Enhanced Face Recognition Method Performance on Android vs Windows Platform

Android is becoming one of the most popular operating systems on smartphones, tablet computers and similar mobile devices. With the quick development in mobile device specifications, it is worthy to think about mobile devices as current or - at least - near future replacement of personal computers. This paper presents an enhanced face recognition method. The method is tested on two different platforms using Windows and Android operating systems. This is done to evaluate the method and to compare the platforms. The platforms are compared according to two factors: development simplicity and performance. The target is evaluating the possibility of replacing personal computers using Windows operating system by mobile devices using Android operating system. Face recognition has been chosen because of the relatively high computing cost of image processing and pattern recognition applications comparing with other applications. The experiment results show acceptable performance of the method on Android platform

Optimum wavelength for oxygen detection using optical absorption

Oxygen gas detection systems are used in many areas such as environment, clinical, food and automotive industries. Most of the detection systems are based on chemical absorption sensing method. This type of sensing method has their own drawbacks. Therefore, a development of a new oxygen sensor using an optical method is necessary as an alternative to the current sensors. A preliminary study on the molecular absorption cross section for oxygen gas is vital to determine the optimum wavelength is reported. The experimental setup consists of four major components which are light source, gas cell, detector and optical fibre cable. For the light source, a deuterium-halogen bulb will be used as it can provide a broadband wavelength light source from 215 nm - 2500 nm. A miniature spectrometer will be used as the detector and the gas cell is connected to the light source and detector using the optical fibre cables. A software package to display absorption of oxygen molecules is installed in a computer to study on the optimum wavelength. The experiment results show that the light is most absorbed at 230 nm and absorption is increased by cell length. The highest absorption was observed to be in a 100 cm gas cell length with pressurized 5 bar of 99% pure oxygen gas. Based on this result, a wavelength of 230 nm is selected as optimum wavelength to detect oxygen

Effects of downscaling channel dimensions on electrical characteristics of InAs-FinFET transistor

In this paper, we present the impact of downscaling of nano-channel dimensions of Indium Arsenide Fin Feld Effect Transistor (InAs- FinFET) on electrical characteristics of the transistor, in particular; (i) ION/IOFF ratio, (ii) Subthreshold Swing (SS), Threshold voltage (VT), and Drain-induced barrier lowering (DIBL). MuGFET simulation tool was utilized to simulate and compare the considered characteristics based on variable channel dimensions: length, width and oxide thickness. The results demonstrate that the best performance of InAs- FinFET was achieved with channel length = 25 nm, width= 5 nm, and oxide thickness between 1.5 to 2.5 nm according to the selected scaling factor (K = 0.125)

Terpaksa catu belangkas untuk santapan pelanggan

Page 3

Characterization of silicon nanowire transistor

This paper analyses the temperature sensitivity of Silicon Nanowire Transistor (SiNWT) depends on the diameter (D.ch) of channel. In addition, it also investigates the possibility of utilizing SiNWT as a Nano- temperature sensor. The MuGFET simulation tool has been utilized to conduct a comprehensive simulation to evaluate both electrical and temperature characteristics of SiNWT. Current-voltage characteristics with different values of temperature and with a varying diameter of the Nano wire channel (D.ch = 80, 40, 20 and 10 nm), were simulated. Diode operating mode connection of the transistor is suggested for measuring the temperature sensitivity of SiNWT. As simulation results demonstrated, the best temperature sensitivity was occurred at lower temperature with increasing the channel diameter. We also illustrate the impact of varying temperature and channel diameter on electrical characteristics of SiNWT including, Subthreshold Swing (SS), Threshold voltage (V.th), and Drain-induced barrier lowering (DIBL), which were proportionally increased with the operating temperature

A novel approach for improving material stiffness using a direct method in below-knee prosthetic sockets

The conventional techniques for producing a socket are time-consuming disproportionate to the significant population afflicted by limb amputations. Although the new manufacturing direct method, the modular socket system (MSS) method, involves reduced labor time, the technique produces sockets with high stiffness that cause discomfort for those with lower limb amputations during walking. This study investigated the tensile characteristics of numerous materials in below-knee prosthetic sockets. Initially, a vacuum molding approach was used to produce the sockets, which involved various polymers and composite materials to improve the prosthesis socket properties. An F-socket device was also employed to ensure efficient production and optimized pressure distribution at the interface between the socket and the residual limb. A SOLIDWORKS® software was then applied to determine the numerical analysis (stress distribution and the maximum internal pressure). The samples from Group E involved utilizing a novel mixture compared to the direct and traditional methods of various materials. This study presents a novel prosthetic limb socket made from a mixture of four carbon fiber layers, utilizing 20% polyurethane resin and 80% acrylic as the matrix. The resulting material demonstrated acceptable stiffness, extended socket life, and reduced curing time. During the patient's gait cycle, peak pressure of 300 KPa was recorded using the F-socket, while SOLIDWORKS® software indicated an internal pressure of 343 KPa, aligning closely with F-socket measurements. The new direct-fit socket design prioritizes comfort and flexibility using materials with reduced stiffness

Electrical Сharacterization of Ge-FinFET Transistor Based on Nanoscale Channel Dimensions

Nano-electronic applications have benefited enormously from the great advancement in the emerging Nano-technology industry. The tremendous downscaling of the transistors’ dimensions has enabled the placement of over 100 million transistors on a single chip thus reduced cost, increased functionality and enhanced performance of integrated circuits (ICs). However, reducing size of the conventional planar transistors would be exceptionally challenging due to leakages electrostatics and other fabrication issues. Fin Field Effect Transistor (FinFET) shows a great potential in scalability and manufacturability as a promising candidate and a successor to conventional planar devices in nanoscale technologies. The structure of FinFET provides superior electrical control over the channel conduction, thus it has attracted widespread interest of researchers in both academia and industry. However, aggressively scaling down of channel dimensions, will degrade the overall performance due to detrimental short channel effects. In this paper, we investigate the impact of downscaling of nano-channel dimensions of Germanium Fin Feld Effect Transistor (Ge-FinFET) on electrical characteristics of the transistor, namely; ION/IOFF ratio, Subthreshold Swing (SS), Threshold voltage (VT), and Drain-induced barrier lowering (DIBL). MuGFET simulation tool was utilized to conduct a simulation study to achieve optimal channel dimensions by considering channel length (L), width (W), and oxide thickness (TOX) individually. In addition, the effects of simultaneous consideration of all dimensions by exploiting a scaling factor, K was evaluated. According to the obtained simulation results, the best performance of Ge-FinFET was achieved at a minimal scaling factor, K 0.25 with 5 nm channel length, 2.5 nm width, and 0.625 nm oxide thickness

Investigation of single segment side-polished optical fiber sensor for shoulder joint monitoring

Shoulder monitoring is an important stage in the diagnosis and treatment process of affected patients. Current devices available in the clinical environment for this application are focusing on flexible ruler or manual goniometer, which are prone to measurement error. Alternative approaches including accelerometer, magnetometer, strain sensor and inertial measurement unit (IMU) are subject to reading error, susceptible to output drift, has bulky overall size and difficult to be attached on the human body (via adhesive or garment). To solve this issue, this paper presents the use of an optical fiber sensor (OFS) based on intensity modulation technique via single segment side-polished fiber. Based on the experimental study, the proposed method can be utilized to measure an angle between 0deg. and 90 deg. Additional optical sensors can be added to increase the sensor's range of motion that is sufficient for shoulder joint measurement

A Verification Of Periodogram Technique For Harmonic Source Diagnostic Analytic By Using Logistic Regression

A harmonic source diagnostic analytic is vital to identify the root causes and type of harmonic source in power system. This paper introduces a verification of periodogram technique to diagnose harmonic sources by using logistic regression classifier. A periodogram gives a correct and accurate classification of harmonic signals. Signature recognition pattern is used to distinguish the harmonic sources accurately by obtaining the distribution of harmonic and interharmonic components and the harmonic contribution changes. This is achieved by using the significant signature recognition of harmonic producing load obtained from the harmonic contribution changes. To verify the performance of the propose method, a logistic regression classifier will analyse the result and give the accuracy and positive rate percentage of the propose method. The adequacy of the proposed methodology is tested and verified on distribution system for several rectifier and inverter-based loads

Topical corticosteroids in clinical practice

Topical corticosteroids are common medications prescribed for skin problems encountered in the primary care or dermatology clinic settings. As skin conditions comprise of around 20% of cases seen in primary care, this article written to guide readers, especially non-dermatologists on the appropriate potency of topical corticosteroids to be chosen for skin problems of patients and to list the side effects both local and systemic