单站两坐标雷达空间目标跟踪新算法研究

在以常规卡尔曼滤波器为基础的各种跟踪算法中，要求精确的模型和噪声统计，但在实际问题中，大多数情况上述要求不能满足。本文给出了考虑初始条件不精确性的改进型卡尔曼滤波算法，并在引入速度量测信息的基础上，运用该滤波方法进行空间目标二维定位。蒙特卡洛仿真表明该方法降低了对模型精度的要求，在工程上是可行的。     

基于体全息技术的WDM器件

利用体全息技术制作波分复用器件是一种新方法。本文介绍了此种方法的基本原理和器件的基本性能，并报道了国外对该项技术的研究进展。     

数字图像纯位相编码分析

研究了图像傅立叶变换过程中的振幅与位相问题，突出了位相在整个变换中的重要性，并利用双位相函数对图像进行加密编码和解码，计算机模拟表明双位相编码和解码能有效的抑制附加噪声。     

LonWorks现场总线技术及应用

简要介绍了现场总线技术的发展与现状；详细论述了LonWorks技术的特点；深入阐述了LON网络的构成和LonTalk协议；并构建了一个基于LoWorks现场总线的楼宇自动化系统。     

机械力化学法制备Pb(Sc0.5Ta0.5)O3弛豫铁电陶瓷微粉

用机械力化学法合成了单相Pb(Sc0.5Ta0.5)O3（R）弛豫铁电陶瓷微粉，并对球磨5h得到的陶瓷粉体和未经球磨的原料进行了热处理研究，实验结果表明，单相Pb(Sc0.5Ta0.5)O3可在球磨7h得到，TEM图像显示，晶粒尺寸为30－40mm，与根据Scheerer公式计算的结果吻合，5h粉体的热处理结果显示，焦绿矿相并未因球磨过程而在煅烧中不出现，原 粉体的热处理结果也显示出焦绿矿在1350℃温度下煅烧4h，仍有少量存在，比较实验的结果表明，在制备Pb(Sc0.5Ta0.5)O3的过程中，初始原料必须经过充分球磨才可实现单相目标产物的合成。     

丙丁烷TDLAS测量系统的吸收峰自动检测

基于丙丁烷在3.37μm处的基频吸收峰,使用相应中心波长的连续带间级联激光器和长光程吸收池,研制了基于波长调制技术的丙丁烷气体检测系统。为自动确定波长调制过程中的锯齿波中心值参数,基于电流与输出光频率的线性关系,通过均匀增加激光器驱动电流获得直接吸收光谱。使用基于洛伦兹线型的拟合算法确定吸收峰值对应电流,使锯齿波输出光以其为中心覆盖吸收峰。实验证明,以拟合结果31.94mA为中心值的锯齿波,在叠加频率为20 000Hz、幅值为0.03V的高频正弦调制波后,系统二次谐波峰值超过100mV。算法全过程不依赖标气和F-P标准具等精密光学器件,可适应实际生产条件下的系统自动定参。     

小鼠在体皮下乳腺癌的太赫兹波成像检测研究

乳腺癌是女性常见癌症之一,乳腺癌区域的精准检测对乳腺癌的治疗有至关重要的作用。本文采用频率为2.52THz的连续太赫兹波反射式成像系统,对小鼠在体皮下乳腺癌模型进行了太赫兹波成像检测。研究结果表明,太赫兹波成像可以清晰识别出乳腺癌区域,且与肉眼可见肿瘤区域一致。在体乳腺癌区域的太赫兹波相对反射率高于正常组织,两者相对反射率差值高达15%。进一步,对距离皮肤表面不同深度的离体乳腺癌组织进行切片和苏木精-伊红(H&E)染色,作为金标准对照。结果发现乳腺癌区域的面积随着距离皮肤表面深度的增加而增大。通过将太赫兹波成像与H&E染色结果对比可知,在距离皮肤表面约460μm处,太赫兹波图像和H&E染色图中的肿瘤区域面积相等。由此可知,太赫兹波对在体皮下乳腺癌的探测深度大约在460μm左右,太赫兹波有望实现深部肿瘤的检测。     

Photothermal Janus Anode with Photosynthesis‐Shielding Effect for Activating Low‐Temperature Biological Wastewater Treatment

Biological wastewater treatment (BWT), which is used to manage global wastewater, suffers from a sharp decrease in microbial activity at low temperature (<10 °C). Photothermal technology with a high energy efficiency theoretically exceeding 80% has the potential to activate low‐temperature BWT. However, photothermal BWT is threatened by the propagation of photosynthetic algae in wastewater under irradiation, and these microorganisms can suppress the functional bacteria or even kill anaerobic species by photosynthetically releasing oxygen. Herein, taking microbial fuel cells (MFCs) as a representative biological reactor, a photothermal Janus anode (PTJA) is designed, composed of a carbon black/polydimethylsiloxane photothermal nonporous layer and a graphite felt porous layer to promote low‐temperature BWT. Unlike traditional symmetrical porous anodes, the nonporous layer of the PTJA can isolate the wastewater in the porous layer from light irradiation during photothermal conversion, thus preventing photosynthetic algae from poisoning anaerobic functional microbes. Under ≈1 sun illumination, the PTJA MFC exhibits 1.6 and 24.2 times higher organic pollutant removal rate and power density generation, respectively, than MFCs using traditional anodes for low‐temperature BWT (7.0 ± 2.0 °C). This development can allow novel utilization of solar energy and is a promising resolution for low‐temperature BWT.     

Electrocatalytic Interlayer with Fast Lithium–Polysulfides Diffusion for Lithium–Sulfur Batteries to Enhance Electrochemical Kinetics under Lean Electrolyte Conditions

Lithium–sulfur batteries are promising energy‐storage devices because of their high theoretical energy densities. For practical Li–S batteries, reducing the amount of electrolyte used is essential for achieving the high energy densities. However, reducing the electrolyte amount leads to severe performance degradation, mainly because of sluggish deposition of discharge products (Li₂S) and the accompanying passivation issue that arise from the insulating nature of Li₂S. In this study, a lightweight, robust interlayer, with a 3D open structure and a low surface area is designed and fabricated. The structure facilitates electrolyte infiltration without trapping too much electrolyte. Moreover, the electrocatalytic Co nanoparticles embedded in the skeleton surface within the interlayer effectively promote Li ion diffusion, polysulfides conversion, and Li₂S deposition, and therefore enhance the electrochemical kinetics under lean electrolyte conditions. The mechanisms involved in the interlayer effects are investigated by microstructural characterizations, electrochemical performance tests, density functional theory calculations, and in situ X‐ray diffraction characterization. These results show the feasibility of using an interlayer strategy to improve the electrochemical performances of Li–S batteries under lean electrolyte conditions to potentially increase the practical energy densities of Li–S batteries.     

The First Flexible Dual‐Ion Microbattery Demonstrates Superior Capacity and Ultrahigh Energy Density: Small and Powerful

Humans live today in a high‐tech and informationalized society. With the development of the emerging electronic information age, various electronic systems are inclined to be multifunctional and miniaturized. It is urgent to develop “small and powerful” micro‐batteries with flexibility and high electrochemical performance to meet the diverse needs of microelectronic components. However, low electrochemical performance exists in traditional microenergy storage devices, which fail to satisfy the energy needs for microdevices. Here, for the first time, a planar integrated flexible rechargeable dual‐ion microbattery (DIMB) is reported, which is fabricated from an interdigital pattern of graphite as an electrode and lithium hexafluorophosphate as an electrolyte. As a microbattery, the DIMB exhibits a high reversible capacity of 56.50 mAh cm^?3, and excellent cycle stability with 90% capacity retention after 300 cycles under a high working voltage. The application of DIMB in microdevices, such as light‐emitting diodes (LEDs), digital electronic game consoles, and electrochromic glasses is also investigated, fully demonstrating its “small and powerful” performance. The integrated DIMB is a high‐voltage microdevice that reaches a nonpareil discharge voltage of about 100 V and a charging capacity of 102 mAh g^?1. This dual ion‐based flexible microbattery could become a promising candidate for energy storage and conversion components in next‐generation microelectronic devices and integrated electronic devices.