An Investigation of How Wavelet Transform can Affect the Correlation Performance of Biomedical Signals : The Correlation of EEG and HRV Frequency Bands in the frontal lobe of the brain

© 2018 by SCITEPRESS – Science and Technology Publications, Lda. All rights reservedRecently, the correlation between biomedical signals, such as electroencephalograms (EEG) and electrocardiograms (ECG) time series signals, has been analysed using the Pearson Correlation method. Although Wavelet Transformations (WT) have been performed on time series data including EEG and ECG signals, so far the correlation between WT signals has not been analysed. This research shows the correlation between the EEG and HRV, with and without WT signals. Our results suggest electrical activity in the frontal lobe of the brain is best correlated with the HRV.We assume this is because the frontal lobe is related to higher mental functions of the cerebral cortex and responsible for muscle movements of the body. Our results indicate a positive correlation between Delta, Alpha and Beta frequencies of EEG at both low frequency (LF) and high frequency (HF) of HRV. This finding is independent of both participants and brain hemisphere.Final Published versio

BcB_{c} →{\to} BPBP, BVBV decays with the QCD factorization approach

We studied the nonleptonic $B_{c}$ ${\to}$ $BP$, $BV$ decay with the QCD factorization approach. It is found that the Cabibbo favored processes of $B_{c}$ ${\to}$ $B_{s}{\pi}$, $B_{s}{\rho}$, $B_{u}\bar{K}$ are the promising decay channels with branching ratio larger than 1\%, which should be observed earlier by the LHCb Collaboration.Comment: 15 pages, revtex4, version appeared in Advances in High Energy Physic

A Low-Power Low-Voltage Bandgap Reference in CMOS

Bandgap reference plays a substantial role in integrated circuit. Traditionally, it provides a constant reference voltage of 1.2051/ for other blocks in the circuit while itself is independent of temperature and power supply. However, the development of CMOS technology has brought us into a new era of high integration and ultra-low power consumption. As the gate length scales down, it is crucial to build circuits that are able to work under a very low voltage power supply, for instance, lower than the bandgap voltage of 1.205V. Building bandgap circuits to generate the conven­ tional bandgap voltage under a low voltage power supply such as 1.2V or IV is no longer practical nor useful. Thus, bandgap references working under low-voltage and consuming low-power is becoming the trend of research and development nowadays. In this thesis work, the potential structure of a low-voltage low-power bandgap reference is proposed, which is based on extracting a current that is a fraction of the traditional bandgap voltage. All the necessary blocks are designed to achieve the high accuracy bandgap reference, including bandgap core circuit, op-amp, start-up circuit and output stage. As a result, the designed bandgap reference is able to work under 1.2V power supply and provides an output reference voltage of 584.7mV. It has a variation of only 244.38fiV for the temperature range of 0°C ~ 125°C and has a variation of only 1.1mV for a power supply range of 1.08V ~ 1.32V. The layout design for the bandgap reference structure is also done carefully at the late stage, with an area of 100fj,m x 85¡xm

Excitation functions of parameters extracted from three-source (net-)proton rapidity distributions in Au-Au and Pb-Pb collisions over an energy range from AGS to RHIC

Experimental results of the rapidity spectra of protons and net-protons (protons minus antiprotons) emitted in gold-gold (Au-Au) and lead-lead (Pb-Pb) collisions, measured by a few collaborations at the alternating gradient synchrotron (AGS), super proton synchrotron (SPS), and relativistic heavy ion collider (RHIC), are described by a three-source distribution. The values of the distribution width $\sigma_C$ and contribution ratio (relative contribution) $k_C$ of the central rapidity region, and the distribution width $\sigma_F$ and rapidity shift $\Delta y$ of the forward/backward rapidity regions, are then obtained. The excitation function of $\sigma_C$ increases generally with increase of the center-of-mass energy per nucleon pair $\sqrt{s_{NN}}$. The excitation function of $\sigma_F$ shows a saturation at $\sqrt{s_{NN}}=8.8$ GeV. The excitation function of $k_C$ shows a minimum at $\sqrt{s_{NN}}=8.8$ GeV and a saturation at $\sqrt{s_{NN}}\approx 17$ GeV. The excitation function of $\Delta y$ increase monotonously with $\ln \sqrt{s_{NN}}$ in the considered energy range.Comment: 19 pages, 8 figures, The European Physical Journal A, accepte