基于平面声全息的全空间场变换:Ⅱ.水下大面积平面发射声基阵的近场声全息实验

研制了一套多通道水声声全息测量系统,解决了多通道系统的校准及弱散射水听器接收线阵的设计等问题。在非消声水池内,利用该系统对水下大面积平面发射声基阵进行了近场声全息实验,给出了声基阵表面的声强分布、声基阵各阵元及全阵的辐射声功率、基阵远场空间指向性图和指向性参数等。实验结果证明脉冲法和分区扫描数据合成的测量方法是可行的,实验系统的设计与实施方法可用于更大规模的声全息系统。     

采用分级聚焦波束形成的快速声成像算法

为了减小常规波束形成所需的庞大计算量以实现快速成像,本文提出了一种新的波束形成算法——分级聚焦波束形成。将基阵划分成各级子阵分级进行处理,对较短的子阵进行远场近似处理,逐级合并子阵进行子阵间的近场聚焦波束形成,并逐级进行波束插值。MAT- LAB仿真计算结果表明,分级聚焦法与常规波束形成相比,计算量和数据存储量大幅下降。该方法尤其适用于多焦点近场聚焦的场合。     

水听器线列阵近场声压测量误差实验研究

本文介绍了用于近场声压的测量水听器中阵元水听器测量声压的可靠性检验方法和实验结果,提出了元水听器测量球面波场中声传播衰减的曲线与现想球面波声场中场传播衰减的曲线对比的检验,要用球面声源声中心测量值对收发距离进行修正的方法,实验水池中对线列阵上十元水吸器在球形声源水池中进行了传播衰减曲线的测量分析,验证了基阵的弱散散射性能,表明线阵可用于距离小至1／7波长的极近场的扫描测量。     

水声共形阵辐射指向性计算方法及其实验验证

用边界元方法,给出了水声发射换能器共形阵各阵元的单元指向性以及基阵的自然波束指向性和束控波束指向性。首先建立了换能器共形阵的边界元模型,并根据换能器结构和声传播介质建立了模型的边界条件,计算了其辐射指向性。然后在消声水池中对共形阵各阵元以及基阵的辐射指向性进行了实验测量。将理论计算结果与实验测量结果进行了对比,二者吻合得比较好。研究结果表明:基于边界元方法建立的模型及计算方法,对基阵的辐射指向性进行理论计算和预报是可行的。     

大角度波束扫描的宽带平面阵研究

本文中介绍了一个可以实现大角度波束扫描的宽带平面声基阵,设计了纵向振动与换能器前盖板弯曲振动相复合的宽带换能器作为基元,保证了基阵具有较好的宽带性能。针对基元的自然指向性难以满足平面阵进行大角度波束扫描的要求,本文中采用通道型橡胶反声障板技术来拓宽阵上换能器的单元指向性,从而实现平面声基阵的大角度、宽带波束扫描。在有限元和边界元进行优化设计的基础上,制作了实验样阵。测试数据表明:在工作频段内换能器响应起伏不超过3 dB,12 kHz时阵上基元指向性达到了140°,基阵-3 dB波束覆盖范围可以达到144.4°,最大旁瓣不超过30%。     

宽带密排平面阵声辐射分析

应用声有限元-边界元法计算了宽带基阵声场分布.建立了平面9元阵有限元-边界元模型,给出了阵元之间互阻抗数值计算方法,分析了阵元间互辐射对声性能影响的变化规律,计算了9元阵3个谐振频率点处指向性和波束宽度.利用3谐振换能器研制出一种宽带密排平面9元阵,并在消声水池中对其输入阻抗和指向性进行了实验测量.研究结果表明,按阵元...     

斜置平面天线阵的近场-远场方向图分析

从平面近场扫描数据处理原理和平面天线阵方向图理论出发,分析了相对于平面近场扫描平面斜置的平面天线阵方向图.基于斜置平面天线阵的空间结构关系,选择阵面旋转轴与阵面法线形成的平面为性能评估考察平面,发展了一种快速计算性能评估平面方向图的方法.得出该平面与平面近场扫描坐标系单位方向球相交曲线的轨迹参数方程.利用快速傅里叶变换技术,计算出斜置平面天线阵平面近场扫描空间方向图,在此基础上结合轨迹参数方程和二维插值方法解出对应该性能评估平面的方向图数据.数值仿真和实际应用结果表明该分析结论和方法的可靠性与实用性.     

径向剪切干涉法综合诊断光束质量研究

 为了解决高功率激光装置光束质量诊断系统的自验证问题，研究了基于空间相位调制的径向剪切干涉法综合诊断光束质量的实验应用。该方法理论上只需一台干涉仪且从单幅干涉图中获取光束的近场、相位和远场分布信息。实验结果表明，目前可以得到高分辨率的相位分布，由测量近场和相位恢复出的远场同CCD直接测量得到的远场形态相同，环围能量比曲线相当吻合，不足之处在于只能提取近场较低空间频率成分，还达不到CCD直接测量的空间分辨水平。     

基于光导微探针的近场/远场可扫描太赫兹光谱技术

太赫兹技术已经成为涉及公共安全、军事国防和国民经济等国家核心利益的前沿研究领域.以往太赫兹测量技术中通常以远场测量为主,如常用的太赫兹时域光谱仪.近年来太赫兹近场技术得到了迅猛的发展,特别是基于光导天线的探针技术的发展,为可扫描的太赫兹近场测量提供了可能.本文详细报道了我们近期在可扫描太赫兹近场光谱仪研究中的进展.采用光纤耦合的光导微探针实现了方便灵活的太赫兹近场/远场三维扫描,并同时获得振幅和相位信息.该系统将有可能广泛应用于人工微结构、石墨烯、表面等离子激元、波导传输、近场成像、生物样品检测、芯片检测等研究领域.     

单壁碳纳米管束针尖增强近场拉曼光谱探测实验研究

针尖增强近场拉曼光谱术是最近发展起来的光谱技术.金属探针在获得样品纳米局域表面形貌的同时,受激光激发,在针尖附近产生增强电磁场,得到与形貌位置精确对应的针尖增强局域拉曼光谱,形貌和光谱的结合实现了纳米局域的光谱指认.文章建立了一套针尖增强近场拉曼光谱测龋装置,并用此装置对电弧法合成的单壁碳纳米管进行了近场拉曼光谱探测.测量了直径为100 nm单壁碳纳米管束的针尖增强拉曼光谱,进一步得到至多3根单壁碳纳米管的近场拉曼光谱,实现了超衍射分辨光谱探测.通过与远场拉曼光谱比较发现,针尖增强近场拉曼光谱的增强因子大于230倍.实验证明,同时具有超衍射空间分辨和拉曼光谱信号增强能力的针尖增强近场拉曼光谱术将是纳米材料和纳米结构表征的一种重要方法.     

Near-field radiative heat transfer between two plane surfaces with one having a dielectric coating

The effect of a dielectric coating on the near-field radiative heat transfer between two plane surfaces is numerically studied in the framework of the fluctuational electrodynamics. The dielectric coating is assumed to be a SiC or SiO₂ film, which is on top of the emitter. The results show that the near-field radiative flux between the plane surfaces can be either diminished or enhanced by the dielectric coating, depending on the thermal radiative properties of the emitter and the receiver. Furthermore, the dielectric coating effect on the near-field radiative flux can be very different from that on the far-field radiative flux. Detailed analysis on the variations of the TE- and TM-wave components of the radiative flux by adding the dielectric coating is provided, along with the physical mechanisms that account for these changes. Dielectric coatings such as SiC and SiO₂ films are widely seen in microelectronic structures and nanofabrication devices. The results obtained in this work should be valuable for further study and nanotechnological applications of near-field radiative heat transfer.     

计算线源声参量阵辐射场的新方法

本文提出一种计算惠更斯积分的新方法,并利用它来研究线源声参量阵。首先将点源函数展开为一个算符对平面波函数的运算,经过计算证明,如果将这个算符对参量阵远场解进行运算,得到的结果即为线源参量阵辐射场的解。其次证明,参量阵的夫琅和费远场解及菲涅耳修正解都可由本文导出,并且证明,菲涅耳修正只是对半束宽角以外的场有贡献。本文还计算了截断参量阵的辐射场,结果表明,这种阵的近场指向性随距离的减小而变尖锐。并且可以预料,实际参量阵辐射场的性质取决于下述三个场参量:kRsin²θ,βR和R_{1 关键词：}     

Near-field characteristics of the parametric loudspeaker using ultrasonic transducers

A parametric speaker is a device for generating and focusing highly directional sound beams. It is essentially a by-product that comes with the nonlinearity of ultrasound. It is noteworthy that this directional beam was controlled and utilized mostly for far-field applications in the past. We empirically study the directivity and attenuation characteristics of the parametric loudspeaker in the near-field where we desire to use it. Physical parameters for experiments are imported from a theoretical model based on the far-field approximation. The findings are that increases in aperture size and modulation frequency cause higher directivity, but have more than twice the beamwidth of the far-field approximation. The attenuation also does not obey the inverse-square law which describes far-field spreading from acoustic sources. The results conclusively explain a series of formation and attenuation of the virtual sound sources and define limitations of use in the near-field.     

Role of fluctuational electrodynamics in near-field radiative heat transfer

The objective of this paper is to discuss the role of fluctuational electrodynamics in the context of a generalized radiative heat transfer problem. Near-field effects, including the interference phenomenon and radiation tunneling, are important for applications to nanostructures. The classical theory of radiative transfer cannot be readily applied as the feature size approaches the dominant wavelength of radiative emission. At all length scales, however, propagation of radiative energy is properly represented by the electromagnetic wave approach, which requires the solution of the Maxwell equations. Fluctuational electrodynamics provides a model for thermal emission when solving a near-field radiation heat transfer problem, and the fluctuation-dissipation theorem provides the bridge between the strength of the fluctuations of the charges inside a body and its local temperature. This paper provides a complete and systematic derivation of the near-field radiative heat flux starting from the Maxwell equations. An illustrative example of near-field versus far-field radiation heat transfer is presented, and the length scale for transition from near- to far-field regime is discussed; the results show that this length scale can be as large as three times than predicted from Wien's law.     

Near-field and far-field modeling of scattered surface waves. Application to the apertureless scanning near-field optical microscopy

The detection of surface waves through scanning near-field optical microscopy (SNOM) is a promising technique for thermal measurements at very small scales. Recent studies have shown that electromagnetic waves, in the vicinity of a scattering structure such as an atomic force microscopy (AFM) tip, can be scattered from near to far-field and thus detected. In the present work, a model based on the finite difference time domain (FDTD) method and the near-field to far-field (NFTFF) transformation for electromagnetic waves propagation is presented. This model has been validated by studying the electromagnetic field of a dipole in vacuum and close to a dielectric substrate. Then simulations for a tetrahedral tip close to an interface are presented and discussed.     

Fourier treatment of near-field synchrotron radiation theory

In this paper, we couple synchrotron radiation (SR) theory with a branch of physical optics, namely laser beam optics. We show that the theory of laser beams is successful in characterizing radiation fields associated with any SR source. Both radiation beam generated by an ultra-relativistic electron in a magnetic device and laser beam are solutions of the wave equation based on paraxial approximation. It follows that they are similar in all aspects. In the space-frequency domain SR beams appear as laser beams whose transverse extents are large compared with the wavelength. In practical situations (e.g. undulator, bending magnet sources), radiation beams exhibit a virtual “waist” where the wavefront is often plane. Remarkably, the field distribution of a SR beam across the waist turns out to be strictly related with the inverse Fourier transform of the far-field angle distribution. Then, we take advantage of standard Fourier Optics techniques and apply the Fresnel propagation formula to characterize the SR beam. Altogether, we show that it is possible to reconstruct the near-field distribution of the SR beam outside the magnetic setup from the knowledge of the far-field pattern. The general theory of SR in the near-zone developed in this paper is illustrated for the special cases of undulator radiation. Using known analytical formulas for the far-field pattern and its inverse Fourier transform we find analytical expressions for near-field distributions in terms of far-field distributions.     

利用近场MVDR双聚焦波束成形方法实现被动测距

本文分析了近场环境下基于双聚焦波束成形的水下被动测距方法。通过修正MVDR方向矢量,得到了适用于近场环境的MVDR。仿真实验证明近场MVDR双聚焦波束成形测距方法优于普通波束成形和远场MVDR双聚焦波束成形,能明显减小目标距离估计的模糊区域。在相邻两个日标的定位性能上,MVDR双聚焦波束成形技术也比MVDR单聚焦系统体现出更大的优势,能较好地分辨目标。     

Near-field probing of photonic crystals

Photonic crystals form an exciting new class of optical materials that can greatly affect optical propagation and light emission. As the relevant length scale is smaller than the wavelength of light, sub-wavelength detection forms an important ingredient to obtain full insight in the physical properties of photonic crystal structures. Spatially resolved near-field measurements allow the observation of phenomena that remain hidden to diffraction-limited far-field investigations. Here, we present near-field investigations in both collection and illumination modes that highlight the power of local studies. We show how propagation losses are unambiguously determined and that light detected in far-field transmission can actually contain contributions from different, sometimes unexpected, local scattering phenomena. Simulations are used to support our findings. Furthermore, it is shown that local coupling of light to a thick three-dimensional photonic crystal is position-dependent and that the spatial distribution of the coupling efficiency itself is frequency-dependent.     

采用DDS的近场扫描光学显微镜探针-样品的纳米距离检测

近场扫描光学显微术中, 近场距离的检测和控制是需要解决的核心技术之一. 本文研究了基于DDS驱动的压电传感器, 在一个压电陶瓷片上, 电极被分成相同的两部分, 分别用于振动驱动和振幅检测. 近场扫描的光纤探针固定于此压电陶瓷片上. 振动驱动信号采用DDS, 在样品的远场时, 可以通过频率扫描得到误差在0.006 Hz以内的压电陶瓷片谐振频率驱动信号, 而当光纤探针处于样品的近场距离之内时, 压电陶瓷片的谐振频率偏离驱动信号频率, 振幅明显减小, 从而检测出近场距离. 高精度振动驱动源DDS和高灵敏度压电传感器的采用提高了检测灵敏度和工作稳定性.