基于小波包分析的心磁信号消噪

心磁图(Magnetocardiography)是一种无创性记录和分析心脏电磁场的方法.由于心磁场强度极其弱小,必须使用超导量子干涉仪(SQUID)才能检测,其中心磁信号消噪处理十分重要.本文对心磁测量中的消噪进行了研究,在小波分析的基础上,提出使用小波包分析方法消噪,通过实验发现小波包分析消噪能获得很好的效果.     

基于隐马尔科夫模型的汉语韵律词基频模型

提出了一种基于隐马尔科夫模型(HMM)的汉语韵律词的统计基频模型。模型能反映韵律环境和基频曲线参数之间的映射关系,从模型可以估计一段基频曲线和一段文本之间的相关度,也可以从文本生成相应的基频曲线。本方法使用HMM作为基木框架,具有HMM理论体系所能支配的各种优点。同时将韵律作为模型单元,使得模型能够反映韵律层次级的连续变调。最后给出了实验结果并对模型的应用前景进行了展望。     

Diode-pumped 671 nm laser frequency doubled by CPM LBO

A design of diode-pumped high-efficiency Nd:YVO₄/LBO red laser is reported. Using critical phase-matching (CPM) LBO, 671 nm red laser was obtained from 1342 nm light by intracavity frequency doubling. With an incident pump laser of 800 mW, using type-I and type-II CPM LBO, 97 and 52 mWTEM₀₀ mode red laser outputs were obtained, with optical-to-optical conversion efficiencies of up to 12.1% and 6.5%, respectively.     

对中学物理"难学难教"现象分析

中学物理“难学难教”似乎己成为多数物理教师和学生的共识，那么物理“难学难教”的涵义是什么？中学物理包括初中物理和高中物理，是不是初中物理和高中物理都存在“难学难教”的现象？笔者做过一次问卷调查，调查对象为初中的初二、初三两个年级学生和高中的高一、高二、高三三个年级学生．调查的内容是：在数学、物理、化学三科中，你认为哪一科最难学？哪一科比较难学？哪一科容易学？认为物理最难、比较难、容易的三项统计结果如表1所示。     

非化学配比锰基钙钛矿输运特性研究

本文报道了用溶胶凝胶法并经过低温(900℃)后处理制备的具有非化学配比的La2/3Ca1/3Mn1-xO3(x=0～0.10)多晶样品的电输运和磁性质的实验研究.结果表明,随x的增加,样品呈现出明显增强的非本征磁电阻效应,同时其本征磁电阻效应减弱.实验还观察到样品的颗粒尺寸随x的增加而减小的现象.基于样品的结构特征,本文讨论了其独特输运性能的形成原因.     

制冷机冷却型小型超导强磁场系统的研制

介绍了一套制冷机冷却型小型超导强磁场系统。超导磁体线圈用铌钛超导线绕制,室温孔直径为75mm,磁场中心Φ25mm×250mm区域内最高场强达到3.64T,磁场不均匀性小于3%。在2.62T场强下连续闭环运行了20天,电流衰减率近似为零。采用4K级低温制冷机冷却防辐射冷屏,液氦蒸发率小于0.03升/小时,系统一次可注入液氦50升,补液周期大于60天。     

Two-axis-scanning laser Doppler vibrometer for precision engineering

Laser Doppler vibrometer (LVD) has been the most favorite instrument for precision dynamics measurement due to its non-contact, high accuracy and high resolution. However, LDV can only give the dynamic data of a particular location on the entire feature. In order to get the whole field data, a laser beam-scanning mechanism has to be implemented. Currently, motor-driven scanning mirror is used to move the measurement probe from one point to another. The mechanical vibrations of the scanning mirror will reduce the measurement accuracy. This paper introduces a novel scanning LDV optical system embodied in an acousto-optic deflector scanning mechanism. It can improve the measurement accuracy since there is no mechanical motion involved. One main advantage of this system is that it generates a laser scanning beam in parallel that is different from the beam scanning in the conventional scanning laser Doppler vibrometer (SLDV). The new system has a board scanning range. The measurement target size ranges from few tens of millimeters down to 10 μm. We have demonstrated the capability of the novel system on scanning measurements of features as big as ultra-precision cutting tool to features as tiny as AFM cantilever. We believe that the novel SLDV will find profound potential applications in the precision engineering field.     

Ar2H+ 分子振动光谱的理论计算

基于近期由本组提供的Ar2 H+ 分子的基态势能面 ,应用含时波包演化方法 ,计算了总角动量J =0时的振动光谱 ,并对其中的一些谱峰进行了指认 .与现有的abinitio结果进行比较 ,这个新势能面包含了关于Ar2 H+ 基态的比较正确的信息     

Driven production of cold antihydrogen and the first measured distribution of antihydrogen states

Cold antihydrogen is produced when antiprotons are repeatedly driven into collisions with cold positrons within a nested Penning trap. Efficient antihydrogen production takes place during many cycles of positron cooling of antiprotons. A first measurement of a distribution of antihydrogen states is made using a preionizing electric field between separated production and detection regions. Surviving antihydrogen is stripped in an ionization well that captures and stores the freed antiproton for background-free detection.     

Background-free observation of cold antihydrogen with field-ionization analysis of its states

A background-free observation of cold antihydrogen atoms is made using field ionization followed by antiproton storage, a detection method that provides the first experimental information about antihydrogen atomic states. More antihydrogen atoms can be field ionized in an hour than all the antimatter atoms that have been previously reported, and the production rate per incident high energy antiproton is higher than ever observed. The high rate and the high Rydberg states suggest that the antihydrogen is formed via three-body recombination.