Parameterized time-frequency analysis to separate multi-radar signals

Multi-radar signal separation is a critical process in modern reconnaissance systems. However, the complicated battlefield is typically confronted with increasing electronic equipment and complex radar waveforms. The intercepted signal is difficult to separate with conventional parameters because of severe overlapping in both time and frequency domains. On the contrary, time-frequency analysis maps the 1D signal into a 2D time-frequency plane, which provides a better insight into the signal than traditional methods. Particularly, the parameterized time-frequency analysis (PTFA) shows great potential in processing such non stationary signals. Five procedures for the PTFA are proposed to separate the overlapped multi-radar signal, including initiation, instantaneous frequency estimation with PTFA, signal demodulation, signal separation with adaptive filter and signal recovery. The proposed method is verified with both simulated and real signals, which shows good performance in the application on multi-radar signal separation.

Spatial transformation of general sampling-aliasing frequency region for rotating-blade parameter identification with emphasis on single-probe blade tip-timing measurement

Blade-health monitoring is intensely required for turbomachinery because of the high failure risk of rotating blades.Blade-Tip Timing(BTT)is considered as the most promising technique for operational blade-vibration monitoring,which obtains the parameters that characterize the blade condition from recorded signals.However,its application is hindered by severe undersampling and stringent probe layouts.An inappropriate probe layout can make most of the existing methods invalid or inaccurate.Additionally,a general conflict arises between the allowed and required layouts because of arrangement restrictions.For the sake of economy and safety,parameter identification based on fewer probes has been preferred by users.In this work,a spatial-transformation-based method for parameter identification is proposed based on a single-probe BTT measurement.To present the general Sampling-Aliasing Frequency(SAFE)map definition,the traditional time-frequency analysis methods are extended to a time-sampling frequency.Then,a SAFE map is projected onto a parameter space using spatial transformation to extract the slope and intercept parameters,which can be physically interpreted as an engine order and a natural frequency using coordinate transformation.Finally,the effectiveness and robustness of the proposed method are verified by simulations and experiments under uniformly and nonuniformly variable speed conditions.

MODAL PARAMETERS EXTRACTION WITH CROSS CORRELATION FUNCTION AND CROSS POWER SPECTRUM UNDER UNKNOWN EXCITATION

In most of real operational conditions only response data are measurable while the actual excitations are unknown, so modal parameter must be extracted only from responses. This paper gives a theoretical formulation for the cross-correlation functions and cross-power spectra between the outputs under the assumption of white-noise excitation. It widens the field of modal analysis under ambient excitation because many classical methods by impulse response functions or frequency response functions can be used easily for modal analysis under unknown excitation. The Polyreference Complex Exponential method and Eigensystem Realization Algorithm using cross-correlation functions in time domain and Orthogonal Polynomial method using cross-power spectra in frequency domain are applied to a steel frame to extract modal parameters under operational conditions. The modal properties of the steel frame from these three methods are compared with those from frequency response functions analysis. The results show that the modal analysis method using cross-correlation functions or cross-power spectra presented in this paper can extract modal parameters efficiently under unknown excitation.

翼伞系统最优归航轨迹设计的敏感度分析方法

本文对三自由度翼伞系统归航轨迹优化问题进行了研究,采用控制变量参数化与时间尺度变换相结合的优化算法对翼伞系统的最优控制问题进行数值求解.该方法是基于灵敏度分析的优化算法,将控制量以及控制量转换时间转化为一系列参数优化问题同时进行求解.仿真结果表明,相对于基于两端边值优化算法而言,灵敏度分析法只需要正向积分进行求解,因而具有计算简单、耗时短等优点,其控制效果良好,距离偏差和方向偏差均满足实际需求,有效地提高了翼伞系统的着陆精度,验证了该优化算法的可行性.

基于能量归一化窗的S变换及应用

为了克服标准S变换对时频谱能量的"加权效应",构造了一种归一化窗S变换。它的窗函数满足能量归一化条件,减少了对高频分量的加权效应,而且可通过参数调整窗函数时宽。文中推导了归一化窗S正反变换的运算实现。模型信号的分析表明,归一化窗S变换在不损失时频分辨率的前提下,更能客观地反映非平稳信号中不同频率成分的能量分布特征,并可通过参数调整其时频分辨率。对实际地震信号的分析发现,它能更加真实地描述实际地震信号的高频衰减现象。

贝叶斯框架下的大坝变形交互式时变预测模型及其验证

大坝变形是同一时刻内外多重风险因素综合作用的结果,应用时序分析方法挖掘历史监测数据潜在规律是变形预测的常用方法,现有时变预测模型不仅参数配置难度高,且难以融入专业知识,导致预测效果并不理想。本文提出一种耦合自动预测算法与大坝专业知识的交互式变形预测模型。该模型在贝叶斯框架下,以加法模型为基础重构各时序分解项作为模型底层,根据仿真结果甄选模型参数缺省值进行自动预测,通过结合参数化检测与直观参数配置实现交互式建模,并借助拟合可视化和统计指标准确反映预测误差来源,从而进一步修正参数以提高模型适用性。基于上述流程协同构建的大坝变形循环预测体系,以某混凝土坝多测点长期变形监测数据为例,对模型的准确性、鲁棒性和灵活性进行了有效验证与分析,为大坝变形安全预测与分析提供了新的模型和手段。

基于参数化时频分析的进动锥裙目标瞬时微多普勒频率提取方法

微动目标散射点的微多普勒对目标运动、结构参数的估计具有重要意义。该文针对表面光滑的锥裙目标,首先依据进动锥裙目标的等效散射点模型,推导出散射点的理论微多普勒曲线表达式。结合进动调制的锥裙目标微多普勒曲线为多阶正弦级数叠加的先验信息,提出一种基于参数化时频分析的进动锥裙目标微多普勒曲线提取方法。针对多分量信号组成的锥裙目标回波,该方法利用相干信号单距离多普勒干涉(CSRDI)方法估计锥旋频率,进而利用参数化时频分析估计散射点的微多普勒曲线,之后利用带阻滤波器分离估计得到的散射点回波信号。基于电磁仿真数据验证了所提方法的有效性。

旋转机械转速波动检测及故障诊断

针对旋转机械运行转速波动导致信息获取及诊断决策困难问题,以非平稳信号的瞬时频率估计为切入点,结合快速路径优化算法进行非平稳信号的瞬时频率估计,以实现转速波动信息的准确获取。基于参数化时频分析理论的短时阶比原理,依据估计的振动信号瞬时频率变化函数构造匹配旋转算子,将转速波动信号的时频特征进行旋转,获得各时频窗内的短时阶次谱,进而完整保留转速波动信号的瞬态信息。仿真及实验结果表明,该方法可以准确提取出旋转机械转速波动工况下的状态信息及故障特征,为后续故障精密诊断奠定基础。

共聚焦点道集偏移速度建模

偏移速度建模可在多种道集实现。基于等时原理和差异时移分析,提出了共聚焦点道集偏移速度建模方法。偏移速度的更新是利用约束参数迭代反演实现,模型的参数化主要依据实际情况而定。为适应横向变速,选用了垂直速度梯度参数。模型试算表明:偏移速度相对误差在0.25%范围内,反射层深度误差小于10m。

铝型材挤压模具交互式参数化实时设计系统的研究

在 VB开发环境下 ,构造了铝型材挤压模具的交互式参数化实时设计系统 ,可实现对铝型材挤压模具强度进行有限元分析的实时处理、人工神经网络技术与遗传算法相结合的结构优化及基于智能化语言 Auto LISP的参数化程序绘图。系统功能强 ,模块通用性好 ,图形库扩展性强 。

某80 m跨钢管桁架结构设计关键问题分析

以某试验厅80 m跨管桁架结构为例,对单榀管桁架进行参数化分析,并对整体结构进行弹性时程分析和关键节点的有限元分析。结果表明,结构是安全可靠的。同时,主桁架的参数化设计可以为截面选型提供参考,以确定合理的结构布置。

飞机舱内声品质的音色参数表达

为有效地描述噪声音色对飞机舱内声品质的影响,开展了3组主观评价实验:不相似度评价、语义细分和偏好度成对比较。首先,不相似评价实验表明,飞机舱内噪声的音色可由一个4维空间表示;然后,回归分析发现后2个维度与语义细分尺度具有关联,其中维度3可描述为"轰鸣的"和"低沉的",而维度4可描述为"刺耳的"和"有节奏的";接着,利用4个声学参数(噪度、ERB谱峰度、短时谱偏度和ERB谱变化)得到了音色空间每个维度的定量表达;最后,通过分析被试偏好度和4个音色参数间的关系,发现偏好度较高的声音具有较少的线谱、随机性较强,同时其频谱具有平坦对称的分布。

心率变异性的小波变换分析方法

本文利用小波变换方法对 Ｈ Ｒ Ｖ 信号进行分解， 在逆变换过程中用 Ｍ ａｌｌａｔ算法提取信号中的非１／ｆ部分， 最后利用信号差的方法将信号１／ｆ部分与其它信号分离， 最终提取出对于心率变异性具有重要研究价值的１／ｆ成分，为心率变异性的研究和分析提供有效分析依据，此法较之以往的基于 Ｃ Ｇ Ｓ Ａ 的分解方法具时频分析的特点， 而且可利用有限数据进行分析。

参数化塔形井架抗震性能分析与研究

为应对频发的海洋地震给石油钻井井架安全性带来的威胁,提出采用参数化塔形井架进行抗震性能分析的方法。首先利用ANSYS APDL对塔形井架进行参数化建模;其次引入时程分析法对塔形井架建立振动方程;最后将太平洋地震加速度波数据导入到ANSYS中利用APDL后处理功能,得到了海洋钻井平台塔形井架的参数化地震响应分析结果。最终证明塔形井架能够满足抗震性能的要求,为参数化海洋平台的研究提供了可行的方法。

流体管道水锤抑制的时间尺度变换控制

在流体管道运行中,打开的阀门突然关闭会造成管道内部流体对阀门及管壁的巨大压力冲击,这种现象叫做水锤效应,严重威胁流体管道的健康运行.基于此,本文研究了阀门关闭过程中抑制水锤效应的最优边界控制问题.水锤模型由一组非线性时空演化方程描述,本文首先通过半离散方法得到一个有限维模型.然后,采用分段一次线性控制变量参数化方法及灵敏度分析方法,结合时间尺度变换方法,推导其梯度形式.最后,结合非线性优化求解器,完成边界最优控制设计.仿真结果显示时间尺度变换方法能够更有效地抑制水锤效应.考虑到实际工程中的控制量为阀门相对开度,在得到阀门处的流量和压力的最优变化过程后,本文给出了阀门相对开度随时间的演化关系.

非平稳强噪条件下的视频相位放大技术研究

针对视频信号在非平稳和强噪声情况下,视频放大技术难以提取目标信号且会将频带内噪声同时放大的缺点,提出了一种基于参数化时频分析及主成分分析的滤波方法。将相变信号降维后,对降维信号做时频分析,提取其中的非平稳信号。不仅重构的信号具有良好的时频特性,且算法运算量也大大降低。实验结果表明,此方法在非平稳强噪信号提取方面具有明显优势。

Optimal Matching Control of a Low Energy Charged Particle Beam in Particle Accelerators

Particle accelerators are devices used for research in scientific problems such as high energy and nuclear physics.In a particle accelerator, the shape of particle beam envelope is changed dynamically along the forward direction. Thus, this reference direction can be considered as an auxiliary "time" beam axis. In this paper, the optimal beam matching control problem for a low energy transport system in a charged particle accelerator is considered. The beam matching procedure is formulated as a finite "time" dynamic optimization problem, in which the Kapchinsky-Vladimirsky(K-V) coupled envelope equations model beam dynamics. The aim is to drive any arbitrary initial beam state to a prescribed target state, as well as to track reference trajectory as closely as possible, through the control of the lens focusing strengths in the beam matching channel. We first apply the control parameterization method to optimize lens focusing strengths, and then combine this with the time-scaling transformation technique to further optimize the drift and lens length in the beam matching channel. The exact gradients of the cost function with respect to the decision parameters are computed explicitly through the state sensitivity-based analysis method. Finally, numerical simulations are illustrated to verify the effectiveness of the proposed approach.

基于灰色关联分析法的驾驶室结构轻量化优化设计

针对汽车结构轻量化优化时间长、变量筛选客观性差的问题,以某商用车驾驶室为研究对象,提出一种基于灰色关联分析法的驾驶室结构轻量化优化方法。首先,在隐式参数化建模软件SFE-Concept中建立商用车驾驶室隐式参数化模型,利用OptiStruct求解器对驾驶室模型进行基础性能分析;其次,结合有限元前处理软件HyperMesh重新划分驾驶室结构,以弹性模量为设计变量进行驾驶室结构灵敏度分析;再次,采用灰色关联分析法在试验设计之前筛选出33个零件厚度、截面变量;最后,构建径向基-响应面混合近似模型,利用序列二次规划算法进行驾驶室结构轻量化优化。优化结果表明:在弯扭刚度、一阶扭转模态频率基本不变的条件下,驾驶室质量降低24.5 kg,减轻了8.0%,一阶弯曲模态频率提升了13.9%,驾驶室结构轻量化优化效果较佳。

安康地区粮食产量预报模型研究

采用仿真技术和时间序列分析方法,建立了粮食产量参数化预报模型,并对模型的精度进行了检验,经4年的应用,预报的粮食产量的平均准确率为96.6%.

单机器人在协调系统中的轨迹规划问题研究

以协调机制下的单机器人为对象,提出了一种基于相平面的时间优化轨迹规划方法。通过对路径参数化,将具有多关节的机器人运动转换为单自由度的具有几何约束的最终运动。通过引入关节力矩输入约束,分析了轨迹规划中的可行性区域。在构造的速度-路径相平面中,利用动态搜索的方法在具有可行最大加减速度条件下规划其时间优化轨迹。以Motoman-UP6为模型,将本文方法与时间最短的轨迹规划方法进行比较,仿真结果证明该方法虽不能得到绝对的时间最短轨迹,但可以减少加减速运动的切换次数,保证机器人运行的平稳性。