耳蜗结构对低频信号频散特性的影响

耳蜗是人体最为精密的力学元器件,能处理频率从几十到几万赫兹的声信号.实验研究表明,声波进入耳蜗后,沿着基底膜传播,基底膜能够将不同频率的声信号分散到不同的位置,并为位于基底膜上的毛细胞所感知,就像一个天然的Fourier(傅里叶)滤波器.在von Békésy行波理论框架体系下,基于Manoussaki等的三维螺旋基底膜流固耦合耳蜗模型,考虑耳蜗导管高度和基底膜刚度均为纵向梯度变化,推导出基底膜声波传播的频散方程,分别分析了基底膜刚度和耳蜗导管高度对频散特性的影响.发现耳蜗内淋巴液的存在大大提高了耳蜗对低频信号的处理能力,且捕获频率随基底膜刚度和耳蜗导管高度的减小而降低,两者梯度变化在声信号调制中起协同作用.最后,以人、沙鼠和豚鼠的具体耳蜗参数为例,得到3种生物耳蜗频率-点位图,并验证了低频段模型预测的正确性,比较分析了耳蜗频散功能与生物适应性之间的关系.     

Fabrication of large-scale ripples on fluorine-doped tin oxide films by femtosecond laser irradiation

The large-scale uniform self-organized ripples are fabricated on fluorine-doped tin oxide （FTO） coated glass by femtosecond laser. They can be smoothly linked in a horizontal line with the moving of XYZ stage by setting its velocity and the repetition rate of the laser. The ripple-to-ripple linking can also be realized through line-by-line scanning on a vertical level. The mechanism analysis shows that the seeding effect plays a key role in the linking of ripples.     

一种模拟动边界绕流的锐利界面浸入边界法

When the structural wall moves over a fixed grid, the structure coverage will change, resulting in many dead and emerging elements. To avoid the influence of malformation and reconstruction of body-fitted grids on the calculation efficiency and accuracy of the fluid-structure interaction problems with coupled boundary movement on the fixed grid, an improved numerical method for describing the interaction between an immersed rigid body and fluid based on a sharp-interface is proposed. In this method, both the fluid and solid are regarded as pure fluid domains in the whole computational domain, and the solid boundary is divided into several Lagrangian grid points. The flow parameter or velocity is reconstructed by interpolation at the interface element, which is then directly used as the boundary condition of the flow field, thus reflecting the influence of the wall boundary conditions. The method constructs the calculation structure of “virtual point, force point and vertical foot point”, and the velocity of the virtual point is obtained by bilinear interpolation. Then, the velocity of the force point is calculated by forcing the solid boundary to meet the no-slip condition, and the equations of the coupling system based on the immersion boundary method are finally solved to realize the numerical simulation of the flow with a complex moving boundary. The numerical program for this immersed boundary method is established using C++, then the accuracy and reliability of the proposed method are validated by comparison with the literature and experimental results of the basic numerical example of flow around a cylinder. Furthermore, the effects of the structural shape and the angle of attack on the trailing vortex structure, the vortex shedding frequency, and the lift/ coefficient characteristics of the flow around the elliptical cylinder have been analyzed. The anti-symmetric S-type, “P+S” Ⅰ-type and “P+S” Ⅱ-type trailing vortex shedding modes, as well as the variation laws of the vortex structure size, vortex shedding frequency and lift-drag coefficients ratio with axis ratio and angle of attack, are captured. The critical angle of attack (25°) corresponding to the maximum lift-drag ratio is determined as 25°.     

轧机主传动系统扭振响应数值模拟及结构失效研究

轧机主传动系统是轧制过程中传递运动和力矩的主要装置,其扭转振动(扭振)是影响钢铁生产质量并导致关键零部件异常破坏的重要原因之一。基于ANSYS有限元软件,针对轧机主传动扭振系统进行数值模拟及结构失效分析。首先,对轧机主传动系统进行模态分析,获得扭振系统固有属性关系;然后,通过谐响应分析得出不同位置零部件的频域响应曲线;最后,对易损部位关键零部件件进行结构失效原因分析,将数值计算结果与实际情况相结合,以验证分析结果的准确性与可靠性。研究结果可为轧机主传动扭振系统中零部件结构优化和进一步动态控制策略的制定提供重要理论参考。     

用功的互等定理求解矩形薄板的自然频率

从虚功原理出发，证明了薄板小挠度弯曲问题的功的互等定理，并由此推出了求解矩形薄板自然频率的公式．算例表明，该公式计算简便，精度较高．     

电磁探测技术在冰层厚度检测中的应用探究

根据海冰、内陆湖泊、河流、冰川等冰资源与环境中的自然科学问题及冬季结冰地区水工结构物安全运行管理中对冰层厚度时空变化资料的需求,基于电磁场的特有性质,讨论了可用于冰层厚度检测的两种电磁探测方法-时间域电磁法和频率域电磁法,较详细讨论了它们的工作原理、研究进展、适用范围和在冰层厚度检测中获得的初步应用结果,并通过对实际测量结果的分析比较,提出了频率域电磁法,相对于时间域电磁法,在冰层厚度检测中具有更多的优势.     

冰层厚度探测的频率域电磁法研究

根据冰层厚度探测的实际需要,研究了频率域电磁法的冰层厚度探测系统.系统是利用频率域电磁法的基本原理设计,同时,利用椭圆率来消除一次场的影响,可实现一次和二次磁场的分离提取、数据采集等模块功能.并且在实验室对传感器的电流发射部分和数据接收部分进行了试验,与理论数据进行比对.实验结果表明,系统可实现冰层厚度检测和生消变化过程检测.     

基于频率调制激光驱动的囚禁离子几何相位逻辑门

为了避免激光相位的起伏对几何相位逻辑门保真度的影响, 提出一种基于囚禁离子的量子几何相位逻辑门的新方案。该机制是利用一束频率调制的行波激光场作用于两个囚禁离子上实现的。它的优点有：操作简单,仅需一步就能实现。不灵敏于激光场的相位也不需要对囚禁离子进行个别寻址。     

频率-电流扫描3ω法表征纳米薄膜界面热阻

纳米薄膜与基体之间的界面热输运是MEMS系统热管理和热设计的热点和难点。建立了频率扫描3ω法的热阻抗网络模型。利用频率-电流扫描3ω法和不同厚度薄膜试样得到单层纳米薄膜与基体之间的界面热阻。ZrO_2、SiO_2增透膜与基体之间的界面热阻分别为0.108 m~2·K·MW~(-1)和0.066 m~2·K·MW~(-1)。发现界面热阻与扫描频率无关,未发现界面热阻随膜厚变化的尺度效应。实验和理论分析表明,声子近界面效应在增透膜和基体界面的热输运过程中起主导作用。     

基于光纤的光学频率传递研究

随着光钟研究的发展, 光钟的稳定度和不确定度均达到10^-18量级. 通过光纤可以实现光钟频率信号的高精度传输, 有望用于未来“秒”定义的复现. 演示了百公里级实验室光纤上的光学频率传递. 对于在实验室70 km光纤盘上实现的光频传递, 光纤相位噪声抑制在1-250 Hz傅里叶频率范围内均接近于光纤延时极限, 对应传输稳定度(Allan偏差)为秒级稳定度1.2×10^-15, 10000 s稳定度为1.4×10^-18. 实验室100 km光纤的光频传递秒级稳定度也达到了5×10^-15. 提出了光纤噪声用户端补偿的方案, 可以简化星形传递网络中心站的复杂度. 在25 km光纤上演示了该传递方案, 实现的传输稳定度接近传统前置补偿传递方案.