input, 2-output, 25 rules, ANFIS based fuzzy controller is proposed to compensate the variations subsequently. In this controller novel structures are presented for each block including membership function generator, Min-Max selector and defuzzifier. As an application, bias points of comparators of a typical flash ADC are controlled through introduced system in order to compensate the process variation effects and minimizing total power consumption consequently. Due to differential structures used in the architecture of the blocks, major part of the power supply noise is rejected. The Hspice (level 49) simulation results are given using a generic 0.35 lm standard CMOS technology parameters and power supply of 3.3 V with total power consumption of 15.6 mW for 7.4 MFLIPS. Because of simple and symmetrical circuitry, layout of the proposed controller is very compact, about 410 lm 9 210 lm.
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