A new fast settling low power CMOS gain stage architecture

This paper presents a new gain stage for high accuracy and fast settling applications. In the proposed structure a novel combination of closed loop and open loop amplifiers is employed to achieve high accuracy and enhanced settling behavior while adding only negligible power to the main circuit power constraint. To evaluate the functionality of the proposed idea, a zero cross based circuit and a switch capacitor amplifier are designed to implement the open loop and the closed loop stages, respectively. Though, other topologies for implementation of open loop and closed loop amplifiers are applicable in the presented gain stage. The proposed structure is implemented in 0.18 μm CMOS technology. HSPICE simulation results, using level 49 models, demonstrate that the new configuration improves the power efficiency and the settling behavior as well as the system accuracy. The proposed scheme shows very fast settling times of 0.8, 1.01, 1.41 ns for the gain accuracies of 6, 8 and 10 bits, respectively, while loaded with 1 pF capacitance and the output swing is 1.6 V. In comparison with a conventional switched capacitor closed loop amplifier, the proposed architecture improves the settling performance by a factor of 3 for 6 bit resolution, while it adds only 0.63 mW power to the total power consumption that is 8.68 mW.     

An enhanced folded cascode Op-Amp using positive feedback and bulk amplification in 0.35 μm CMOS process

In this paper a new operational amplifier is presented which is based on the conventional folded cascode Op-Amp structure. A new method of positive feedback is used to increase dc-gain. This method does not limit the range of the output voltage swing. True performance of the Op-Amp in higher output voltage swings is another advantage of the proposed Op-Amp in comparison with the conventional structures. Bulk amplification and positive feedback are used to improve the Op-Amp specifications. Proposed structure has been simulated by HSPICE software using level 49 parameters (BSIM3v3) in a typical 0.35 μm CMOS technology. The HSPICE simulation confirms the theoretical estimated improvements.     

Efficient binary to quaternary and vice versa converters: embedding in quaternary arithmetic circuits

The Journal of Supercomputing - Reversible logic is a nowadays promising choice for circuit design technologies since it is having diversified applications in the fields of digital signal...     

A 110–140 GHz Millimeter-Wave VCO Using Varactor and Bulk Effective Technique in 65 nm CMOS Process

In this paper, an enhanced voltage controlled oscillator (VCO) at center frequency 125 GHz with tuning rang of 24% is presented. The proposed idea is based on the tuning capacitance using MOS varactor. The structure is consisted of applying an MOS varactor capacitor to the drain and bulk (in parallel) of NMOS transistor in 65 nm CMOS standard technology. The obtained output of the proposed VCO at 2nd harmonic is tunable at 110–140 GHz frequency with applying?±?1.2 input tuning voltage. Simulation results of the proposed circuit are obtained after extracting post layout (with total chip size of 0.07 mm²) and confirm theoretical results. Compared to the resent designs, the obtained results indicate that the proposed circuit has high tuning range, low die area and a good figure of merit @ 1.2 power supply voltage.

     

Chemical kinetics simulation of deposition and sp2/sp3 bond ratio of diamond-like carbon film in plasma

In this work a theoretical model for the simulation of diamond-like carbon (DLC) film deposition in thermal plasma will be investigated. A chemical kinetics model for the most important molecular processes occurring in the gas-phase and gas-surface will be presented. This investigation is focused on the molecular processes in the gas and the elementary interactions of activated gas species with the deposited surface. The model quantitatively predicts the kinetics concentration of important plasma activated species. Also the net rate of the production of gas, surface, and bulk phase species will be calculated. Finally the growth rate of DLC film and the sp²/sp³ growth ratio under different reactor conditions (temperature, gas flow rate and reactor pressure) will be calculated and verified with literature data.     

Amperometric detection of hydrogen peroxide at nano-nickel oxide/thionine and celestine blue nanocomposite-modified glassy carbon electrodes

A simple procedure was developed to prepare a glassy carbon (GC) electrode modified with nickel oxide (NiOx) nanoparticles and water-soluble dyes. By immersing the GC/NiOx modified electrode into thionine (TH) or celestine blue (CB) solutions for a short period of time (5–120 s), a thin film of the proposed molecules was immobilized onto the electrode surface. The modified electrodes showed stable and a well-defined redox couples at a wide pH range (2–12), with surface confined characteristics. In comparison to usual methods for the immobilization of dye molecules, such as electropolymerization or adsorption on the surface of preanodized electrodes, the electrochemical reversibility and stability of these modified electrodes have been improved. The surface coverage and heterogeneous electron transfer rate constants (k_s) of thionin and celestin blue immobilized on a NiOx-GC electrode were approximately 3.5 × 10⁻¹⁰ mol cm⁻², 6.12 s⁻¹, 5.9 × 10⁻¹⁰ mol cm⁻² and 6.58 s⁻¹, respectively. The results clearly show the high loading ability of the NiOx nanoparticles and great facilitation of the electron transfer between the immobilized TH, CB and NiOx nanoparticles. The modified electrodes show excellent electrocatalytic activity toward hydrogen peroxide reduction at a reduced overpotential. The catalytic rate constants for hydrogen peroxide reduction at GC/NiOx/CB and GC/NiOx/TH were 7.96 (±0.2) × 10³ M⁻¹ s⁻¹ and 5.5 (±0.2) × 10³ M⁻¹ s⁻¹, respectively. The detection limit, sensitivity and linear concentration range for hydrogen peroxide detection were 1.67 μM, 4.14 nA μM⁻¹ nA μM⁻¹ and 5 μM to 20 mM, and 0.36 μM, 7.62 nA μM⁻¹, and 1 μM to 10 mM for the GC/NiOx/TH and GC/NiOx/CB modified electrodes, respectively. Compared to other modified electrodes, these modified electrodes have many advantages, such as remarkable catalytic activity, good reproducibility, simple preparation procedures and long-term stabilities of signal responses during hydrogen peroxide reduction.     

Development of Al- and Cu-based nanocomposites reinforced by graphene nanoplatelets: Fabrication and characterization

Aluminum and copper matrix nanocomposites reinforced by graphene nanoplatelets (GNPs) were successfully fabricated by a wet mixing method followed by conventional powder metallurgy. The uniform dispersion of GNPs within the metal matrices showed that the wet mixing method has a great potential to be used as a mixing technique. However, by increasing the GNPs content, GNPs agglomeration was more visible. DSC and XRD of Al/GNPs nanocomposites showed that no new phase formed below the melting point of Al. Microstructural observations in both nanocomposites reveal the evident grain refinement effect as a consequence of GNPs addition. The interfacial bonding evaluation shows a poor interfacial bonding between GNPs and Al, while the interfacial bonding between Cu and GNPs is strong enough to improve the properties of the Cu/GNPs nanocomposites. In both composites, the coefficient of thermal expansion decreases as a function of GNPs while, their hardness is improved by increasing the GNPs content as well as their elastic modulus.     

Numerical and experimental investigation on the breast cancer tumour parameters by inverse heat transfer method using genetic algorithm and image processing

This study presents numerical and experimental investigation on breast cancer tumour parameters by inverse heat transfer method using genetic algorithm (GA) and image processing (IP) to determine the depth and rate of heat generation of a breast cancer tumour. To simulate the problem, using the energy equation in a cylinder including a heater, the surface temperature distribution was obtained. Then, the temperature surface of the cylinder was analysed by the GA in MATLAB software to determine the depth and rate of heat generation of heater. The validity of the numerical method was evaluated using the IP from a laboratory sample. A thermal heater was placed inside a cylinder and was covered by a tissue similar to the human body tissue. According to the obtained results, it was determined that the results of the laboratory sample and the numerical method were in agreement with each other. Finally, these steps were applied on the thermal image of a patient’s cancer breast to determine the depth and rate of heat generation of the breast tumour. It is shown that the average computational error between numerical and experimental results in this method to determine the depth of the tumour is about 8–10% and to determine the rate of tumour heat generation is about 0.01–1%.